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Egalware/EgtMachKernel:master Egalware/EgtMachKernel:NewLink Egalware/EgtMachKernel:Preview Egalware/EgtMachKernel:feature/Svuotature Egalware/EgtMachKernel:Sgrossature Egalware/EgtMachKernel:VmillAdditivo Egalware/EgtMachKernel:Svuotature_LeadIn/Out Egalware/EgtMachKernel:svuotature Egalware/EgtMachKernel:Drilling Egalware/EgtMachKernel:develop Egalware/EgtMachKernel:feature/SvuotatureConIsole Egalware/EgtMachKernel:Sara
Egalware/EgtMachKernel:2.7b3 Egalware/EgtMachKernel:2024/01/09 Egalware/EgtMachKernel:AutoSave_2024/03/08 Egalware/EgtMachKernel:AutoSave_2024/02/02 Egalware/EgtMachKernel:AutoSave_2024/10/01 Egalware/EgtMachKernel:SvuotatureConIsole
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Egalware/EgtMachKernel:master Egalware/EgtMachKernel:NewLink Egalware/EgtMachKernel:Preview Egalware/EgtMachKernel:feature/Svuotature Egalware/EgtMachKernel:Sgrossature Egalware/EgtMachKernel:VmillAdditivo Egalware/EgtMachKernel:Svuotature_LeadIn/Out Egalware/EgtMachKernel:svuotature Egalware/EgtMachKernel:Drilling Egalware/EgtMachKernel:develop Egalware/EgtMachKernel:feature/SvuotatureConIsole Egalware/EgtMachKernel:Sara
Egalware/EgtMachKernel:2.7b3 Egalware/EgtMachKernel:2024/01/09 Egalware/EgtMachKernel:AutoSave_2024/03/08 Egalware/EgtMachKernel:AutoSave_2024/02/02 Egalware/EgtMachKernel:AutoSave_2024/10/01 Egalware/EgtMachKernel:SvuotatureConIsole

278 Commits
develop ... Sgrossature

Author SHA1 Message Date
Riccardo Elitropi 3a71918a12 Merge commit '361eb4423612c3a65ef1033d76e5f095a579921e' into Sgrossature 2024-09-23 07:51:08 +02:00
Dario Sassi 361eb44236 EgtMachKernel : 
- in sgrossatura superfici VerifySubType ora accetta anche SURFROU_SUB_CONFORMAL_ONEWAY
- in svuotatura VerifySubType ora accetta aanche POCKET_SUB_CONFORMAL_ZIGZAG e POCKET_SUB_CONFORMAL_ONEWAY e li rimanda sui tipi standard.
 2024-09-20 14:21:52 +02:00
SaraP 037e3281a5 EgtMachKernel : 
- in fresatura con lama nel calcolo ingressi e uscite utilizzata anche info OutRaw.
 2024-09-19 15:49:33 +02:00
Dario Sassi 096a890c42 EgtMachKernel : 
- in svuotatura con aggregato da sotto corretta la verifica della distanza limite dal bordo
- nelle simulazioni migliorata visualizzazione collisioni con fixtures
- in fresatura standard di singola curva e in centro fresa con variazioni su geometria di lavorazione (info MVar) si emette l'indice EMT.IDX riferito alla geometria originale (1-based).
 2024-09-19 12:48:15 +02:00
Dario Sassi e779f874fc Merge commit '0ee84b1d1ae174054977df5c7e9a192ab8352d1b' 2024-09-19 12:34:04 +02:00
Riccardo Elitropi 0ee84b1d1a EgtMachKernel : 
- piccole migliorie.
 2024-09-19 09:04:55 +02:00
Riccardo Elitropi ddf18390a6 Merge commit 'b951536dfbbbb249acec08e71c4e042d37759364' into Sgrossature 2024-09-18 08:53:46 +02:00
SaraP b951536dfb EgtMachKernel : 
- in svuotature a spirale corretti i casi in cui il valore dell'offset è pari al valore limite per la curva.
 2024-09-17 10:43:51 +02:00
Dario Sassi 8e196fbfc6 EgtMachKernel 2.6i2 : 
- per aggregato da sotto aggiunta gestione approcci/retrazione di tipo 3 (prima parallelo al grezzo poi ruota a perpendicolare stando sotto e viceversa)
- ai punti aggiunti per garantire la precisione lineare con assi rotanti in movimento tolto flag 401 e impostato flag2 a -1
- nelle forature aggiustati i fori a step con i foratori multipli rotanti.
 2024-09-14 12:37:41 +02:00
Riccardo Elitropi fa6ae61eef Merge commit '431246b4724ae6ded129590a0e2a9fec19f1195d' into Sgrossature 2024-09-11 09:26:49 +02:00
Dario Sassi 431246b472 EgtMachKernel : 
- in svuotature chiuse migliorata scelta lato ottimale di inizio
- altri sviluppi in SimulatorMP.
 2024-09-09 09:30:14 +02:00
Dario Sassi 4b835a27be EgtMachKernel 2.6i1 : 
- introduzione secondo simulatore sperimentale per macchine multiprocesso.
 2024-09-05 08:29:20 +02:00
Riccardo Elitropi 3bfb6e3ffb Merge commit 'ac72518e4415e2bb79a2e90b3034018651d5ab54' into Sgrossature 2024-09-02 09:19:38 +02:00
Dario Sassi ac72518e44 EgtMachKernel : 
- corretti alcuni commenti.
 2024-08-30 16:34:08 +02:00
Dario Sassi b3895266a1 Merge commit 'f6afb6ac9c377b04b20ae81dc9887cc79b2c52c4' 2024-08-29 16:02:44 +02:00
Riccardo Elitropi f6afb6ac9c EgtMachKernel : 
- LeadIn/LeadOut mediante SafeZ.
 2024-08-29 10:41:17 +02:00
Dario Sassi b2b1206df1 Merge commit '5247e2d09706e7226c4823776bd3cdb62f4a4e26' 2024-08-23 09:19:49 +02:00
Riccardo Elitropi 5247e2d097 EgtMachKernel : 
- Aggiunta gestione punti iniziali in Sgrossature e Finiture.
 2024-08-22 12:56:42 +02:00
Riccardo Elitropi 3c48318ebe Merge commit '532746cf840522a9810551b9e3072c7d28522474' into Sgrossature 2024-08-22 12:55:12 +02:00
Dario Sassi 532746cf84 EgtMachKernel : 
- in simulazione ora si marcano con tipo diverso le parti che vanno in collisione.
 2024-08-22 09:13:11 +02:00
Riccardo Elitropi 7b0e3ddba2 Merge commit '45cf4129850edebba6862ec1e9eedc0b61d156d9' into Sgrossature 2024-08-22 08:21:38 +02:00
Dario Sassi 45cf412985 EgtMachKernel : 
- ore ZSAFEDELTA di testa per sole mortasature accetta un secondo valore che viene applicato quando l'inclinazione dall'orizzontale è minore di 45deg (default primo valore).
 2024-08-20 12:55:38 +02:00
Riccardo Elitropi 83366e8d33 Merge commit 'b1d0f10b55daef70fe556bc435c9f51c7287eb72' into Sgrossature 2024-08-19 08:08:22 +02:00
Dario Sassi b1d0f10b55 EgtMachKernel : 
- inserite diverse modalità di movimento assi nei link tra lavorazioni, per ora impostato sempre tutti interpolati tra loro.
 2024-08-07 14:28:14 +02:00
Dario Sassi 114c13d781 EgtMachKernel : 
- in sgrossatura superfici correzioni nell'applicazione dell'offset longitudinale.
 2024-08-07 09:42:47 +02:00
Dario Sassi a26846ed4f Merge commit 'c55962ae9b5edd05a13ad14ba3bb8f66cffabb41' 2024-08-06 18:44:51 +02:00
Riccardo Elitropi c55962ae9b EgtMachKernel : 
- piccola modifica.
 2024-08-06 15:05:48 +02:00
Riccardo Elitropi f9e121af32 Merge commit '450a37e4f3a0f124867165c6945ff8ad7e1db5fe' into Sgrossature 2024-08-06 15:05:14 +02:00
Dario Sassi 450a37e4f3 EgtMachKernel 2.6h1 : 
- aggiunta gestione SpecialEstimate (stima speciale lanciata in automatico prima di generare).
 2024-08-06 14:43:36 +02:00
Dario Sassi 5a4f77030c EgtMachKernel : 
- aggiunto flag in Ini macchina [Machinings] RapidOnOut=1 per abilitare approcci e retrazioni in rapido diretti su estremi fresature 1 passata fuori dal grezzo
- migliorata precisione nella verifica collisioni per link tra lavorazioni con vere geometrie utensile con nome Tool_* (Tool_C, Tool_S,...).
 2024-07-31 20:30:13 +02:00
Dario Sassi 5d945b983d Merge commit '0dee26360c567c18a2800dfb4ba077d06b69a54a' 2024-07-31 08:46:38 +02:00
Riccardo Elitropi 0dee26360c EgtMachKernel : 
- aggiunto parametro SURFROU_SUB_CONFORMAL_ZIGZAG.
 2024-07-30 18:35:22 +02:00
Riccardo Elitropi d0be3ec4dd EgtMachKernel : 
- aggiunto controllo per POCKET_CONFORMAL_ZIGZAG.
 2024-07-30 14:02:51 +02:00
Riccardo Elitropi 21e398cef7 Merge commit '46e52e09950db882602fdf54b0f4f676f900cbbf' into Sgrossature 2024-07-30 14:02:03 +02:00
Dario Sassi 46e52e0995 EgtMachKernel 2.6g8 : 
- minimo step per fori abbassato a 1mm.
 2024-07-30 11:45:24 +02:00
Dario Sassi 6348a40e18 EgtMachKernel 2.6g7 : 
- prime modifiche per gestire link tra lavorazioni con diverse modalità (per ora rimane la standard).
 2024-07-30 09:28:05 +02:00
Dario Sassi 68a92f942c EgtMachKerenel : 
- ulteriore modifica per controllo punto medio in calcolo assi macchina di tipo centro di lavoro.
 2024-07-29 10:15:38 +02:00
Riccardo Elitropi 8156cf92e5 Merge commit '82e464c481a4a3eb5ee8da89a073d12ae233d2c1' 2024-07-25 12:35:34 +02:00
Riccardo Elitropi 82e464c481 EgtMachKernel : 
- aggiunti percorsi di Bordo per Sgrossature ZigZag e OneWay.
- migliorie varie.
 2024-07-25 12:32:48 +02:00
Riccardo Elitropi 23d29eec0a Merge commit 'c8fe978a9669e2a506e74b5c316f6113c61dda85' into Sgrossature 2024-07-25 12:15:41 +02:00
SaraP c8fe978a96 EgtMachKernel 2.6g6 : 
- modifica provvisoria per problema in progetto marmo.
 2024-07-25 11:48:15 +02:00
Dario Sassi 6d742580fa EgtMachKernel : 
- in simulazione, generazione e stima aggiunti alcuni dati del movimento successivo.
 2024-07-23 16:31:36 +02:00
Dario Sassi c4ee2661b0 Merge remote-tracking branch 'origin/Sgrossature' 2024-07-23 12:38:41 +02:00
Dario Sassi c68d841b46 EgtMachKernel : 
- in simulazione migliorata scelta oggetti da visualizzare per collisione.
 2024-07-23 12:02:09 +02:00
Riccardo Elitropi 73f189e59d Merge commit 'db580f95d23c4efa3059c8158f401b6882449cd2' into Sgrossature 2024-07-23 11:54:07 +02:00
Riccardo Elitropi 34488601f2 EgtMachKernel : 
- migliorie varie.
 2024-07-23 11:53:46 +02:00
Dario Sassi db580f95d2 EgtMachKernel : 
- in simulazione dopo una collisione si evidenziano i gruppi che l'hanno prodotta, al riavvio del movimento si torna alla visualizzazione standard.
 2024-07-22 16:13:39 +02:00
Dario Sassi b1232ac9d3 Merge commit '4af6caf657ede99d3dc1507cad110d55936e827c' 2024-07-22 14:58:50 +02:00
Riccardo Elitropi 4af6caf657 EgtMachKernel : 
- migliorie LeadIn ed Entrate
- Semplificazione codice con funzioni in classe SurfFlatRegion.
 2024-07-22 11:44:45 +02:00
Dario Sassi 0ab121d217 Merge commit '4a2f6fa43980530393a28617d0b230f106150edd' 2024-07-19 12:04:59 +02:00
Riccardo Elitropi 4a2f6fa439 EgtMachKernel : 
- pulizia codice dopo il merge con ramo master.
 2024-07-19 12:04:00 +02:00
Riccardo Elitropi 1396303d5f Merge commit '8950f2aca1e4f7292dd46ccfd6e279a0a9a1f3ee' into Sgrossature 2024-07-19 10:18:52 +02:00
Riccardo Elitropi c3552d411f EgtMachKernel : 
- aggiunti controlli per limitazione percorsi alla curva di Pocketing
- migliorati i controlli LeadIn per Helix e ZigZag.
 2024-07-19 10:18:34 +02:00
Dario Sassi 8950f2aca1 EgtMachKernel 2.6g5 : 
- ricompilazione con cambio versione.
 2024-07-18 20:20:08 +02:00
SaraP 325482d50c EgtMachKernel 2.6g4 : 
- correzioni nuova modalità WaterJet.
 2024-07-18 09:53:44 +02:00
Dario Sassi 38b9433a97 EgtMachKernel : 
- raggio minimo per tab su fresatura portato da 100 a 50 mm.
 2024-07-17 17:20:12 +02:00
SaraP 9640415ff7 EgtMachKernel 2.6g3 : 
- in WaterJet aggiunta nuova modalità per angoli interni WJET_IC_SLOW_FULL.
 2024-07-17 14:22:38 +02:00
Dario Sassi b5682b4185 EgtMachKernel : 
- al salvataggio utensile per sole frese verifico e aggiusto corrispondenza tra feed di testa e sottotipo ( TT_MILL_STD o TT_MILL_NOTIP).
 2024-07-17 11:27:28 +02:00
Dario Sassi cd323ec583 EgtMachKernel : 
- piccola modifica a sgrossatura superfici.
 2024-07-16 08:39:23 +02:00
Dario Sassi 6333707386 Merge commit 'ff9a1dd55b9683a920fbb55a1af10691a101b3e7' 2024-07-15 17:04:46 +02:00
Riccardo Elitropi ff9a1dd55b EgtMachKernel : 
- Correzione OffsetL per superfici di Pocketing.
 2024-07-15 13:30:38 +02:00
Riccardo Elitropi 4048e2f09e Merge commit '3745da80c1f00ce0f8c63bda532177190c2a4fa2' into Sgrossature 2024-07-15 11:27:30 +02:00
Dario Sassi 3745da80c1 EgtMachKernel : 
- in sgrossatura superfici corretto calcolo P1 sopra elica di attacco per area successiva alla prima.
 2024-07-15 10:18:14 +02:00
Dario Sassi 068a1c9fb7 EgtMachkernel : 
- in finitura superfici silhouette approssimate con archi e reset proprietà curve dei contorni risultanti
- in sgrossatura superfici silhouette approssimate con archi e migliorie stilistiche.
 2024-07-15 07:10:26 +02:00
Dario Sassi abd9855823 Merge commit '05baa2f0fc33100a7b2d0e6165671436140b92dd' 2024-07-12 19:48:18 +02:00
Riccardo Elitropi 05baa2f0fc EgtMachKernel : 
- aggiunta la possibilità di non calcolare i percorsi ottinimizzati in lavorazioni che richiamano CalcPocketing.
 2024-07-12 17:37:52 +02:00
Riccardo Elitropi 7aa4e5ac32 Merge commit '846412f2561f2f7002d349e97bb7f0b12663abaa' into Sgrossature 2024-07-12 16:06:13 +02:00
Dario Sassi 846412f256 EgtMachKerenel : 
- ora SurfFinishing non calcola più le svuotature ma usa CalcPocketing.
 2024-07-12 08:47:20 +02:00
Dario Sassi bcfc71d5b9 Merge commit '6cfe0a2178d4bdb012e2a026816ea7be3f4a62e4' 2024-07-11 15:10:17 +02:00
Riccardo Elitropi 6cfe0a2178 EgtMachKernel : 
- correzione errore in RemoveChunksUnderTolerance.
 2024-07-11 12:48:59 +02:00
Riccardo Elitropi c0f84c1909 Merge commit '5ecfe9ec58f7d82bf98fca21773a1dba49f8cda7' into Sgrossature 2024-07-11 09:02:14 +02:00
Dario Sassi 5ecfe9ec58 EgtMachKernel : 
- modifiche a finiture di superficie.
 2024-07-11 09:00:48 +02:00
Dario Sassi f53bf7a7ce Merge commit 'f81bff5254339c1d64eb8873df2488784ba40ff6' 2024-07-10 13:21:38 +02:00
Riccardo Elitropi f81bff5254 EgtMachKernel : 
- Aggiunta inversione dei percorsi.
 2024-07-10 12:36:24 +02:00
Dario Sassi 6c3a7e7dbb Merge commit 'ee7b9c9562a8ab1ebb440e7b9152900a0498f546' 2024-07-10 12:07:02 +02:00
Riccardo Elitropi ee7b9c9562 EgtMachKernel : 
- aggiornamento Feed tra steps.
 2024-07-10 10:28:10 +02:00
Riccardo Elitropi b65a119731 Merge commit '7a51dae75351087736aaa5f5219f8d96801db5fd' into Sgrossature 2024-07-10 08:03:32 +02:00
Dario Sassi 7a51dae753 EgtMachKernel : 
- in finitura superfici corretto calcolo esterno di inizio e fine per movimento ortogonale di attacco e uscita.
 2024-07-09 20:19:01 +02:00
Riccardo Elitropi 658018bed8 EgtMachKernel : 
- rimozione memory Leak.
 2024-07-09 11:07:28 +02:00
Riccardo Elitropi 9d68ea5057 Merge commit 'de5782f2a520bf718fcbb076798b3b8e9513d11f' into Sgrossature 2024-07-09 08:35:50 +02:00
Dario Sassi de5782f2a5 EgtMachkernel : 
- corretto errore in taglio con lama prodotto dall'aggiunta di vtFaceUse (24/06/24).
 2024-07-08 18:51:52 +02:00
Dario Sassi 375a7f4636 EgtMachKernel 2.6g2 : 
- in sgrossatura superfici corretti approcci ai vari step e feed di discesa in aria
- in calcolo movimenti 5assi corretto controllo punto medio (sbagliato con tavole mobili).
 2024-07-08 17:04:14 +02:00
Dario Sassi 6755753509 Merge commit '608918b619896f868c1a4eb5ce0313a3d39d7125' 2024-07-08 13:20:13 +02:00
Riccardo Elitropi 608918b619 EgtMachKernel : 
- migliorie su SubSteps per aggiornamento regioni di Pocket.
 2024-07-08 13:02:55 +02:00
Riccardo Elitropi 1b00139b8a Merge commit '8af2794f87927e4ca715f795beb877ccea72311b' into Sgrossature 2024-07-08 10:21:17 +02:00
Dario Sassi 8af2794f87 EgtMachKernel : 
- in sgrossatura superfici piccole migliorie.
 2024-07-08 10:18:33 +02:00
Dario Sassi 38635cade4 EgtMachKerenl : 
- in sgrossatura superfici piccola modifica su ENABLE_DEBUG.
 2024-07-08 09:10:22 +02:00
Dario Sassi bc373d2e33 EgtMachKernel : 
- in sgrossatura superfici piccola modifica per Zloc attacchi dei vari livelli con eliche e similari.
 2024-07-08 08:58:16 +02:00
Dario Sassi bc2baf17a7 Merge remote-tracking branch 'origin/Sgrossature' 2024-07-05 15:09:42 +02:00
Riccardo Elitropi 2017d45b99 Merge commit 'ce827dc0f3fcdcaf6d1f65b251dc9758835a88f2' into Sgrossature 2024-07-05 10:52:46 +02:00
Riccardo Elitropi d02422474c EgtMachKernel : 
- Aggiunta Progress Bar in Sgrossature.
 2024-07-05 10:52:21 +02:00
Dario Sassi ce827dc0f3 Merge commit '7ff79c295a6ead6a95cee805fc0aa38dd700e013' 2024-07-05 09:33:35 +02:00
Riccardo Elitropi 7ff79c295a Merge commit '37d602c6d95d3d3918cadc4a69466e130b1212e4' into Sgrossature 2024-07-04 08:45:20 +02:00
Dario Sassi 37d602c6d9 EgtMachKerenl : 
- in sgrossatura superfici inglobato ramo "Riccardo" e aggiunto utilizzo della riduzione di feed.
 2024-07-03 17:09:13 +02:00
Riccardo Elitropi 2cea265ce3 EgtMachKernel : 
- Aggiunte Feed e migliorie su lati aperti per Sgrossature.
 2024-07-03 13:25:06 +02:00
Dario Sassi 7269e97a70 EgtMachKernel : 
- in svuotatura il limite per fare trapezi ottimizzati è dato dallo step di lato se non è dato "MaxOptSize=" nelle note utente.
 2024-07-03 12:15:10 +02:00
Dario Sassi 02a0928b06 Revert "Merge commit '6f7adce5e22f8102ce4948e1e1be09cf386bbddd'" 
This reverts commit 462832fa8f, reversing
changes made to e6a74d0b45.
 2024-07-03 11:22:31 +02:00
Dario Sassi 462832fa8f Merge commit '6f7adce5e22f8102ce4948e1e1be09cf386bbddd' 2024-07-03 11:09:41 +02:00
Dario Sassi e6a74d0b45 EgtMachKernel : 
- modifica a drilling per impostazione geometria senza con create anzichè add.
 2024-07-01 14:46:20 +02:00
Dario Sassi 9c5b90858f EgtMachKernel 2.6g1 : 
- ricompilazione con cambio versione.
 2024-07-01 12:46:55 +02:00
Riccardo Elitropi 6f7adce5e2 Merge commit '1badb47d71f9451753f128e12492750ceed3203a' into Sgrossature 2024-07-01 08:57:28 +02:00
Riccardo Elitropi b43700909b EgtMachKernel : 
- codice di test per Feed.
 2024-07-01 08:57:07 +02:00
Dario Sassi 1badb47d71 EgtMachKernel : 
- in sgrossatura superfici migliorie e semplificazioni.
 2024-06-29 18:47:27 +02:00
Dario Sassi c2bb3bc43b Merge remote-tracking branch 'origin/Sgrossature' 2024-06-27 14:37:12 +02:00
Dario Sassi 07f75b3994 EgtMachKernel : 
- correzione in fresatura e svuotatura di approccio/retrazione rinvio da sotto per ingombro di lato.
 2024-06-27 12:52:35 +02:00
Riccardo Elitropi 50ebe36cd1 EgtMachKernel : 
- migliorie entrate Elica e ZigZag.
 2024-06-27 12:34:37 +02:00
Dario Sassi 70a9aeed15 Merge commit '83aa3824630fec1ea808a9adc38b4b9f14e5905e' 2024-06-27 10:26:22 +02:00
Riccardo Elitropi 83aa382463 EgtMachKernel : 
- migliorata funzione per scelta lati Aperti/Chiusi.
 2024-06-27 09:08:34 +02:00
Dario Sassi fcca2706c3 Merge commit 'c917f6bb4e6f01543f3cb4aa9656570858aa32aa' 2024-06-25 19:14:40 +02:00
Riccardo Elitropi c917f6bb4e EgtMachKernel : 
- Aggiunta gestione della superficie limite
- aggiunte funzioni per SubSteps
- correzioni varie.
 2024-06-25 13:30:41 +02:00
Riccardo Elitropi 63ca83fa01 Merge commit '6ccfaa76519a02735f715df8390d7c8b6a22be5a' into Sgrossature 2024-06-25 13:19:28 +02:00
Dario Sassi 6ccfaa7651 EgtMachKernel 2.6f4 : 
- in fresatura aggiunta possibilità in FaceUse di dare direzione di riferimento con un vettore di chiave VtFaceUse nelle note utente.
 2024-06-24 16:20:20 +02:00
Dario Sassi e379c216b8 Merge commit 'f51cfd089f7dfd7c678fdb49dc2d77bf91537d5c' 2024-06-18 18:18:04 +02:00
Riccardo Elitropi f51cfd089f EgtMachKernel : 
- Se lavorazione Spiral, gli Step extra sono lavorati sempre in SpiralIN.
 2024-06-18 11:18:56 +02:00
Riccardo Elitropi 3e3a31051e Merge commit '9b47b777d4f837d696d3855d82ab1d88d0f8c8ac' into Sgrossature 2024-06-18 11:16:21 +02:00
Dario Sassi 9b47b777d4 EgtMachKernel : 
- piccola miglioria in simulazione per robot.
 2024-06-18 07:34:02 +02:00
Dario Sassi 95d26a9c11 Merge commit '0449d9fe8cc266fb08e08ad6b7e973a8ce0e5105' 2024-06-17 12:22:42 +02:00
Riccardo Elitropi 0449d9fe8c EgtMachKernel : 
- Offset radiale applicato alla Silhouette.
 2024-06-17 11:49:13 +02:00
Riccardo Elitropi a6a9ab5bba Merge commit 'fdf4326f3aeb49265c82059e835df40ece20670f' into Sgrossature 2024-06-17 09:17:20 +02:00
Dario Sassi fdf4326f3a EgtMachKernel : 
- aggiustamenti per modifiche a CollisionAvoid e calcolo silhouette che lo sfrutta.
 2024-06-17 07:13:05 +02:00
Dario Sassi e81290308d Merge remote-tracking branch 'origin/Sgrossature' 2024-06-16 20:22:55 +02:00
Riccardo Elitropi 469b2a0935 Merge commit 'd098e4bcbc0995b608ce6bd46533ddbdb7ffd423' into Sgrossature 2024-06-14 16:46:12 +02:00
Riccardo Elitropi 1bd74a3c3c EgtMachKernel : 
- gestione SubSteps
- migliorie varie.
 2024-06-14 16:45:57 +02:00
Dario Sassi d098e4bcbc EgtMachKernel : 
- in foratura con teste con uscite multiple ammesse anche frese che lavorano di testa.
 2024-06-13 12:21:53 +02:00
Dario Sassi fbf91fcafa EgtMachKernel : 
- in foratura con teste con uscite multiple non si considerano gli utensili diversi da punta a forare.
 2024-06-13 12:09:39 +02:00
Riccardo Elitropi 78b67c1527 Merge commit '3d46b4b41b6887cae66afcff1d83730f1e488cef' into Sgrossature 2024-06-13 08:20:59 +02:00
Dario Sassi 3d46b4b41b EgtMachKernel : 
- in sgrossatura superfici aggiunto controllo massimo arco al centro archi (come nelle altre lavorazioni)
- in sgrossatura superfici semplificata impostazione lati aperti di regioni grazie a nuove funzioni.
 2024-06-13 08:02:38 +02:00
Dario Sassi 9e5dbcf5fb EgtMachKernel 2.6f3 : 
- in sgrossatura superfici ridotto step di campionamento per silhouette a 0.5.
 2024-06-12 14:34:45 +02:00
Dario Sassi ab6a0db22d EgtMachKernel : 
- inserimento in sgrossatura superfici di nuovo metodo per calcolo silhouettte.
 2024-06-11 09:32:08 +02:00
Dario Sassi 7929a41d5f EgtMachKernel : 
- in SurfRoughing corretto passaggio parametro IntersParPlanesSurfTm (deve essere per riferimento).
 2024-06-07 19:02:49 +02:00
Riccardo Elitropi a26a1fa546 Merge commit 'a9d57c8021822c594764091dba1fdae0e1093739' into Sgrossature 2024-06-07 12:52:47 +02:00
Dario Sassi a9d57c8021 EgtMachKernel : 
- in sgrossatura superfici corretto GetParam e SetParam per substep.
 2024-06-07 12:48:26 +02:00
Dario Sassi 931083217c Merge commit '86853914b24936604cec6ad5695dd611b55e339f' 2024-06-07 11:22:32 +02:00
Riccardo Elitropi 86853914b2 EgtMachKernel : 
- Correzioni LeadIn/LeadOut.
- Gestione lati aperti.
 2024-06-07 10:22:06 +02:00
Riccardo Elitropi 679ce5bcbc Merge commit '310acbdb6410ec65a714b9b9ae88e91aca3baabd' into Sgrossature 2024-06-06 18:35:42 +02:00
Dario Sassi 310acbdb64 EgtMachKernel : 
- miglioria a riconoscimento curve non adatte per foratura.
 2024-06-06 17:44:15 +02:00
Riccardo Elitropi bfc52671cd Merge commit '731e698404f6b0b60748fab95f65d47b9418c62c' into Sgrossature 2024-06-06 14:49:36 +02:00
Riccardo Elitropi 4ac0de990e EgtMachKernel : 
- Aggiunta gestione lati aperti.
 2024-06-06 14:49:06 +02:00
Dario Sassi 731e698404 EgtMachKernel : 
- tolti parametri inutili da sgrossatura superfici
- razionalizzato uso parametri globali da BD lavorazioni.
 2024-06-06 12:25:03 +02:00
Dario Sassi a07c76377e Merge commit '60ce7627938e3489c15474fc75fe67a6ef400263' 2024-06-06 09:54:54 +02:00
Riccardo Elitropi 60ce762793 EgtMachKernel : 
- LeadIn/LeadOut.
 2024-06-06 09:52:08 +02:00
Dario Sassi 3959ab60a3 EgtmachKernel : 
- in fresatura corretto caso di circonferenza con due step in oneway e attacco glide che generava un arco di 360deg con conseguenti errori vari.
 2024-06-05 20:06:38 +02:00
Dario Sassi 516a85a950 EgtMachKernel 2.6f2 : 
- nei tagli di lama a passate OneWay ora i ritorni sono in rapido (come già era nelle fresature).
 2024-06-05 19:08:34 +02:00
Dario Sassi c7cd7dfea8 EgtMachKernel : 
- aggiustamento parametri per sgrossatura superfici.
 2024-06-05 17:17:07 +02:00
Dario Sassi c6d500174e EgtMachKernel : 
- correzione a sgrossatura superfici per caso lavandino.
 2024-06-05 10:50:50 +02:00
Dario Sassi 920dcb502f EgtMachKernel : 
- correzione a fresatura standard per approcci/retrazioni di frese con lunghezza totale diversa da lunghezza di lavoro
- piccola modifica a sgrossatura superfici.
 2024-06-04 15:55:12 +02:00
Dario Sassi b001f26339 EgtMachKernel : 
- modifiche a sgrossatura superfici.
 2024-06-03 09:11:08 +02:00
Dario Sassi 8c4c606ee1 EgtMachKernel 2.6f1 : 
- modifiche per sgrossatura superfici.
 2024-06-03 08:16:08 +02:00
Dario Sassi 9c73479441 RgtMachKernel : 
- resa funzionante GetToolPreviewStepCount.
 2024-05-31 07:58:27 +02:00
Dario Sassi 719bb994bd EgtMachKernel : 
- aggiunta funzione GetPreviewMachiningToolStepCount
- nella funzione PreviewMachiningTool il secondo parametro non è più un flag ma il numero di passi con il verso.
 2024-05-30 15:24:50 +02:00
Dario Sassi e61dd3d17b EgtMachKernel 2.6e6 : 
- in Finitura Superfici aggiunto sottotipo OneWay
- in Finitura Superfici aggiunta verifica utensile con superfici in attacchi e uscite
- nelle lavorazioni di Superficie escluso utilizzo di rinvio da sotto
- corretto Dump di svuotature per stringhe chiave-valore vuote
- prime modifiche a Sgrossatura Supefici.
 2024-05-29 19:02:10 +02:00
Dario Sassi 9e52787c8b EgtMachKernel : 
- correzione in operazioni FiveAxisMilling e SurfRoughing per tipo restituito nella GetParam.
 2024-05-27 08:43:11 +02:00
Dario Sassi 92fba6f1d4 EgtMachKernel : 
- aggiunta lavorazione sgrossatura superfici (per ora solo una copia della finitura).
 2024-05-24 18:59:55 +02:00
Dario Sassi a3511ba89d EgtMachKernel : 
- correzioni per calcolo posizione utensile fuori pezzo in fresatura
- ora GetElevation può gestire un offset della superficie utensile tramite il parametro dSafeDist.
 2024-05-24 12:47:03 +02:00
Dario Sassi a31dfa3378 EgtMachKernel 2.6e5 : 
- aggiunta gestione lavorazione fresatura a 5 assi.
 2024-05-23 11:48:51 +02:00
Dario Sassi 171c473e5b EgtMachKernel : 
- nel calcolo degli assi macchina su percorsi ora si infittiscono opportunamente i punti quando necessario a 5 assi.
 2024-05-22 08:20:56 +02:00
Dario Sassi 9c38fcd015 EgtMachKernel : 
- aggiunta gestione attacchi e uscite in finitura di superfici (per ora senza Collision Avoid).
 2024-05-20 10:53:24 +02:00
Dario Sassi 6986c01fba EgtMachKernel 2.6e4 : 
- in lavorazioni generiche ora si imposta l'utensile per il calcolo prima di chiamare lo script
- in lavorazioni generiche si passa allo script anche la variabile EMC.ISROBOT (flag che indica se la catena cinematica è di tipo robot).
 2024-05-16 12:51:11 +02:00
Dario Sassi 68a6a544c6 EgtMachKernel : 
- piccola miglioria a lavorazione finitura superfici per riconoscimento parti a massimo affondamento da eliminare.
 2024-05-13 07:58:54 +02:00
Dario Sassi fece411fa7 EgtMachKernel : 
- piccola correzione nei collegamenti tra le passate delle Fresature OneWay.
 2024-05-09 20:22:50 +02:00
Dario Sassi 103c5d0388 EgtMachKernel : 
- in finitura superficie aggiunta gestione SkipMaxDown=1 per eliminare i movimenti a massimo affondamento.
 2024-05-07 12:03:59 +02:00
Dario Sassi 2e1d247e27 EgtMachKernel 2.6e1 : 
- ricompilazione per modifiche a gestione chiave di rete.
 2024-04-30 16:55:23 +02:00
Dario Sassi 888cc604b5 EgtMachKernel : 
- piccola miglioria a simulazione (aumentato limite massimo dello step).
 2024-04-29 12:47:06 +02:00
Dario Sassi c191d6d831 EgtMachKernel : 
- in simulazione sistemato richiamo OnEndMove dopo errore di collisione alla fine del movimento.
 2024-04-29 08:43:10 +02:00
Dario Sassi e97b9df6d4 EgtMachKernel : 
- in simulazione a funzione SimSetToolForVmill aggiunti parametri nFlag, dPar1 e dPar2 per additive ( modificate EmtSetToolForVmill e EmtAddToolForVmill)
- in simulazione aggiunta funzione SimEnableToolsForVmill per abilitare/disabilitare le operazioni virtual (aggiunta EmtEnableToolsForVmill).
 2024-04-26 11:44:37 +02:00
Dario Sassi e6a03b0b2e EgtMachKernel : 
- correzioni a collegamenti tra passate ZigZag di Fresature con Utensili NoTip
- aggiunta in interfaccia MachMgr funzione GetExitId
- in simulazione VirtualMilling aggiunta gestione utensile Chisel.
 2024-04-22 15:29:23 +02:00
Dario Sassi bafb8f55ed EgtMachKernel : 
- correzioni a collegamenti tra passate OneWay di Fresature con Utensili NoTip.
 2024-04-22 10:53:43 +02:00
Dario Sassi d1406baa2e EgtMachKernel : 
- corretto passaggio parametri spezzatura in pocketing e milling (correzione #1765).
 2024-04-17 11:39:10 +02:00
Dario Sassi 89d46baf43 EgtMachKernel 2.6d4 : 
- aggiunta gestione riferimento canonico per calcolo cinematica robot comunque disposto nello spazio
- adattamento funzioni di calcolo posizione, direzione utensile e ausiliaria da questi angoli
- in svuotatura corretta mancata esplosione di archi in rette sui percorsi di ritorno quando richiesta.
 2024-04-17 06:58:27 +02:00
Dario Sassi 1f57693da8 EgtMachKernel : 
- in foratura corretta segnalazione di errore fuorviante
- in fresatura sistemata gestione direzioni inizio e fine con percorrenze in direzione inversa
- in link tra percorsi di lavorazione per robot aggiunta posizione iniziale a Zmax dopo inserimento di risalita a Zmax in percorso immediatamente precedente.
 2024-04-13 17:44:30 +02:00
Dario Sassi 010f676234 EgtMachKernel : 
- modifiche a fresature per direzioni di riferimento di attacchi e uscite come inizio e fine dei percorsi originali
- migliorata in fresatura visualizzazione movimento lame quando interessano 2 o 3 curve di lavoro.
 2024-04-11 00:24:09 +02:00
SaraP 1839b45e96 EgtMachKernel 2.6d3 : 
- in WaterJet modificati anelli per angoli esterni
- spezzatura movimenti per robot.
 2024-04-10 12:04:10 +02:00
Dario Sassi 9bc699be18 EgtMachKernel 2.6d2 : 
- ricompilazione per modifiche a EgtLock.
 2024-04-09 14:49:50 +02:00
Dario Sassi f701828a25 EgtMachKernel : 
- aggiunta a MachMgr funzione GetClEntAxesMask
- gestione emissione in generazione/simulazione/stima di tutti gli assi rotanti del robot.
 2024-04-03 08:14:20 +02:00
Dario Sassi f8d2f26692 EgtMachKernel 2.6d1 : 
- se robot sempre spezzatura
- spezzatura movimenti per robot
- in tagli con lama, tolto da Apply preview.
 2024-04-02 15:37:22 +02:00
Dario Sassi 4e3079e504 EgtMachKernel : 
- in fresature aggiunte inserzioni ed estrazioni su link di percorsi OneWay con lame o utensili che non tagliano di testa.
 2024-03-26 17:32:56 +01:00
Dario Sassi 0d0f195d8b EgtMachKernel : 
- modifiche a fresature per approcci/retrazioni con frese che non lavorano di testa.
 2024-03-26 13:32:13 +01:00
Dario Sassi 7fbce2b593 EgtMachKernel : 
- aggiunta gestione oggetti per verifica collisioni nei link tra lavorazioni anche nelle tavole
- in fresatura standard migliorati approcci e retrazioni per frese che non lavorano di testa
- in simulazione migliorata gestione comandi ausiliari di start in Disposizioni senza movimenti.
 2024-03-19 18:11:50 +01:00
Dario Sassi 74b2874f56 EgtMachKernel : 
- correzione a gestione visualizzazione tavola corrente.
 2024-03-16 10:32:57 +01:00
SaraP 9540563a87 EgtMachKernel 2.6c3 : 
- modifiche allo split nei grezzi con lavorazioni per gestire tagli inclinati
- introdotte regioni up e down per i grezzi
- nelle preview di sawing e milling aggiunte superfici di lavorazione in corrispondenza delle facce del grezzo.
 2024-03-14 10:30:37 +01:00
Dario Sassi 8eeca04757 EgtMachKernel 2.6c2 : 
- ricompilazione con cambio versione.
 2024-03-10 10:26:06 +01:00
Dario Sassi db6ae7538f EgtMachKernel 2.6c1 : 
- migliorato calcolo collegamento tra passate di fresature a step OneWay.
 2024-03-05 08:57:15 +01:00
Dario Sassi 839639fcc8 EgtMachKernel : 
- eliminate alcune variabili non usate.
 2024-02-27 18:36:32 +01:00
Dario Sassi c3729befbb EgtMachKernel : 
- modifiche e correzioni per flag di fine passata (301) in fresatura con lama a ZigZag e OneWay.
 2024-02-27 10:36:52 +01:00
Dario Sassi a79d9c9fe8 EgtMachKernel : 
- piccola correzione a fresature con attacco/uscita a scivolo.
 2024-02-26 18:06:22 +01:00
Dario Sassi d3b281a858 EgtMachKernel : 
- migliorata fresatura di lato con lama con più passaggi (ZigZag e OneWay) con note utente
      SideElev anche negativa per avere controllo MaxMat con Step
      TrimExt=nClosedStmId per definire superficie chiusa con cui estendere/trimmare il percorso di lavoro.
 2024-02-26 15:15:07 +01:00
Dario Sassi 37d0b8f552 EgtMachKernel : 
- in Milling corretto calcolo punto inizio attacco nel caso percorso invertito per ZigZag o similare.
 2024-02-22 16:59:14 +01:00
Dario Sassi 737124b0bd EgtMachKernel : 
- modifiche per configurazione canonica robot da ZYY-ZYZ a ZYY-XYX.
 2024-02-20 10:52:23 +01:00
Dario Sassi 09bdd4852d EgtMachKernel : 
- corretto controllo catena cinematica in assenza di assi lineari (eliminato anche possibile crash).
 2024-02-19 17:16:14 +01:00
Dario Sassi 1d3c722fd3 EgtMachKernel 2.6b4 : 
- in simulazione aggiunti eventi Init e Exit a cui possono rispondere le funzioni lua OnSimulInit e OnSimulExit.
 2024-02-19 14:54:50 +01:00
Dario Sassi 3ca2db72e9 EgtMachKernel 2.6b3 : 
- adattamenti per modifiche a funzioni di Collision Detection.
 2024-02-16 08:47:33 +01:00
Dario Sassi 028a5b7bba EgtMachKernel : 
- aggiunta gestione macchine di tipo Robot, le altre sono ora definite di tipo Center.
 2024-02-13 11:45:05 +01:00
Dario Sassi 1179ad7e84 EgtMachKernel 2.6b1 : 
- migliorato controlli su testa e suo attrezzaggio per MultipleDrill.
 2024-02-02 16:20:05 +01:00
Dario Sassi d8c5fe0ea7 EgtMachkernel : 
- ora vengono restituiti ThDiam e ThLength anche per le mortasatrici/seghe a catena (ovviamente vanno considerati nella direzione dell'utensile).
 2024-01-29 19:54:17 +01:00
Dario Sassi a21be79df8 EgtMachKernel 2.6a2 : 
- modificato controllo parametri in LuaEmtMoveAxes per evitare crash in R64
- piccole migliorie.
 2024-01-25 08:35:26 +01:00
Dario Sassi d66cc47936 EgtMachKernel : 
- aggiunta funzione ChangeMachGroupName di MachMgr.
 2024-01-16 19:44:30 +01:00
Dario Sassi cd2315af46 EgtMachKernel 2.6a1 : 
- ricompilazione con cambio versione.
 2024-01-16 15:50:38 +01:00
Dario Sassi 204d63b7c9 EgtMachKernel : 
- modifiche per gestione teste multiple in foratura con modalità fissa, singola o multipla.
 2024-01-16 09:35:21 +01:00
Dario Sassi 5a5b48326f EgtMachKernel : 
- in foratura con testa multiuscite senza assi rotanti tolta necessità di presenza Asse Ausiliario.
 2024-01-15 17:21:54 +01:00
Dario Sassi bd448babd9 EgtMachKernel 2.5l6 : 
- aggiunta gestione script opzionale OnSpecialTestCollisionAvoid per avere un test custom di verifica collisione nei movimenti link tra le lavorazioni.
 2024-01-15 15:06:50 +01:00
Dario Sassi 73ba4eb93a EgtMachKernel : 
- allo script di aggiornamento utensili custom ora viene passata anche la SPEED (per permettere di sistemare il senso di rotazione indicato)
- nelle fresature in approccio e retrazione aggiunta gestione extra tra lunghezza di lavoro e lunghezza totale.
 2024-01-06 15:47:57 +01:00
Dario Sassi 268fa05cc0 EgtMachKernel 2.5l5 : 
- correzioni per forature semplici con rinvii
- correzioni per forature con aggregato da sotto.
 2024-01-05 19:09:39 +01:00
Dario Sassi b5ef9ae6dc EgtMachKernel : 
- aggiunto nuovo calcolo elevazione per un segmento dati gli estremi
- in fresatura migliorato approccio e retrazione per lame e frese che non lavorano di testa e non considerate fuori completamente dal pezzo.
 2024-01-02 16:00:59 +01:00
Dario Sassi fcaf15cbe1 EgtMachKernel : 
- in generazione CN e stima si imposta fase a 1 prima dell'inizio e al termine
- in simulazione aggiunta gestione errore in evento OnToolSelect.
 2023-12-29 13:08:21 +01:00
Dario Sassi ab84757a80 EgtMachKernel 2.5l4 : 
- piccole migliorie e correzioni a forature multiple con aggregato.
 2023-12-20 17:37:34 +01:00
Dario Sassi 0fab073568 Merge remote-tracking branch 'origin/Drilling' 2023-12-20 08:22:21 +01:00
Dario Sassi 4d29452c2d EgtMachKernel : 
- in fresatura aggiunta gestione movimento compensazione raggio utensile in ingressi e uscite lineari e tangenti anche senza correzione raggio fresa in macchina.
 2023-12-19 16:47:43 +01:00
Dario Sassi 1bcff0eb79 EgtMachKernel : 
- in svuotatura cambiato calcolo elevazione.
 2023-12-18 09:31:31 +01:00
Dario Sassi 52bcc69023 EgtMachKernel 2.5l3 : 
- in fresature migliorato calcolo di retrazione orizzontale quando quasi sotto il pezzo con utensile lama o fresa notip.
 2023-12-15 19:57:55 +01:00
Dario Sassi 18ccead437 EgtMachKernel 2.5l2 : 
- rimossa costante non più utilizzata.
 2023-12-11 10:28:31 +01:00
Dario Sassi d49f198720 EgtMachKernel : 
- ulteriori migliorie nel calcolo dell'elevazione.
 2023-12-07 11:00:26 +01:00
Dario Sassi 368721dcaa EgtMachKernel 2.5l1 : 
- elevation ora viene calcolato più precisamente tramite Collision Avoid.
 2023-12-01 16:51:48 +01:00
Dario Sassi c8c8d9e2a5 EgtMachKernel : 
- preparazione nuova gestione calcolo elevazioni.
 2023-11-28 09:39:06 +01:00
Dario Sassi d5c39485ea EgtMachKernel 2.5k3 : 
- aggiunta la possibilità di forzare sempre la visualizzazione del versore fresa negli oggetti CamData
- le funzioni lua EmtAddRapidStart, EmtAddRapidMove, EmtAddLinearMove e EmtAddArcMove ora hanno un parametro opzionale in più per forzare la visualizzazione della direzione utensile
- agli script per Lavorazioni Generiche ora sono passati parecchi dati geometrici e non dell'utensile utilizzato
- in visualizzazione dei percorsi in Doppio ora si tiene conto anche del parametro opzionale DeltaZ.
 2023-11-22 20:31:38 +01:00
Dario Sassi e14c8eb8b3 EgtMachKernel 2.5k2 : 
- correzioni a CalculateClPathAxesValues per lavorazioni 5 assi in continuo.
 2023-11-16 18:59:46 +01:00
Dario Sassi d5638e192c EgtMachKernel : 
- corretta GetDistanceFromRawSide per sapere quanto una posizione è all'interno del grezzo (sbagliava se posizione sul bordo e direzione di fuga tangente al bordo).
 2023-11-06 11:10:41 +01:00
Dario Sassi 85cdb84a5a EgtMachKernel : 
- corretto crash in simulazione con posizione Tc vuota dovuto a modifiche commit precedente.
 2023-11-06 09:33:17 +01:00
Dario Sassi 63a71db7ff EgtMachKernel : 
- modifiche per gestire aggregati di utensili su tool changer.
 2023-11-06 08:49:27 +01:00
Dario Sassi aa369739c9 EgtMachKernel 2.5k1 : 
- ricompilazione con cambio versione.
 2023-11-03 17:24:28 +01:00
Dario Sassi d19dfc5f8f EgtMachKernel 2.5j5 : 
- migliorato calcolo approcci di fresature e svuotature
- in fresatura e svuotatura ora attacchi elica, zigzag e inseguimento partono 2mm sopra il materiale
- in fresatura migliorato passaggio ad inseguimento tra uno step e il successivo.
 2023-11-01 19:21:28 +01:00
Dario Sassi d874e30288 EgtMachKernel 2.5j4 : 
- aggiunte a interfaccia di MachMgr le funzioni GetClEntAxesVal, GetToolSetupPosInCurrSetup e GetAllCurrAxesName.
 2023-10-28 18:13:56 +02:00
Dario Sassi 4047b8385e EgtMachKernel : 
- aggiunto messaggio di log nel caso di utensile non caricato perchè l'insieme tavola-testa non ha tre assi lineari.
 2023-10-24 11:52:23 +02:00
Dario Sassi 63e95ab2fe EgtMachKernel 2.5j3 : 
- migliorata simulazione con assi principali che non fanno movimento mentre lo fanno gli ausiliari (per controllo collisioni)
- la funzione EmtMoveAxes base per SimulMoveAxes ora gestisce fino a 10 assi in contemporanea.
 2023-10-22 15:58:36 +02:00
Dario Sassi 93a5bd72c7 EgtMachKernel 2.5j2 : 
- in creazione disegno utensile si nascondono eventuali Carter se è per visualizzazione in gestione DB utensili
- in OnToolData per generazione aggiunto parametro tipo utensile EMT.TTYPE
- in simulazione si lancia UpdateCurrSetup solo al primo avvio.
 2023-10-16 16:10:24 +02:00
Dario Sassi b3a1ee8e6c EgtMachKernel 2.5j1 : 
- ricompilazione con cambio versione.
 2023-10-09 13:02:22 +02:00
Dario Sassi 562e8342c3 EgtMachKernel 2.5i6 : 
- in fresatura e svuotatura modificati approcci e retrazioni per macchine con TiltingTable (TURN) per stare più lontani dal materiale.
 2023-09-27 21:11:18 +02:00
Dario Sassi 8c821750ba EgtMachKernel 2.5i5 : 
- ricompilazione a 64bit con Enable Enhanced Instruction Set = Not Set.
 2023-09-21 15:26:02 +02:00
Dario Sassi 6669fdc7a9 EgtMachKernel : 
- migliorato log di virtual  milling in simulazione.
 2023-09-18 08:15:19 +02:00
Dario Sassi e2043a7e3a EgtMachKerenl : 
- piccole migliorie a simulazione (aumento velocità in rapidi e log).
 2023-09-14 17:25:44 +02:00
Dario Sassi f92cec9d3d EgtMachKernel 2.5i1 : 
- aggiunta visualizzazione geometria di lavorazione in doppio per Drill, Pocketing e Milling
- a OnSetHead passata anche variabile globale EMC.USERNOTES con note utente dell'utensile
- in Simulazione corretto richiamo impostazione virtual milling su utensili con raggio maggiore del massimo gambo ammesso dal portautensile.
 2023-09-11 10:47:42 +02:00
Dario Sassi f30f028b17 EgtMachKernel 2.5h3 : 
- aggiunta possibilità di copiare un gruppo di lavoro.
 2023-08-27 18:30:01 +02:00
Dario Sassi 1adcb2991c EgtMachKernel : 
- in SurfFinishing possibilità di invertire anche percorso di lavorazione a ZigZag.
 2023-08-25 10:42:53 +02:00
Dario Sassi 285e0ce910 EgtMachKernel 2.5h2 : 
- aggiunta definizione EMC.VER con versione della dll a OnSetTable, OnSetHead e OnVerifyProtectedAreas
- alla modifica di posizione o direzione di un asse si sistema anche la geometria per la simulazione
- alla modifica della posizione di una uscita si sistema anche la geometria per la simulazione
- corretto carico uscite di una testa per direzioni poco discoste da quelle canoniche non correttamente assegnate.
 2023-08-19 11:53:38 +02:00
Dario Sassi 652aa35aaa EgtMachKernel 2.5h1 : 
- alla info di testa ZMAXONROT aggiunto parametro opzionale (3°) che indica lo spessore dei pezzi oltre il quale applicare la prescrizione.
 2023-08-02 20:02:50 +02:00
DarioS 2b5aacc160 EgtMachKernel 2.5g3 : 
- corretta fresatura zigzag con attacco con componente in direzione utensile (poteva risultare movimento nullo con conseguente erore)
- modificato controllo indeterminazione angoli su primo asse rotante per gestire correttamente macchina Multiax C1522 con rinvio da sotto.
 2023-07-27 09:31:59 +02:00
DarioS 1097f2a19f EgtMachKernel : 
- semplificazioni con utilizzo di ConvertCurveToComposite.
 2023-07-21 15:12:35 +02:00
DarioS 8c1b61b6b8 EgtMachKernel 2.5g2 : 
- prima di fare il calcolo degli assi nell'update delle lavorazioni si cancellano le entità di tipo CLIMB, RISE e HOME che potrebbero dare errori come extra-corse e che in ogni caso verrebbero cancellate e ricalcolate subito dopo con la funzione AdjustStartEndMovements.
 2023-07-20 20:43:33 +02:00
DarioS 80363af1f6 EgtMachKernel : 
- piccola miglioria stilistica.
 2023-07-19 09:54:12 +02:00
DarioS 9b5adeaeb3 EgtMachKernel : 
- i movimenti in rapido sono disegnati tratteggiati.
 2023-07-10 11:17:59 +02:00
DarioS 01854f30ed EgtMachKernel 2.5g1 : 
- in svuotatura corretta gestione forzatura contorni chiusi (Open=0 in UserNotes della lavorazione) con i casi ottimizzati.
 2023-07-07 17:08:56 +02:00
DarioS cdb35b4c38 EgtMachKernel 2.5f3 : 
- dove possibile e sicuro sostituiti dynamic_cast con static_cast.
 2023-06-30 11:51:03 +02:00
DarioS 994658da16 EgtMachKernel : 
- in simulazione aggiunta gestione collisione anche con poliedri.
 2023-06-19 08:12:03 +02:00
DarioS 135c0bda51 EgtMachKernel 2.5f2 : 
- correzione in fresatura per approccio con lame/frese notip.
 2023-06-14 15:05:46 +02:00
DarioS d927848815 EgtMachKernel : 
- in milling corretto approccio/retrazione di frese che non lavorano di testa.
 2023-06-09 16:05:28 +02:00
DarioS 7b91c17cb3 EgtMachKernel : 
- nell'interpretazione degli assi rotanti bloccati e degli angoli suggeriti dal token asse si toglie eventuale '=' finale che non può essere gestito nelle note utente della lavorazione.
 2023-06-08 10:16:57 +02:00
DarioS 3851bdcecb EgtMachKernel 2.5f1 : 
- in svuotature modificata gestione lati aperti, ora vengono lavorati con affondo laterali pari al passo di lato.
 2023-06-08 08:17:54 +02:00
Riccardo Elitropi d2965af836 Merge commit 'df86ffdee340b33c359d7e6b57598a70c1a1c006' into Drilling 2023-06-05 08:27:00 +02:00
DarioS df86ffdee3 EgtMachKernel : 
- migliorato controllo gestione chiave di rete.
 2023-05-30 10:29:13 +02:00
DarioS 05a6f56cfe EgtMachKernel 2.5e5 : 
- in fresatura modifiche a retrazione di frese NoTip e lame per allontanarsi quanto necessario dal pezzo in tutti i casi.
 2023-05-29 15:53:50 +02:00
DarioS 8f7fdc3a80 EgtMachKernel 2.5e4 : 
- negli angoli macchina suggeriti ora si tiene conto di Invert e di Offset (quindi per l'utente sono i valori che vede in simulazione e sul CN).
 2023-05-26 08:43:48 +02:00
DarioS 90dbb068a9 EgtMachKernel 2.5e3 : 
- correzzioni a svuotature ottimizzate per attacchi e sucite sui lati aperti (distanze).
 2023-05-20 12:04:46 +02:00
DarioS 577143d176 EgtMachKernel 2.5e2 : 
- correzione a Disposizione per gestire correttamente errori in casi senza testa equivalente.
 2023-05-18 18:34:34 +02:00
DarioS c6aa83ccd5 EgtMachKernel 2.5e1 : 
- ricompilazione per aggiornamento lua.
 2023-05-03 09:46:50 +02:00
DarioS 9e12f9d3b6 EgtMachKernel : 
- corretto Virtual Milling in Simulazione per frese che non lavorano di testa ma che si muovono con un piccolo angolo verso il basso (max 5deg).
 2023-04-18 09:47:45 +02:00
DarioS fc6af5de55 EgtMachKernel : 
- in svuotature con utensili che non possono lavorare di testa aggiunto controllo che effettivamente gli ingressi siano fatti a spirale o zigzag
- aggiunti controlli su Set di Frame3d con due versori per verificare non siano allineati.
 2023-04-18 08:00:55 +02:00
DarioS 8afece4a6c EgtMachKernel : 
- corretto errore visualizzazione Versori di oggetti CamData quando allineati
- nel calcolo angoli alzata tolleranza direzione richiesta allineata a direzione singolare a 0.001deg (tramite GetRotation con tolleranza SIN_EPS_ANG_SMALL).
 2023-04-17 09:32:20 +02:00
DarioS dc3ed5ea0a EgtMachKernel : 
- correzione in fresature a ZigZag per passaggio da uno step al successivo.
 2023-04-14 10:00:04 +02:00
DarioS 27a23bcdaa EgtMachKernel 2.5d3 : 
- ricompilazione con cambio versione.
 2023-04-11 19:38:44 +02:00
DarioS 7d554efe60 EgtMachKernel 2.5d2 : 
- in taglio con lama modificato riconsocimento Fsta e Fend ora devono essere del tipo "Key=F,PuRed;" .
 2023-04-06 18:03:24 +02:00
DarioS 075c0f4e95 EgtMachKernel : 
- in svuotatura aggiunta gestione minima sicurezza su ingresso da lato aperto tramite nota "OpenMinSafe=Val" in Note utente.
 2023-04-04 12:58:27 +02:00
DarioS 6378dddcdf EgtMachKernel 2.5d1 : 
- eliminata la necessità di testa dummy per disposizioni con comandi StartAux o EndAux e senza movimenti diretti.
 2023-04-03 08:50:46 +02:00
DarioS 025eea9c0f EgtMachKernel : 
- aggiustamenti per PtrOwner nuova funzione Set.
 2023-03-27 20:42:33 +02:00
DarioS 4b93557efe EgtMachKernel 2.5c2 : 
- nelle lavorazioni all'aggiornamento utensile si prendono i dati opportuni anche dall'attrezzaggio corrente.
 2023-03-23 19:08:44 +01:00
DarioS 04cf5a69a8 EgtMachKernel : 
- migliorata gestione approcci/retrazione in fresature di utensili che non lavorano di testa
- corretta gestione passaggio da aperto a chiuso (curve a J) in svuotature.
- corretta gestione angolo di fianco in tagli con lama con variazioni di Z sulla linea da seguire.
 2023-03-20 08:29:18 +01:00
DarioS 7d819a9500 EgtMachKernel : 
- modifiche a fresature per approcci e retrazioni di lame e frese che non lavorano di testa
- in simulatore migliorati controlli per frese che non lavorano di testa.
 2023-03-13 08:14:28 +01:00
DarioS a0da9d4e7d EgtMachKernel 2.5c1 : 
- cambiato nome parametro a Operation::GetExtraZ per renderlo piùsignificativo.
 2023-03-05 20:27:02 +01:00
DarioS dd960cb8a4 EgtMachKernel : 
- modifiche in svuotature per gestione di lati aperti concatenati con rientranze.
 2023-03-01 13:16:47 +01:00
DarioS 44af4a5bf4 EgtMachKernel 2.5b6 : 
- ricompilazione con cambio versione.
 2023-02-27 08:18:32 +01:00
DarioS 8ac85f6754 EgtMachKernel : 
- in fresatura e svuotatura corretto calcolo direzione di approccio per testa da sopra con aggregato da sotto in presenza di geometria che esce dal grezzo.
 2023-02-23 17:04:14 +01:00
DarioS e3cfe48da3 EgtMachKernel 2.5b5 : 
- correzione in ApproxWithArcsIfUseful di Operation (non riconosceva i percorsi piani su piani diversi da XY).
 2023-02-23 15:33:12 +01:00
DarioS 068e99df97 EgtMachKernel 2.5b4 : 
- ricompilazione con cambio versione.
 2023-02-20 09:17:12 +01:00
DarioS e3121ff553 EgtMachKernel 2.5b3 : 
- modifiche quote approccio e retrazione
 2023-02-17 12:08:10 +01:00
Riccardo Elitropi 0e8c41192d EgtMachKernel : 
- Fori con più tools.
 2023-02-16 15:11:47 +01:00
DarioS 15931dc304 EgtMachKernel 2.5b2 : 
- nel calcolo spostamenti in disposizioni (movimenti di pezzi con ventose) è ora possibile fare rotazioni non minime pur di stare nelle corse.
 2023-02-10 16:28:00 +01:00
DarioS c97cc00cdc EgtMachKernel 2.5b1 : 
- modifiche per gestione gambo utensile in calcolo MaxDepth e in disegno dello stesso.
 2023-02-09 10:39:27 +01:00
DarioS 8b0bbe4ab0 EgtMachKernel 2.5a4 : 
- corretto controllo e modifica approcci e retrazioni lame in milling.
 2023-01-31 19:53:35 +01:00
DarioS 4f264ee64e EgtMachKernel 2.5a3 : 
- correzione calcolo assi rotanti nel caso indeterminato con corsa asse che non comprende lo zero.
 2023-01-26 10:07:05 +01:00
DarioS 4e8953e864 EgtMachKernel : 
- ritorno a stato pre svuotature con isole.
 2023-01-23 17:26:31 +01:00
96 changed files with 22071 additions and 9956 deletions
Expand all files Collapse all files
Axis.cpp
+16 -13
View File
@@ -17,9 +17,11 @@
#include "Axis.h"
#include "MachConst.h"
#include "/EgtDev/Include/EGkGdbConst.h"
#include "/EgtDev/Include/EGkGeoVector3d.h"
#include "/EgtDev/Include/EGkUserObjFactory.h"
#include "/EgtDev/Include/EGkStringUtils3d.h"
#include "/EgtDev/Include/EGkUiUnits.h"
#include "/EgtDev/Include/EgtNumUtils.h"
using namespace std ;
@@ -137,9 +139,8 @@ Axis::Set( const string& sName, const string& sToken, bool bInvert, double dOffs
bool
Axis::Modify( const Point3d& ptPos, double dAxisMaxAdjust)
{
// Verifico che lo spostamento non superi il massimo ammesso
Vector3d vtDelta = ptPos - m_ptPos ;
Vector3d vtDeltaPerp = vtDelta - ( vtDelta * m_vtDir) * m_vtDir ;
// Verifico che lo spostamento perpendicolare alla sua direzione non superi il massimo ammesso
Vector3d vtDeltaPerp = OrthoCompo( ptPos - m_ptPos, m_vtDir) ;
if ( vtDeltaPerp.Len() > dAxisMaxAdjust) {
string sOut = " Modify Axis " + m_sName + " Position (" + ToString( ptPos) + ") failed" ;
LOG_ERROR( GetEMkLogger(), sOut.c_str()) ;
@@ -147,6 +148,11 @@ Axis::Modify( const Point3d& ptPos, double dAxisMaxAdjust)
}
// Assegno la nuova posizione
m_ptPos = ptPos ;
// Sistemo la geometria dell'asse
int nV = m_pGeomDB->GetFirstNameInGroup( m_nOwnerId, m_sName) ;
IGeoVector3d* pGV = GetGeoVector3d( m_pGeomDB->GetGeoObj( nV)) ;
if ( pGV != nullptr)
pGV->ChangeBase( m_ptPos) ;
return true ;
}
@@ -164,6 +170,11 @@ Axis::Modify( const Vector3d& vtDir, double dAxisMaxRotAdj)
}
// Assegno la nuova direzione
m_vtDir = vtDirN ;
// Sistemo la geometria dell'asse
int nV = m_pGeomDB->GetFirstNameInGroup( m_nOwnerId, m_sName) ;
IGeoVector3d* pGV = GetGeoVector3d( m_pGeomDB->GetGeoObj( nV)) ;
if ( pGV != nullptr)
pGV->ChangeVector( m_vtDir) ;
return true ;
}
@@ -172,10 +183,7 @@ bool
Axis::Modify( const STROKE& Stroke)
{
m_Stroke = Stroke ;
if ( m_dHomeVal < m_Stroke.Min)
m_dHomeVal = m_Stroke.Min ;
else if ( m_dHomeVal > m_Stroke.Max)
m_dHomeVal = m_Stroke.Max ;
m_dHomeVal = Clamp( m_dHomeVal, m_Stroke.Min, m_Stroke.Max) ;
return true ;
}
@@ -183,12 +191,7 @@ Axis::Modify( const STROKE& Stroke)
bool
Axis::Modify( double dHome)
{
if ( dHome < m_Stroke.Min)
m_dHomeVal = m_Stroke.Min ;
else if ( dHome > m_Stroke.Max)
m_dHomeVal = m_Stroke.Max ;
else
m_dHomeVal = dHome ;
m_dHomeVal = Clamp( dHome, m_Stroke.Min, m_Stroke.Max) ;
return true ;
}
CamData.cpp
+29 -8
View File
@@ -1,13 +1,14 @@
//----------------------------------------------------------------------------
// EgalTech 2015-2016
// EgalTech 2015-2023
//----------------------------------------------------------------------------
// File : CamData.cpp Data : 24.02.16 Versione : 1.6n8
// File : CamData.cpp Data : 22.11.23 Versione : 2.5k3
// Contenuto : Implementazione informazioni Cam di ogni movimento.
//
//
//
// Modifiche : 10.06.15 DS Creazione modulo.
// 24.02.16 DS Versione 2 (aggiunti m_nMove e m_ptCen).
// 22.11.23 DS Aggiunto flag ToolShow (forza in ogni caso la visualizzazione della direzione utensile).
//
//----------------------------------------------------------------------------
@@ -53,7 +54,9 @@ static int CAM_PARAM_V7 = 22 ;
static string CAM_ORIGFEED = "OrFeed" ;
static int CAM_PARAM_V8 = 23 ;
static string CAM_FLAG2 = "Flg2" ;
static int CAM_TOTPARAM =CAM_PARAM_V8 ;
static int CAM_PARAM_V9 = 24 ;
static string CAM_TOOLSHOW = "TSh" ;
static int CAM_TOTPARAM = CAM_PARAM_V9 ;
//----------------------------------------------------------------------------
@@ -79,6 +82,7 @@ CamData::Clone( void) const
pCam->m_pGeomDB = nullptr ;
pCam->m_nMove = m_nMove ;
pCam->m_nCorre = m_nCorre ;
pCam->m_bToolShow = m_bToolShow ;
pCam->m_vtTool = m_vtTool ;
pCam->m_vtCorr = m_vtCorr ;
pCam->m_vtAux = m_vtAux ;
@@ -139,6 +143,7 @@ CamData::Dump( string& sOut, bool bMM, const char* szNewLine) const
sOut += CAM_AXND + "=" + ToString( m_vtMachN) + szNewLine ;
sOut += CAM_NDLT + "=" + ToString( m_dDeltaN) + szNewLine ;
sOut += CAM_BDIR + "=" + ToString( m_vtBackAux) + szNewLine ;
sOut += CAM_TOOLSHOW + "=" + ToString( m_bToolShow) + szNewLine ;
return true ;
}
@@ -149,6 +154,8 @@ CamData::SetOwner( int nId, IGeomDB* pGDB)
{
m_nOwnerId = nId ;
m_pGeomDB = pGDB ;
if ( m_pGeomDB != nullptr)
m_pGeomDB->SetStipple( m_nOwnerId, ( m_nMove == 0 ? 3 : 0), 0x8C8C) ;
return ( m_nOwnerId != GDB_ID_NULL && m_pGeomDB != nullptr) ;
}
@@ -203,6 +210,8 @@ CamData::Save( int nBaseId, STRVECTOR& vString) const
vString[++k] = CAM_ORIGFEED + "=" + ToString( m_dOrigFeed) ;
// parametri aggiunti V8
vString[++k] = CAM_FLAG2 + "=" + ToString( m_nFlag2) ;
// parametri aggiunti V9
vString[++k] = CAM_TOOLSHOW + "=" + ToString( m_bToolShow) ;
}
catch( ...) {
return false ;
@@ -295,6 +304,14 @@ CamData::Load( const STRVECTOR& vString, int nBaseGdbId)
else {
m_nFlag2 = 0 ;
}
// parametri aggiunti V9
if ( int( vString.size()) >= CAM_PARAM_V9) {
if ( ! GetVal( vString[++k], CAM_TOOLSHOW, m_bToolShow))
return false ;
}
else {
m_bToolShow = false ;
}
return true ;
}
@@ -311,7 +328,7 @@ CamData::GetDrawPolyLines( POLYLINELIST& lstPL) const
PolyLine& PL = lstPL.back() ;
// dimensioni
const double TLEN = 40 ;
const double ALEN = 4 ;
const double ALEN = 1 ;
// inserisco disegno nella polilinea
PL.AddUPoint( 0, m_ptEnd) ;
Point3d ptTip = m_ptEnd + m_vtTool * TLEN ;
@@ -333,6 +350,9 @@ CamData::GetDrawPolyLines( POLYLINELIST& lstPL) const
ptP6.ToGlob( frF) ;
PL.AddUPoint( 6, ptP6) ;
PL.AddUPoint( 6, ptTip) ;
// da visualizzare sempre se richiesto
if ( m_bToolShow)
PL.SetTempProp( 1) ;
}
// se vettore correzione non nullo
if ( ! m_vtCorr.IsSmall()) {
@@ -342,14 +362,14 @@ CamData::GetDrawPolyLines( POLYLINELIST& lstPL) const
PolyLine& PL = lstPL.back() ;
// dimensioni
const double CLEN = 20 ;
const double ALEN = 2 ;
const double ALEN = 1 ;
// inserisco disegno nella polilinea
PL.AddUPoint( 0, m_ptEnd) ;
Point3d ptTip = m_ptEnd + m_vtCorr * CLEN ;
PL.AddUPoint( 1, ptTip) ;
// aggiungo simil-freccia
Frame3d frF ;
if ( m_vtTool. IsSmall())
if ( m_vtTool. IsSmall() || AreSameOrOppositeVectorApprox( m_vtTool, m_vtCorr))
frF.Set( ptTip, m_vtCorr) ;
else
frF.Set( ptTip, m_vtCorr, m_vtTool) ;
@@ -371,14 +391,14 @@ CamData::GetDrawPolyLines( POLYLINELIST& lstPL) const
PolyLine& PL = lstPL.back() ;
// dimensioni
const double CLEN = 20 ;
const double ALEN = 2 ;
const double ALEN = 1 ;
// inserisco disegno nella polilinea
PL.AddUPoint( 0, m_ptEnd) ;
Point3d ptTip = m_ptEnd + m_vtAux * CLEN ;
PL.AddUPoint( 1, ptTip) ;
// aggiungo simil-freccia
Frame3d frF ;
if ( m_vtTool. IsSmall())
if ( m_vtTool. IsSmall() || AreSameOrOppositeVectorApprox( m_vtTool, m_vtAux))
frF.Set( ptTip, m_vtAux) ;
else
frF.Set( ptTip, m_vtAux, m_vtTool) ;
@@ -546,6 +566,7 @@ CamData::CamData( void)
m_pGeomDB = nullptr ;
m_nMove = 0 ;
m_nCorre = 0 ;
m_bToolShow = false ;
m_dAngCen = 0 ;
m_dDeltaN = 0 ;
m_dFeed = 0 ;
CamData.h
+10 -5
View File
@@ -68,11 +68,13 @@ class CamData : public IUserObj
bool SetAxesAngCen( double dAngCen) ;
bool SetAxesNormDir( const Vector3d& vtDir) ;
bool SetBackAuxDir( const Vector3d& vtDir) ;
const int GetMoveType( void) const
bool SetToolShow( bool bShow)
{ m_bToolShow = bShow ; return true ; }
int GetMoveType( void) const
{ return m_nMove ; }
const bool IsLine( void) const
bool IsLine( void) const
{ return ( m_nMove == 0 || m_nMove == 1) ; }
const bool IsArc( void) const
bool IsArc( void) const
{ return ( m_nMove == 2 || m_nMove == 3) ; }
const Vector3d& GetToolDir( void) const
{ return m_vtTool ; }
@@ -108,14 +110,16 @@ class CamData : public IUserObj
{ return m_vMachAxes ; }
const Point3d& GetAxesCen( void) const
{ return m_ptMachCen ; }
const double GetAxesRad( void) const
double GetAxesRad( void) const
{ return m_dMachRad ; }
const double GetAxesAngCen( void) const
double GetAxesAngCen( void) const
{ return m_dMachAngCen ; }
const Vector3d& GetAxesNormDir( void) const
{ return m_vtMachN ; }
const Vector3d& GetBackAuxDir( void) const
{ return m_vtBackAux ; }
bool GetToolShow( void) const
{ return m_bToolShow ; }
public :
enum { AS_NONE = 0,
@@ -139,6 +143,7 @@ class CamData : public IUserObj
IGeomDB* m_pGeomDB ;
int m_nMove ; // tipo movimento (0=rapido, 1=lineare, 2=arco CW, 3=arco CCW)
int m_nCorre ; // tipo correzione (0, 41, 42, 141, 142, 40)
bool m_bToolShow ; // flag per forzare la visualizzazione della direzione utensile in ogni caso
Vector3d m_vtTool ; // versore fresa
Vector3d m_vtCorr ; // versore correzione
Vector3d m_vtAux ; // versore ausiliario
Chiseling.cpp
+31 -8
View File
@@ -595,6 +595,9 @@ Chiseling::Update( bool bPostApply)
return true ;
}
// elimino le entità CLIMB, RISE e HOME della lavorazione, potrebbero falsare i calcoli degli assi (in ogni casi vengono riaggiunte dopo)
RemoveClimbRiseHome() ;
// imposto eventuale asse bloccato da lavorazione
SetBlockedRotAxis( m_Params.m_sBlockedAxis) ;
@@ -768,11 +771,31 @@ Chiseling::UpdateToolData( bool* pbChanged)
const ToolData* pTdata = pTMgr->GetTool( m_Params.m_ToolUuid) ;
if ( pTdata == nullptr)
return false ;
// verifico se sono diversi (ad esclusione del nome)
m_TParams.m_sName = pTdata->m_sName ;
bool bChanged = ! SameTool( m_TParams, *pTdata) ;
// salvo posizione TC, testa e uscita originali
string sOrigTcPos = m_TParams.m_sTcPos ;
string sOrigHead = m_TParams.m_sHead ;
int nOrigExit = m_TParams.m_nExit ;
// verifico se sono diversi (ad esclusione di nome, posizione TC, testa e uscita)
bool bChanged = ( ! SameTool( m_TParams, *pTdata, false)) ;
// aggiorno comunque i parametri
m_TParams = *pTdata ;
// se definito attrezzaggio, aggiorno i parametri che ne possono derivare
string sTcPos ; string sHead ; int nExit ;
if ( m_pMchMgr->GetCurrSetupMgr().GetToolData( m_TParams.m_sName, sTcPos, sHead, nExit)) {
if ( sOrigTcPos != sTcPos ||
sOrigHead != sHead ||
nOrigExit != nExit)
bChanged = true ;
m_TParams.m_sTcPos = sTcPos ;
m_TParams.m_sHead = sHead ;
m_TParams.m_nExit = nExit ;
}
else {
if ( sOrigTcPos != pTdata->m_sTcPos ||
sOrigHead != pTdata->m_sHead ||
nOrigExit != pTdata->m_nExit)
bChanged = true ;
}
// eventuali segnalazioni
if ( ! EqualNoCase( m_Params.m_sToolName, m_TParams.m_sName)) {
string sInfo = "Warning in Chiseling : tool name changed (" +
@@ -987,7 +1010,7 @@ Chiseling::GetCurves( SelData Id, ICURVEPLIST& lstPC)
// la porto in globale
pCrvCompo->ToGlob( frGlob) ;
// sistemazioni varie
AdjustCurveFromSurf( pCrvCompo, TOOL_ORTHO, FACE_CONT, 0) ;
AdjustCurveFromSurf( pCrvCompo, TOOL_ORTHO, FACE_CONT, V_NULL, 0) ;
// la restituisco
lstPC.emplace_back( Release( pCrvCompo)) ;
return true ;
@@ -1013,8 +1036,8 @@ Chiseling::GetCurves( SelData Id, ICURVEPLIST& lstPC)
for ( int nC = nCstart ; nC < nCend ; ++ nC) {
// recupero i contorni del chunk
for ( int nL = 0 ; nL < pReg->GetLoopCount( nC) ; ++ nL) {
PtrOwner<ICurveComposite> pCrvCompo( CreateCurveComposite()) ;
if ( IsNull( pCrvCompo) || ! pCrvCompo->AddCurve( pReg->GetLoop( nC, nL)))
PtrOwner<ICurveComposite> pCrvCompo ;
if ( ! pCrvCompo.Set( ConvertCurveToComposite( pReg->GetLoop( nC, nL))))
return false ;
// assegno l'estrusione dalla normale alla regione
pCrvCompo->SetExtrusion( vtN) ;
@@ -1023,7 +1046,7 @@ Chiseling::GetCurves( SelData Id, ICURVEPLIST& lstPC)
// la porto in globale
pCrvCompo->ToGlob( frGlob) ;
// sistemazioni varie
AdjustCurveFromSurf( pCrvCompo, TOOL_ORTHO, FACE_CONT, 0) ;
AdjustCurveFromSurf( pCrvCompo, TOOL_ORTHO, FACE_CONT, V_NULL, 0) ;
// la restituisco
lstPC.emplace_back( Release( pCrvCompo)) ;
}
@@ -1494,7 +1517,7 @@ Chiseling::GenerateChiselingCl( const SqHole& hole, int nPathId)
SetAuxDir( hole.vtAux) ;
// 1 -> punto approccio
SetFlag( 1) ;
double dAppr = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dAppr = GetSafeZ() ;
Point3d ptP1 = hole.ptIni + hole.vtExtr * dAppr ;
if ( AddRapidStart( ptP1) == GDB_ID_NULL)
return false ;
ChiselingData.h
+6 -2
View File
@@ -71,6 +71,10 @@ struct ChiselingData : public MachiningData
//----------------------------------------------------------------------------
inline const ChiselingData* GetChiselingData( const MachiningData* pMdata)
{ return (dynamic_cast<const ChiselingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_CHISELING)
return nullptr ;
return ( static_cast<const ChiselingData*>( pMdata)) ; }
inline ChiselingData* GetChiselingData( MachiningData* pMdata)
{ return (dynamic_cast<ChiselingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_CHISELING)
return nullptr ;
return ( static_cast<ChiselingData*>( pMdata)) ; }
Disposition.cpp
+27 -7
View File
@@ -86,6 +86,8 @@ Disposition::Clone( void) const
// eseguo copia dei dati
if ( pDisp != nullptr) {
try { pDisp->m_sTabName = m_sTabName ;
pDisp->m_pMchMgr = m_pMchMgr ;
pDisp->m_nPhase = m_nPhase ;
pDisp->m_ptRef1 = m_ptRef1 ;
pDisp->m_b3Area1 = m_b3Area1 ;
pDisp->m_dAreaOffset = m_dAreaOffset ;
@@ -885,7 +887,7 @@ Disposition::MoveToCornerRawPart( int nRawId, const Point3d& ptP, int nFlag, boo
case MCH_CR_TR :
vtMove = ( m_ptRef1 + ptP) - Point3d( b3Raw.GetMax().x, b3Raw.GetMax().y, b3Raw.GetMin().z) ;
break ;
default : // RPCP_BL
default : // MCH_CR_BL
vtMove = ( m_ptRef1 + ptP) - b3Raw.GetMin() ;
break ;
case MCH_CR_BR :
@@ -936,7 +938,7 @@ Disposition::MoveToCenterRawPart( int nRawId, const Point3d& ptP, int nFlag, boo
case MCH_CE_TC :
vtMove = ( m_ptRef1 + ptP) - Point3d( ptCen.x, b3Raw.GetMax().y, ptCen.z) ;
break ;
default : // RPCE_ML
default : // MCH_CE_ML
vtMove = ( m_ptRef1 + ptP) - Point3d( b3Raw.GetMin().x, ptCen.y, ptCen.z) ;
break ;
case MCH_CE_MR :
@@ -1060,7 +1062,7 @@ Disposition::RotateRawPart( int nRawId, const Vector3d& vtAx, double dAngRotDeg)
case MCH_CR_TR :
vtCorr = Vector3d( b3Raw.GetMax().x - b3OriRaw.GetMax().x, b3Raw.GetMax().y - b3OriRaw.GetMax().y, b3Raw.GetMin().z - b3OriRaw.GetMin().z) ;
break ;
default : // RPCP_BL
default : // MCH_CR_BL
vtCorr = Vector3d( b3Raw.GetMin().x - b3OriRaw.GetMin().x, b3Raw.GetMin().y - b3OriRaw.GetMin().y, b3Raw.GetMin().z - b3OriRaw.GetMin().z) ;
break ;
case MCH_CR_BR :
@@ -1075,7 +1077,7 @@ Disposition::RotateRawPart( int nRawId, const Vector3d& vtAx, double dAngRotDeg)
case MCH_CE_TC :
vtCorr = Vector3d( ptCen.x - ptOriCen.x, b3Raw.GetMax().y - b3OriRaw.GetMax().y, ptCen.z - ptOriCen.z) ;
break ;
default : // RPCE_ML
default : // MCH_CE_ML
vtCorr = Vector3d( b3Raw.GetMin().x - b3OriRaw.GetMin().x, ptCen.y - ptOriCen.y, ptCen.z - ptOriCen.z) ;
break ;
case MCH_CE_MR :
@@ -1205,6 +1207,23 @@ Disposition::InsertMoveInfoInList( int nRawId, int nType, const Point3d& ptP, in
return true ;
}
//----------------------------------------------------------------------------
bool
Disposition::UpdateRawPartId( int nRawId, int nNewRawId)
{
// aggiorno i movimenti registrati per questo grezzo
while ( true) {
auto iIter = find_if( m_vMvrData.begin(), m_vMvrData.end(),
[ nRawId]( const MoveRawData& Mrv)
{ return ( Mrv.nRawId == nRawId) ; }) ;
if ( iIter == m_vMvrData.end())
break ;
else
iIter->nRawId = nNewRawId ;
}
return true ;
}
//----------------------------------------------------------------------------
bool
Disposition::RemoveRawPart( int nRawId)
@@ -1353,7 +1372,8 @@ Disposition::SpecialApply( bool bRecalc)
bOk = bOk && pMch->LuaResetGlobVar( EMC_VAR) ;
// segnalo errori ed esco
if ( ! bOk || nErr > 0) {
m_nShifts = - 1 ;
if ( m_nShifts != -1)
m_nShifts = -2 ;
string sOut = sMsg ;
if ( IsEmptyOrSpaces( sOut))
sOut = " Error in " + ON_SPECIAL_APPLY + " (" + ToString( nErr) + ")" ;
@@ -1393,12 +1413,12 @@ Disposition::SpecialUpdate( void)
// se disposizione vuota, esco
if ( m_nShifts <= 0) {
if ( m_nShifts < 0)
if ( m_nShifts == -2)
m_pMchMgr->SetWarning( 2052, "Warning in Disposition : No shifts") ;
return true ;
}
// calcolo assi macchina
if ( ! CalculateAxesValues( "")) {
if ( ! CalculateAxesValues( "", false)) {
string sInfo = m_pMchMgr->GetOutstrokeInfo() ;
if ( sInfo.empty())
m_pMchMgr->SetLastError( 2007, "Error in Disposition : axes values not calculable") ;
Disposition.h
+10 -7
View File
@@ -56,14 +56,14 @@ class Disposition : public Operation
{ return true ; }
bool Save( int nBaseId, STRVECTOR& vString) const override ;
bool Load( const STRVECTOR& vString, int nBaseGdbId) override ;
public : // Operation
int GetType( void) const override
{ return OPER_DISP ; }
bool IsEmpty( void) const override
{ return ( m_nShifts == 0) ; }
int GetType( void) const override
{ return OPER_DISP ; }
bool IsEmpty( void) const override
{ return ( m_nShifts == 0) ; }
bool UpdateStatus( int nModif) override
{ m_nStatus |= nModif ; return true ; }
{ m_nStatus |= nModif ; return true ; }
protected : // Operation
const std::string& GetToolName( void) const override ;
@@ -71,7 +71,7 @@ class Disposition : public Operation
int GetExitNbr( void) const override ;
const std::string& GetToolTcPos( void) const override ;
int GetSolCh( void) const override
{ return 0 ; }
{ return 0 ; }
bool NeedPrevHome( void) const override ;
public :
@@ -102,6 +102,7 @@ class Disposition : public Operation
bool MoveRawPart( int nRawId, const Vector3d& vtMove) ;
bool RotateRawPart( int nRawId, const Vector3d& vtAx, double dAngRotDeg) ;
bool ApplyRotationToRawPart( int nRawId, double dAngCDeg, double dAngADeg, double dAngC1Deg, bool bAddToList = true) ;
bool UpdateRawPartId( int nRawId, int nNewRawId) ;
bool RemoveRawPart( int nRawId) ;
bool GetFixtureData( int nInd, std::string& sName, int& nId, Point3d& ptPos,
double& dAngDeg, double& dMov) const ;
@@ -111,6 +112,8 @@ class Disposition : public Operation
bool GetToolData( std::string& sName, std::string& sHead, int& nExit, std::string& sTcPos) const ;
bool GetSomeByHand( void) const
{ return m_bSomeByHand ; }
bool IsWithTool( void)
{ return ( m_nShifts != -1) ;}
private :
bool InsertMoveInfoInList( int nRawId, int nType, const Point3d& ptP, int nFlag) ;
Drilling.cpp
+763 -71
View File
File diff suppressed because it is too large Load Diff
Drilling.h
+17 -4
View File
@@ -19,7 +19,13 @@
#include "MachiningConst.h"
struct Hole ;
struct MHDrill ;
struct HoleInfo ;
struct ToolInfo ;
class ICurve ;
typedef std::vector<std::vector<MHDrill>> TABMHDRILL ;
typedef std::vector<HoleInfo> VECTORHOLE ;
typedef std::vector<ToolInfo> VECTORTOOL ;
//----------------------------------------------------------------------------
class Drilling : public Machining
@@ -68,18 +74,24 @@ class Drilling : public Machining
private :
bool GetHoleData( SelData Id, Hole& hole) ;
bool StdandardProcess( bool bRecalc, int nPvId, int nClId) ;
bool StandardProcess( bool bRecalc, int nPvId, int nClId) ;
bool AlongCurveProcess( bool bRecalc, int nPvId, int nClId) ;
bool Chain( int nGrpDestId) ;
ICurve* GetCurve( SelData Id) ;
bool ProcessPath( int nPathId, int nPvId, int nClId) ;
bool GenerateHolePv( int nInd, const SelData& nCircId, const std::string& sPName, int nPvId) ;
bool GenerateHoleCl( int nInd, const SelData& nCircId, const std::string& sPName, int nClId) ;
bool GenerateHoleCl( int nInd, const SelData& nCircId, const std::string& sPName, int nClId, double dMHOff = .0, Vector3d vtAux = V_NULL) ;
bool GenerateHoleRegionPv( int nFirstId, int nCount, int nPvId) ;
bool VerifyDiameter( double dHdiam, double dTdiam, double ddiamTol) ;
bool VerifyHoleFromBottom( const Hole& hole, SelData Id) ;
bool DoStandardDrilling( const Hole& hole, SelData Id, int nPathId) ;
bool DoPeckDrilling( const Hole& hole, SelData Id, int nPathId) ;
bool DoStandardDrilling( const Hole& hole, SelData Id, int nPathId, double nMHOff, const Vector3d& vtA) ;
bool DoPeckDrilling( const Hole& hole, SelData Id, int nPathId, double dMHOff, const Vector3d& vtA) ;
bool MultiHeadDrilling( const SELVECTOR& vId, int nClId, TABMHDRILL& vDrills, double& dMHOff, bool bOrd = true) ;
bool CalcMask( VECTORHOLE& vHoles, const VECTORTOOL& vTools, int nIndMT, const Vector3d& vtTool, const Vector3d& vtAux) ;
bool CheckOtherHolesWithTools( VECTORHOLE& vHoles, const VECTORTOOL& vTools, int nIndTM, int nIndHTM, Hole holeICP,
const Frame3d& frHTM, const Frame3d& frHMTOP, double dDiamToler, int& nDrills) ;
bool MultiHeadVerifyHole( Hole& hole, const ToolData* Tool, double dDiamToler, SelData Id) ;
bool VerifyMultiParallelFixedDrills( void) ;
private :
double GetSpeed() const
@@ -100,6 +112,7 @@ class Drilling : public Machining
int m_nStatus ; // stato di aggiornamento della lavorazione
int m_nDrillings ; // numero di fori generati
bool m_bTiltingTab ; // flag utilizzo tavola basculante
Vector3d m_vtTiltingAx ; // versore direzione eventuale asse basculante
bool m_bAboveHead ; // flag utilizzo testa da sopra
bool m_bAggrBottom ; // flag di utilizzo dell'aggregato da sotto
Vector3d m_vtAggrBottom ; // vettore direzione ausiliaria aggregato da sotto
DrillingData.h
+6 -2
View File
@@ -75,6 +75,10 @@ struct DrillingData : public MachiningData
//----------------------------------------------------------------------------
inline const DrillingData* GetDrillingData( const MachiningData* pMdata)
{ return (dynamic_cast<const DrillingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_DRILLING)
return nullptr ;
return ( static_cast<const DrillingData*>( pMdata)) ; }
inline DrillingData* GetDrillingData( MachiningData* pMdata)
{ return (dynamic_cast<DrillingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_DRILLING)
return nullptr ;
return ( static_cast<DrillingData*>( pMdata)) ; }
EgtMachKernel.rc
BIN
View File
Binary file not shown.
EgtMachKernel.vcxproj
+38 -5
View File
@@ -21,7 +21,7 @@
<PropertyGroup Label="Globals">
<ProjectGuid>{0BD58222-92F3-48B2-B656-4497D1956874}</ProjectGuid>
<RootNamespace>EgtMachKernel</RootNamespace>
<WindowsTargetPlatformVersion>10.0.17763.0</WindowsTargetPlatformVersion>
<WindowsTargetPlatformVersion>10.0.20348.0</WindowsTargetPlatformVersion>
</PropertyGroup>
<Import Project="$(VCTargetsPath)\Microsoft.Cpp.Default.props" />
<PropertyGroup Condition="'$(Configuration)|$(Platform)'=='Debug|Win32'" Label="Configuration">
@@ -102,9 +102,10 @@
<MultiProcessorCompilation>true</MultiProcessorCompilation>
<PreprocessorDefinitions>WIN32;_WINDOWS;I_AM_EMK;_DEBUG;%(PreprocessorDefinitions)</PreprocessorDefinitions>
<MinimalRebuild>false</MinimalRebuild>
<OpenMPSupport>true</OpenMPSupport>
<OpenMPSupport>false</OpenMPSupport>
<PrecompiledHeader>Use</PrecompiledHeader>
<CompileAs>CompileAsCpp</CompileAs>
<LanguageStandard>stdcpp17</LanguageStandard>
</ClCompile>
<Link>
<GenerateDebugInformation>true</GenerateDebugInformation>
@@ -166,6 +167,7 @@ copy $(TargetPath) \EgtProg\DllD64</Command>
<EnableFiberSafeOptimizations>true</EnableFiberSafeOptimizations>
<EnableParallelCodeGeneration>true</EnableParallelCodeGeneration>
<WholeProgramOptimization>false</WholeProgramOptimization>
<LanguageStandard>stdcpp17</LanguageStandard>
</ClCompile>
<Link>
<GenerateDebugInformation>false</GenerateDebugInformation>
@@ -193,7 +195,7 @@ copy $(TargetPath) \EgtProg\Dll32</Command>
<FavorSizeOrSpeed>Speed</FavorSizeOrSpeed>
<OmitFramePointers>true</OmitFramePointers>
<PreprocessorDefinitions>WIN32;_WINDOWS;I_AM_EMK;NDEBUG;%(PreprocessorDefinitions)</PreprocessorDefinitions>
<EnableEnhancedInstructionSet>AdvancedVectorExtensions2</EnableEnhancedInstructionSet>
<EnableEnhancedInstructionSet>NotSet</EnableEnhancedInstructionSet>
<OpenMPSupport>false</OpenMPSupport>
<PrecompiledHeader>Use</PrecompiledHeader>
<CompileAs>CompileAsCpp</CompileAs>
@@ -235,6 +237,8 @@ copy $(TargetPath) \EgtProg\Dll64</Command>
<ClCompile Include="EMkDllMain.cpp" />
<ClCompile Include="Estimator.cpp" />
<ClCompile Include="Exit.cpp" />
<ClCompile Include="FiveAxisMilling.cpp" />
<ClCompile Include="FiveAxisMillingData.cpp" />
<ClCompile Include="Generator.cpp" />
<ClCompile Include="GenMachining.cpp" />
<ClCompile Include="GenMachiningData.cpp" />
@@ -279,7 +283,8 @@ copy $(TargetPath) \EgtProg\Dll64</Command>
<ClCompile Include="SawRoughing.cpp" />
<ClCompile Include="SawRoughingData.cpp" />
<ClCompile Include="SetupMgr.cpp" />
<ClCompile Include="Simulator.cpp" />
<ClCompile Include="SimulatorSP.cpp" />
<ClCompile Include="SimulatorMP.cpp" />
<ClCompile Include="stdafx.cpp">
<PrecompiledHeader Condition="'$(Configuration)|$(Platform)'=='Debug|Win32'">Create</PrecompiledHeader>
<PrecompiledHeader Condition="'$(Configuration)|$(Platform)'=='Debug|x64'">Create</PrecompiledHeader>
@@ -289,6 +294,8 @@ copy $(TargetPath) \EgtProg\Dll64</Command>
<ClCompile Include="Head.cpp" />
<ClCompile Include="SurfFinishing.cpp" />
<ClCompile Include="SurfFinishingData.cpp" />
<ClCompile Include="SurfRoughing.cpp" />
<ClCompile Include="SurfRoughingData.cpp" />
<ClCompile Include="Table.cpp" />
<ClCompile Include="TcPos.cpp" />
<ClCompile Include="ToolData.cpp" />
@@ -301,7 +308,15 @@ copy $(TargetPath) \EgtProg\Dll64</Command>
<ClInclude Include="..\Include\EGkArcSpecial.h" />
<ClInclude Include="..\Include\EGkBBox1d.h" />
<ClInclude Include="..\Include\EGkBBox3d.h" />
<ClInclude Include="..\Include\EGkCDeBoxPolyhedron.h" />
<ClInclude Include="..\Include\EGkBiArcs.h" />
<ClInclude Include="..\Include\EGkCalcPocketing.h" />
<ClInclude Include="..\Include\EGkCAvSilhouetteSurfTm.h" />
<ClInclude Include="..\Include\EGkCAvToolSurfTm.h" />
<ClInclude Include="..\Include\EGkCDeBoxClosedSurfTm.h" />
<ClInclude Include="..\Include\EGkCDeClosedSurfTmClosedSurfTm.h" />
<ClInclude Include="..\Include\EGkCDeConeFrustumClosedSurfTm.h" />
<ClInclude Include="..\Include\EGkCDeCylClosedSurfTm.h" />
<ClInclude Include="..\Include\EGkCDeSpheClosedSurfTm.h" />
<ClInclude Include="..\Include\EGkChainCurves.h" />
<ClInclude Include="..\Include\EGkColor.h" />
<ClInclude Include="..\Include\EGkCurve.h" />
@@ -309,8 +324,11 @@ copy $(TargetPath) \EgtProg\Dll64</Command>
<ClInclude Include="..\Include\EGkCurveAux.h" />
<ClInclude Include="..\Include\EGkCurveComposite.h" />
<ClInclude Include="..\Include\EGkCurveLine.h" />
<ClInclude Include="..\Include\EGkCurveLocal.h" />
<ClInclude Include="..\Include\EGkCurvePointDiffGeom.h" />
<ClInclude Include="..\Include\EGkDistPointCurve.h" />
<ClInclude Include="..\Include\EGkDistPointLine.h" />
<ClInclude Include="..\Include\EGkDistPointSurfTm.h" />
<ClInclude Include="..\Include\EGkExtText.h" />
<ClInclude Include="..\Include\EGkFrame3d.h" />
<ClInclude Include="..\Include\EGkGdbConst.h" />
@@ -323,10 +341,13 @@ copy $(TargetPath) \EgtProg\Dll64</Command>
<ClInclude Include="..\Include\EGkGeoObjType.h" />
<ClInclude Include="..\Include\EGkGeoPoint3d.h" />
<ClInclude Include="..\Include\EGkGeoVector3d.h" />
<ClInclude Include="..\Include\EGkHashGrids1d.h" />
<ClInclude Include="..\Include\EGkHashGrids2d.h" />
<ClInclude Include="..\Include\EGkIntersCurves.h" />
<ClInclude Include="..\Include\EGkIntersCurveSurfTm.h" />
<ClInclude Include="..\Include\EGkIntersLineSurfTm.h" />
<ClInclude Include="..\Include\EGkIntersLineTria.h" />
<ClInclude Include="..\Include\EGkIntersPlaneSurfTm.h" />
<ClInclude Include="..\Include\EGkIntervals.h" />
<ClInclude Include="..\Include\EGkLuaAux.h" />
<ClInclude Include="..\Include\EGkMaterial.h" />
@@ -337,7 +358,10 @@ copy $(TargetPath) \EgtProg\Dll64</Command>
<ClInclude Include="..\Include\EGkPoint3d.h" />
<ClInclude Include="..\Include\EGkPointGrid3d.h" />
<ClInclude Include="..\Include\EGkPolyArc.h" />
<ClInclude Include="..\Include\EGkPolygon3d.h" />
<ClInclude Include="..\Include\EGkPolygonElevation.h" />
<ClInclude Include="..\Include\EGkPolyLine.h" />
<ClInclude Include="..\Include\EGkQuaternion.h" />
<ClInclude Include="..\Include\EGkSelection.h" />
<ClInclude Include="..\Include\EGkSfrCreate.h" />
<ClInclude Include="..\Include\EGkStmFromCurves.h" />
@@ -345,6 +369,7 @@ copy $(TargetPath) \EgtProg\Dll64</Command>
<ClInclude Include="..\Include\EGkStringUtils3d.h" />
<ClInclude Include="..\Include\EGkSurf.h" />
<ClInclude Include="..\Include\EGkSurfFlatRegion.h" />
<ClInclude Include="..\Include\EGkSurfLocal.h" />
<ClInclude Include="..\Include\EGkSurfTriMesh.h" />
<ClInclude Include="..\Include\EGkTriangle3d.h" />
<ClInclude Include="..\Include\EGkUiUnits.h" />
@@ -354,6 +379,7 @@ copy $(TargetPath) \EgtProg\Dll64</Command>
<ClInclude Include="..\Include\EGkVolZmap.h" />
<ClInclude Include="..\Include\EGnEgtUUID.h" />
<ClInclude Include="..\Include\EGnFileUtils.h" />
<ClInclude Include="..\Include\EGnGetKeyData.h" />
<ClInclude Include="..\Include\EGnGetModuleVer.h" />
<ClInclude Include="..\Include\EGnLuaAux.h" />
<ClInclude Include="..\Include\EGnLuaMgr.h" />
@@ -368,6 +394,7 @@ copy $(TargetPath) \EgtProg\Dll64</Command>
<ClInclude Include="..\Include\EgtLibVer.h" />
<ClInclude Include="..\Include\EgtNumCollection.h" />
<ClInclude Include="..\Include\EgtNumUtils.h" />
<ClInclude Include="..\Include\EgtPerfCounter.h" />
<ClInclude Include="..\Include\EgtPointerOwner.h" />
<ClInclude Include="..\Include\EgtStringBase.h" />
<ClInclude Include="..\Include\EgtStringConverter.h" />
@@ -395,6 +422,8 @@ copy $(TargetPath) \EgtProg\Dll64</Command>
<ClInclude Include="DrillingData.h" />
<ClInclude Include="Estimator.h" />
<ClInclude Include="Exit.h" />
<ClInclude Include="FiveAxisMilling.h" />
<ClInclude Include="FiveAxisMillingData.h" />
<ClInclude Include="Generator.h" />
<ClInclude Include="GenMachining.h" />
<ClInclude Include="GenMachiningData.h" />
@@ -431,10 +460,14 @@ copy $(TargetPath) \EgtProg\Dll64</Command>
<ClInclude Include="SetTempPhase.h" />
<ClInclude Include="SetupMgr.h" />
<ClInclude Include="Simulator.h" />
<ClInclude Include="SimulatorSP.h" />
<ClInclude Include="SimulatorMP.h" />
<ClInclude Include="stdafx.h" />
<ClInclude Include="Head.h" />
<ClInclude Include="SurfFinishing.h" />
<ClInclude Include="SurfFinishingData.h" />
<ClInclude Include="SurfRoughing.h" />
<ClInclude Include="SurfRoughingData.h" />
<ClInclude Include="Table.h" />
<ClInclude Include="TcPos.h" />
<ClInclude Include="ToolData.h" />
EgtMachKernel.vcxproj.filters
+98 -5
View File
@@ -150,7 +150,7 @@
<ClCompile Include="MachMgrDBTools.cpp">
<Filter>Source Files\MachMgr</Filter>
</ClCompile>
<ClCompile Include="Simulator.cpp">
<ClCompile Include="SimulatorSP.cpp">
<Filter>Source Files\Output</Filter>
</ClCompile>
<ClCompile Include="MachMgrPhases.cpp">
@@ -234,6 +234,21 @@
<ClCompile Include="TcPos.cpp">
<Filter>Source Files\Machine</Filter>
</ClCompile>
<ClCompile Include="FiveAxisMillingData.cpp">
<Filter>Source Files\Machinings</Filter>
</ClCompile>
<ClCompile Include="FiveAxisMilling.cpp">
<Filter>Source Files\Operations</Filter>
</ClCompile>
<ClCompile Include="SurfRoughingData.cpp">
<Filter>Source Files\Machinings</Filter>
</ClCompile>
<ClCompile Include="SurfRoughing.cpp">
<Filter>Source Files\Operations</Filter>
</ClCompile>
<ClCompile Include="SimulatorMP.cpp">
<Filter>Source Files\Output</Filter>
</ClCompile>
</ItemGroup>
<ItemGroup>
<ClInclude Include="DllMain.h">
@@ -329,7 +344,7 @@
<ClInclude Include="..\Include\EMkDispositionConst.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="Simulator.h">
<ClInclude Include="SimulatorSP.h">
<Filter>Header Files</Filter>
</ClInclude>
<ClInclude Include="Generator.h">
@@ -410,9 +425,6 @@
<ClInclude Include="..\Include\EGkBBox3d.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkCDeBoxPolyhedron.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkChainCurves.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
@@ -668,6 +680,87 @@
<ClInclude Include="..\Include\EGkBBox1d.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="FiveAxisMillingData.h">
<Filter>Header Files</Filter>
</ClInclude>
<ClInclude Include="FiveAxisMilling.h">
<Filter>Header Files</Filter>
</ClInclude>
<ClInclude Include="SurfRoughingData.h">
<Filter>Header Files</Filter>
</ClInclude>
<ClInclude Include="SurfRoughing.h">
<Filter>Header Files</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkBiArcs.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkCalcPocketing.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkCAvSilhouetteSurfTm.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkCAvToolSurfTm.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkCDeBoxClosedSurfTm.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkCDeClosedSurfTmClosedSurfTm.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkCDeConeFrustumClosedSurfTm.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkCDeCylClosedSurfTm.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkCDeSpheClosedSurfTm.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkCurveLocal.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkDistPointLine.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkDistPointSurfTm.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkHashGrids1d.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkIntersCurveSurfTm.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkIntersPlaneSurfTm.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkPolygon3d.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkPolygonElevation.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkQuaternion.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGkSurfLocal.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EGnGetKeyData.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="..\Include\EgtPerfCounter.h">
<Filter>Header Files\Include</Filter>
</ClInclude>
<ClInclude Include="SimulatorMP.h">
<Filter>Header Files</Filter>
</ClInclude>
<ClInclude Include="Simulator.h">
<Filter>Header Files</Filter>
</ClInclude>
</ItemGroup>
<ItemGroup>
<ResourceCompile Include="EgtMachKernel.rc">
Exit.cpp
+3
View File
@@ -124,6 +124,9 @@ Exit::Modify( const Point3d& ptPos, double dExitMaxAdjust)
}
// Assegno la nuova posizione
m_ptPos = ptPos ;
// Sistemo la geometria dell'uscita
if ( ! vtDelta.IsZero())
m_pGeomDB->Translate( m_nOwnerId, vtDelta) ;
return true ;
}
FiveAxisMilling.cpp
+984
View File
@@ -0,0 +1,984 @@
//----------------------------------------------------------------------------
// EgalTech 2024-2024
//----------------------------------------------------------------------------
// File : FiveAxisMilling.cpp Data : 22.05.24 Versione : 2.6e5
// Contenuto : Implementazione gestione lavorazione 5 assi.
//
//
//
// Modifiche : 22.05.24 DS Creazione modulo.
//
//
//----------------------------------------------------------------------------
//--------------------------- Include ----------------------------------------
#include "stdafx.h"
#include "MachMgr.h"
#include "DllMain.h"
#include "FiveAxisMilling.h"
#include "OperationConst.h"
#include "/EgtDev/Include/EGkCurveLine.h"
#include "/EgtDev/Include/EGkCurveArc.h"
#include "/EgtDev/Include/EGkCurveComposite.h"
#include "/EgtDev/Include/EGkArcSpecial.h"
#include "/EgtDev/Include/EGkSfrCreate.h"
#include "/EgtDev/Include/EGkSurfTriMesh.h"
#include "/EgtDev/Include/EGkUserObjFactory.h"
#include "/EgtDev/Include/EGnStringKeyVal.h"
#include "/EgtDev/Include/EgtPointerOwner.h"
#include "/EgtDev/Include/EgtIniFile.h"
using namespace std ;
//------------------------------ Errors --------------------------------------
// 3301 = "Error in FiveAxisMilling : UpdateToolData failed"
// 3302 = "Error in FiveAxisMilling : missing Script (xxx)"
// 3303 = "Error in FiveAxisMilling : Error in xxx (nnn)"
// 3304 = "Error in FiveAxisMilling : axes values not calculable"
// 3305 = "Error in FiveAxisMilling : outstroke xx"
// 3306 = "Error in FiveAxisMilling : link movements not calculable"
// 3307 = "Error in FiveAxisMilling : link outstroke xx"
// 3308 = "Error in FiveAxisMilling : post apply not calculable"
// 3309 = "Error in FiveAxisMilling : Tool loading failed"
// 3310 = "Error in FiveAxisMilling : aggregate from bottom not allowed"
// 3351 = "Warning in FiveAxisMilling : Skipped entity (xx)"
// 3352 = "Warning in FiveAxisMilling : No machinable path"
// 3353 = "Warning in FiveAxisMilling : Tool name changed (xx)"
// 3354 = "Warning in FiveAxisMilling : Tool data changed (xx)"
//------------------------------ Constants -----------------------------------
static const string EMC_VAR = "EMC" ; // tabella variabili locali per calcolo
static const string EVAR_MACHID = ".MACHID" ; // IN (int) identificativo della lavorazione
static const string EVAR_GEOM = ".GEOM" ; // IN (table) tabella delle entità da lavorare
static const string EVAR_DEPTH = ".DEPTH" ; // IN (string) affondamento (espressione numerica)
static const string EVAR_TINVERT = ".TOOLINVERT" ; // IN (bool) flag di inversione direzione utensile
static const string EVAR_INVERT = ".INVERT" ; // IN (bool) flag di inversione direzione lavorazione
static const string EVAR_STARTPOS = ".STARTPOS" ; // IN (num) quota di inizio lavorazione (sempre >= 0)
static const string EVAR_OFFSR = ".OFFSR" ; // IN (num) offset radiale
static const string EVAR_OFFSL = ".OFFSL" ; // IN (num) offset longitudinale
static const string EVAR_SYSNOTES = ".SYSNOTES" ; // IN (string) note interne
static const string EVAR_USERNOTES = ".USERNOTES" ;// IN (string) note dell'utente
static const string EVAR_TOOL = ".TOOL" ; // IN (string) nome dell'utensile
static const string EVAR_HEAD = ".HEAD" ; // IN (string) nome testa
static const string EVAR_EXIT = ".EXIT" ; // IN (int) indice uscita
static const string EVAR_TTYPE = ".TTYPE" ; // IN (int) tipo utensile
static const string EVAR_TMAXMAT = ".TMAXMAT" ; // IN (num) massimo materiale
static const string EVAR_TDIAM = ".TDIAM" ; // IN (num) diametro utensile
static const string EVAR_TTOTDIAM = ".TTOTDIAM" ; // IN (num) diametro totale utensile
static const string EVAR_TLEN = ".TLEN" ; // IN (num) lunghezza utensile
static const string EVAR_TTOTLEN = ".TTOTLEN" ; // IN (num) lunghezza totale utensile
static const string EVAR_TTHICK = ".THICK" ; // IN (num) spessore per lame o altezza taglienti
static const string EVAR_TCORNRAD = ".TCORNRAD" ; // IN (num) raggio corner
static const string EVAR_TSIDEANG = ".TSIDEANG" ; // IN (num) angolo del fianco rispetto all'asse
static const string EVAR_FEED = ".FEED" ; // IN (num) feed dell'utensile
static const string EVAR_STARTFEED = ".STARTFEED" ;// IN (num) feed di inizio dell'utensile
static const string EVAR_ENDFEED = ".ENDFEED" ; // IN (num) feed di fine dell'utensile
static const string EVAR_TIPFEED = ".TIPFEED" ; // IN (num) feed di punta dell'utensile
static const string EVAR_ISROBOT = ".ISROBOT" ; // IN (bool) flag per indicare che la cinematica è di tipo robot
static const string EVAR_ERROR = ".ERR" ; // OUT (int) codice di errore ( 0 = ok)
static const string EVAR_MILLS = ".MILLS" ; // OUT (int) numero di percorsi di lavoro
static const string ON_PREVIEW = "OnPreview_" ;
static const string ON_APPLY = "OnApply_" ;
//----------------------------------------------------------------------------
USEROBJ_REGISTER( GetOperationClass( OPER_FIVEAXISMILLING), FiveAxisMilling) ;
//----------------------------------------------------------------------------
const string&
FiveAxisMilling::GetClassName( void) const
{
return USEROBJ_GETNAME( FiveAxisMilling) ;
}
//----------------------------------------------------------------------------
FiveAxisMilling*
FiveAxisMilling::Clone( void) const
{
// alloco oggetto
FiveAxisMilling* pGenM = new(nothrow) FiveAxisMilling ;
// eseguo copia dei dati
if ( pGenM != nullptr) {
try {
pGenM->m_vId = m_vId ;
pGenM->m_pMchMgr = m_pMchMgr ;
pGenM->m_nPhase = m_nPhase ;
pGenM->m_Params = m_Params ;
pGenM->m_TParams = m_TParams ;
pGenM->m_nStatus = m_nStatus ;
pGenM->m_nMills = m_nMills ;
}
catch( ...) {
delete pGenM ;
return nullptr ;
}
}
// ritorno l'oggetto
return pGenM ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::Dump( string& sOut, bool bMM, const char* szNewLine) const
{
sOut += GetClassName() + "[mm]" + szNewLine ;
sOut += KEY_PHASE + EQUAL + ToString( m_nPhase) + szNewLine ;
sOut += KEY_IDS + EQUAL + ToString( m_vId) + szNewLine ;
for ( int i = 0 ; i < m_Params.GetSize() ; ++ i)
sOut += m_Params.ToString( i) + szNewLine ;
for ( int i = 0 ; i < m_TParams.GetSize() ; ++ i)
sOut += m_TParams.ToString( i) + szNewLine ;
sOut += KEY_NUM + EQUAL + ToString( m_nMills) + szNewLine ;
sOut += KEY_STAT + EQUAL + ToString( m_nStatus) + szNewLine ;
return true ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::Save( int nBaseId, STRVECTOR& vString) const
{
try {
int nSize = 1 + m_Params.GetSize() + m_TParams.GetSize() + 3 ;
vString.insert( vString.begin(), nSize, "") ;
int k = - 1 ;
if ( ! SetVal( KEY_IDS, m_vId, vString[++k]))
return false ;
for ( int i = 0 ; i < m_Params.GetSize() ; ++ i)
vString[++k] = m_Params.ToString( i) ;
for ( int i = 0 ; i < m_TParams.GetSize() ; ++ i)
vString[++k] = m_TParams.ToString( i) ;
if ( ! SetVal( KEY_PHASE, m_nPhase, vString[++k]))
return false ;
if ( ! SetVal( KEY_NUM, m_nMills, vString[++k]))
return false ;
if ( ! SetVal( KEY_STAT, m_nStatus, vString[++k]))
return false ;
}
catch( ...) {
return false ;
}
return true ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::Load( const STRVECTOR& vString, int nBaseGdbId)
{
int nSize = int( vString.size()) ;
// lista identificativi geometrie da lavorare
int k = - 1 ;
if ( k >= nSize - 1 || ! GetVal( vString[++k], KEY_IDS, m_vId))
return false ;
for ( auto& Sel : m_vId)
Sel.nId += nBaseGdbId ;
// parametri lavorazione
for ( int i = 0 ; i < m_Params.GetSize() ; ++ i) {
int nKey ;
if ( k >= nSize - 1 || ! m_Params.FromString( vString[++k], nKey) || nKey != i) {
if ( m_Params.IsOptional( i))
-- k ;
else
return false ;
}
}
// parametri utensile
for ( int i = 0 ; i < m_TParams.GetSize() ; ++ i) {
int nKey ;
if ( k >= nSize - 1 || ! m_TParams.FromString( vString[++k], nKey) || nKey != i)
return false ;
}
// parametri di stato
while ( k < nSize - 1) {
// separo chiave da valore
string sKey, sVal ;
SplitFirst( vString[++k], "=", sKey, sVal) ;
// leggo
if ( sKey == KEY_PHASE) {
if ( ! FromString( sVal, m_nPhase))
return false ;
}
else if ( sKey == KEY_NUM) {
if ( ! FromString( sVal, m_nMills))
return false ;
}
else if ( sKey == KEY_STAT) {
if ( ! FromString( sVal, m_nStatus))
return false ;
}
}
return true ;
}
//----------------------------------------------------------------------------
//----------------------------------------------------------------------------
FiveAxisMilling::FiveAxisMilling( void)
{
m_Params.m_sName = "*" ;
m_Params.m_sToolName = "*" ;
m_TParams.m_sName = "*" ;
m_TParams.m_sHead = "*" ;
m_nStatus = MCH_ST_TO_VERIFY ;
m_nMills = 0 ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::Prepare( const string& sGenMchName)
{
// verifico il gestore lavorazioni
if ( m_pMchMgr == nullptr)
return false ;
// recupero il gestore DB utensili della macchina corrente
ToolsMgr* pTMgr = m_pMchMgr->GetCurrToolsMgr() ;
if ( pTMgr == nullptr)
return false ;
// recupero il gestore DB lavorazioni della macchina corrente
MachiningsMgr* pMMgr = m_pMchMgr->GetCurrMachiningsMgr() ;
if ( pMMgr == nullptr)
return false ;
// ricerca della lavorazione di libreria con il nome indicato
const FiveAxisMillingData* pDdata = GetFiveAxisMillingData( pMMgr->GetMachining( sGenMchName)) ;
if ( pDdata == nullptr)
return false ;
m_Params = *pDdata ;
// ricerca dell'utensile usato dalla lavorazione
const ToolData* pTdata = pTMgr->GetTool( m_Params.m_ToolUuid) ;
if ( pTdata == nullptr)
return false ;
m_TParams = *pTdata ;
m_Params.m_sToolName = m_TParams.m_sName ;
return true ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::SetParam( int nType, bool bVal)
{
switch ( nType) {
case MPA_INVERT :
if ( bVal != m_Params.m_bInvert)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_bInvert = bVal ;
return true ;
case MPA_TOOLINVERT :
if ( bVal != m_Params.m_bToolInvert)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_bToolInvert = bVal ;
return true ;
}
return false ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::SetParam( int nType, int nVal)
{
switch ( nType) {
case MPA_SCC :
if ( ! m_Params.VerifySolCh( nVal))
return false ;
if ( nVal != m_Params.m_nSolCh)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_nSolCh = nVal ;
return true ;
case MPA_SUBTYPE :
if ( nVal != m_Params.m_nSubType)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_nSubType = nVal ;
return true ;
}
return false ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::SetParam( int nType, double dVal)
{
switch ( nType) {
case MPA_SPEED :
if ( ! m_TParams.VerifySpeed( dVal))
return false ;
if ( abs( m_TParams.m_dSpeed - dVal) < EPS_MACH_ANG_PAR)
dVal = 0 ;
if ( abs( dVal - m_Params.m_dSpeed) > EPS_MACH_ANG_PAR)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_dSpeed = dVal ;
return true ;
case MPA_FEED :
if ( abs( m_TParams.m_dFeed - dVal) < EPS_MACH_LEN_PAR)
dVal = 0 ;
if ( abs( dVal - m_Params.m_dFeed) > EPS_MACH_LEN_PAR)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_dFeed = dVal ;
return true ;
case MPA_STARTFEED :
if ( abs( m_TParams.m_dStartFeed - dVal) < EPS_MACH_LEN_PAR)
dVal = 0 ;
if ( abs( dVal - m_Params.m_dStartFeed) > EPS_MACH_LEN_PAR)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_dStartFeed = dVal ;
return true ;
case MPA_ENDFEED :
if ( abs( m_TParams.m_dEndFeed - dVal) < EPS_MACH_LEN_PAR)
dVal = 0 ;
if ( abs( dVal - m_Params.m_dEndFeed) > EPS_MACH_LEN_PAR)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_dEndFeed = dVal ;
return true ;
case MPA_TIPFEED :
if ( abs( m_TParams.m_dTipFeed - dVal) < EPS_MACH_LEN_PAR)
dVal = 0 ;
if ( abs( dVal - m_Params.m_dTipFeed) > EPS_MACH_LEN_PAR)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_dTipFeed = dVal ;
return true ;
case MPA_OFFSR :
if ( abs( m_TParams.m_dOffsR - dVal) < EPS_MACH_LEN_PAR)
dVal = UNKNOWN_PAR ;
if ( abs( dVal - m_Params.m_dOffsR) > EPS_MACH_LEN_PAR)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_dOffsR = dVal ;
return true ;
case MPA_OFFSL :
if ( abs( m_TParams.m_dOffsL - dVal) < EPS_MACH_LEN_PAR)
dVal = UNKNOWN_PAR ;
if ( abs( dVal - m_Params.m_dOffsL) > EPS_MACH_LEN_PAR)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_dOffsL = dVal ;
return true ;
case MPA_DEPTH: {
string sVal = ToString( dVal) ;
if ( sVal != m_Params.m_sDepth)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_sDepth = sVal ;
} return true ;
case MPA_STARTPOS :
if ( abs( dVal - m_Params.m_dStartPos) > EPS_MACH_LEN_PAR)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_dStartPos = dVal ;
return true ;
}
return false ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::SetParam( int nType, const string& sVal)
{
switch ( nType) {
case MPA_TOOL : {
const ToolData* pTdata ;
if ( ! m_Params.VerifyTool( m_pMchMgr->GetCurrToolsMgr(), sVal, pTdata))
return false ;
if ( ! SameTool( m_TParams, *pTdata))
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_sToolName = sVal ;
m_Params.m_ToolUuid = pTdata->m_Uuid ;
m_TParams = *pTdata ;
} return true ;
case MPA_DEPTH_STR :
if ( sVal != m_Params.m_sDepth)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_sDepth = sVal ;
return true ;
case MPA_SYSNOTES :
if ( sVal != m_Params.m_sSysNotes)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_sSysNotes = sVal ;
return true ;
case MPA_USERNOTES :
if ( sVal != m_Params.m_sUserNotes)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_sUserNotes = sVal ;
return true ;
case MPA_INITANGS :
if ( sVal != m_Params.m_sInitAngs)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_sInitAngs = sVal ;
return true ;
case MPA_BLOCKEDAXIS :
if ( sVal != m_Params.m_sBlockedAxis)
m_nStatus |= MCH_ST_PARAM_MODIF ;
m_Params.m_sBlockedAxis = sVal ;
return true ;
}
return false ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::SetGeometry( const SELVECTOR& vIds)
{
// verifico validità gestore DB geometrico
if ( m_pGeomDB == nullptr)
return false ;
// reset della geometria corrente
m_vId.clear() ;
// verifico che gli identificativi rappresentino delle entità ammissibili (tutte curve o tutte facce)
int nType = GEO_NONE ;
for ( const auto& Id : vIds) {
// test sull'entità
int nSubs ;
if ( ! VerifyGeometry( Id, nSubs, nType)) {
string sInfo = "Warning in FiveAxisMilling : Skipped entity " + ToString( Id) ;
m_pMchMgr->SetWarning( 3351, sInfo) ;
continue ;
}
// posso aggiungere alla lista
m_vId.emplace_back( Id) ;
}
// aggiorno lo stato
m_nStatus |= MCH_ST_GEO_MODIF ;
// restituisco presenza geometria da lavorare
return ( ! m_vId.empty() || vIds.empty()) ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::Preview( bool bRecalc)
{
// reset numero percorsi di lavoro generati
m_nMills = 0 ;
// verifico validità gestore DB geometrico e Id del gruppo
if ( m_pGeomDB == nullptr || ! m_pGeomDB->ExistsObj( m_nOwnerId))
return false ;
// aggiorno dati geometrici dell'utensile
if ( ! UpdateToolData()) {
m_pMchMgr->SetLastError( 3301, "Error in FiveAxisMilling : UpdateToolData failed") ;
return false ;
}
// rendo corrente l'utensile usato nella lavorazione
if ( ! m_pMchMgr->SetCalcTool( m_TParams.m_sName, m_TParams.m_sHead, m_TParams.m_nExit)) {
m_pMchMgr->SetLastError( 3309, "Error in FiveAxisMilling : Tool loading failed") ;
return false ;
}
// recupero gruppo per geometria di Preview
int nPvId = m_pGeomDB->GetFirstNameInGroup( m_nOwnerId, MCH_PV) ;
// se non c'è, lo aggiungo
if ( nPvId == GDB_ID_NULL) {
nPvId = m_pGeomDB->AddGroup( GDB_ID_NULL, m_nOwnerId, Frame3d()) ;
if ( nPvId == GDB_ID_NULL)
return false ;
m_pGeomDB->SetName( nPvId, MCH_PV) ;
}
// altrimenti lo svuoto
else
m_pGeomDB->EmptyGroup( nPvId) ;
// recupero la macchina corrente
Machine* pMch = m_pMchMgr->GetCurrMachine() ;
if ( pMch == nullptr)
return false ;
// nome della funzione lua da Ini della macchina
string sMachIni = pMch->GetMachineDir() + "\\" + pMch->GetMachineName() + ".ini" ;
string sKey = FIVEAXISMILLING_SCRIPT_KEY + ToString( m_Params.m_nSubType) ;
string sName = GetPrivateProfileStringUtf8( FIVEAXISMILLING_SEC.c_str(), sKey.c_str(), "", sMachIni.c_str()) ;
string sPreview = ON_PREVIEW + sName ;
// verifico esistenza funzione
if ( ! pMch->LuaExistsFunction( sPreview)) {
string sErr = "Error in FiveAxisMilling : missing Script " + sPreview ;
m_pMchMgr->SetLastError( 3302, sErr) ;
return false ;
}
// imposto stato
bool bOk = true ;
int nErr = 99 ;
// imposto valori parametri
bOk = bOk && pMch->LuaCreateGlobTable( EMC_VAR) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_MACHID, m_nOwnerId) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_GEOM, m_vId) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_DEPTH, m_Params.m_sDepth) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TINVERT, m_Params.m_bToolInvert) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_INVERT, m_Params.m_bInvert) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_STARTPOS, m_Params.m_dStartPos) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_OFFSR, GetOffsR()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_OFFSL, GetOffsL()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_SYSNOTES, m_Params.m_sSysNotes) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_USERNOTES, m_Params.m_sUserNotes) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TOOL, m_TParams.m_sName) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_HEAD, m_TParams.m_sHead) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_EXIT, m_TParams.m_nExit) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TTYPE, m_TParams.m_nType) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TMAXMAT, m_TParams.m_dMaxMat) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TDIAM, m_TParams.m_dDiam) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TTOTDIAM, m_TParams.m_dTDiam) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TLEN, m_TParams.m_dLen) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TTOTLEN, m_TParams.m_dTLen) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TTHICK, m_TParams.m_dThick) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TCORNRAD, m_TParams.m_dCornRad) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TSIDEANG, m_TParams.m_dSideAng) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_FEED, GetFeed()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_STARTFEED, GetStartFeed()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_ENDFEED, GetEndFeed()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TIPFEED, GetTipFeed()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_ISROBOT, m_pMchMgr->GetCurrIsRobot()) ;
// eseguo
bOk = bOk && pMch->LuaCallFunction( sPreview, false) ;
// recupero valori parametri obbligatori
bOk = bOk && pMch->LuaGetGlobVar( EMC_VAR + EVAR_ERROR, nErr) ;
bOk = bOk && pMch->LuaGetGlobVar( EMC_VAR + EVAR_MILLS, m_nMills) ;
// reset
bOk = bOk && pMch->LuaResetGlobVar( EMC_VAR) ;
// segnalo errori
if ( ! bOk || nErr != 0) {
m_nMills = 0 ;
string sErr = "Error in FiveAxisMilling : Error in " + sPreview + " (" + ToString( nErr) + ")" ;
m_pMchMgr->SetLastError( 3303, sErr) ;
return false ;
}
return true ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::Apply( bool bRecalc, bool bPostApply)
{
// reset numero percorsi di lavoro generati
int nCurrMills = m_nMills ;
m_nMills = 0 ;
// verifico validità gestore DB geometrico e Id del gruppo
if ( m_pGeomDB == nullptr || ! m_pGeomDB->ExistsObj( m_nOwnerId))
return false ;
// aggiorno dati geometrici dell'utensile
bool bToolChanged = true ;
if ( ! UpdateToolData( &bToolChanged)) {
m_pMchMgr->SetLastError( 3301, "Error in FiveAxisMilling : UpdateToolData failed") ;
return false ;
}
// non è prevista fresatura 5 assi con aggregato da sotto
if ( IsAggrBottom( m_TParams.m_sHead)) {
m_pMchMgr->SetLastError( 3310, "Error in FiveAxisMilling : aggregate from bottom not allowed") ;
return false ;
}
// verifico se necessario continuare nell'aggiornamento
if ( ! bRecalc && ! bToolChanged &&
( m_nStatus == MCH_ST_OK || ( ! bPostApply && m_nStatus == MCH_ST_NO_POSTAPPL))) {
// confermo i percorsi di lavorazione
m_nMills = nCurrMills ;
LOG_DBG_INFO( GetEMkLogger(), "FiveAxisMilling apply skipped : status already ok") ;
// eseguo aggiornamento assi macchina e collegamento con operazione precedente
if ( ! Update( bPostApply))
return false ;
LOG_DBG_INFO( GetEMkLogger(), "Update done") ;
// esco con successo
return true ;
}
m_nStatus = MCH_ST_TO_VERIFY ;
// rendo corrente l'utensile usato nella lavorazione
if ( ! m_pMchMgr->SetCalcTool( m_TParams.m_sName, m_TParams.m_sHead, m_TParams.m_nExit)) {
m_pMchMgr->SetLastError( 3309, "Error in FiveAxisMilling : Tool loading failed") ;
return false ;
}
// recupero gruppo per geometria di lavorazione (Cutter Location)
int nClId = m_pGeomDB->GetFirstNameInGroup( m_nOwnerId, MCH_CL) ;
// se non c'è, lo aggiungo
if ( nClId == GDB_ID_NULL) {
nClId = m_pGeomDB->AddGroup( GDB_ID_NULL, m_nOwnerId, Frame3d()) ;
if ( nClId == GDB_ID_NULL)
return false ;
m_pGeomDB->SetName( nClId, MCH_CL) ;
}
// altrimenti lo svuoto
else
m_pGeomDB->EmptyGroup( nClId) ;
// recupero la macchina corrente
Machine* pMch = m_pMchMgr->GetCurrMachine() ;
if ( pMch == nullptr)
return false ;
// nome della funzione lua da Ini della macchina
string sMachIni = pMch->GetMachineDir() + "\\" + pMch->GetMachineName() + ".ini" ;
string sKey = FIVEAXISMILLING_SCRIPT_KEY + ToString( m_Params.m_nSubType) ;
string sName = GetPrivateProfileStringUtf8( FIVEAXISMILLING_SEC.c_str(), sKey.c_str(), "", sMachIni.c_str()) ;
string sApply = ON_APPLY + sName ;
// verifico esistenza funzione
if ( ! pMch->LuaExistsFunction( sApply)) {
string sErr = "Error in FiveAxisMilling : missing Script " + sApply ;
m_pMchMgr->SetLastError( 3302, sErr) ;
return false ;
}
// imposto stato
bool bOk = true ;
int nErr = 99 ;
// imposto valori parametri
bOk = bOk && pMch->LuaCreateGlobTable( EMC_VAR) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_MACHID, m_nOwnerId) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_GEOM, m_vId) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_DEPTH, m_Params.m_sDepth) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TINVERT, m_Params.m_bToolInvert) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_INVERT, m_Params.m_bInvert) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_STARTPOS, m_Params.m_dStartPos) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_OFFSR, GetOffsR()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_OFFSL, GetOffsL()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_SYSNOTES, m_Params.m_sSysNotes) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_USERNOTES, m_Params.m_sUserNotes) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TOOL, m_TParams.m_sName) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_HEAD, m_TParams.m_sHead) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_EXIT, m_TParams.m_nExit) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TTYPE, m_TParams.m_nType) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TMAXMAT, m_TParams.m_dMaxMat) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TDIAM, m_TParams.m_dDiam) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TTOTDIAM, m_TParams.m_dTDiam) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TLEN, m_TParams.m_dLen) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TTOTLEN, m_TParams.m_dTLen) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TTHICK, m_TParams.m_dThick) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TCORNRAD, m_TParams.m_dCornRad) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TSIDEANG, m_TParams.m_dSideAng) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_FEED, GetFeed()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_STARTFEED, GetStartFeed()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_ENDFEED, GetEndFeed()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TIPFEED, GetTipFeed()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_ISROBOT, m_pMchMgr->GetCurrIsRobot()) ;
// eseguo
bOk = bOk && pMch->LuaCallFunction( sApply, false) ;
// recupero valori parametri obbligatori
bOk = bOk && pMch->LuaGetGlobVar( EMC_VAR + EVAR_ERROR, nErr) ;
bOk = bOk && pMch->LuaGetGlobVar( EMC_VAR + EVAR_MILLS, m_nMills) ;
// reset
bOk = bOk && pMch->LuaResetGlobVar( EMC_VAR) ;
// segnalo errori
if ( ! bOk || nErr != 0) {
m_nMills = 0 ;
string sErr = "Error in FiveAxisMilling : Error in " + sApply + " (" + ToString( nErr) + ")" ;
m_pMchMgr->SetLastError( 3303, sErr) ;
return false ;
}
// assegno ingombri dei vari percorsi di lavorazione e della lavorazione nel suo complesso
CalcAndSetBBox( nClId) ;
// eseguo aggiornamento assi macchina e collegamento con operazione precedente
if ( ! Update( bPostApply))
return false ;
// aggiorno stato della lavorazione
m_nStatus = ( bPostApply ? MCH_ST_OK : MCH_ST_NO_POSTAPPL) ;
// dichiaro successiva da aggiornare
UpdateFollowingOperationsStatus( MCH_ST_OTH_MODIF) ;
LOG_DBG_INFO( GetEMkLogger(), "FiveAxisMilling apply done") ;
return true ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::Update( bool bPostApply)
{
// verifico validità gestore DB geometrico e Id del gruppo
if ( m_pGeomDB == nullptr || ! m_pGeomDB->ExistsObj( m_nOwnerId))
return false ;
// se lavorazione vuota, esco
if ( m_nMills == 0) {
m_pMchMgr->SetWarning( 3352, "Warning in FiveAxisMilling : No machinable path") ;
return true ;
}
// elimino le entità CLIMB, RISE e HOME della lavorazione, potrebbero falsare i calcoli degli assi (in ogni casi vengono riaggiunte dopo)
RemoveClimbRiseHome() ;
// imposto eventuale asse bloccato da lavorazione
SetBlockedRotAxis( m_Params.m_sBlockedAxis) ;
// calcolo gli assi macchina
string sHint = ExtractHint( m_Params.m_sUserNotes) ;
if ( ! m_Params.m_sInitAngs.empty())
sHint = m_Params.m_sInitAngs ;
if ( ! CalculateAxesValues( sHint)) {
string sInfo = m_pMchMgr->GetOutstrokeInfo() ;
if ( sInfo.empty())
m_pMchMgr->SetLastError( 3304, "Error in FiveAxisMilling : axes values not calculable") ;
else
m_pMchMgr->SetLastError( 3305, "Error in FiveAxisMilling : outstroke ") ;
return false ;
}
// gestione movimenti all'inizio di ogni singolo percorso di lavorazione e alla fine della lavorazione
bool bVpl ;
if ( ! FromString( ExtractInfo( m_Params.m_sUserNotes, "Vpl:"), bVpl))
bVpl = true ;
if ( ! AdjustStartEndMovements( bVpl)) {
string sInfo = m_pMchMgr->GetOutstrokeInfo() ;
if ( sInfo.empty())
m_pMchMgr->SetLastError( 3306, "Error in FiveAxisMilling : link movements not calculable") ;
else
m_pMchMgr->SetLastError( 3307, "Error in FiveAxisMilling : link outstroke ") ;
return false ;
}
// assegno estremi degli assi dei vari percorsi di lavorazione e della lavorazione nel suo complesso
CalcAndSetAxesBBox() ;
// esecuzione eventuali personalizzazioni
string sErr ;
if ( bPostApply && ! PostApply( sErr)) {
if ( ! IsEmptyOrSpaces( sErr))
m_pMchMgr->SetLastError( 3308, sErr) ;
else
m_pMchMgr->SetLastError( 3308, "Error in FiveAxisMilling : post apply not calculable") ;
return false ;
}
return true ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::GetParam( int nType, bool& bVal) const
{
switch ( nType) {
case MPA_INVERT :
bVal = m_Params.m_bInvert ;
return true ;
case MPA_TOOLINVERT :
bVal = m_Params.m_bToolInvert ;
return true ;
}
bVal = false ;
return false ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::GetParam( int nType, int& nVal) const
{
switch ( nType) {
case MPA_TYPE :
nVal = MT_FIVEAXISMILLING ;
return true ;
case MPA_SCC :
nVal = m_Params.m_nSolCh ;
return true ;
case MPA_SUBTYPE :
nVal = m_Params.m_nSubType ;
return true ;
}
nVal = 0 ;
return false ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::GetParam( int nType, double& dVal) const
{
switch ( nType) {
case MPA_SPEED :
dVal = GetSpeed() ;
return true ;
case MPA_FEED :
dVal = GetFeed() ;
return true ;
case MPA_STARTFEED :
dVal = GetStartFeed() ;
return true ;
case MPA_ENDFEED :
dVal = GetEndFeed() ;
return true ;
case MPA_TIPFEED :
dVal = GetTipFeed() ;
return true ;
case MPA_OFFSR :
dVal = GetOffsR() ;
return true ;
case MPA_OFFSL :
dVal = GetOffsL() ;
return true ;
case MPA_STARTPOS :
dVal = m_Params.m_dStartPos ;
return true ;
}
dVal = 0 ;
return false ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::GetParam( int nType, string& sVal) const
{
switch ( nType) {
case MPA_NAME :
sVal = m_Params.m_sName ;
return true ;
case MPA_TOOL :
sVal = m_Params.m_sToolName ;
return true ;
case MPA_DEPTH_STR :
sVal = m_Params.m_sDepth ;
return true ;
case MPA_TUUID :
sVal = ToString( m_Params.m_ToolUuid) ;
return true ;
case MPA_UUID :
sVal = ToString( m_Params.m_Uuid) ;
return true ;
case MPA_SYSNOTES :
sVal = m_Params.m_sSysNotes ;
return true ;
case MPA_USERNOTES :
sVal = m_Params.m_sUserNotes ;
return true ;
case MPA_INITANGS :
sVal = m_Params.m_sInitAngs ;
return true ;
case MPA_BLOCKEDAXIS :
sVal = m_Params.m_sBlockedAxis ;
return true ;
}
sVal = "" ;
return false ;
}
//----------------------------------------------------------------------------
const ToolData&
FiveAxisMilling::GetToolData( void) const
{
return m_TParams ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::UpdateToolData( bool* pbChanged)
{
// recupero il gestore DB utensili della macchina corrente
ToolsMgr* pTMgr = m_pMchMgr->GetCurrToolsMgr() ;
if ( pTMgr == nullptr)
return false ;
// recupero l'utensile nel DB utensili
const ToolData* pTdata = pTMgr->GetTool( m_Params.m_ToolUuid) ;
if ( pTdata == nullptr)
return false ;
// salvo posizione TC, testa e uscita originali
string sOrigTcPos = m_TParams.m_sTcPos ;
string sOrigHead = m_TParams.m_sHead ;
int nOrigExit = m_TParams.m_nExit ;
// verifico se sono diversi (ad esclusione di nome, posizione TC, testa e uscita)
bool bChanged = ( ! SameTool( m_TParams, *pTdata, false)) ;
// aggiorno comunque i parametri
m_TParams = *pTdata ;
// se definito attrezzaggio, aggiorno i parametri che ne possono derivare
string sTcPos ; string sHead ; int nExit ;
if ( m_pMchMgr->GetCurrSetupMgr().GetToolData( m_TParams.m_sName, sTcPos, sHead, nExit)) {
if ( sOrigTcPos != sTcPos ||
sOrigHead != sHead ||
nOrigExit != nExit)
bChanged = true ;
m_TParams.m_sTcPos = sTcPos ;
m_TParams.m_sHead = sHead ;
m_TParams.m_nExit = nExit ;
}
else {
if ( sOrigTcPos != pTdata->m_sTcPos ||
sOrigHead != pTdata->m_sHead ||
nOrigExit != pTdata->m_nExit)
bChanged = true ;
}
// eventuali segnalazioni
if ( ! EqualNoCase( m_Params.m_sToolName, m_TParams.m_sName)) {
string sInfo = "Warning in FiveAxisMilling : tool name changed (" +
m_Params.m_sToolName + "->" + m_TParams.m_sName + ")" ;
m_pMchMgr->SetWarning( 3353, sInfo) ;
m_Params.m_sToolName = m_TParams.m_sName ;
}
if ( bChanged) {
string sInfo = "Warning in FiveAxisMilling : tool data changed (" +
m_Params.m_sToolName + ")" ;
m_pMchMgr->SetWarning( 3354, sInfo) ;
}
// se definito parametro di ritorno, lo assegno
if ( pbChanged != nullptr)
*pbChanged = bChanged ;
return true ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::GetGeometry( SELVECTOR& vIds) const
{
// restituisco l'elenco delle entità
vIds = m_vId ;
return true ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMilling::VerifyGeometry( SelData Id, int& nSubs, int& nType)
{
// ammessi : tutte curve o tutte facce di trimesh
const IGeoObj* pGObj = m_pGeomDB->GetGeoObj( Id.nId) ;
if ( pGObj == nullptr)
return false ;
// se ammesse curve ed è tale
if ( nType != GEO_SURF && ( pGObj->GetType() & GEO_CURVE) != 0) {
const ICurve* pCurve = nullptr ;
// se direttamente la curva
if ( Id.nSub == SEL_SUB_ALL) {
pCurve = ::GetCurve( pGObj) ;
if ( pCurve != nullptr) {
if ( pCurve->GetType() == CRV_COMPO)
nSubs = ::GetCurveComposite( pCurve)->GetCurveCount() ;
else
nSubs = 0 ;
}
}
// altrimenti sottocurva di composita
else {
const ICurveComposite* pCompo = GetCurveComposite( pGObj) ;
if ( pCompo != nullptr)
pCurve = pCompo->GetCurve( Id.nSub) ;
nSubs = 0 ;
}
return ( pCurve != nullptr) ;
}
// se altrimenti ammesse superfici trimesh ed è tale
else if ( nType != GEO_CURVE && ( pGObj->GetType() & GEO_SURF) != 0) {
const ISurfTriMesh* pSurf = ::GetSurfTriMesh( pGObj) ;
if ( pSurf == nullptr)
return false ;
// se direttamente la superficie
if ( Id.nSub == SEL_SUB_ALL) {
nSubs = pSurf->GetFacetCount() ;
return true ;
}
// altrimenti faccia di superficie trimesh
else {
// se faccia non esistente
if ( Id.nSub > pSurf->GetFacetCount())
return false ;
// tutto bene
nSubs = 0 ;
return true ;
}
}
// altrimenti errore
else
return false ;
}
//----------------------------------------------------------------------------
double
FiveAxisMilling::GetApproxLinTol( void) const
{
double dLinTol ;
if ( GetValInNotes( m_Params.m_sUserNotes, "LinTol", dLinTol))
return dLinTol ;
else
return Operation::GetApproxLinTol() ;
}
FiveAxisMilling.h
+94
View File
@@ -0,0 +1,94 @@
//----------------------------------------------------------------------------
// EgalTech 2024-2024
//----------------------------------------------------------------------------
// File : FiveAxisMilling.h Data : 22.05.24 Versione : 2.6e5
// Contenuto : Dichiarazione della classe FiveAxisMilling.
//
//
//
// Modifiche : 22.05.24 DS Creazione modulo.
//
//
//----------------------------------------------------------------------------
#pragma once
#include "Machining.h"
#include "FiveAxisMillingData.h"
#include "ToolData.h"
class ICurve ;
class ICurveComposite ;
//----------------------------------------------------------------------------
class FiveAxisMilling : public Machining
{
public : // IUserObj
FiveAxisMilling* Clone( void) const override ;
const std::string& GetClassName( void) const override ;
bool Dump( std::string& sOut, bool bMM = true, const char* szNewLine = "\n") const override ;
bool ToSave( void) const override
{ return true ; }
bool Save( int nBaseId, STRVECTOR& vString) const override ;
bool Load( const STRVECTOR& vString, int nBaseGdbId) override ;
public : // Operation
int GetType( void) const override
{ return OPER_FIVEAXISMILLING ; }
bool IsEmpty( void) const override
{ return ( m_nMills == 0) ; }
bool UpdateStatus( int nModif) override
{ m_nStatus |= nModif ; return true ; }
protected : // Operation
int GetSolCh( void) const override
{ return m_Params.m_nSolCh ; }
public : // Machining
bool Prepare( const std::string& sMillName) override ;
bool SetParam( int nType, bool bVal) override ;
bool SetParam( int nType, int nVal) override ;
bool SetParam( int nType, double dVal) override ;
bool SetParam( int nType, const std::string& sVal) override ;
bool SetGeometry( const SELVECTOR& vIds) override ;
bool Preview( bool bRecalc) override ;
bool Apply( bool bRecalc, bool bPostApply) override ;
bool Update( bool bPostApply) override ;
bool GetParam( int nType, bool& bVal) const override ;
bool GetParam( int nType, int& nVal) const override ;
bool GetParam( int nType, double& dVal) const override ;
bool GetParam( int nType, std::string& sVal) const override ;
bool UpdateToolData( bool* pbChanged = nullptr) override ;
const ToolData& GetToolData( void) const override ;
bool GetGeometry( SELVECTOR& vIds) const override ;
public :
FiveAxisMilling( void) ;
private :
bool VerifyGeometry( SelData Id, int& nSubs, int& nType) ;
double GetApproxLinTol( void) const override ;
private :
double GetSpeed() const
{ return ( IsNullAngValue( m_Params.m_dSpeed) ? m_TParams.m_dSpeed : m_Params.m_dSpeed) ; }
double GetFeed() const
{ return ( IsNullLenValue( m_Params.m_dFeed) ? m_TParams.m_dFeed : m_Params.m_dFeed) ; }
double GetStartFeed() const
{ return ( IsNullLenValue( m_Params.m_dStartFeed) ? m_TParams.m_dStartFeed : m_Params.m_dStartFeed) ; }
double GetEndFeed() const
{ return ( IsNullLenValue( m_Params.m_dEndFeed) ? m_TParams.m_dEndFeed : m_Params.m_dEndFeed) ; }
double GetTipFeed() const
{ return ( IsNullLenValue( m_Params.m_dTipFeed) ? m_TParams.m_dTipFeed : m_Params.m_dTipFeed) ; }
double GetOffsL() const
{ return ( IsUnknownValue( m_Params.m_dOffsL) ? m_TParams.m_dOffsL : m_Params.m_dOffsL) ; }
double GetOffsR() const
{ return ( IsUnknownValue( m_Params.m_dOffsR) ? m_TParams.m_dOffsR : m_Params.m_dOffsR) ; }
private :
SELVECTOR m_vId ; // identificativi entità geometriche da lavorare
FiveAxisMillingData m_Params ; // parametri lavorazione
ToolData m_TParams ; // parametri utensile
int m_nStatus ; // stato di aggiornamento della lavorazione
int m_nMills ; // numero di percorsi di lavoro generati
} ;
FiveAxisMillingData.cpp
+557
View File
@@ -0,0 +1,557 @@
//----------------------------------------------------------------------------
// EgalTech 2024-2024
//----------------------------------------------------------------------------
// File : FiveAxisMillingData.cpp Data : 22.05.24 Versione : 2.6e5
// Contenuto : Implementazione struttura dati fresatura a 5 assi.
//
//
//
// Modifiche : 22.05.24 DS Creazione modulo.
//
//
//----------------------------------------------------------------------------
//--------------------------- Include ----------------------------------------
#include "stdafx.h"
#include "FiveAxisMillingData.h"
#include "MachiningDataFactory.h"
#include "MachiningConst.h"
#include "/EgtDev/Include/EmkToolConst.h"
#include "/EgtDev/Include/EmkSimuGenConst.h"
#include "/EgtDev/Include/EGnStringUtils.h"
#include <array>
#include <cassert>
using namespace std ;
//----------------------------------------------------------------------------
enum nFiveAxisMillingKey {
KEY_AB = 0,
KEY_AI,
KEY_DH,
KEY_F,
KEY_FE,
KEY_FS,
KEY_FT,
KEY_INV,
KEY_NAME,
KEY_NNS,
KEY_NNU,
KEY_OL,
KEY_OR,
KEY_PS,
KEY_S,
KEY_SCC,
KEY_SUBTYPE,
KEY_TI,
KEY_TNAME,
KEY_TUUID,
KEY_UUID,
KEY_ZZZ} ; // rappresenta il numero di elementi
static const array<string,KEY_ZZZ> sFiveAxisMillingKey = {
"AB",
"AI",
"DH",
"F",
"FE",
"FS",
"FT",
"INV",
"NAME",
"NNS",
"NNU",
"OL",
"OR",
"PS",
"S",
"SCC",
"SUB",
"TI",
"TN",
"TU",
"UUID"} ;
//----------------------------------------------------------------------------
MCHDATA_REGISTER( MT_FIVEAXISMILLING, "FIVEAXISMILLING", FiveAxisMillingData) ;
//----------------------------------------------------------------------------
FiveAxisMillingData*
FiveAxisMillingData::Clone( void) const
{
// alloco oggetto
FiveAxisMillingData* pDdata = new(nothrow) FiveAxisMillingData ;
// copio i dati
if ( pDdata != nullptr) {
if ( ! pDdata->CopyFrom( this)) {
delete pDdata ;
return nullptr ;
}
}
return pDdata ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMillingData::CopyFrom( const MachiningData* pMdata)
{
// è inutile copiare se sorgente coincide con destinazione
if ( pMdata == this)
return true ;
// la sorgente deve essere dello stesso tipo
const FiveAxisMillingData* pFdata = GetFiveAxisMillingData( pMdata) ;
if ( pFdata == nullptr)
return false ;
// eseguo copia
m_Uuid = pFdata->m_Uuid ;
m_sName = pFdata->m_sName ;
m_ToolUuid = pFdata->m_ToolUuid ;
m_sToolName = pFdata->m_sToolName ;
m_sBlockedAxis = pFdata->m_sBlockedAxis ;
m_sInitAngs = pFdata->m_sInitAngs ;
m_nSolCh = pFdata->m_nSolCh ;
m_dSpeed = pFdata->m_dSpeed ;
m_dFeed = pFdata->m_dFeed ;
m_dEndFeed = pFdata->m_dEndFeed ;
m_dStartFeed = pFdata->m_dStartFeed ;
m_dTipFeed = pFdata->m_dTipFeed ;
m_dOffsL = pFdata->m_dOffsL ;
m_dOffsR = pFdata->m_dOffsR ;
m_bToolInvert = pFdata->m_bToolInvert ;
m_bInvert = pFdata->m_bInvert ;
m_sDepth = pFdata->m_sDepth ;
m_dStartPos = pFdata->m_dStartPos ;
m_nSubType = pFdata->m_nSubType ;
m_sSysNotes = pFdata->m_sSysNotes ;
m_sUserNotes = pFdata->m_sUserNotes ;
return true ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMillingData::SameAs(const MachiningData* pMdata) const
{
// se coincide con altro -> uguali
if ( pMdata == this)
return true ;
// se sono di tipo diverso -> diversi
const FiveAxisMillingData* pFdata = GetFiveAxisMillingData( pMdata) ;
if ( pFdata == nullptr)
return false ;
// confronto termine a termine
return ( m_Uuid == pFdata->m_Uuid &&
m_sName == pFdata->m_sName &&
m_ToolUuid == pFdata->m_ToolUuid &&
m_sToolName == pFdata->m_sToolName &&
m_sBlockedAxis == pFdata->m_sBlockedAxis &&
m_sInitAngs == pFdata->m_sInitAngs &&
m_nSolCh == pFdata->m_nSolCh &&
abs( m_dSpeed - pFdata->m_dSpeed) < EPS_MACH_ANG_PAR &&
abs( m_dFeed - pFdata->m_dFeed) < EPS_MACH_LEN_PAR &&
abs( m_dEndFeed - pFdata->m_dEndFeed) < EPS_MACH_LEN_PAR &&
abs( m_dStartFeed - pFdata->m_dStartFeed) < EPS_MACH_LEN_PAR &&
abs( m_dTipFeed - pFdata->m_dTipFeed) < EPS_MACH_LEN_PAR &&
abs( m_dOffsL - pFdata->m_dOffsL) < EPS_MACH_LEN_PAR &&
abs( m_dOffsR - pFdata->m_dOffsR) < EPS_MACH_LEN_PAR &&
m_bToolInvert == pFdata->m_bToolInvert &&
m_bInvert == pFdata->m_bInvert &&
m_sDepth == pFdata->m_sDepth &&
abs( m_dStartPos - pFdata->m_dStartPos) < EPS_MACH_LEN_PAR &&
m_nSubType == pFdata->m_nSubType &&
m_sSysNotes == pFdata->m_sSysNotes &&
m_sUserNotes == pFdata->m_sUserNotes) ;
}
//----------------------------------------------------------------------------
int
FiveAxisMillingData::GetSize( void) const
{
// in debug verifico validità ultimo campo
assert( sFiveAxisMillingKey[KEY_UUID] == "UUID") ;
return KEY_ZZZ ;
}
//----------------------------------------------------------------------------
string
FiveAxisMillingData::GetTitle( void) const
{
return MCHDATA_GETNAME( FiveAxisMillingData) ;
}
//----------------------------------------------------------------------------
int
FindFiveAxisMillingKey( const string& sKey)
{
auto TheRange = equal_range( sFiveAxisMillingKey.cbegin(), sFiveAxisMillingKey.cend(), sKey) ;
if ( TheRange.first == TheRange.second)
return - 1 ;
return int( TheRange.first - sFiveAxisMillingKey.cbegin()) ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMillingData::FromString( const string& sString, int& nKey)
{
// separo chiave da valore
string sKey, sVal ;
SplitFirst( sString, "=", sKey, sVal) ;
// riconosco la chiave
nKey = FindFiveAxisMillingKey( ToUpper( sKey)) ;
bool bOk = ( nKey >= 0) ;
switch ( nKey) {
case KEY_AB :
m_sBlockedAxis = sVal ;
break ;
case KEY_AI :
m_sInitAngs = sVal ;
break ;
case KEY_DH :
m_sDepth = sVal ;
if ( m_sDepth.empty())
m_sDepth = "0" ;
break ;
case KEY_F :
bOk = ::FromString( sVal, m_dFeed) ;
break ;
case KEY_FE :
bOk = ::FromString( sVal, m_dEndFeed) ;
break ;
case KEY_FS :
bOk = ::FromString( sVal, m_dStartFeed) ;
break ;
case KEY_FT :
bOk = ::FromString( sVal, m_dTipFeed) ;
break ;
case KEY_INV :
bOk = ::FromString( sVal, m_bInvert) ;
break ;
case KEY_NAME :
m_sName = sVal ;
bOk = ! m_sName.empty() ;
break ;
case KEY_NNS :
m_sSysNotes = sVal ;
break ;
case KEY_NNU :
m_sUserNotes = sVal ;
break ;
case KEY_OL :
bOk = ::FromString( sVal, m_dOffsL) ;
break ;
case KEY_OR :
bOk = ::FromString( sVal, m_dOffsR) ;
break ;
case KEY_PS :
bOk = ::FromString( sVal, m_dStartPos) ;
break ;
case KEY_S :
bOk = ::FromString( sVal, m_dSpeed) ;
break ;
case KEY_SCC :
bOk = ::FromString( sVal, m_nSolCh) ;
break ;
case KEY_SUBTYPE :
bOk = ::FromString( sVal, m_nSubType) ;
break ;
case KEY_TNAME :
m_sToolName = sVal ;
break ;
case KEY_TI :
bOk = ::FromString( sVal, m_bToolInvert) ;
break ;
case KEY_TUUID :
bOk = ::FromString( sVal, m_ToolUuid) ;
break ;
case KEY_UUID :
bOk = ::FromString( sVal, m_Uuid) ;
break ;
default :
bOk = false ;
break ;
}
return bOk ;
}
//----------------------------------------------------------------------------
string
FiveAxisMillingData::ToString( int nKey) const
{
switch ( nKey) {
case KEY_AB : return ( sFiveAxisMillingKey[KEY_AB] + "=" + m_sBlockedAxis) ;
case KEY_AI : return ( sFiveAxisMillingKey[KEY_AI] + "=" + m_sInitAngs) ;
case KEY_DH : return ( sFiveAxisMillingKey[KEY_DH] + "=" + m_sDepth) ;
case KEY_F : return ( sFiveAxisMillingKey[KEY_F] + "=" + ::ToString( m_dFeed)) ;
case KEY_FE : return ( sFiveAxisMillingKey[KEY_FE] + "=" + ::ToString( m_dEndFeed)) ;
case KEY_FS : return ( sFiveAxisMillingKey[KEY_FS] + "=" + ::ToString( m_dStartFeed)) ;
case KEY_FT : return ( sFiveAxisMillingKey[KEY_FT] + "=" + ::ToString( m_dTipFeed)) ;
case KEY_INV : return ( sFiveAxisMillingKey[KEY_INV] + "=" + ::ToString( m_bInvert)) ;
case KEY_NAME : return ( sFiveAxisMillingKey[KEY_NAME] + "=" + m_sName) ;
case KEY_NNS : return ( sFiveAxisMillingKey[KEY_NNS] + "=" + m_sSysNotes) ;
case KEY_NNU : return ( sFiveAxisMillingKey[KEY_NNU] + "=" + m_sUserNotes) ;
case KEY_OL : return ( sFiveAxisMillingKey[KEY_OL] + "=" + ::ToString( m_dOffsL)) ;
case KEY_OR : return ( sFiveAxisMillingKey[KEY_OR] + "=" + ::ToString( m_dOffsR)) ;
case KEY_PS : return ( sFiveAxisMillingKey[KEY_PS] + "=" + ::ToString( m_dStartPos)) ;
case KEY_S : return ( sFiveAxisMillingKey[KEY_S] + "=" + ::ToString( m_dSpeed)) ;
case KEY_SCC : return ( sFiveAxisMillingKey[KEY_SCC] + "=" + ::ToString( m_nSolCh)) ;
case KEY_SUBTYPE : return ( sFiveAxisMillingKey[KEY_SUBTYPE] + "=" + ::ToString( m_nSubType)) ;
case KEY_TI : return ( sFiveAxisMillingKey[KEY_TI] + "=" + ::ToString( m_bToolInvert)) ;
case KEY_TNAME : return ( sFiveAxisMillingKey[KEY_TNAME] + "=" + m_sToolName) ;
case KEY_TUUID : return ( sFiveAxisMillingKey[KEY_TUUID] + "=" + ::ToString( m_ToolUuid)) ;
case KEY_UUID : return ( sFiveAxisMillingKey[KEY_UUID] + "=" + ::ToString( m_Uuid)) ;
default : return "" ;
}
}
//----------------------------------------------------------------------------
bool
FiveAxisMillingData::IsOptional( int nKey) const
{
return false ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMillingData::VerifySolCh( int nVal) const
{
return IsValidOperationScc( nVal) ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMillingData::VerifyTool( const ToolsMgr* pToolsMgr, const string& sVal, const ToolData*& pTdata) const
{
if ( pToolsMgr == nullptr)
return false ;
pTdata = pToolsMgr->GetTool( sVal) ;
if ( pTdata == nullptr)
return false ;
if ( ( pTdata->m_nType & TF_MILL) == 0)
return false ;
return true ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMillingData::GetTool( const ToolsMgr* pToolsMgr, const ToolData*& pTdata) const
{
if ( pToolsMgr == nullptr)
return false ;
pTdata = pToolsMgr->GetTool( m_ToolUuid) ;
return ( pTdata != nullptr) ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMillingData::SetParam( int nType, bool bVal)
{
switch ( nType) {
case MPA_INVERT :
m_bInvert = bVal ;
return true ;
case MPA_TOOLINVERT :
m_bToolInvert = bVal ;
return true ;
}
return false ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMillingData::SetParam( int nType, int nVal)
{
switch ( nType) {
case MPA_SCC :
if ( ! VerifySolCh( nVal))
return false ;
m_nSolCh = nVal ;
return true ;
case MPA_SUBTYPE :
m_nSubType = nVal ;
return true ;
}
return false ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMillingData::SetParam( int nType, double dVal)
{
switch ( nType) {
case MPA_SPEED :
m_dSpeed = dVal ;
return true ;
case MPA_FEED :
m_dFeed = dVal ;
return true ;
case MPA_STARTFEED :
m_dStartFeed = dVal ;
return true ;
case MPA_ENDFEED :
m_dEndFeed = dVal ;
return true ;
case MPA_TIPFEED :
m_dTipFeed = dVal ;
return true ;
case MPA_OFFSL :
m_dOffsL = dVal ;
return true ;
case MPA_OFFSR :
m_dOffsR = dVal ;
return true ;
case MPA_DEPTH :
m_sDepth = ::ToString( dVal) ;
return true ;
case MPA_STARTPOS :
m_dStartPos = dVal ;
return true ;
}
return false ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMillingData::SetParam( int nType, const string& sVal)
{
switch ( nType) {
case MPA_NAME :
m_sName = sVal ;
return true ;
case MPA_TOOL :
m_sToolName = sVal ;
return true ;
case MPA_DEPTH_STR :
m_sDepth = sVal ;
return true ;
case MPA_TUUID :
return ::FromString( sVal, m_ToolUuid) ;
case MPA_UUID :
return ::FromString( sVal, m_Uuid) ;
case MPA_SYSNOTES :
m_sSysNotes = sVal ;
return true ;
case MPA_USERNOTES :
m_sUserNotes = sVal ;
return true ;
case MPA_INITANGS :
m_sInitAngs = sVal ;
return true ;
case MPA_BLOCKEDAXIS :
m_sBlockedAxis = sVal ;
return true ;
}
return false ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMillingData::ResetTool( void)
{
m_sToolName.clear() ;
m_ToolUuid.Clear() ;
return true ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMillingData::GetParam( int nType, bool& bVal) const
{
switch ( nType) {
case MPA_INVERT :
bVal = m_bInvert ;
return true ;
case MPA_TOOLINVERT :
bVal = m_bToolInvert ;
return true ;
}
bVal = false ;
return false ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMillingData::GetParam( int nType, int& nVal) const
{
switch ( nType) {
case MPA_TYPE :
nVal = MT_FIVEAXISMILLING ;
return true ;
case MPA_SCC :
nVal = m_nSolCh ;
return true ;
case MPA_SUBTYPE :
nVal = m_nSubType ;
return true ;
}
nVal = 0 ;
return false ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMillingData::GetParam( int nType, double& dVal) const
{
switch ( nType) {
case MPA_SPEED :
dVal = m_dSpeed ;
return true ;
case MPA_FEED :
dVal = m_dFeed ;
return true ;
case MPA_STARTFEED :
dVal = m_dStartFeed ;
return true ;
case MPA_ENDFEED :
dVal = m_dEndFeed ;
return true ;
case MPA_TIPFEED :
dVal = m_dTipFeed ;
return true ;
case MPA_OFFSL :
dVal = m_dOffsL ;
return true ;
case MPA_OFFSR :
dVal = m_dOffsR ;
return true ;
case MPA_STARTPOS :
dVal = m_dStartPos ;
return true ;
}
dVal = 0 ;
return false ;
}
//----------------------------------------------------------------------------
bool
FiveAxisMillingData::GetParam( int nType, string& sVal) const
{
switch ( nType) {
case MPA_NAME :
sVal = m_sName ;
return true ;
case MPA_TOOL :
sVal = m_sToolName ;
return true ;
case MPA_DEPTH_STR :
sVal = m_sDepth ;
return true ;
case MPA_TUUID :
sVal = ::ToString( m_ToolUuid) ;
return true ;
case MPA_UUID :
sVal = ::ToString( m_Uuid) ;
return true ;
case MPA_SYSNOTES :
sVal = m_sSysNotes ;
return true ;
case MPA_USERNOTES :
sVal = m_sUserNotes ;
return true ;
case MPA_INITANGS :
sVal = m_sInitAngs ;
return true ;
case MPA_BLOCKEDAXIS :
sVal = m_sBlockedAxis ;
return true ;
}
sVal = "" ;
return false ;
}
FiveAxisMillingData.h
+76
View File
@@ -0,0 +1,76 @@
//----------------------------------------------------------------------------
// EgalTech 2024-2024
//----------------------------------------------------------------------------
// File : FiveAxisMillingData.h Data : 22.05.24 Versione : 2.6e5
// Contenuto : Dichiarazione della struct FiveAxisMillingData e costanti associate.
//
//
//
// Modifiche : 22.05.24 DS Creazione modulo.
//
//
//----------------------------------------------------------------------------
#pragma once
#include "MachiningData.h"
//----------------------------------------------------------------------------
struct FiveAxisMillingData : public MachiningData
{
EgtUUID m_ToolUuid ; // identificativo universale dell'utensile
std::string m_sToolName ; // nome dell'utensile
std::string m_sInitAngs ; // angoli iniziali suggeriti (Nome1=val1,Nome2=val2)
std::string m_sBlockedAxis ; // eventuale asse rotante bloccato (Nome=val)
int m_nSolCh ; // criterio scelta soluzione (quando possibili molteplici)
double m_dSpeed ; // velocità di rotazione (+ se CCW, - se CW) ( se 0 da utensile)
double m_dFeed ; // velocità di lavorazione normale ( se 0 da utensile)
double m_dStartFeed ; // velocità di lavorazione iniziale ( se 0 da utensile)
double m_dEndFeed ; // velocità di lavorazione finale ( se 0 da utensile)
double m_dTipFeed ; // velocità di lavorazione di sfondamento ( se 0 da utensile)
double m_dOffsR ; // offset radiale ( se UNKNOWN_PAR da utensile)
double m_dOffsL ; // offset longitudinale ( se UNKNOWN_PAR da utensile)
bool m_bToolInvert ; // flag per inversione direzione utensile da geometria
bool m_bInvert ; // flag di inversione direzione lavorazione
std::string m_sDepth ; // affondamento (espressione numerica)
double m_dStartPos ; // quota di inizio lavorazione (sempre >= 0)
int m_nSubType ; // da [GenMachining] di Ini di macchina
std::string m_sSysNotes ; // note interne
std::string m_sUserNotes ; // note dell'utente
FiveAxisMillingData( void)
: m_ToolUuid(), m_nSolCh( 0), m_dSpeed( 0), m_dFeed( 0), m_dStartFeed( 0), m_dEndFeed( 0), m_dTipFeed( 0),
m_dOffsR( 0), m_dOffsL( 0), m_bToolInvert( false), m_bInvert( false), m_dStartPos( 0), m_nSubType( 0) {}
FiveAxisMillingData* Clone( void) const override ;
bool CopyFrom( const MachiningData* pMdata) override ;
bool SameAs(const MachiningData* pMdata) const override ;
int GetType( void) const override
{ return MT_FIVEAXISMILLING ; }
int GetSize( void) const override ;
std::string GetTitle( void) const override ;
bool FromString( const std::string& sString, int& nKey) override ;
std::string ToString( int nKey) const override ;
bool IsOptional( int nKey) const override ;
bool SetParam( int nType, bool bVal) override ;
bool SetParam( int nType, int nVal) override ;
bool SetParam( int nType, double dVal) override ;
bool SetParam( int nType, const std::string& sVal) override ;
bool ResetTool( void) override ;
bool GetParam( int nType, bool& bVal) const override ;
bool GetParam( int nType, int& nVal) const override ;
bool GetParam( int nType, double& dVal) const override ;
bool GetParam( int nType, std::string& sVal) const override ;
bool GetTool( const ToolsMgr* pToolsMgr, const ToolData*& pTdata) const override ;
bool VerifyTool( const ToolsMgr* pToolsMgr, const std::string& sVal, const ToolData*& pTdata) const override ;
bool VerifySolCh( int nVal) const ;
} ;
//----------------------------------------------------------------------------
inline const FiveAxisMillingData* GetFiveAxisMillingData( const MachiningData* pMdata)
{ if ( pMdata == nullptr || pMdata->GetType() != MT_FIVEAXISMILLING)
return nullptr ;
return ( static_cast<const FiveAxisMillingData*>( pMdata)) ; }
inline FiveAxisMillingData* GetFiveAxisMillingData( MachiningData* pMdata)
{ if ( pMdata == nullptr || pMdata->GetType() != MT_FIVEAXISMILLING)
return nullptr ;
return ( static_cast<FiveAxisMillingData*>( pMdata)) ; }
GenMachining.cpp
+94 -11
View File
@@ -39,6 +39,7 @@ using namespace std ;
// 2806 = "Error in GenMachining : link movements not calculable"
// 2807 = "Error in GenMachining : link outstroke xx"
// 2808 = "Error in GenMachining : post apply not calculable"
// 2809 = "Error in GenMachining : Tool loading failed"
// 2851 = "Warning in GenMachining : Skipped entity (xx)"
// 2852 = "Warning in GenMachining : No machinable path"
// 2853 = "Warning in GenMachining : Tool name changed (xx)"
@@ -54,15 +55,27 @@ static const string EVAR_INVERT = ".INVERT" ; // IN (bool) flag di inversio
static const string EVAR_STARTPOS = ".STARTPOS" ; // IN (num) quota di inizio lavorazione (sempre >= 0)
static const string EVAR_OFFSR = ".OFFSR" ; // IN (num) offset radiale
static const string EVAR_OFFSL = ".OFFSL" ; // IN (num) offset longitudinale
static const string EVAR_SYSNOTES = ".SYSNOTES" ; // IN (string) note interne
static const string EVAR_USERNOTES = ".USERNOTES" ;// IN (string) note dell'utente
static const string EVAR_TOOL = ".TOOL" ; // IN (string) nome dell'utensile
static const string EVAR_HEAD = ".HEAD" ; // IN (string) nome testa
static const string EVAR_EXIT = ".EXIT" ; // IN (int) indice uscita
static const string EVAR_TTYPE = ".TTYPE" ; // IN (int) tipo utensile
static const string EVAR_TMAXMAT = ".TMAXMAT" ; // IN (num) massimo materiale
static const string EVAR_TDIAM = ".TDIAM" ; // IN (num) diametro utensile
static const string EVAR_TTOTDIAM = ".TTOTDIAM" ; // IN (num) diametro totale utensile
static const string EVAR_TLEN = ".TLEN" ; // IN (num) lunghezza utensile
static const string EVAR_TTOTLEN = ".TTOTLEN" ; // IN (num) lunghezza totale utensile
static const string EVAR_TTHICK = ".THICK" ; // IN (num) spessore per lame o altezza taglienti
static const string EVAR_TCORNRAD = ".TCORNRAD" ; // IN (num) raggio corner
static const string EVAR_TSIDEANG = ".TSIDEANG" ; // IN (num) angolo del fianco rispetto all'asse
static const string EVAR_FEED = ".FEED" ; // IN (num) feed dell'utensile
static const string EVAR_STARTFEED = ".STARTFEED" ;// IN (num) feed di inizio dell'utensile
static const string EVAR_ENDFEED = ".ENDFEED" ; // IN (num) feed di fine dell'utensile
static const string EVAR_TIPFEED = ".TIPFEED" ; // IN (num) feed di punta dell'utensile
static const string EVAR_SYSNOTES = ".SYSNOTES" ; // IN (string) note interne
static const string EVAR_USERNOTES = ".USERNOTES" ;// IN (string) note dell'utente
static const string EVAR_ERROR = ".ERR" ; // OUT (int) codice di errore ( 0 = ok)
static const string EVAR_MILLS = ".MILLS" ; // OUT (int) numero di percorsi di lavoro
static const string EVAR_ISROBOT = ".ISROBOT" ; // IN (bool) flag per indicare che la cinematica è di tipo robot
static const string EVAR_ERROR = ".ERR" ; // OUT (int) codice di errore ( 0 = ok)
static const string EVAR_MILLS = ".MILLS" ; // OUT (int) numero di percorsi di lavoro
static const string ON_PREVIEW = "OnPreview_" ;
static const string ON_APPLY = "OnApply_" ;
@@ -436,6 +449,12 @@ GenMachining::Preview( bool bRecalc)
return false ;
}
// rendo corrente l'utensile usato nella lavorazione
if ( ! m_pMchMgr->SetCalcTool( m_TParams.m_sName, m_TParams.m_sHead, m_TParams.m_nExit)) {
m_pMchMgr->SetLastError( 2809, "Error in GenMachining : Tool loading failed") ;
return false ;
}
// recupero gruppo per geometria di Preview
int nPvId = m_pGeomDB->GetFirstNameInGroup( m_nOwnerId, MCH_PV) ;
// se non c'è, lo aggiungo
@@ -480,13 +499,25 @@ GenMachining::Preview( bool bRecalc)
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_STARTPOS, m_Params.m_dStartPos) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_OFFSR, GetOffsR()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_OFFSL, GetOffsL()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_SYSNOTES, m_Params.m_sSysNotes) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_USERNOTES, m_Params.m_sUserNotes) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TOOL, m_TParams.m_sName) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_HEAD, m_TParams.m_sHead) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_EXIT, m_TParams.m_nExit) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TTYPE, m_TParams.m_nType) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TMAXMAT, m_TParams.m_dMaxMat) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TDIAM, m_TParams.m_dDiam) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TTOTDIAM, m_TParams.m_dTDiam) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TLEN, m_TParams.m_dLen) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TTOTLEN, m_TParams.m_dTLen) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TTHICK, m_TParams.m_dThick) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TCORNRAD, m_TParams.m_dCornRad) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TSIDEANG, m_TParams.m_dSideAng) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_FEED, GetFeed()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_STARTFEED, GetStartFeed()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_ENDFEED, GetEndFeed()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TIPFEED, GetTipFeed()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_SYSNOTES, m_Params.m_sSysNotes) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_USERNOTES, m_Params.m_sUserNotes) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_ISROBOT, m_pMchMgr->GetCurrIsRobot()) ;
// eseguo
bOk = bOk && pMch->LuaCallFunction( sPreview, false) ;
// recupero valori parametri obbligatori
@@ -539,6 +570,12 @@ GenMachining::Apply( bool bRecalc, bool bPostApply)
}
m_nStatus = MCH_ST_TO_VERIFY ;
// rendo corrente l'utensile usato nella lavorazione
if ( ! m_pMchMgr->SetCalcTool( m_TParams.m_sName, m_TParams.m_sHead, m_TParams.m_nExit)) {
m_pMchMgr->SetLastError( 2809, "Error in GenMachining : Tool loading failed") ;
return false ;
}
// recupero gruppo per geometria di lavorazione (Cutter Location)
int nClId = m_pGeomDB->GetFirstNameInGroup( m_nOwnerId, MCH_CL) ;
// se non c'è, lo aggiungo
@@ -583,13 +620,25 @@ GenMachining::Apply( bool bRecalc, bool bPostApply)
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_STARTPOS, m_Params.m_dStartPos) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_OFFSR, GetOffsR()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_OFFSL, GetOffsL()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_SYSNOTES, m_Params.m_sSysNotes) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_USERNOTES, m_Params.m_sUserNotes) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TOOL, m_TParams.m_sName) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_HEAD, m_TParams.m_sHead) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_EXIT, m_TParams.m_nExit) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TTYPE, m_TParams.m_nType) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TMAXMAT, m_TParams.m_dMaxMat) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TDIAM, m_TParams.m_dDiam) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TTOTDIAM, m_TParams.m_dTDiam) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TLEN, m_TParams.m_dLen) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TTOTLEN, m_TParams.m_dTLen) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TTHICK, m_TParams.m_dThick) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TCORNRAD, m_TParams.m_dCornRad) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TSIDEANG, m_TParams.m_dSideAng) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_FEED, GetFeed()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_STARTFEED, GetStartFeed()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_ENDFEED, GetEndFeed()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_TIPFEED, GetTipFeed()) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_SYSNOTES, m_Params.m_sSysNotes) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_USERNOTES, m_Params.m_sUserNotes) ;
bOk = bOk && pMch->LuaSetGlobVar( EMC_VAR + EVAR_ISROBOT, m_pMchMgr->GetCurrIsRobot()) ;
// eseguo
bOk = bOk && pMch->LuaCallFunction( sApply, false) ;
// recupero valori parametri obbligatori
@@ -636,6 +685,9 @@ GenMachining::Update( bool bPostApply)
return true ;
}
// elimino le entità CLIMB, RISE e HOME della lavorazione, potrebbero falsare i calcoli degli assi (in ogni casi vengono riaggiunte dopo)
RemoveClimbRiseHome() ;
// imposto eventuale asse bloccato da lavorazione
SetBlockedRotAxis( m_Params.m_sBlockedAxis) ;
@@ -806,11 +858,31 @@ GenMachining::UpdateToolData( bool* pbChanged)
const ToolData* pTdata = pTMgr->GetTool( m_Params.m_ToolUuid) ;
if ( pTdata == nullptr)
return false ;
// verifico se sono diversi (ad esclusione del nome)
m_TParams.m_sName = pTdata->m_sName ;
bool bChanged = ! SameTool( m_TParams, *pTdata) ;
// salvo posizione TC, testa e uscita originali
string sOrigTcPos = m_TParams.m_sTcPos ;
string sOrigHead = m_TParams.m_sHead ;
int nOrigExit = m_TParams.m_nExit ;
// verifico se sono diversi (ad esclusione di nome, posizione TC, testa e uscita)
bool bChanged = ( ! SameTool( m_TParams, *pTdata, false)) ;
// aggiorno comunque i parametri
m_TParams = *pTdata ;
// se definito attrezzaggio, aggiorno i parametri che ne possono derivare
string sTcPos ; string sHead ; int nExit ;
if ( m_pMchMgr->GetCurrSetupMgr().GetToolData( m_TParams.m_sName, sTcPos, sHead, nExit)) {
if ( sOrigTcPos != sTcPos ||
sOrigHead != sHead ||
nOrigExit != nExit)
bChanged = true ;
m_TParams.m_sTcPos = sTcPos ;
m_TParams.m_sHead = sHead ;
m_TParams.m_nExit = nExit ;
}
else {
if ( sOrigTcPos != pTdata->m_sTcPos ||
sOrigHead != pTdata->m_sHead ||
nOrigExit != pTdata->m_nExit)
bChanged = true ;
}
// eventuali segnalazioni
if ( ! EqualNoCase( m_Params.m_sToolName, m_TParams.m_sName)) {
string sInfo = "Warning in GenMachining : tool name changed (" +
@@ -892,3 +964,14 @@ GenMachining::VerifyGeometry( SelData Id, int& nSubs, int& nType)
else
return false ;
}
//----------------------------------------------------------------------------
double
GenMachining::GetApproxLinTol( void) const
{
double dLinTol ;
if ( GetValInNotes( m_Params.m_sUserNotes, "LinTol", dLinTol))
return dLinTol ;
else
return Operation::GetApproxLinTol() ;
}
GenMachining.h
+1
View File
@@ -67,6 +67,7 @@ class GenMachining : public Machining
private :
bool VerifyGeometry( SelData Id, int& nSubs, int& nType) ;
double GetApproxLinTol( void) const override ;
private :
double GetSpeed() const
GenMachiningData.h
+6 -2
View File
@@ -67,6 +67,10 @@ struct GenMachiningData : public MachiningData
//----------------------------------------------------------------------------
inline const GenMachiningData* GetGenMachiningData( const MachiningData* pMdata)
{ return (dynamic_cast<const GenMachiningData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_GENMACHINING)
return nullptr ;
return ( static_cast<const GenMachiningData*>( pMdata)) ; }
inline GenMachiningData* GetGenMachiningData( MachiningData* pMdata)
{ return (dynamic_cast<GenMachiningData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_GENMACHINING)
return nullptr ;
return ( static_cast<GenMachiningData*>( pMdata)) ; }
Generator.cpp
+30 -12
View File
@@ -19,6 +19,7 @@
#include "OutputConst.h"
#include "/EgtDev/Include/EMkDllMain.h"
#include "/EgtDev/Include/EGnFileUtils.h"
#include "/EgtDev/Include/EGnGetKeyData.h"
using namespace std ;
@@ -46,19 +47,31 @@ Generator::Init( MachMgr* pMchMgr)
bool
Generator::Run( const string& sCncFile, const string& sInfo)
{
// verifico sia abilitato dalla licenza
bool bEnabled = false ;
if ( GetEMkNetHwKey()) {
bEnabled = true ;
}
else {
unsigned int nOpt1, nOpt2 ;
int nOptExpDays ;
int nRet = GetKeyOptions( GetEMkKey(), KEY_BASELIB_PROD, KEY_BASELIB_VER, KEY_BASELIB_LEV,
// Controllo della licenza
unsigned int nOpt1, nOpt2 ;
int nOptExpDays ;
int nRet = GetEGnKeyOptions( KEY_BASELIB_PROD, KEY_BASELIB_VER, KEY_BASELIB_LEV,
nOpt1, nOpt2, nOptExpDays) ;
bEnabled = ( nRet == KEY_OK && ( nOpt1 & KEYOPT_EMK_NC_OFF) == 0) ;
}
if ( bEnabled) {
if ( ! GetEMkNetHwKey())
nRet = GetKeyOptions( GetEMkKey(), KEY_BASELIB_PROD, KEY_BASELIB_VER, KEY_BASELIB_LEV,
nOpt1, nOpt2, nOptExpDays) ;
// Verifica della abilitazione
bool bMinTime = false ;
if ( nOptExpDays >= GetMinDay())
bMinTime = true ;
bool bCurrTime = false ;
if ( nOptExpDays >= GetCurrDay())
bCurrTime = true ;
bool bKey = false ;
if ( nRet == KEY_OK)
bKey = true ;
bool bOption = false ;
if ( ( nOpt1 & KEYOPT_EMK_NC_OFF) == 0)
bOption = true ;
// Esecuzione
if ( bMinTime && bCurrTime && bKey && bOption) {
// emetto info di log
{ string sOut = "Generator Run : " + sCncFile ;
@@ -79,6 +92,11 @@ Generator::Run( const string& sCncFile, const string& sInfo)
return bOk ;
}
// cancello l'eventuale file di uscita (e anche il file errore)
EraseFile( sCncFile) ;
string sErrFile = ChangeFileExtension( sCncFile, ERR_EXT) ;
EraseFile( sErrFile) ;
// Generazione non abilitata
m_pMchMgr->SetLastError( 1000, "NC_OFF") ;
std::string sErr = "Warning on Key (MKC/NCO)" ;
GeoCalc.cpp
+1 -1
View File
@@ -82,7 +82,7 @@ GetRotationComponent( const Vector3d& vtDir1, double dComp, const Vector3d& vtDi
double dDenom = dT0uv * dSinG ;
double dNumer = dComp - dT0w * dCosG ;
// due angoli possibili
if ( abs( dDenom) > abs( dNumer)) {
if ( abs( dDenom) > abs( dNumer) + SIN_EPS_ANG_ZERO) {
double dDeltaAngRad = acos( dNumer / dDenom) ;
dAng1Deg = ( dOffsAngRad + dDeltaAngRad) * RADTODEG ;
dAng2Deg = ( dOffsAngRad - dDeltaAngRad) * RADTODEG ;
GeoConst.h
+3 -1
View File
@@ -19,8 +19,10 @@
//----------- Costanti per approssimazioni con polilinee o poliarchi --------
const double LIN_TOL_STD = 0.1 ;
const double LIN_TOL_MID = 0.05 ;
const double ANG_TOL_MAX_DEG = 90 ;
const double LIN_TOL_RAW = 0.5 ;
const double ANG_TOL_STD_DEG = 15 ;
const double ANG_TOL_MID_DEG = 45 ;
const double ANG_TOL_MAX_DEG = 90 ;
const double LIN_FEA_STD = 20 ;
//----------- Costante per offset salva spigoli di lama su cornici curve ----
Head.cpp
+8 -2
View File
@@ -52,6 +52,7 @@ Head::Clone( void) const
pHead->m_bMaxDeltaR2On1 = m_bMaxDeltaR2On1 ;
pHead->m_Rot2Stroke = m_Rot2Stroke ;
pHead->m_nSolCh = m_nSolCh ;
pHead->m_vsOtherColl = m_vsOtherColl ;
}
catch( ...) {
delete pHead ;
@@ -73,6 +74,7 @@ Head::Dump( string& sOut, bool bMM, const char* szNewLine) const
sOut += "ExitCount=" + ToString( m_nExitCount) + szNewLine ;
sOut += "HSet=" + ToString( m_vsHSet) + szNewLine ;
sOut += "ADir=" + ToString( m_vtADir) + szNewLine ;
sOut += "OtherColl=" + ToString( m_vsOtherColl) + szNewLine ;
return true ;
}
@@ -103,7 +105,7 @@ Head::GetGeomDB( void) const
//----------------------------------------------------------------------------
Head::Head( void)
: m_nOwnerId( GDB_ID_NULL), m_pGeomDB( nullptr), m_nType( MCH_HT_NONE), m_nExitCount( 0),
m_dRot1W( 1), m_bMaxDeltaR2On1( true), m_nSolCh( MCH_SCC_NONE)
m_nSelectType( MCH_SLT_FIXEDEXITS), m_dRot1W( 1), m_bMaxDeltaR2On1( true), m_nSolCh( MCH_SCC_NONE)
{
m_Rot2Stroke.Min = - INFINITO ;
m_Rot2Stroke.Max = INFINITO ;
@@ -111,7 +113,7 @@ Head::Head( void)
//----------------------------------------------------------------------------
bool
Head::Set( const string& sName, int nType, int nExitCount, const string& sHSet, const Vector3d& vtADir,
Head::Set( const string& sName, int nType, int nExitCount, const string& sHSet, int nSelectType, const Vector3d& vtADir,
double dRot1W, bool bMaxDeltaR2On1, const STROKE& Rot2Stroke, int nSolCh, const STRVECTOR& vsOthColl)
{
m_sName = sName ;
@@ -122,6 +124,10 @@ Head::Set( const string& sName, int nType, int nExitCount, const string& sHSet,
m_nExitCount = 1 ;
m_vsHSet.clear() ;
m_vsHSet.push_back( sHSet) ;
if ( nSelectType == MCH_SLT_FIXEDEXITS || nSelectType == MCH_SLT_ONEEXIT || nSelectType == MCH_SLT_MULTIEXITS)
m_nSelectType = nSelectType ;
else
m_nSelectType = MCH_SLT_FIXEDEXITS ;
m_vtADir = vtADir ;
m_vtADir.Normalize() ;
m_dRot1W = dRot1W ;
Head.h
+4 -1
View File
@@ -30,7 +30,7 @@ class Head : public IUserObj
public :
Head( void) ;
bool Set( const std::string& sName, int nType, int nExitCount, const std::string& sHSet,
bool Set( const std::string& sName, int nType, int nExitCount, const std::string& sHSet, int nSelectType,
const Vector3d& vtADir, double dRot1W, bool bMaxDeltaR2On1, const STROKE& Rot2Stroke, int nSolCh,
const STRVECTOR& vsOthColl) ;
bool AddHeadToHSet( const std::string& sHead) ;
@@ -43,6 +43,8 @@ class Head : public IUserObj
{ return m_nExitCount ; }
const STRVECTOR& GetHSet(void) const
{ return m_vsHSet ; }
int GetSelectType( void) const
{ return m_nSelectType ; }
const Vector3d& GetADir( void) const
{ return m_vtADir ; }
double GetRot1W( void) const
@@ -63,6 +65,7 @@ class Head : public IUserObj
int m_nType ;
int m_nExitCount ;
STRVECTOR m_vsHSet ;
int m_nSelectType ;
Vector3d m_vtADir ;
double m_dRot1W ;
bool m_bMaxDeltaR2On1 ;
MachConst.h
+19
View File
@@ -47,6 +47,10 @@ const std::string MACH_RAW_SOLID = "RawSolid" ;
const std::string MACH_RAW_CENTER = "RawCenter" ;
// Nome del contorno esterno del grezzo
const std::string MACH_RAW_OUTLINE = "RawOutline" ;
// Nome della regione superiore del grezzo
const std::string MACH_RAW_UP_REG = "RawUpReg" ;
// Nome della regione inferiore del grezzo
const std::string MACH_RAW_DOWN_REG = "RawDwnReg" ;
// Nome del kerf del grezzo
const std::string MACH_RAW_KERF = "Kerf" ;
@@ -80,6 +84,12 @@ const std::string GENMACHINING_SEC = "GenMachining" ;
// Chiave (radice) per nome lavorazione generica i-esima
const std::string GENMACHINING_SCRIPT_KEY = "GenScript" ;
//----------------------------------------------------------------------------
// Sezione fresature 5assi nel file INI di macchina
const std::string FIVEAXISMILLING_SEC = "5AxMilling" ;
// Chiave (radice) per nome lavorazione 5assi i-esima
const std::string FIVEAXISMILLING_SCRIPT_KEY = "5AxScript" ;
//----------------------------------------------------------------------------
// Sezione di attrezzaggio nel file INI di macchina
const std::string SETUP_SEC = "Setup" ;
@@ -112,6 +122,12 @@ const std::string MILLHOLDER_KEY = "MillHolder" ;
// Sezione portautensili nel file INI di macchina
const std::string TOOLHOLDER_SEC = "ToolHolder" ;
//----------------------------------------------------------------------------
// Sezione lavorazioni nel file INI di macchina
const std::string MACHININGS_SEC = "Machinings" ;
// Chiave per abilitare discesa e risalita in rapido da fresature con estremi fuori dal grezzo
const std::string RAPIDONOUT_KEY = "RapidOnOut" ;
//----------------------------------------------------------------------------
// Minimo spessore del grezzo
const double RAW_MIN_H = 1 ;
@@ -131,7 +147,10 @@ const double LIO_ELEV_TOL = 2.0 ;
//----------------------------------------------------------------------------
// Per FlatParts (vedi Nesting di EgtExecutor)
const std::string NST_EXT_LAYER = "OutLoop" ;
const std::string NST_PARTREG_LAYER = "Region" ;
//----------------------------------------------------------------------------
// Minima componente zeta di versore utensile per lavorazione da sopra (-45deg)
const double MIN_ZDIR_TOP_TOOL = -0.7072 ;
// Minima componente zeta di versose utensile èer mortasatura quasi verticale (45deg)
const double MIN_ZDIR_VERT_CHSAW = 0.7072 ;
MachMgr.h
+28 -8
View File
@@ -1,7 +1,7 @@
//----------------------------------------------------------------------------
// EgalTech 2015-2022
// EgalTech 2015-2024
//----------------------------------------------------------------------------
// File : MachMgr.h Data : 21.09.22 Versione : 2.4i4
// File : MachMgr.h Data : 22.04.24 Versione : 2.6d4
// Contenuto : Dichiarazione della classe MachMgr.
//
//
@@ -11,6 +11,11 @@
// 17.08.20 DS Aggiunte GetAxisMin e GetAxisMax.
// 17.03.21 DS Aggiunte funzioni per import/export utensili.
// 21.09.22 DS Aggiunta GetAxisOffset.
// 25.08.23 DS Aggiunta CopyMachGroup.
// 28.10.23 DS Aggiunte GetClEntAxesVal e GetToolSetupPosInCurrSetup.
// 30.03.24 DS Aggiunte GetAllAxesNames e GetCalcTable.
// 02.04.24 DS Aggiunta GetClEntAxesMask.
// 22.04.24 DS Aggiunta GetExitId.
//
//----------------------------------------------------------------------------
@@ -95,7 +100,9 @@ class MachMgr : public IMachMgr
int GetPrevMachGroup( int nId) const override ;
bool GetMachGroupNewName( std::string& sName) const override ;
int AddMachGroup( const std::string& sName, const std::string& sMachineName) override ;
int CopyMachGroup( const std::string& sSouName, const std::string& sName) override ;
bool RemoveMachGroup( int nId) override ;
bool ChangeMachGroupName( int nId, const std::string& sNewName) override ;
std::string GetMachGroupName( int nId) const override ;
std::string GetMachGroupMachineName( int nId) const override ;
int GetMachGroupId( const std::string& sName) const override ;
@@ -203,6 +210,7 @@ class MachMgr : public IMachMgr
bool ImportSetup( const std::string& sName) override ;
bool VerifyCurrSetup( STRVECTOR& vsErrors) override ;
bool FindToolInCurrSetup( const std::string& sTool) override ;
bool GetToolSetupPosInCurrSetup( const std::string& sTool, std::string& sTcPos) override ;
bool GetToolsInCurrSetupPos( const std::string& sTcPos, STRVECTOR& vsTools) override ;
bool UpdateCurrSetup( void) override ;
bool EraseCurrSetup( void) override ;
@@ -290,7 +298,8 @@ class MachMgr : public IMachMgr
bool MachiningUpdate( bool bPostApply = true) override ;
bool PreparePreviewMachiningTool( void) const override ;
bool RemovePreviewMachiningTool( void) const override ;
int PreviewMachiningTool( int nEntId, int nFlag) const override ;
int GetPreviewMachiningToolStepCount( void) const override ;
int PreviewMachiningTool( int nEntId, int nStep) const override ;
bool GetMachiningParam( int nType, bool& bVal) const override ;
bool GetMachiningParam( int nType, int& nVal) const override ;
bool GetMachiningParam( int nType, double& dVal) const override ;
@@ -301,8 +310,10 @@ class MachMgr : public IMachMgr
bool GetMachiningEndPoint( Point3d& ptEnd) const override ;
// CL Entities Interrogations
bool GetClEntMove( int nEntId, int& nMove) const override ;
bool GetClEntFlag( int nEntId, int& nFlag) const override ;
bool GetClEntFlag( int nEntId, int& nFlag, int& nFlag2) const override ;
bool GetClEntIndex( int nEntId, int& nIndex) const override ;
bool GetClEntAxesMask( int nEntId, int& nMask) const override ;
bool GetClEntAxesVal( int nEntId, DBLVECTOR& vAxes) const override ;
// Simulation
bool SimInit( void) override ;
bool SimStart( bool bFirst) override ;
@@ -321,8 +332,10 @@ class MachMgr : public IMachMgr
// Machine Calc
bool SetCalcTable( const std::string& sTable) override ;
bool SetCalcTool( const std::string& sTool, const std::string& sHead, int nExit) override ;
bool GetAllCurrAxesNames( STRVECTOR& vAxName) const override ;
bool SetRotAxisBlock( const std::string& sAxis, double dVal) override ;
bool GetRotAxisBlocked( int nInd, std::string& sAxis, double& dVal) const override ;
bool GetCalcTable( std::string& sTable) const override ;
bool GetCalcTool( std::string& sTool) const override ;
bool GetCalcHead( std::string& sHead) const override ;
bool GetCalcExit( int& nExit) const override ;
@@ -350,6 +363,7 @@ class MachMgr : public IMachMgr
int GetAxisId( const std::string& sAxis) const override ;
int GetHeadId( const std::string& sHead) const override ;
int GetHeadExitCount( const std::string& sHead) const override ;
int GetExitId( const std::string& sHead, int nExit) const override ;
int GetTcPosId( const std::string& sTcPos) const override ;
bool GetAxisToken( const std::string& sAxis, std::string& sToken) const override ;
bool GetAxisType( const std::string& sAxis, bool& bLinear) const override ;
@@ -363,6 +377,7 @@ class MachMgr : public IMachMgr
bool ResetAxisPos( const std::string& sAxis) override ;
bool ResetAllAxesPos( void) override ;
bool GetAllTablesNames( STRVECTOR& vNames) const override ;
bool GetAllAxesNames( STRVECTOR& vNames) const override ;
bool GetAllHeadsNames( STRVECTOR& vNames) const override ;
bool GetAllTcPosNames( STRVECTOR& vNames) const override ;
bool LoadTool( const std::string& sHead, int nExit, const std::string& sTool) override ;
@@ -430,10 +445,11 @@ class MachMgr : public IMachMgr
// MachineCalc
int GetCurrLinAxes( void) const ;
int GetCurrRotAxes( void) const ;
bool GetAllCurrAxesName( STRVECTOR& vAxName) const ;
bool GetAllCurrAxesHomePos( DBLVECTOR& vAxHomeVal) const ;
bool GetCurrAxisHomePos( int nInd, double& dHome) const ;
const Frame3d& GetCurrLinAxesFrame( void) const ;
bool GetCurrIsCenter( void) const ;
bool GetCurrIsRobot( void) const ;
bool ApplyRotAxisBlock( void) ;
void ClearRotAxisBlock( void)
{ m_vAxisBlock.clear() ; }
@@ -455,11 +471,14 @@ class MachMgr : public IMachMgr
bool SimAddCollisionObj( int nInd, bool bToolOn, int nFrameId, int nType, const Vector3d& vtMove, double dPar1, double dPar2, double dPar3) ;
bool SimExecCollisionCheck( int& nCdInd, int& nObjInd, int nMoveType) ;
bool SimOnCollision( int nCdInd, int nObjInd, int& nErr) ;
bool SimSetToolForVmill( const std::string& sTool, const std::string& sHead, int nExit, const INTVECTOR& vVmill, bool bFirst) ;
bool SimSetToolForVmill( const std::string& sTool, const std::string& sHead, int nExit, int nFlag, double dPar1, double dPar2,
const INTVECTOR& vVmill, bool bFirst) ;
bool SimEnableToolsForVmill( bool bEnable) ;
int SimMoveAxes( int nMoveType, const SAMVECTOR& vAxNaEpSt) ;
bool SimSaveCmd( int nType, int nPar, const std::string& sPar) ;
// Machine
bool GetHeadAbove( const std::string& sHead) const ;
double GetDeltaSafeZ( const std::string& sHead) const ;
double GetAngDeltaMinForHome( void) const ;
private :
@@ -486,6 +505,7 @@ class MachMgr : public IMachMgr
// RawParts
int AddRawPart( int nCrvId, double dOverMat, double dZmin, double dHeight, Color cCol) ;
int AddRawPart( int nSurfId, Color cCol) ;
int AddRawPart( int nSurfUpId, int nSurfDownId, double dHeight, Color cCol) ;
bool SetRawPartCenter( int nRawId) ;
bool ResetRawPartCenter( int nRawId) ;
// Parts
@@ -532,5 +552,5 @@ class MachMgr : public IMachMgr
int m_nCurrDispId ; // identificativo della disposizione corrente
int m_nCurrMachiningId ; // identificativo della lavorazione corrente
AXBLOCKVECTOR m_vAxisBlock ; // elenco assi da bloccare
Simulator* m_pSimul ; // puntatore al simulatore attivo
ISimulator* m_pSimul ; // puntatore al simulatore attivo
} ;
MachMgrBasic.cpp
+5 -1
View File
@@ -311,7 +311,11 @@ MachMgr::SetLastError( int nErr, const string& sErr)
{
m_nLastError = nErr ;
m_sLastError = sErr ;
string sInfo = m_sLastError + " (" + ToString( nErr) + ")" ;
string sInfo ;
if ( sErr._Starts_with( "Error"))
sInfo = m_sLastError + " (" + ToString( nErr) + ")" ;
else
sInfo = "Error " + ToString( nErr) + " : " + m_sLastError ;
LOG_ERROR( GetEMkLogger(), sInfo.c_str()) ;
return true ;
}
MachMgrClEntities.cpp
+43 -4
View File
@@ -1,7 +1,7 @@
//----------------------------------------------------------------------------
// EgalTech 2019-2019
// EgalTech 2019-2023
//----------------------------------------------------------------------------
// File : MachMgrClEntities.cpp Data : 15.10.19 Versione : 2.1j4
// File : MachMgrClEntities.cpp Data : 27.10.23 Versione : 2.5j4
// Contenuto : Implementazione interrogazione entità CL della classe MachMgr.
//
//
@@ -16,6 +16,7 @@
#include "DllMain.h"
#include "MachMgr.h"
#include "MachConst.h"
#include "CamData.h"
using namespace std ;
@@ -39,10 +40,11 @@ MachMgr::GetClEntMove( int nEntId, int& nMove) const
//----------------------------------------------------------------------------
bool
MachMgr::GetClEntFlag( int nEntId, int& nFlag) const
MachMgr::GetClEntFlag( int nEntId, int& nFlag, int& nFlag2) const
{
// default
nFlag = 0 ;
nFlag2 = 0 ;
// verifico validita GeomDB
if ( m_pGeomDB == nullptr)
return false ;
@@ -50,8 +52,9 @@ MachMgr::GetClEntFlag( int nEntId, int& nFlag) const
const CamData* pCamData = GetCamData( m_pGeomDB->GetUserObj( nEntId)) ;
if ( pCamData == nullptr)
return false ;
// recupero il flag
// recupero i flag
nFlag = pCamData->GetFlag() ;
nFlag2 = pCamData->GetFlag2() ;
return true ;
}
@@ -72,3 +75,39 @@ MachMgr::GetClEntIndex( int nEntId, int& nIndex) const
nIndex = pCamData->GetIndex() ;
return true ;
}
//----------------------------------------------------------------------------
bool
MachMgr::GetClEntAxesMask( int nEntId, int& nMask) const
{
// default
nMask = 0 ;
// verifico validita GeomDB
if ( m_pGeomDB == nullptr)
return false ;
// recupero l'oggetto CamData
const CamData* pCamData = GetCamData( m_pGeomDB->GetUserObj( nEntId)) ;
if ( pCamData == nullptr)
return false ;
// recupero il tipo di movimento
nMask = pCamData->GetAxesMask() ;
return true ;
}
//----------------------------------------------------------------------------
bool
MachMgr::GetClEntAxesVal( int nEntId, DBLVECTOR& vAxes) const
{
// default
vAxes.clear() ;
// verifico validita GeomDB
if ( m_pGeomDB == nullptr)
return false ;
// recupero l'oggetto CamData
const CamData* pCamData = GetCamData( m_pGeomDB->GetUserObj( nEntId)) ;
if ( pCamData == nullptr)
return false ;
// recupero i valori degli assi
vAxes = pCamData->GetAxesVal() ;
return true ;
}
MachMgrDBMachinings.cpp
+7 -2
View File
@@ -1,7 +1,7 @@
//----------------------------------------------------------------------------
// EgalTech 2015-2015
// EgalTech 2015-2024
//----------------------------------------------------------------------------
// File : MachMgrDBMachinings.cpp Data : 11.11.15 Versione : 1.6k5
// File : MachMgrDBMachinings.cpp Data : 29.03.24 Versione : 2.6d1
// Contenuto : Implementazione gestione DB lavorazioni della classe MachMgr.
//
//
@@ -304,6 +304,8 @@ MachMgr::MdbSetGeneralParam( int nType, double dVal)
return pMsMgr->SetSafeAggrBottZ( dVal) ;
case MGP_MAXDEPTHSAFE :
return pMsMgr->SetMaxDepthSafe( dVal) ;
case MGP_APPROXLINTOL :
return pMsMgr->SetApproxLinTol( dVal) ;
}
return false ;
}
@@ -379,6 +381,9 @@ MachMgr::MdbGetGeneralParam( int nType, double& dVal) const
case MGP_MAXDEPTHSAFE :
dVal = pMsMgr->GetMaxDepthSafe() ;
return true ;
case MGP_APPROXLINTOL :
dVal = pMsMgr->GetApproxLinTol() ;
return true ;
}
return false ;
}
MachMgrDBTools.cpp
+17 -1
View File
@@ -631,6 +631,8 @@ MachMgr::UpdateStandardToolDraw( const ToolData* pTdata, int nGenCtx, int nToolC
pTdata->GetParam( TPA_TOTDIAM, dTotDiam) ;
double dDist = 0 ;
pTdata->GetParam( TPA_DIST, dDist) ;
double dStemDiam = 0 ;
pTdata->GetParam( TPA_STEMDIAM, dStemDiam) ;
double dMaxMat = 0 ;
pTdata->GetParam( TPA_MAXMAT, dMaxMat) ;
double dCornRad = 0 ;
@@ -694,6 +696,7 @@ MachMgr::UpdateStandardToolDraw( const ToolData* pTdata, int nGenCtx, int nToolC
bOk = bOk && ExeLuaSetGlobNumVar( "TOOL.LEN", dLen) ;
bOk = bOk && ExeLuaSetGlobNumVar( "TOOL.TOTDIAM", dTotDiam) ;
bOk = bOk && ExeLuaSetGlobNumVar( "TOOL.DIAM", dDiam) ;
bOk = bOk && ExeLuaSetGlobNumVar( "TOOL.STEMDIAM", dStemDiam) ;
bOk = bOk && ExeLuaSetGlobNumVar( "TOOL.MAXMAT", dMaxMat) ;
bOk = bOk && ExeLuaSetGlobNumVar( "TOOL.HEIGHT", dThick) ;
bOk = bOk && ExeLuaSetGlobNumVar( "TOOL.SIDEANG", dSideAng) ;
@@ -718,7 +721,7 @@ MachMgr::UpdateStandardToolDraw( const ToolData* pTdata, int nGenCtx, int nToolC
if ( ! ExeLuaGetGlobIntVar( "TOOL.ERR", &nErr) || nErr != 0)
return nErr ;
// Se per salvataggio
if ( bOk && bToSave) {
if ( bOk && bToSave) {
// Nascondo layer ausiliario
int nAuxId = ExeGetFirstNameInGroup( ExeGetFirstGroupInGroup( GDB_ID_ROOT), "AUX") ;
ExeSetStatus( { nAuxId}, GDB_ST_OFF) ;
@@ -728,6 +731,16 @@ MachMgr::UpdateStandardToolDraw( const ToolData* pTdata, int nGenCtx, int nToolC
ExeRotate( { nPartId}, ORIG, Z_AX, -90, RTY_GLOB) ;
}
}
// altrimenti per visualizzazione
else if ( bOk) {
// Nascondo oggetto/i Carter
int nSolidId = ExeGetFirstNameInGroup( ExeGetFirstGroupInGroup( GDB_ID_ROOT), "SOLID") ;
int nCarterId = ExeGetFirstNameInGroup( nSolidId, "Carter") ;
while ( nCarterId != GDB_ID_NULL) {
ExeSetStatus( { nCarterId}, GDB_ST_OFF) ;
nCarterId = ExeGetNextName( nCarterId, "Carter") ;
}
}
return ( bOk ? 0 : TD_INT_ERR) ;
}
@@ -747,6 +760,8 @@ MachMgr::UpdateCustomToolDraw( const ToolData* pTdata, int nGenCtx, int nToolCtx
pTdata->GetParam( TPA_DIAM, dDiam) ;
double dDist = 0 ;
pTdata->GetParam( TPA_DIST, dDist) ;
double dSpeed = 0 ;
pTdata->GetParam( TPA_SPEED, dSpeed) ;
// Imposto contesto per il disegno utensile
if ( ! ExeSetCurrentContext( nToolCtx))
return TD_INT_ERR ;
@@ -756,6 +771,7 @@ MachMgr::UpdateCustomToolDraw( const ToolData* pTdata, int nGenCtx, int nToolCtx
bOk = bOk && ExeLuaSetGlobNumVar( "TOOL.LEN", dLen) ;
bOk = bOk && ExeLuaSetGlobNumVar( "TOOL.DIAM", dDiam) ;
bOk = bOk && ExeLuaSetGlobNumVar( "TOOL.DIST", dDist) ;
bOk = bOk && ExeLuaSetGlobNumVar( "TOOL.SPEED", dSpeed) ;
// Eseguo aggiornamento utensile
bOk = bOk && ExeLuaCallFunction( "AdjustCustomTool") ;
// Recupero errore
MachMgrGeneration.cpp
+19 -2
View File
@@ -18,6 +18,7 @@
#include "MachConst.h"
#include "Generator.h"
#include "Estimator.h"
#include "/EgtDev/Include/EGnFileUtils.h"
using namespace std ;
@@ -25,6 +26,22 @@ using namespace std ;
bool
MachMgr::Generate( const string& sCncFile, const string& sInfo)
{
// se macchina multiprocesso è necessaria stima speciale
if ( GetCurrMachine() != nullptr && GetCurrMachine()->GetMultiProcess()) {
// inizializzazione stimatore
Estimator estPP ;
if ( ! estPP.Init( this)) {
LOG_ERROR( GetEMkLogger(), "Error on Estimate Init")
return false ;
}
// esecuzione della stima
string sEstFile = ChangeFileExtension( sCncFile, "sest") ;
if ( ! estPP.Run( sEstFile, sInfo)) {
LOG_ERROR( GetEMkLogger(), "Error on Estimate Run")
return false ;
}
}
// inizializzazione generatore
Generator genPP ;
if ( ! genPP.Init( this)) {
@@ -44,13 +61,13 @@ MachMgr::Generate( const string& sCncFile, const string& sInfo)
bool
MachMgr::Estimate( const string& sEstFile, const string& sInfo)
{
// inizializzazione generatore
// inizializzazione stimatore
Estimator estPP ;
if ( ! estPP.Init( this)) {
LOG_ERROR( GetEMkLogger(), "Error on Estimate Init")
return false ;
}
// esecuzione della generazione
// esecuzione della stima
if ( ! estPP.Run( sEstFile, sInfo)) {
LOG_ERROR( GetEMkLogger(), "Error on Estimate Run")
return false ;
MachMgrMachGroups.cpp
+80 -21
View File
@@ -182,6 +182,52 @@ MachMgr::AddMachGroup( const string& sName, const string& sMachineName)
return nNewId ;
}
//----------------------------------------------------------------------------
int
MachMgr::CopyMachGroup( const string& sSouName, const string& sName)
{
// recupero il gruppo sorgente
int nSouMGrpId = GetMachGroupId( sSouName) ;
if ( nSouMGrpId == GDB_ID_NULL)
return GDB_ID_NULL ;
// verifico esista la sua macchina
string sMachineName ;
m_pGeomDB->GetInfo( nSouMGrpId, MACH_MACHINE_KEY, sMachineName) ;
if ( sMachineName.empty() || ! LoadMachine( sMachineName))
return GDB_ID_NULL ;
// verifico nome nuovo gruppo (non deve essere vuoto e non deve esserci già un gruppo con questo nome)
if ( &sName == nullptr || sName.empty() || GetMachGroupId( sName) != GDB_ID_NULL)
return GDB_ID_NULL ;
// reset gruppo corrente
ResetCurrMachGroup() ;
// eseguo la copia del gruppo sorgente e la metto in coda
int nNewMGrpId = m_pGeomDB->Copy( nSouMGrpId, GDB_ID_NULL, m_nMachBaseId) ;
if ( nNewMGrpId == GDB_ID_NULL)
return GDB_ID_NULL ;
// assegno il nome
m_pGeomDB->SetName( nNewMGrpId, sName) ;
// converto opportunamente gli indicativi dei grezzi nelle disposizioni
int nSouRawPartId = m_pGeomDB->GetFirstGroupInGroup( m_pGeomDB->GetFirstNameInGroup( nSouMGrpId, MACH_RAW_GROUP)) ;
int nNewRawPartId = m_pGeomDB->GetFirstGroupInGroup( m_pGeomDB->GetFirstNameInGroup( nNewMGrpId, MACH_RAW_GROUP)) ;
while ( nSouRawPartId != GDB_ID_NULL && nNewRawPartId != GDB_ID_NULL) {
// ciclo sulle disposizioni del nuovo gruppo di lavoro
int nOperId = m_pGeomDB->GetFirstGroupInGroup( m_pGeomDB->GetFirstNameInGroup( nNewMGrpId, MACH_OPER_GROUP)) ;
while ( nOperId != GDB_ID_NULL) {
Disposition* pDisp = GetDisposition( m_pGeomDB->GetUserObj( nOperId)) ;
if ( pDisp != nullptr)
pDisp->UpdateRawPartId( nSouRawPartId, nNewRawPartId) ;
nOperId = m_pGeomDB->GetNextGroup( nOperId) ;
}
// passo alla coppia successiva
nSouRawPartId = m_pGeomDB->GetNextGroup( nSouRawPartId) ;
nNewRawPartId = m_pGeomDB->GetNextGroup( nNewRawPartId) ;
}
// lo rendo corrente
SetCurrMachGroup( nNewMGrpId) ;
// restituisco l'identificativo del gruppo
return nNewMGrpId ;
}
//----------------------------------------------------------------------------
bool
MachMgr::RemoveMachGroup( int nId)
@@ -222,44 +268,60 @@ MachMgr::VerifyMachGroup( int nId, MachGrp& mgData) const
// verifica della macchina
bool bMName = m_pGeomDB->GetInfo( nId, MACH_MACHINE_KEY, mgData.MGeoName) ;
// scansiono i sottogruppi
PtrOwner<IGdbIterator> pIter( CreateGdbIterator( m_pGeomDB)) ;
if ( IsNull( pIter))
return false ;
bool bSetup = false ;
bool bFixt = false ;
bool bRaw = false ;
bool bOper = false ;
bool bIter = pIter->GoToFirstGroupInGroup( nId) ;
while ( bIter) {
int nGrpId = m_pGeomDB->GetFirstGroupInGroup( nId) ;
while ( nGrpId != GDB_ID_NULL) {
string sName ;
if ( pIter->GetName( sName)) {
if ( m_pGeomDB->GetName( nGrpId, sName)) {
if ( sName == MACH_SETUP_GROUP) {
if ( ! bSetup)
mgData.SetupGroupId = pIter->GetId() ;
mgData.SetupGroupId = nGrpId ;
bSetup = true ;
}
else if ( sName == MACH_FIXT_GROUP) {
if ( ! bFixt)
mgData.FixtGroupId = pIter->GetId() ;
mgData.FixtGroupId = nGrpId ;
bFixt = true ;
}
else if ( sName == MACH_RAW_GROUP) {
if ( ! bRaw)
mgData.RawGroupId = pIter->GetId() ;
mgData.RawGroupId = nGrpId ;
bRaw = true ;
}
else if ( sName == MACH_OPER_GROUP) {
if ( ! bOper)
mgData.OperGroupId = pIter->GetId() ;
mgData.OperGroupId = nGrpId ;
bOper = true ;
}
}
// passo al successivo
bIter = pIter->GoToNextGroup() ;
nGrpId = m_pGeomDB->GetNextGroup( nGrpId) ;
}
return ( bMName && bSetup && bRaw && bOper) ;
}
//----------------------------------------------------------------------------
bool
MachMgr::ChangeMachGroupName( int nId, const string& sNewName)
{
// verifica del gruppo base per le lavorazioni
if ( ! VerifyMachBase())
return false ;
// verifico che il gruppo ricevuto sia corretto
if ( m_pGeomDB->GetParentId( nId) != m_nMachBaseId)
return false ;
// verifico nome non vuoto e non esista già un gruppo con lo stesso nome
if ( &sNewName == nullptr || sNewName.empty() || GetMachGroupId( sNewName) != GDB_ID_NULL)
return false ;
// cambio il nome del gruppo di lavoro
if ( ! m_pGeomDB->SetName( nId, sNewName))
return false ;
return true ;
}
//----------------------------------------------------------------------------
string
MachMgr::GetMachGroupName( int nId) const
@@ -298,22 +360,19 @@ MachMgr::GetMachGroupId( const string& sName) const
{
// verifica dei parametri
if ( &sName == nullptr || sName.empty())
return false ;
return GDB_ID_NULL ;
// verifica del gruppo base per le lavorazioni
if ( ! VerifyMachBase())
return false ;
return GDB_ID_NULL ;
// recupero l'identificativo del gruppo con il nome indicato
PtrOwner<IGdbIterator> pIter( CreateGdbIterator( m_pGeomDB)) ;
if ( IsNull( pIter))
return false ;
bool bIter = pIter->GoToFirstGroupInGroup( m_nMachBaseId) ;
while( bIter) {
int nGrpId = m_pGeomDB->GetFirstGroupInGroup( m_nMachBaseId) ;
while ( nGrpId != GDB_ID_NULL) {
// verifico il nome
string sMGroupName ;
if ( pIter->GetName( sMGroupName) && EqualNoCase( sMGroupName, sName))
return pIter->GetId() ;
if ( m_pGeomDB->GetName( nGrpId, sMGroupName) && EqualNoCase( sMGroupName, sName))
return nGrpId ;
// passo al successivo
bIter = pIter->GoToNextGroup() ;
nGrpId = m_pGeomDB->GetNextGroup( nGrpId) ;
}
return GDB_ID_NULL ;
}
MachMgrMachines.cpp
+53 -17
View File
@@ -274,6 +274,15 @@ MachMgr::GetHeadExitCount( const string& sHead) const
return ( ( pMch != nullptr) ? pMch->GetHeadExitCount( sHead) : 0) ;
}
//----------------------------------------------------------------------------
int
MachMgr::GetExitId( const string& sHead, int nExit) const
{
Machine* pMch = GetCurrMachine() ;
// recupero identificativo dell'uscita della testa indicata nella macchina corrente
return ( ( pMch != nullptr) ? pMch->GetExitId( sHead, nExit) : GDB_ID_NULL) ;
}
//----------------------------------------------------------------------------
int
MachMgr::GetTcPosId( const string& sTcPos) const
@@ -294,18 +303,6 @@ MachMgr::GetHeadAbove( const string& sHead) const
return ( ! m_pGeomDB->GetInfo( GetHeadId( sHead), MCH_ABOVE, bAbove) || bAbove) ;
}
//----------------------------------------------------------------------------
double
MachMgr::GetDeltaSafeZ( const string& sHead) const
{
if ( m_pGeomDB == nullptr)
return 0 ;
// Leggo da testa Info ZSAFEDELTA
double dDeltaSafeZ = 0 ;
m_pGeomDB->GetInfo( GetHeadId( sHead), MCH_ZSAFEDELTA, dDeltaSafeZ) ;
return dDeltaSafeZ ;
}
//----------------------------------------------------------------------------
double
MachMgr::GetAngDeltaMinForHome( void) const
@@ -356,7 +353,7 @@ bool
MachMgr::SetAxisPos( const string& sAxis, double dVal, double* pdNewVal)
{
Machine* pMch = GetCurrMachine() ;
return ( ( pMch != nullptr) ? pMch->SetAxisPos( sAxis, dVal, pdNewVal) : false) ;
return ( ( pMch != nullptr) ? pMch->SetAxisPos( sAxis, dVal, true, pdNewVal) : false) ;
}
//----------------------------------------------------------------------------
@@ -534,6 +531,14 @@ MachMgr::SetCalcSolCh( int nScc, bool bExact)
return pMch->SetSolCh( nScc, bExact) ;
}
//----------------------------------------------------------------------------
bool
MachMgr::GetCalcTable( string& sTable) const
{
Machine* pMch = GetCurrMachine() ;
return ( ( pMch != nullptr) ? pMch->GetCurrTable( sTable) : false) ;
}
//----------------------------------------------------------------------------
bool
MachMgr::GetCalcTool( string& sTool) const
@@ -609,6 +614,17 @@ MachMgr::GetAllTablesNames( STRVECTOR& vNames) const
return ( ( pMch != nullptr) ? pMch->GetAllTablesNames( vNames) : false) ;
}
//----------------------------------------------------------------------------
bool
MachMgr::GetAllAxesNames( STRVECTOR& vNames) const
{
// pulisco il vettore
vNames.clear() ;
// richiedo elenco assi alla macchina corrente
Machine* pMch = GetCurrMachine() ;
return ( ( pMch != nullptr) ? pMch->GetAllAxesNames( vNames) : false) ;
}
//----------------------------------------------------------------------------
bool
MachMgr::GetAllHeadsNames( STRVECTOR& vNames) const
@@ -649,10 +665,10 @@ MachMgr::GetCurrRotAxes( void) const
//----------------------------------------------------------------------------
bool
MachMgr::GetAllCurrAxesName( STRVECTOR& vAxName) const
MachMgr::GetAllCurrAxesNames( STRVECTOR& vAxName) const
{
Machine* pMch = GetCurrMachine() ;
return ( ( pMch != nullptr) ? pMch->GetAllCurrAxesName( vAxName) : false) ;
return ( ( pMch != nullptr) ? pMch->GetAllCurrAxesNames( vAxName) : false) ;
}
//----------------------------------------------------------------------------
@@ -683,6 +699,26 @@ MachMgr::GetCurrLinAxesFrame( void) const
return pMch->GetCurrLinAxesFrame() ;
}
//----------------------------------------------------------------------------
bool
MachMgr::GetCurrIsCenter( void) const
{
Machine* pMch = GetCurrMachine() ;
if ( pMch == nullptr)
return false ;
return ( pMch->GetCurrKinematicChainType() == KIN_CHAIN_CENTER) ;
}
//----------------------------------------------------------------------------
bool
MachMgr::GetCurrIsRobot( void) const
{
Machine* pMch = GetCurrMachine() ;
if ( pMch == nullptr)
return false ;
return ( pMch->GetCurrKinematicChainType() == KIN_CHAIN_ROBOT) ;
}
//----------------------------------------------------------------------------
bool
MachMgr::GetCalcAngles( const Vector3d& vtDirT, const Vector3d& vtDirA,
@@ -727,7 +763,7 @@ MachMgr::GetCalcTipFromPositions( double dX, double dY, double dZ, double dAngA,
{
DBLVECTOR vAng( 2) ; vAng[0] = dAngA ; vAng[1] = dAngB ;
Machine* pMch = GetCurrMachine() ;
return ( ( pMch != nullptr) ? pMch->GetTipFromPositions( dX, dY, dZ, vAng, bOverall, bBottom, ptTip) : false) ;
return ( ( pMch != nullptr) ? pMch->GetTipFromPositions( dX, dY, dZ, vAng, bOverall, bBottom, false, ptTip) : false) ;
}
//----------------------------------------------------------------------------
@@ -736,7 +772,7 @@ MachMgr::GetCalcTipFromPositions( double dX, double dY, double dZ, const DBLVECT
bool bOverall, bool bBottom, Point3d& ptTip) const
{
Machine* pMch = GetCurrMachine() ;
return ( ( pMch != nullptr) ? pMch->GetTipFromPositions( dX, dY, dZ, vAng, bOverall, bBottom, ptTip) : false) ;
return ( ( pMch != nullptr) ? pMch->GetTipFromPositions( dX, dY, dZ, vAng, bOverall, bBottom, false, ptTip) : false) ;
}
//----------------------------------------------------------------------------
MachMgrOperations.cpp
+18 -2
View File
@@ -1122,7 +1122,23 @@ MachMgr::RemovePreviewMachiningTool( void) const
//----------------------------------------------------------------------------
int
MachMgr::PreviewMachiningTool( int nEntId, int nFlag) const
MachMgr::GetPreviewMachiningToolStepCount( void) const
{
// recupero la lavorazione corrente
int nCurrMchId = GetCurrMachining() ;
if ( nCurrMchId == GDB_ID_NULL)
return 0 ;
// ne recupero il gestore
Machining* pMch = GetMachining( m_pGeomDB->GetUserObj( nCurrMchId)) ;
if ( pMch == nullptr)
return 0 ;
// eseguo
return pMch->GetToolPreviewStepCount() ;
}
//----------------------------------------------------------------------------
int
MachMgr::PreviewMachiningTool( int nEntId, int nStep) const
{
// recupero la lavorazione corrente
int nCurrMchId = GetCurrMachining() ;
@@ -1133,7 +1149,7 @@ MachMgr::PreviewMachiningTool( int nEntId, int nFlag) const
if ( pMch == nullptr)
return GDB_ID_NULL ;
// eseguo
return pMch->ToolPreview( nEntId, nFlag) ;
return pMch->ToolPreview( nEntId, nStep) ;
}
//----------------------------------------------------------------------------
MachMgrRawParts.cpp
+410 -134
View File
@@ -29,6 +29,7 @@
#include "/EgtDev/Include/EGkStmStandard.h"
#include "/EgtDev/Include/EGkStmFromCurves.h"
#include "/EgtDev/Include/EgtPointerOwner.h"
#include "/EgtDev/Include/EXeConst.h"
using namespace std ;
@@ -96,7 +97,7 @@ MachMgr::AddRawPart( const Point3d& ptOrig, double dLen, double dWidth, double d
m_pGeomDB->SetInfo( nRawId, MACH_RAW_PHASE, m_nCurrPhase) ;
// creo solido e outline
bOk = bOk && ModifyRawPart( nRawId, ptOrig, dLen, dWidth, dHeight, cCol) ;
// se qualcosa è andato storto, cancello tutto
// se qualcosa è andato storto, cancello tutto
if ( ! bOk) {
m_pGeomDB->Erase( nRawId) ;
return GDB_ID_NULL ;
@@ -112,7 +113,7 @@ MachMgr::ModifyRawPart( int nRawId, const Point3d& ptOrig, double dLen, double d
// le dimensioni non possono essere nulle
if ( dLen < EPS_SMALL || dWidth < EPS_SMALL || dHeight < EPS_SMALL)
return false ;
// verifica validità grezzo
// verifica validità grezzo
if ( ! VerifyRawPart( nRawId))
return false ;
// creo il solido
@@ -171,7 +172,7 @@ MachMgr::AddRawPartWithPart( int nPartId, int nCrvSrfId, double dOverMat, Color
// verifico il gruppo dei grezzi nella macchinata corrente
if ( GetCurrRawGroupId() == GDB_ID_NULL)
return GDB_ID_NULL ;
// verifico che il pezzo non sia già usato nella macchinata corrente
// verifico che il pezzo non sia già usato nella macchinata corrente
if ( m_pGeomDB->GetParentId( nPartId) != GDB_ID_ROOT)
return GDB_ID_NULL ;
// recupero il tipo di oggetto per definire il grezzo
@@ -180,7 +181,7 @@ MachMgr::AddRawPartWithPart( int nPartId, int nCrvSrfId, double dOverMat, Color
Point3d ptRef ;
// costruzione del grezzo
int nRawId = GDB_ID_NULL ;
// se grezzo da superficie (per ora senza possibilità di offset)
// se grezzo da superficie (per ora senza possibilità di offset)
if ( ( nGtype & GEO_SURF) != 0) {
// inserisco il grezzo
nRawId = AddRawPart( nCrvSrfId, cCol) ;
@@ -284,7 +285,7 @@ MachMgr::AddRawPart( int nCrvId, double dOverMat, double dZmin, double dHeight,
m_pGeomDB->SetInfo( nRawId, MACH_RAW_PHASE, m_nCurrPhase) ;
// creo solido e outline
bOk = bOk && ModifyRawPart( nRawId, nCrvId, dOverMat, dZmin, dHeight, cCol) ;
// se qualcosa è andato storto, cancello tutto
// se qualcosa è andato storto, cancello tutto
if ( ! bOk) {
m_pGeomDB->Erase( nRawId) ;
return GDB_ID_NULL ;
@@ -297,7 +298,7 @@ MachMgr::AddRawPart( int nCrvId, double dOverMat, double dZmin, double dHeight,
bool
MachMgr::ModifyRawPart( int nRawId, int nCrvId, double dOverMat, double dZmin, double dHeight, Color cCol)
{
// verifica validità grezzo
// verifica validità grezzo
if ( ! VerifyRawPart( nRawId))
return false ;
// recupero il riferimento della curva
@@ -321,7 +322,7 @@ MachMgr::ModifyRawPart( int nRawId, int nCrvId, double dOverMat, double dZmin, d
// la schiaccio a Z = 0
if ( ! pMyCrv->Scale( Frame3d(), 1, 1, 0))
return false ;
// se non è chiusa, la chiudo
// se non è chiusa, la chiudo
pMyCrv->Close() ;
// la oriento in senso CCW
double dAreaXY ;
@@ -375,11 +376,11 @@ MachMgr::AddRawPart( int nSurfId, Color cCol)
if ( nRawGroupId == GDB_ID_NULL)
return GDB_ID_NULL ;
// recupero l'ingombro della superficie in globale
BBox3d b3Crv ;
if ( ! m_pGeomDB->GetGlobalBBox( nSurfId, b3Crv))
BBox3d b3Surf ;
if ( ! m_pGeomDB->GetGlobalBBox( nSurfId, b3Surf))
return GDB_ID_NULL ;
// inserisco il gruppo del grezzo nella macchinata
Frame3d frRaw( b3Crv.GetMin()) ;
Frame3d frRaw( b3Surf.GetMin()) ;
int nRawId = m_pGeomDB->AddGroup( GDB_ID_NULL, nRawGroupId, frRaw) ;
if ( nRawId == GDB_ID_NULL)
return GDB_ID_NULL ;
@@ -456,11 +457,11 @@ MachMgr::AddRawPart( int nSurfId, Color cCol)
int nCrvId = ( bOk ? m_pGeomDB->AddGeoObj( GDB_ID_NULL, nRawId, Release( pCrvCompo)) : GDB_ID_NULL) ;
bOk = bOk && ( nCrvId != GDB_ID_NULL) ;
// assegno il nome alla curva
bOk = bOk && m_pGeomDB->SetName( nCrvId, MACH_RAW_SOLID) ;
bOk = bOk && m_pGeomDB->SetName( nCrvId, MACH_RAW_OUTLINE) ;
// assegno il colore alla curva
bOk = bOk && m_pGeomDB->SetMaterial( nCrvId, cCol) ;
bOk = bOk && m_pGeomDB->SetMaterial( nCrvId, cCol) ;
}
// se qualcosa è andato storto, cancello tutto
// se qualcosa è andato storto, cancello tutto
if ( ! bOk) {
m_pGeomDB->Erase( nRawId) ;
return GDB_ID_NULL ;
@@ -471,6 +472,156 @@ MachMgr::AddRawPart( int nSurfId, Color cCol)
return nRawId ;
}
//----------------------------------------------------------------------------
int
MachMgr::AddRawPart( int nSfrUpId, int nSfrDownId, double dHeight, Color cCol)
{
// recupero il gruppo dei grezzi nella macchinata corrente
int nRawGroupId = GetCurrRawGroupId() ;
if ( nRawGroupId == GDB_ID_NULL)
return GDB_ID_NULL ;
// recupero l'ingombro della superficie up in globale
BBox3d b3Surf ;
if ( ! m_pGeomDB->GetGlobalBBox( nSfrUpId, b3Surf))
return GDB_ID_NULL ;
// inserisco il gruppo del grezzo nella macchinata
Frame3d frRaw( b3Surf.GetMin()) ;
int nRawId = m_pGeomDB->AddGroup( GDB_ID_NULL, nRawGroupId, frRaw) ;
if ( nRawId == GDB_ID_NULL)
return GDB_ID_NULL ;
// assegno il nome al gruppo
bool bOk = m_pGeomDB->SetName( nRawId, MACH_RAW_PART) ;
// assegno la fase al gruppo
bOk = bOk && m_pGeomDB->SetInfo( nRawId, MACH_RAW_PHASE, m_nCurrPhase) ;
// recupero il frame originale della superficie up ( deve essere lo stesso della down)
Frame3d frSurf ;
bOk = bOk && m_pGeomDB->GetGlobFrame( nSfrUpId, frSurf) ;
// creo il volume in modo approssimativo a partire dalle due superfici considerando soltanto un'approssimazione dei bordi esterni
// regione up
PtrOwner<ISurfFlatRegion> pSurfUp( CloneSurfFlatRegion( m_pGeomDB->GetGeoObj( nSfrUpId))) ;
bOk = bOk && ( ! IsNull( pSurfUp)) ;
// calcolo offset e contro-offset per unificare i chunk ed eliminare eventuali rientranze nella superficie
double dOffs = 8 ;
bOk = bOk && pSurfUp->Offset( dOffs, ICurve::OFF_FILLET) ;
bOk = bOk && pSurfUp->Offset( -dOffs, ICurve::OFF_FILLET) ;
// recupero il chunk di area maggiore
int nKMax = 0 ;
if ( bOk && pSurfUp->GetChunkCount() > 1) {
double dAreaMax = -1 ;
for ( int k = 0 ; k < pSurfUp->GetChunkCount() ; k ++) {
PtrOwner<ISurfFlatRegion> pSfrChunk( pSurfUp->CloneChunk( k)) ;
double dArea = -1 ; pSfrChunk->GetGrossArea( dArea) ;
if ( dArea > dAreaMax) {
nKMax = k ;
dAreaMax = dArea ;
}
}
}
PtrOwner<ICurve> pCrvUp ;
bOk = bOk && pCrvUp.Set( pSurfUp->GetLoop( nKMax, 0)) ;
bOk = bOk && ( ! IsNull( pCrvUp)) ;
// regione down
PtrOwner<ISurfFlatRegion> pSurfDown( CloneSurfFlatRegion( m_pGeomDB->GetGeoObj( nSfrDownId))) ;
bOk = bOk && ( ! IsNull( pSurfDown)) ;
bOk = bOk && pSurfDown->Offset( dOffs, ICurve::OFF_FILLET) ;
bOk = bOk && pSurfDown->Offset( -dOffs, ICurve::OFF_FILLET) ;
nKMax = 0 ;
if ( bOk && pSurfDown->GetChunkCount() > 1) {
double dAreaMax = -1 ;
for ( int k = 0 ; k < pSurfDown->GetChunkCount() ; k ++) {
PtrOwner<ISurfFlatRegion> pSfrChunk( pSurfDown->CloneChunk( k)) ;
double dArea = -1 ; pSfrChunk->GetGrossArea( dArea) ;
if ( dArea > dAreaMax) {
nKMax = k ;
dAreaMax = dArea ;
}
}
}
PtrOwner<ICurveComposite> pCrvDown ;
bOk = bOk && pCrvDown.Set( ConvertCurveToComposite( pSurfDown->GetLoop( nKMax, 0))) ;
bOk = bOk && ( ! IsNull( pCrvDown)) ;
// sposto il punto di inizio il più vicino possibile a quello della curva up per migliorare il calcolo della rigata
if ( bOk) {
Point3d ptS ; pCrvUp->GetStartPoint( ptS) ;
DistPointCurve distPC( ptS, *pCrvDown) ;
double dPar ; int nFlag ;
bOk = bOk && distPC.GetParamAtMinDistPoint( 0, dPar, nFlag) ;
bOk = bOk && pCrvDown->ChangeStartPoint( dPar) ;
}
// volume
PtrOwner<ISurfTriMesh> pStmRaw ;
bOk = bOk && pStmRaw.Set( GetSurfTriMeshByFlatContour( pCrvUp)) ;
bOk = bOk && ( ! IsNull( pStmRaw)) ;
PtrOwner<ISurfTriMesh> pStmLat ;
bOk = bOk && pStmLat.Set( GetSurfTriMeshRuled( pCrvDown, pCrvUp, ISurfTriMesh::RLT_MINDIST)) ;
bOk = bOk && ( ! IsNull( pStmLat)) ;
bOk = bOk && pStmRaw->DoSewing( *pStmLat) ;
PtrOwner<ISurfTriMesh> pStmDown ;
bOk = bOk && pStmDown.Set( GetSurfTriMeshByFlatContour( pCrvDown)) ;
bOk = bOk && pStmDown->Invert() ;
bOk = bOk && pStmRaw->DoSewing( *pStmDown) ;
bOk = bOk && pStmRaw->DoCompacting() ;
bOk = bOk && pStmRaw->Repair() ;
bOk = bOk && pStmRaw->LocToLoc( frSurf, frRaw) ;
int nId = bOk ? m_pGeomDB->AddGeoObj( GDB_ID_NULL, nRawId, Release( pStmRaw)) : GDB_ID_NULL ;
bOk = bOk && ( nId != GDB_ID_NULL) ;
// assegno il nome al solido
bOk = bOk && m_pGeomDB->SetName( nId, MACH_RAW_SOLID) ;
// assegno il colore al solido
bOk = bOk && m_pGeomDB->SetMaterial( nId, cCol) ;
// rendo visibile il solido
bOk = bOk && m_pGeomDB->SetStatus( nId, GDB_ST_ON) ;
// calcolo il punto centro del solido
bOk = bOk && SetRawPartCenter( nRawId) ;
if ( bOk) {
// costruisco la curva di contorno
PtrOwner<ISurfFlatRegion> pSfrUp( CloneSurfFlatRegion( m_pGeomDB->GetGeoObj( nSfrUpId))) ;
PtrOwner<ISurfFlatRegion> pSfrDown( CloneSurfFlatRegion( m_pGeomDB->GetGeoObj( nSfrDownId))) ;
bOk = bOk && ( ! IsNull( pSfrUp)) && ( ! IsNull( pSfrDown)) ;
if ( bOk)
pSfrUp->Add( *pSfrDown) ;
PtrOwner<ICurve> pCrv ;
bOk = bOk && pCrv.Set( pSfrUp->GetLoop( 0, 0)) ;
bOk = bOk && ( ! IsNull( pCrv)) ;
bOk = bOk && pCrv->LocToLoc( frSurf, frRaw) ;
int nLoop = bOk ? m_pGeomDB->AddGeoObj( GDB_ID_NULL, nRawId, Release( pCrv)) : GDB_ID_NULL ;
bOk = bOk && ( nLoop != GDB_ID_NULL) ;
bOk = bOk && ExeMove( {nLoop}, -dHeight * Z_AX, RTY_LOC) ;
// assegno il nome alla curva
bOk = bOk && m_pGeomDB->SetName( nLoop, MACH_RAW_OUTLINE) ;
// assegno il colore alla curva
bOk = bOk && m_pGeomDB->SetMaterial( nLoop, cCol) ;
// recupero le superfici up e down
int nSurfUpId = ( bOk ? m_pGeomDB->CopyGlob( nSfrUpId, GDB_ID_NULL, nRawId) : GDB_ID_NULL) ;
bOk = bOk && ( nSurfUpId != GDB_ID_NULL) ;
bOk = bOk && m_pGeomDB->SetName( nSurfUpId, MACH_RAW_UP_REG) ;
bOk = bOk && m_pGeomDB->SetMaterial( nSurfUpId, cCol) ;
bOk = bOk && m_pGeomDB->SetStatus( nSurfUpId, GDB_ST_OFF) ;
int nSurfDownId = ( bOk ? m_pGeomDB->CopyGlob( nSfrDownId, GDB_ID_NULL, nRawId) : GDB_ID_NULL) ;
bOk = bOk && ( nSurfDownId != GDB_ID_NULL) ;
bOk = bOk && m_pGeomDB->SetName( nSurfDownId, MACH_RAW_DOWN_REG) ;
bOk = bOk && m_pGeomDB->SetMaterial( nSurfDownId, cCol) ;
bOk = bOk && m_pGeomDB->SetStatus( nSurfDownId, GDB_ST_OFF) ;
}
// se qualcosa è andato storto, cancello tutto
if ( ! bOk) {
m_pGeomDB->Erase( nRawId) ;
return GDB_ID_NULL ;
}
// tutto ok
return nRawId ;
}
//----------------------------------------------------------------------------
bool
MachMgr::ModifyRawPartSize( int nRawId, double dLength, double dWidth, double dHeight)
@@ -478,7 +629,7 @@ MachMgr::ModifyRawPartSize( int nRawId, double dLength, double dWidth, double dH
// le nuove dimensioni non possono essere nulle
if ( dLength < EPS_SMALL || dWidth < EPS_SMALL || dHeight < EPS_SMALL)
return false ;
// verifica validità grezzo
// verifica validità grezzo
if ( ! VerifyRawPart( nRawId))
return false ;
// recupero il solido del grezzo
@@ -520,10 +671,10 @@ MachMgr::ModifyRawPartSize( int nRawId, double dLength, double dWidth, double dH
bool
MachMgr::ModifyRawPartHeight( int nRawId, double dHeight)
{
// la nuova altezza non può essere nulla
// la nuova altezza non può essere nulla
if ( dHeight < EPS_SMALL)
return false ;
// verifica validità grezzo
// verifica validità grezzo
if ( ! VerifyRawPart( nRawId))
return false ;
// recupero il solido del grezzo
@@ -552,10 +703,10 @@ MachMgr::GetRawPartPhases( int nRawId, INTVECTOR& vPhase) const
{
// pulisco parametro di ritorno
vPhase.clear() ;
// verifica validità grezzo
// verifica validità grezzo
if ( ! VerifyRawPart( nRawId))
return false ;
// recupero le fasi in cui è presente il grezzo (se manca è fase 1)
// recupero le fasi in cui è presente il grezzo (se manca è fase 1)
if ( ! m_pGeomDB->GetInfo( nRawId, MACH_RAW_PHASE, vPhase) || vPhase.empty())
vPhase.emplace_back( 1) ;
return true ;
@@ -565,11 +716,11 @@ MachMgr::GetRawPartPhases( int nRawId, INTVECTOR& vPhase) const
bool
MachMgr::KeepRawPart( int nRawId, int nSouPhase)
{
// verifico validità e recupero fasi in cui è presente
// verifico validità e recupero fasi in cui è presente
INTVECTOR vPhase ;
if ( ! GetRawPartPhases( nRawId, vPhase))
return false ;
// se fase corrente già presente, non devo fare alcunché
// se fase corrente già presente, non devo fare alcunché
if ( find( vPhase.begin(), vPhase.end(), m_nCurrPhase) != vPhase.end())
return true ;
// aggiungo la fase corrente
@@ -621,10 +772,11 @@ MachMgr::KeepRawPart( int nRawId, int nSouPhase)
bool
MachMgr::VerifyRawPartPhase( int nRawId, int nPhase) const
{
// verifico validità e recupero fasi in cui è presente
// verifico validità e recupero fasi in cui è presente
INTVECTOR vPhase ;
if ( ! GetRawPartPhases( nRawId, vPhase))
return false ;
// verifico presenza nella fase indicata
return ( find( vPhase.begin(), vPhase.end(), nPhase) != vPhase.end()) ;
}
@@ -632,11 +784,11 @@ MachMgr::VerifyRawPartPhase( int nRawId, int nPhase) const
bool
MachMgr::RemoveRawPartFromCurrPhase( int nRawId)
{
// verifico validità e recupero fasi in cui è presente
// verifico validità e recupero fasi in cui è presente
INTVECTOR vPhase ;
if ( ! GetRawPartPhases( nRawId, vPhase))
return false ;
// se non appartiene alla fase corrente, non devo fare alcunché
// se non appartiene alla fase corrente, non devo fare alcunché
auto iIter = find( vPhase.begin(), vPhase.end(), m_nCurrPhase) ;
if ( iIter == vPhase.end())
return true ;
@@ -663,7 +815,7 @@ MachMgr::RemoveRawPartFromCurrPhase( int nRawId)
bool
MachMgr::RemoveRawPart( int nRawId)
{
// verifica validità grezzo
// verifica validità grezzo
if ( ! VerifyRawPart( nRawId))
return false ;
// tolgo dalle disposizioni in cui compare gli eventuali movimenti registrati di questo grezzo
@@ -687,7 +839,7 @@ MachMgr::VerifyRawPart( int nRawId, bool bLinkedAllowed) const
int nRawGroupId = GetCurrRawGroupId() ;
if ( nRawGroupId != GDB_ID_NULL && m_pGeomDB->GetParentId( nRawId) == nRawGroupId)
return true ;
// se consentito linkaggio ed il grezzo è linkato ad un gruppo della macchina corrente, va bene
// se consentito linkaggio ed il grezzo è linkato ad un gruppo della macchina corrente, va bene
if ( bLinkedAllowed) {
Machine* pMch = GetCurrMachine() ;
if ( pMch != nullptr && pMch->IsLinkedRawPart( nRawId))
@@ -807,12 +959,12 @@ MachMgr::ResetRawPartCenter( int nRawId)
bool
MachMgr::GetRawPartCenter( int nRawId, Point3d& ptCen)
{
// verifica validità grezzo
// verifica validità grezzo
if ( ! VerifyRawPart( nRawId))
return false ;
// cerco di recuperare l'oggetto
int nGPntId = m_pGeomDB->GetFirstNameInGroup( nRawId, MACH_RAW_CENTER) ;
// ne verifico la validità
// ne verifico la validità
int nMode ;
if ( nGPntId == GDB_ID_NULL ||
! m_pGeomDB->GetMode( nGPntId, nMode) || nMode != GDB_MD_STD) {
@@ -840,7 +992,7 @@ MachMgr::GetRawPartCenter( int nRawId, Point3d& ptCen)
bool
MachMgr::GetRawPartBBox( int nRawId, BBox3d& b3Raw)
{
// verifica validità grezzo
// verifica validità grezzo
if ( ! VerifyRawPart( nRawId))
return false ;
// recupero solido del grezzo
@@ -848,6 +1000,103 @@ MachMgr::GetRawPartBBox( int nRawId, BBox3d& b3Raw)
return m_pGeomDB->GetGlobalBBox( nRawSolidId, b3Raw) ;
}
//---------------------------------------------------------------------------
static bool
AssociateSurfs( IGeomDB* pGeomDB, int nSurfUpId, int nSurfDownId, vector<pair<int,int>>& vRawSurfs)
{
// vRawSurfs contiene tutte le coppie ( id regioneUp, id regioneDown) che definiscono i nuovi grezzi
vRawSurfs.clear() ;
int nUpCnt = ExeSurfFrChunkCount( nSurfUpId) ;
int nDownCnt = ExeSurfFrChunkCount( nSurfDownId) ;
// se non sono stati creati più grezzi
if ( nUpCnt == 1 || nDownCnt == 1) {
vRawSurfs.emplace_back( nSurfUpId, nSurfDownId) ;
return true ;
}
int nUpFirstId = ExeExplodeSurface( nSurfUpId, &nUpCnt) ;
int nDownFirstId = ExeExplodeSurface( nSurfDownId, &nDownCnt) ;
// ad ogni chunk della regione up associo i chunk corrispondenti della regione down
INTVECTOR vChunks( nUpCnt, GDB_ID_NULL) ;
for ( int nIdD = nDownFirstId ; nIdD < nDownFirstId + nDownCnt ; nIdD ++) {
ISurfFlatRegion* pSfrD = GetSurfFlatRegion( pGeomDB->GetGeoObj( nIdD)) ;
if ( pSfrD == nullptr)
return false ;
BBox3d bBoxD ; ExeGetBBox( nIdD, BBF_STANDARD, bBoxD) ;
// inidividuo il chunk della superficie up che interagisce maggiormente con il chunk corrente della superficie down
int k = -1 ;
double dMaxArea = -1 ;
for ( int j = 0 ; j < nUpCnt ; j ++) {
BBox3d bBoxU ; ExeGetBBox( nUpFirstId + j, BBF_STANDARD, bBoxU) ;
if ( bBoxU.OverlapsXY( bBoxD)) {
PtrOwner<ISurfFlatRegion> pSfrU( CloneSurfFlatRegion( pGeomDB->GetGeoObj( nUpFirstId + j))) ;
if ( IsNull( pSfrU))
return false ;
// le due superfici sono nello stesso frame
pSfrU->Intersect( *pSfrD) ;
double dArea = -1 ; pSfrU->GetArea( dArea) ;
if ( dArea > dMaxArea) {
k = j ;
dMaxArea = dArea ;
}
}
}
// aggiorno le superfici con l'associazione trovata
if ( k == -1)
return false ;
if ( vChunks[k] == GDB_ID_NULL)
vChunks[k] = nIdD ;
else {
ExeSurfFrAdd( vChunks[k], nIdD) ;
ExeErase( {nIdD}) ;
}
}
// controllo per ogni chunk della superficie up il corrispondente della nuova superficie down
for ( int i = 0 ; i < nUpCnt ; i ++) {
ISurfFlatRegion* pSfrU = GetSurfFlatRegion( pGeomDB->GetGeoObj( nUpFirstId + i)) ;
if ( pSfrU == nullptr)
return false ;
BBox3d bBoxU ; ExeGetBBox( nUpFirstId + i, BBF_STANDARD, bBoxU) ;
// individuo il chunk della superficie down che interagisce maggiormente con il chunk corrente della superficie up
int k = -1 ;
double dMaxArea = -1 ;
for ( int j = 0 ; j < int( vChunks.size()) ; j ++) {
BBox3d bBoxD ; ExeGetBBox( vChunks[j], BBF_STANDARD, bBoxD) ;
// se i box interferiscono allora verifico di quanto si sovrappongono le due regioni
if ( bBoxD.OverlapsXY( bBoxU)) {
PtrOwner<ISurfFlatRegion> pSfrD( CloneSurfFlatRegion( pGeomDB->GetGeoObj( vChunks[j]))) ;
if ( IsNull( pSfrD))
return false ;
pSfrD->Intersect( *pSfrU) ;
double dArea = -1 ; pSfrD->GetArea( dArea) ;
if ( dArea > dMaxArea) {
k = j ;
dMaxArea = dArea ;
}
}
}
if ( k == -1)
return false ;
// se è la stessa associazione individuata da vChunks allora aggiorno il vettore finale dei grezzi
if ( k == i)
vRawSurfs.emplace_back( nUpFirstId + i, vChunks[i]) ;
else {
// altrimenti unisco le regioni associate appena individuate sia per la superficie up sia per la down
ExeSurfFrAdd( nUpFirstId + k, nUpFirstId + i) ;
ExeErase( {nUpFirstId + i}) ;
ExeSurfFrAdd( vChunks[k], vChunks[i]) ;
ExeErase( {vChunks[i]}) ;
}
}
return true ;
}
//----------------------------------------------------------------------------
int
MachMgr::SplitFlatRawPartWithMachinings( int nRawId, const INTVECTOR& vMchId)
@@ -871,7 +1120,6 @@ MachMgr::SplitFlatRawPartWithMachinings( int nRawId, const INTVECTOR& vMchId)
BBox3d b3Raw ;
if ( ! m_pGeomDB->GetGlobalBBox( nRawSolId, b3Raw))
return GDB_ID_NULL ;
double dZmin = b3Raw.GetMin().z ;
double dHeight = b3Raw.GetMax().z - b3Raw.GetMin().z ;
// il colore del grezzo
Color cCol = AQUA ;
@@ -880,19 +1128,31 @@ MachMgr::SplitFlatRawPartWithMachinings( int nRawId, const INTVECTOR& vMchId)
Frame3d frRaw ;
if ( ! m_pGeomDB->GetGroupGlobFrame( nRawId, frRaw))
return GDB_ID_NULL ;
// creo la regione del grezzo a partire dal suo contorno
// recupero il contorno
int nOutCrvId = m_pGeomDB->GetFirstNameInGroup( nRawId, MACH_RAW_OUTLINE) ;
if ( nOutCrvId == GDB_ID_NULL)
return GDB_ID_NULL ;
// creo la regione
INTVECTOR vCrvIds ;
vCrvIds.emplace_back( nOutCrvId) ;
int nSfrId = ExeCreateSurfFlatRegion( nRawId, vCrvIds, nullptr) ;
if ( nSfrId == GDB_ID_NULL)
return GDB_ID_NULL ;
m_pGeomDB->SetLevel( nSfrId, GDB_LV_TEMP) ;
// creo le regioni inferiore e superiore del grezzo da aggiornare con le lavorazioni
int nSfrDownId = GDB_ID_NULL, nSfrUpId = GDB_ID_NULL ;
int nSfrDownOrigId = m_pGeomDB->GetFirstNameInGroup( nRawId, MACH_RAW_DOWN_REG) ;
int nSfrUpOrigId = m_pGeomDB->GetFirstNameInGroup( nRawId, MACH_RAW_UP_REG) ;
if ( nSfrDownOrigId == GDB_ID_NULL || nSfrUpOrigId == GDB_ID_NULL) {
// se le regioni del grezzo di partenza non sono definite, le creo a partire dall'outline
nSfrDownId = ExeCreateSurfFlatRegion( nRawId, {nOutCrvId}, nullptr) ;
if ( nSfrDownId == GDB_ID_NULL)
return GDB_ID_NULL ;
nSfrUpId = ExeCopyGlob( nSfrDownId, nRawId, GDB_LAST_SON) ;
if ( nSfrUpId == GDB_ID_NULL)
return GDB_ID_NULL ;
ExeMove( { nSfrUpId}, dHeight * Z_AX, RTY_LOC) ;
}
else {
nSfrDownId = ExeCopyGlob( nSfrDownOrigId, nRawId, GDB_LAST_SON) ;
nSfrUpId = ExeCopyGlob( nSfrUpOrigId, nRawId, GDB_LAST_SON) ;
if ( nSfrDownId == GDB_ID_NULL || nSfrUpId == GDB_ID_NULL)
return GDB_ID_NULL ;
}
// se esiste il kerf, ne creo la regione
PtrOwner<ISurfFlatRegion> pSfrKerf ;
@@ -907,7 +1167,8 @@ MachMgr::SplitFlatRawPartWithMachinings( int nRawId, const INTVECTOR& vMchId)
}
// recupero le regioni delle lavorazioni
INTVECTOR vMchRReg ;
INTVECTOR vMchRRegUp ;
INTVECTOR vMchRRegDown ;
for ( auto nMchId : vMchId) {
// recupero gruppo preview lavorazioni nella lavorazione
int nPVGrp = m_pGeomDB->GetFirstNameInGroup( nMchId, MCH_PV) ;
@@ -915,94 +1176,110 @@ MachMgr::SplitFlatRawPartWithMachinings( int nRawId, const INTVECTOR& vMchId)
return GDB_ID_NULL ;
// se vuoto, cerco il rimando al preview nel pezzo
if ( m_pGeomDB->GetGroupObjs( nPVGrp) == 0 &&
! m_pGeomDB->GetInfo( nPVGrp, MCH_PV_KEY_RELOCATE, nPVGrp))
! m_pGeomDB->GetInfo( nPVGrp, MCH_PV_KEY_RELOCATE, nPVGrp))
return GDB_ID_NULL ;
// ciclo sui percorsi utensile (CL)
int nClId = m_pGeomDB->GetFirstGroupInGroup( nPVGrp) ;
while ( nClId != GDB_ID_NULL) {
// tagli ridotti
int nCrId = m_pGeomDB->GetFirstNameInGroup( nClId, MCH_PV_RRCUT) ;
while ( nCrId != GDB_ID_NULL) {
vMchRReg.emplace_back( nCrId) ;
nCrId = m_pGeomDB->GetNextName( nCrId, MCH_PV_RRCUT) ;
}
// lavorazioni per regione inferiore
int nCrDownId = m_pGeomDB->GetFirstNameInGroup( nClId, MCH_PV_DOWN_RAWCUT) ;
// se non esiste la regione inferiore la lavorazione non è passante quindi può essere ignorata
if ( nCrDownId != GDB_ID_NULL) {
while ( nCrDownId != GDB_ID_NULL) {
vMchRRegDown.emplace_back( nCrDownId) ;
nCrDownId = m_pGeomDB->GetNextName( nCrDownId, MCH_PV_DOWN_RAWCUT) ;
}
// lavorazioni per regione superiore
int nCrUpId = m_pGeomDB->GetFirstNameInGroup( nClId, MCH_PV_UP_RAWCUT) ;
while ( nCrUpId != GDB_ID_NULL) {
vMchRRegUp.emplace_back( nCrUpId) ;
nCrUpId = m_pGeomDB->GetNextName( nCrUpId, MCH_PV_UP_RAWCUT) ;
}
}
// passo al successivo percorso utensile
nClId = m_pGeomDB->GetNextGroup( nClId) ;
}
}
// sottraggo queste regioni a quella del grezzo
for ( auto nMchRReg : vMchRReg) {
ExeSurfFrSubtract( nSfrId, nMchRReg) ;
}
// sottraggo le lavorazioni alle superfici del grezzo
for ( auto nMchRReg : vMchRRegUp)
ExeSurfFrSubtract( nSfrUpId, nMchRReg) ;
for ( auto nMchRReg : vMchRRegDown)
ExeSurfFrSubtract( nSfrDownId, nMchRReg) ;
// classifico i chunks della regione up e down per individuare le regioni che definiscono i nuovi grezzi
vector<pair<int,int>> vSurfRaws ;
AssociateSurfs( m_pGeomDB, nSfrUpId, nSfrDownId, vSurfRaws) ;
// creo i grezzi risultanti
// creo i nuovi grezzi
INTVECTOR vNewIds ;
int nCount ;
int nChunk = 0 ;
int nFirstLoopId = ExeExtractSurfFrChunkLoops( nSfrId, nChunk, nRawId, &nCount) ;
while ( nFirstLoopId != GDB_ID_NULL) {
// !!! in attesa di gestire i grezzi con i buchi !!!
// cancello le eventuali curve successive (sono i loop interni ovvero i buchi)
for ( int i = 1 ; i < nCount ; ++ i) {
m_pGeomDB->Erase( nFirstLoopId + i) ;
}
// dichiaro temporanea la curva
m_pGeomDB->SetLevel( nFirstLoopId, GDB_LV_TEMP) ;
// creo il grezzo
int nId = AddRawPart( nFirstLoopId, 0, dZmin, dHeight, cCol) ;
if ( nId == GDB_ID_NULL)
return GDB_ID_NULL ;
vNewIds.emplace_back( nId) ;
// imposto lo stato del contorno di questo grezzo come quello del grezzo di partenza
int nStat = GDB_ST_ON ;
if ( m_pGeomDB->GetStatus( nOutCrvId, nStat) && nStat == GDB_ST_OFF)
m_pGeomDB->SetStatus( m_pGeomDB->GetFirstNameInGroup( nId, MACH_RAW_OUTLINE), nStat) ;
// assegno la fase al gruppo
m_pGeomDB->SetInfo( nId, MACH_RAW_PHASE, m_nCurrPhase) ;
// se esiste il kerf uso questa curva per creare il kerf del nuovo grezzo
if ( ! IsNull( pSfrKerf)) {
// creo la regione con la curva
SurfFlatRegionByContours SfrCntr ;
SfrCntr.AddCurve( GetCurve( m_pGeomDB->RemoveGeoObjAndErase( nFirstLoopId))) ;
PtrOwner<ISurfFlatRegion> pSfrNewKerf( SfrCntr.GetSurf()) ;
if ( IsNull( pSfrNewKerf))
return GDB_ID_NULL ;
// la limito con la regione di kerf precedente (va bene anche se fallisce)
pSfrNewKerf->Intersect( *pSfrKerf) ;
// se risultato non vuoto
if ( pSfrNewKerf->IsValid()) {
// riferimento del nuovo grezzo
Frame3d frNewRaw ;
if ( ! m_pGeomDB->GetGroupGlobFrame( nId, frNewRaw))
return GDB_ID_NULL ;
// la porto dal riferimento del grezzo originale al riferimento di questo grezzo
pSfrNewKerf->LocToLoc( frRaw, frNewRaw) ;
// la porto sulla faccia sopra del grezzo
pSfrNewKerf->Translate( Vector3d( 0, 0, dHeight)) ;
// recupero il contorno e lo inserisco come kerf del nuovo grezzo
PtrOwner<ICurve> pCrv( pSfrNewKerf->GetLoop( 0, 0)) ;
int nNewKerfId = m_pGeomDB->AddGeoObj( GDB_ID_NULL, nId, Release( pCrv)) ;
if ( nNewKerfId == GDB_ID_NULL)
return GDB_ID_NULL ;
m_pGeomDB->CopyMaterial( nKerfId, nNewKerfId) ;
m_pGeomDB->SetName( nNewKerfId, MACH_RAW_KERF) ;
}
}
// altrimenti la cancello
else
m_pGeomDB->Erase( nFirstLoopId) ;
// passo alla prossima curva
++ nChunk ;
nFirstLoopId = ExeExtractSurfFrChunkLoops( nSfrId, nChunk, nRawId, &nCount) ;
}
// cancello la regione
m_pGeomDB->Erase( nSfrId) ;
// verifico esista almeno un nuovo grezzo
if ( vNewIds.empty())
return GDB_ID_NULL ;
INTVECTOR vNewIds ;
for ( int i = 0 ; i < int( vSurfRaws.size()) ; i++) {
// aggiungo il grezzo
int nId = AddRawPart( vSurfRaws[i].first, vSurfRaws[i].second, dHeight, cCol) ;
m_pGeomDB->Erase( vSurfRaws[i].first) ;
m_pGeomDB->Erase( vSurfRaws[i].second) ;
if ( nId == GDB_ID_NULL)
return GDB_ID_NULL ;
vNewIds.emplace_back( nId) ;
// imposto lo stato del contorno di questo grezzo come quello del grezzo di partenza
int nStat = GDB_ST_ON ;
if ( m_pGeomDB->GetStatus( nOutCrvId, nStat) && nStat == GDB_ST_OFF)
m_pGeomDB->SetStatus( m_pGeomDB->GetFirstNameInGroup( nId, MACH_RAW_OUTLINE), nStat) ;
// assegno la fase al gruppo
m_pGeomDB->SetInfo( nId, MACH_RAW_PHASE, m_nCurrPhase) ;
// se esiste il kerf uso questa curva per creare il kerf del nuovo grezzo
if ( ! IsNull( pSfrKerf)) {
// riferimento del nuovo grezzo
Frame3d frNewRaw ;
if ( ! m_pGeomDB->GetGroupGlobFrame( nId, frNewRaw))
return GDB_ID_NULL ;
// considero il nuovo kerf come la regione superiore del nuovo grezzo
int nSfrUpId = m_pGeomDB->GetFirstNameInGroup( nId, MACH_RAW_UP_REG) ;
if ( nSfrUpId == GDB_ID_NULL)
return GDB_ID_NULL ;
PtrOwner<ISurfFlatRegion> pSfrNewKerf( CloneSurfFlatRegion( m_pGeomDB->GetGeoObj( nSfrUpId))) ;
if ( IsNull( pSfrNewKerf))
return GDB_ID_NULL ;
// porto nello stesso riferimento del grezzo originale
pSfrNewKerf->LocToLoc( frNewRaw, frRaw) ;
// la limito con la regione di kerf precedente ( va bene anche se fallisce)
pSfrNewKerf->Intersect( *pSfrKerf) ;
// se risultato non vuoto
if ( pSfrNewKerf->IsValid()) {
// la porto dal riferimento del grezzo originale al riferimento di questo grezzo
pSfrNewKerf->LocToLoc( frRaw, frNewRaw) ;
// recupero il contorno esterno del chunk più grande e lo inserisco come kerf del nuovo grezzo
double dAreaMax = -1 ;
int nKMax = 0 ;
for ( int k = 0 ; k < pSfrNewKerf->GetChunkCount() ; k ++) {
PtrOwner<ISurfFlatRegion> pSfrChunk( pSfrNewKerf->CloneChunk( k)) ;
double dArea = -1 ; pSfrChunk->GetGrossArea( dArea) ;
if ( dArea > dAreaMax) {
nKMax = k ;
dAreaMax = dArea ;
}
}
PtrOwner<ICurve> pCrv( pSfrNewKerf->GetLoop( nKMax, 0)) ;
if ( IsNull( pCrv))
return GDB_ID_NULL ;
int nNewKerfId = m_pGeomDB->AddGeoObj( GDB_ID_NULL, nId, Release( pCrv)) ;
if ( nNewKerfId == GDB_ID_NULL)
return GDB_ID_NULL ;
m_pGeomDB->CopyMaterial( nKerfId, nNewKerfId) ;
m_pGeomDB->SetName( nNewKerfId, MACH_RAW_KERF) ;
}
}
}
// cancello le regioni usate per i conti
m_pGeomDB->Erase( nSfrUpId) ;
m_pGeomDB->Erase( nSfrDownId) ;
// verifico esista almeno un nuovo grezzo
if ( vNewIds.empty())
return GDB_ID_NULL ;
// inserisco i pezzi del grezzo originale nei nuovi grezzi
int nGroupId = m_pGeomDB->GetFirstGroupInGroup( nRawId) ;
while ( nGroupId != GDB_ID_NULL) {
@@ -1012,32 +1289,31 @@ MachMgr::SplitFlatRawPartWithMachinings( int nRawId, const INTVECTOR& vMchId)
// scambio con pezzo
int nPartId = SwapRawPartPart( nNewGroupId, true) ;
// verifico se il pezzo sta nel grezzo
int nLayerId = m_pGeomDB->GetFirstNameInGroup( nPartId, NST_EXT_LAYER) ;
int nLayerId = m_pGeomDB->GetFirstNameInGroup( nPartId, NST_PARTREG_LAYER) ;
if ( nLayerId == GDB_ID_NULL || m_pGeomDB->GetGdbType( nLayerId) != GDB_TY_GROUP)
nLayerId = m_pGeomDB->GetFirstGroupInGroup( nPartId) ;
int nEntId = m_pGeomDB->GetFirstInGroup( nLayerId) ;
int nEntGeoType = m_pGeomDB->GetGeoType( nEntId) ;
Point3d ptTest ;
if ( ( ( nEntGeoType & GEO_CURVE) != 0 && ExeMidPoint( nEntId, nNewId, ptTest)) ||
( ( nEntGeoType & GEO_CURVE) == 0 && ExeCenterPoint( nEntId, nNewId, ptTest))) {
// cerco la regione del pezzo
int nEntId = m_pGeomDB->GetFirstInGroup( nLayerId) ;
while ( nEntId != GDB_ID_NULL) {
int nEntGeoType = m_pGeomDB->GetGeoType( nEntId) ;
if ( nEntGeoType == SRF_FLATRGN)
break ;
nEntId = m_pGeomDB->GetNext( nEntId) ;
}
if ( nEntId != GDB_ID_NULL) {
// verifico se è interna al grezzo
int nOutCrvId = m_pGeomDB->GetFirstNameInGroup( nNewId, MACH_RAW_OUTLINE) ;
BBox3d b3Raw ; m_pGeomDB->GetGlobalBBox( nOutCrvId, b3Raw) ;
double dRawDiam = 0 ; b3Raw.GetDiameter( dRawDiam) ;
BBox3d b3Part ; m_pGeomDB->GetGlobalBBox( nEntId, b3Part) ;
double dPartDiam = 0 ; b3Part.GetDiameter( dPartDiam) ;
if ( dRawDiam > 0.9 * dPartDiam) {
ICurve* pCurve = GetCurve( m_pGeomDB->GetGeoObj( nOutCrvId)) ;
if ( pCurve != nullptr) {
int nSide ;
double dDist ;
DistPointCurve distPC( ptTest, *pCurve) ;
if ( distPC.GetDist( dDist) &&
( dDist < 100 * EPS_SMALL ||
( distPC.GetSideAtMinDistPoint( 0, Z_AX, nSide) && nSide != MDS_RIGHT)))
break ;
}
}
}
int nSfrUp = m_pGeomDB->GetFirstNameInGroup( nNewId, MACH_RAW_UP_REG) ;
if ( ! ExeSurfFrTestExternal( nSfrUp, nEntId, EPS_SMALL))
break ;
}
}
// altrimenti scambio pezzo ed elimino gruppo
nNewGroupId = SwapRawPartPart( nPartId, false) ;
m_pGeomDB->Erase( nNewGroupId) ;
@@ -1045,5 +1321,5 @@ MachMgr::SplitFlatRawPartWithMachinings( int nRawId, const INTVECTOR& vMchId)
nGroupId = m_pGeomDB->GetNextGroup( nGroupId) ;
}
return vNewIds[0] ;
return vNewIds[0] ;
}
MachMgrSetup.cpp
+7
View File
@@ -130,6 +130,13 @@ MachMgr::FindToolInCurrSetup( const string& sTool)
return m_stuMgr.FindTool( sTool) ;
}
//----------------------------------------------------------------------------
bool
MachMgr::GetToolSetupPosInCurrSetup( const string& sTool, string& sTcPos)
{
return m_stuMgr.GetToolSetupPos( sTool, sTcPos) ;
}
//----------------------------------------------------------------------------
bool
MachMgr::GetToolsInCurrSetupPos( const string& sTcPos, STRVECTOR& vsTools)
MachMgrSimulation.cpp
+34 -5
View File
@@ -16,7 +16,8 @@
#include "DllMain.h"
#include "MachMgr.h"
#include "MachConst.h"
#include "Simulator.h"
#include "SimulatorSP.h"
#include "SimulatorMP.h"
using namespace std ;
@@ -27,7 +28,12 @@ MachMgr::SimInit( void)
// alloco o rialloco il simulatore
if ( m_pSimul != nullptr)
delete m_pSimul ;
m_pSimul = new( nothrow) Simulator ;
if ( GetCurrMachine() == nullptr)
return false ;
if ( GetCurrMachine()->GetMultiProcess( 2))
m_pSimul = CreateSimulatorMP() ;
else
m_pSimul = CreateSimulatorSP() ;
if ( m_pSimul == nullptr)
return false ;
// lo inizializzo
@@ -183,13 +189,25 @@ MachMgr::SimOnCollision( int nCdInd, int nObjInd, int& nErr)
//----------------------------------------------------------------------------
bool
MachMgr::SimSetToolForVmill( const string& sTool, const string& sHead, int nExit, const INTVECTOR& vVmill, bool bFirst)
MachMgr::SimSetToolForVmill( const string& sTool, const string& sHead, int nExit, int nFlag, double dPar1, double dPar2,
const INTVECTOR& vVmill, bool bFirst)
{
// verifico simulatore
if ( m_pSimul == nullptr)
return false ;
// imposto utensile per Vmill
return m_pSimul->SetToolForVmill( sTool, sHead, nExit, vVmill, bFirst) ;
return m_pSimul->SetToolForVmill( sTool, sHead, nExit, nFlag, dPar1, dPar2, vVmill, bFirst) ;
}
//----------------------------------------------------------------------------
bool
MachMgr::SimEnableToolsForVmill( bool bEnable)
{
// verifico simulatore
if ( m_pSimul == nullptr)
return false ;
// imposto abilitazione Vmill
return m_pSimul->EnableToolsForVmill( bEnable) ;
}
//----------------------------------------------------------------------------
@@ -198,7 +216,18 @@ MachMgr::SimMoveAxes( int nMoveType, const SAMVECTOR& vAxNaEpSt)
{
// verifico simulatore
if ( m_pSimul == nullptr)
return false ;
return SIM_AXMV_RES_ERR ;
// lancio movimento assi
return m_pSimul->MoveAxes( nMoveType, vAxNaEpSt) ;
}
//----------------------------------------------------------------------------
bool
MachMgr::SimSaveCmd( int nType, int nPar, const string& sPar)
{
// verifico simulatore
if ( m_pSimul == nullptr)
return false ;
// salvo il comando
return m_pSimul->SaveCmd( nType, nPar, sPar) ;
}
Machine.cpp
+83 -13
View File
@@ -41,6 +41,7 @@ Machine::Machine( void)
m_dExitMaxAdjust = EPS_SMALL ;
m_dExitMaxRotAdj = 10 * EPS_ANG_SMALL ;
m_dAngDeltaMinForHome = INFINITO ;
m_nMultiProcess = 0 ;
m_nCalcTabId = GDB_ID_NULL ;
m_nCalcHeadId = GDB_ID_NULL ;
m_nCalcExitId = GDB_ID_NULL ;
@@ -58,6 +59,8 @@ Machine::Machine( void)
m_nHeadRotAxes = 0 ;
m_nHeadSpecRotAxis = -1 ;
m_frLinAx.Reset( false) ;
m_frRobot.Reset( false) ;
m_nCalcChainType = KIN_CHAIN_NONE ;
m_nMachineLook = MCH_LOOK_NONE ;
}
@@ -141,6 +144,8 @@ Machine::Init( const string& sMachineName, const string& sMachineDir, MachMgr* p
m_nMachineLook = ( bOk ? MCH_LOOK_ALL : MCH_LOOK_NONE) ;
// metto tutti gli assi in posizione home
bOk = bOk && ResetAllAxesPos() ;
// reset catena cinematica corrente
m_nCalcChainType = KIN_CHAIN_NONE ;
return bOk ;
}
@@ -209,7 +214,7 @@ Machine::AdjustAuxGeometry( const STRVECTOR& vsAux, int nLay)
bool
Machine::LoadMachineTable( const string& sName, const string& sParent, int nType,
const Point3d& ptRef1, double dCoeffX, double dCoeffY, double dCoeffZ,
const string& sGeo, const STRVECTOR& vsAux)
const STRVECTOR& vsColl, const string& sGeo, const STRVECTOR& vsAux)
{
// recupero pezzo e layer della geometria originale della tavola
string sPart, sLay ;
@@ -248,7 +253,7 @@ Machine::LoadMachineTable( const string& sName, const string& sParent, int nType
Table* pTab = new(nothrow) Table ;
if ( pTab == nullptr)
return false ;
pTab->Set( sName, nType, ptRef1, b3Area1) ;
pTab->Set( sName, nType, ptRef1, b3Area1, vsColl) ;
m_pGeomDB->SetUserObj( nLay, pTab) ;
// lo inserisco nel dizionario dei gruppi della macchina
return m_mapGroups.emplace( sName, nLay).second ;
@@ -441,8 +446,16 @@ Machine::ModifyMachineAxisPosition( const string& sName, const Point3d& ptPos)
Axis* pAx = GetAxis( nAxGrp) ;
if ( pAx == nullptr)
return false ;
// se valore dell'asse non nullo, lo annullo
double dCurrVal = pAx->GetCurrVal() ;
if ( abs( dCurrVal) > EPS_ZERO)
SetAxisPos( sName, 0, false) ;
// eseguo la modifica
return pAx->Modify( ptPos, m_dAxisMaxAdjust) ;
bool bOk = pAx->Modify( ptPos, m_dAxisMaxAdjust) ;
// ripristino l'asse al valore corrente
if ( abs( dCurrVal) > EPS_ZERO)
SetAxisPos( sName, dCurrVal, false) ;
return bOk ;
}
//----------------------------------------------------------------------------
@@ -458,8 +471,16 @@ Machine::ModifyMachineAxisDirection( const string& sName, const Vector3d& vtDir)
Axis* pAx = GetAxis( nAxGrp) ;
if ( pAx == nullptr)
return false ;
// se valore dell'asse non nullo, lo annullo
double dCurrVal = pAx->GetCurrVal() ;
if ( abs( dCurrVal) > EPS_ZERO)
SetAxisPos( sName, 0, false) ;
// eseguo la modifica
return pAx->Modify( vtDir, m_dAxisMaxRotAdj) ;
bool bOk = pAx->Modify( vtDir, m_dAxisMaxRotAdj) ;
// ripristino l'asse al valore corrente
if ( abs( dCurrVal) > EPS_ZERO)
SetAxisPos( sName, dCurrVal, false) ;
return bOk ;
}
//----------------------------------------------------------------------------
@@ -528,7 +549,7 @@ Machine::LoadMachineStdHead( const string& sName, const string& sParent, const s
Head* pHead = new(nothrow) Head ;
if ( pHead == nullptr)
return false ;
pHead->Set( sName, MCH_HT_STD, 1, sHSet, vtADir, dRot1W, bMaxDeltaR2On1, Rot2Stroke, nSolCh, vsOthColl) ;
pHead->Set( sName, MCH_HT_STD, 1, sHSet, 0, vtADir, dRot1W, bMaxDeltaR2On1, Rot2Stroke, nSolCh, vsOthColl) ;
m_pGeomDB->SetUserObj( nLay, pHead) ;
// aggiorno la testa capostipite
if ( ! AddHeadToSet( sHSet, sName))
@@ -548,7 +569,7 @@ Machine::LoadMachineStdHead( const string& sName, const string& sParent, const s
//----------------------------------------------------------------------------
bool
Machine::LoadMachineMultiHead( const string& sName, const string& sParent, const string& sHSet,
const MUEXITVECTOR& vMuExit, const Vector3d& vtADir,
int nSelectType, const MUEXITVECTOR& vMuExit, const Vector3d& vtADir,
double dRot1W, bool bMaxDeltaR2On1, const STROKE& Rot2Stroke, int nSolCh, const STRVECTOR& vsOthColl,
const string& sGeo, const STRVECTOR& vsAux)
{
@@ -577,7 +598,8 @@ Machine::LoadMachineMultiHead( const string& sName, const string& sParent, const
Head* pHead = new(nothrow) Head ;
if ( pHead == nullptr)
return false ;
pHead->Set( sName, MCH_HT_MULTI, int( vMuExit.size()), sHSet, vtADir, dRot1W, bMaxDeltaR2On1, Rot2Stroke, nSolCh, vsOthColl) ;
pHead->Set( sName, MCH_HT_MULTI, int( vMuExit.size()), sHSet, nSelectType,
vtADir, dRot1W, bMaxDeltaR2On1, Rot2Stroke, nSolCh, vsOthColl) ;
m_pGeomDB->SetUserObj( nLay, pHead) ;
// aggiorno la testa capostipite
if ( ! AddHeadToSet( sHSet, sName))
@@ -624,7 +646,7 @@ Machine::LoadMachineSpecialHead( const string& sName, const string& sParent, con
Head* pHead = new(nothrow) Head ;
if ( pHead == nullptr)
return false ;
pHead->Set( sName, MCH_HT_SPECIAL, 1, sHSet, vtADir, dRot1W, bMaxDeltaR2On1, Rot2Stroke, nSolCh, vsOthColl) ;
pHead->Set( sName, MCH_HT_SPECIAL, 1, sHSet, 0, vtADir, dRot1W, bMaxDeltaR2On1, Rot2Stroke, nSolCh, vsOthColl) ;
m_pGeomDB->SetUserObj( nLay, pHead) ;
// aggiorno la testa capostipite
if ( ! AddHeadToSet( sHSet, sName))
@@ -643,9 +665,9 @@ Machine::LoadMachineSpecialHead( const string& sName, const string& sParent, con
//----------------------------------------------------------------------------
bool
Machine::LoadMachineTcPos( const string& sName, const string& sParent,
const Point3d& ptPos, const Vector3d& vtTDir, const Vector3d& vtADir,
const string& sGeo, const STRVECTOR& vsAux)
Machine::LoadMachineStdTcPos( const string& sName, const string& sParent,
const Point3d& ptPos, const Vector3d& vtTDir, const Vector3d& vtADir,
const string& sGeo, const STRVECTOR& vsAux)
{
// recupero pezzo e layer della geometria originale della posizione nel cambio utensile
string sPart, sLay ;
@@ -685,6 +707,48 @@ Machine::LoadMachineTcPos( const string& sName, const string& sParent,
return m_mapGroups.emplace( sName, nLay).second ;
}
//----------------------------------------------------------------------------
bool
Machine::LoadMachineMultiTcPos( const string& sName, const string& sParent,
const MUEXITVECTOR& vMuExit, const Vector3d& vtADir,
const string& sGeo, const STRVECTOR& vsAux)
{
// recupero pezzo e layer della geometria originale della posizione nel cambio utensile
string sPart, sLay ;
Split( sGeo, "/", true, sPart, sLay) ;
// cerco il gruppo nella geometria originale
int nPart = m_pGeomDB->GetFirstNameInGroup( m_nTempGroupId, sPart) ;
int nLay = m_pGeomDB->GetFirstNameInGroup( nPart, sLay) ;
if ( nLay == GDB_ID_NULL)
return false ;
// cerco il gruppo padre per spostarvelo
int nParentId = GetGroup( sParent) ;
if ( nParentId == GDB_ID_NULL ||
! m_pGeomDB->RelocateGlob( nLay, nParentId, GDB_LAST_SON))
return false ;
// sistemo lo stato di visualizzazione
m_pGeomDB->SetStatus( nLay, GDB_ST_ON) ;
// gli assegno il nome
m_pGeomDB->SetName( nLay, sName) ;
// sistemo la geometria ausiliaria
if ( ! AdjustAuxGeometry( vsAux, nLay))
return false ;
// installo e inizializzo il gestore della posizione nel cambio utensile
TcPos* pTcPos = new(nothrow) TcPos ;
if ( pTcPos == nullptr)
return false ;
pTcPos->Set( sName, vtADir) ;
m_pGeomDB->SetUserObj( nLay, pTcPos) ;
// sistemo il riferimento dell'uscita rispetto alla direzione ausiliaria
if ( ! AdjustExitFrames( nLay, vMuExit, vtADir))
return false ;
// trasformazione del riferimento di uscita in gruppo di uscita
if ( ! CreateExitGroups( nLay, vMuExit))
return false ;
// lo inserisco nel dizionario dei gruppi della macchina
return m_mapGroups.emplace( sName, nLay).second ;
}
//----------------------------------------------------------------------------
int
Machine::GetGroup( const string& sGroup) const
@@ -918,7 +982,7 @@ Machine::CreateExitGroups( int nLay, const MUEXITVECTOR& vMuExit)
return false ;
}
else {
Vector3d vtRotAx = vtTDir ^ vtDirN ; vtRotAx.Normalize() ;
Vector3d vtRotAx = vtTDir ^ vtDirN ; vtRotAx.Normalize( EPS_ZERO) ;
string sOut = " Exit " + sName + " rotation = (" + ToString( dAngRot) + "/" + ToString( vtRotAx) + ")" ;
LOG_DBG_INFO( GetEMkLogger(), sOut.c_str()) ;
vtRotAx.ToLoc( frHead) ;
@@ -976,7 +1040,11 @@ Machine::ModifyMachineExitPosition( const string& sHead, int nExit, const Point3
if ( pExit == nullptr)
return false ;
// eseguo la modifica
return pExit->Modify( ptPos, m_dExitMaxAdjust) ;
if ( ! pExit->Modify( ptPos, m_dExitMaxAdjust))
return false ;
// eventuale aggiornamento variabile lua EMC.EXITPOS con la nuova posizione
LuaSetGlobVar( "EMC.EXITPOS", ptPos) ;
return true ;
}
//----------------------------------------------------------------------------
@@ -1000,6 +1068,8 @@ Machine::SetLook( int nFlag)
nTabId = GetFirstTable() ;
if ( nTabId == GDB_ID_NULL)
return false ;
// il gruppo tavola corrente deve essere sempre visibile
m_pGeomDB->SetStatus( nTabId, GDB_ST_ON) ;
// nascondo o visualizzo i fratelli e tutti i fratelli degli ascendenti della tavola
bool bTabOnly = ( nFlag != MCH_LOOK_ALL) ;
int nTabCurrId = nTabId ;
Machine.h
+35 -12
View File
@@ -53,7 +53,7 @@ class Machine
int GetHeadId( const std::string& sHead) const
{ int nId = GetGroup( sHead) ;
return ( IsHeadGroup( nId) ? nId : GDB_ID_NULL) ; }
int GetExitId( const std::string& sHead, int nExit) const
int GetExitId( const std::string& sHead, int nExit) const
{ int nHeadId = GetHeadId( sHead) ;
int nId = ( m_pGeomDB != nullptr ? m_pGeomDB->GetFirstNameInGroup( nHeadId, MCH_EXIT + ToString( nExit)) : GDB_ID_NULL) ;
return ( IsExitGroup( nId) ? nId : GDB_ID_NULL) ; }
@@ -61,14 +61,18 @@ class Machine
{ int nId = GetGroup( sTcPos) ;
return ( IsTcPosGroup( nId) ? nId : GDB_ID_NULL) ; }
bool GetAllTablesNames( STRVECTOR& vNames) const ;
bool GetAllAxesNames( STRVECTOR& vNames) const ;
bool GetAllHeadsNames( STRVECTOR& vNames) const ;
bool GetAllTcPosNames( STRVECTOR& vNames) const ;
int GetFirstTable( void) const ;
int GetHeadExitCount( const std::string& sHead) const ;
int GetHeadExitPosDirAux( const std::string& sHead, int nExit, Point3d& ptPos, Vector3d& vtDir, Vector3d& vtAux) const ;
int GetHeadSolCh( const std::string& sHead) const ;
int GetHeadSelectType(const std::string& sHead) const ;
double GetAngDeltaMinForHome( void) const
{ return m_dAngDeltaMinForHome ; }
bool GetMultiProcess( int nOpt = 1) const
{ return ( m_nMultiProcess >= nOpt) ; }
bool LoadTool( const std::string& sHead, int nExit, const std::string& sTool) ;
bool GetLoadedTool( const std::string& sHead, int nExit, std::string& sTool) const ;
bool UnloadTool( const std::string& sHead, int nExit) ;
@@ -81,7 +85,7 @@ class Machine
bool GetAxisInvert( const std::string& sAxis, bool& bInvert) const ;
bool GetAxisOffset( const std::string& sAxis, double& dOffset) const ;
bool GetAxisType( const std::string& sAxis, bool& bLinear) const ;
bool SetAxisPos( const std::string& sAxis, double dVal, double* pdNewVal = nullptr) ;
bool SetAxisPos( const std::string& sAxis, double dVal, bool bInStroke = true, double* pdNewVal = nullptr) ;
bool GetAxisPos( const std::string& sAxis, double& dVal) const ;
bool GetAxisMin( const std::string& sAxis, double& dMin) const ;
bool GetAxisMax( const std::string& sAxis, double& dMax) const ;
@@ -95,7 +99,8 @@ class Machine
bool GetCurrTableRef1( Point3d& ptRef1) const ;
bool GetCurrTableArea1( BBox3d& b3Area1) const ;
bool GetCurrTableDeltaRef1( Vector3d& vtDelta1) const ;
bool GetCurrTableIsTilting( bool& bTilting) const ;
bool GetCurrTableIsTilting( bool& bTilting, Vector3d& vtTiltingAx) const ;
bool GetCurrTableCollGroups( INTVECTOR& vIds) const ;
bool SetCurrTool( const std::string& sTool, const std::string& sHead, int nExit) ;
bool ResetCurrTool( void) ;
int GetCurrTool( void) const ;
@@ -120,25 +125,32 @@ class Machine
int GetCurrLinAxes( void) const ;
int GetCurrRotAxes( void) const ;
bool GetCurrAxisName( int nInd, std::string& sAxName) const ;
bool GetAllCurrAxesName( STRVECTOR& vAxName) const ;
bool GetAllCurrAxesNames( STRVECTOR& vAxName) const ;
bool GetCurrAxisToken( int nInd, std::string& sAxToken) const ;
bool GetAllCurrAxesToken( STRVECTOR& vAxToken) const ;
bool GetAllCurrAxesTokens( STRVECTOR& vAxToken) const ;
bool GetCurrAxisType( int nInd, bool& bLinear, bool& bHead) const ;
bool GetCurrAxisMin( int nInd, double& dMin) const ;
bool GetCurrAxisMax( int nInd, double& dMax) const ;
bool GetCurrAxisOffset( int nInd, double& dOffset) const ;
bool GetCurrAxisInvert( int nInd, bool& bInvert) const ;
bool GetCurrAxisHomePos( int nInd, double& dHome) const ;
bool GetAllCurrAxesHomePos( DBLVECTOR& vAxHomeVal) const ;
const Frame3d& GetCurrLinAxesFrame( void) const
{ return m_frLinAx ; }
int GetCurrKinematicChainType( void) const
{ return m_nCalcChainType ; }
bool GetAngles( const Vector3d& vtDirT, const Vector3d& vtDirA,
int& nStat, double& dAngA1, double& dAngB1, double& dAngA2, double& dAngB2) const ;
bool GetAngles( const Vector3d& vtDirT, const Vector3d& vtDirA,
int& nStat, DBLVECTOR& vAng1, DBLVECTOR& vAng2) const ;
bool GetPositions( const Point3d& ptP, const DBLVECTOR& vAng,
int& nStat, double& dX, double& dY, double& dZ) const ;
bool GetRobotAngles( const Point3d& ptP, const Vector3d& vtDirT, const Vector3d& vtDirA,
DBLVECTOR& vAng1, DBLVECTOR& vAng2) const ;
bool GetNoseFromPositions( double dX, double dY, double dZ, const DBLVECTOR& vAng,
Point3d& ptNose) const ;
bool GetTipFromPositions( double dX, double dY, double dZ, const DBLVECTOR& vAng,
bool bBottom, bool bOverall, Point3d& ptTip) const ;
bool bOverall, bool bBottom, bool bBack, Point3d& ptTip) const ;
bool GetToolDirFromAngles( const DBLVECTOR& vAng, Vector3d& vtDir) const ;
bool GetAuxDirFromAngles( const DBLVECTOR& vAng, Vector3d& vtDir) const ;
bool GetPartDirFromAngles( const Vector3d& vtPart, const DBLVECTOR& vAng, Vector3d& vtDir) const ;
@@ -190,7 +202,7 @@ class Machine
bool AdjustAuxGeometry( const STRVECTOR& vsAux, int nLay) ;
bool LoadMachineTable( const std::string& sName, const std::string& sParent, int nType,
const Point3d& ptRef1, double dCoeffX, double dCoeffY, double dCoeffZ,
const std::string& sGeo, const STRVECTOR& vsAux) ;
const STRVECTOR& vsColl, const std::string& sGeo, const STRVECTOR& vsAux) ;
bool AdjustTable( int nLay, const Point3d& ptRef1) ;
bool LoadMachineAxis( const std::string& sName, const std::string& sParent, const std::string& sToken, bool bInvert,
double dOffset, int nType, const Point3d& ptPos, const Vector3d& vtDir, const STROKE& Stroke,
@@ -206,16 +218,19 @@ class Machine
double dRot1W, bool bMaxDeltaR2On1, const STROKE& Rot2Stroke, int nSolCh, const STRVECTOR& vsOthColl,
const std::string& sGeo, const STRVECTOR& vsAux) ;
bool LoadMachineMultiHead( const std::string& sName, const std::string& sParent, const std::string& sHSet,
const MUEXITVECTOR& vMuExit, const Vector3d& vtADir,
int nSelectType, const MUEXITVECTOR& vMuExit, const Vector3d& vtADir,
double dRot1W, bool bMaxDeltaR2On1, const STROKE& Rot2Stroke, int nSolCh, const STRVECTOR& vsOthColl,
const std::string& sGeo, const STRVECTOR& vsAux) ;
bool LoadMachineSpecialHead( const std::string& sName, const std::string& sParent, const std::string& sHSet,
const Point3d& ptPos, const Vector3d& vtTDir, const Vector3d& vtADir,
double dRot1W, bool bMaxDeltaR2On1, const STROKE& Rot2Stroke, int nSolCh, const STRVECTOR& vsOthColl,
const std::string& sGeo, const STRVECTOR& vsAux) ;
bool LoadMachineTcPos( const std::string& sName, const std::string& sParent,
const Point3d& ptPos, const Vector3d& vtTDir, const Vector3d& vtADir,
const std::string& sGeo, const STRVECTOR& vsAux) ;
bool LoadMachineStdTcPos( const std::string& sName, const std::string& sParent,
const Point3d& ptPos, const Vector3d& vtTDir, const Vector3d& vtADir,
const std::string& sGeo, const STRVECTOR& vsAux) ;
bool LoadMachineMultiTcPos( const std::string& sName, const std::string& sParent,
const MUEXITVECTOR& vMuExit, const Vector3d& vtADir,
const std::string& sGeo, const STRVECTOR& vsAux) ;
int GetGroup( const std::string& sGroup) const ;
bool IsBaseGroup( int nGroup) const ;
Axis* GetAxis( int nGroup) const ;
@@ -278,6 +293,7 @@ class Machine
double m_dExitMaxAdjust ; // massimo aggiustamento uscita da geometria a descrizione cinematica
double m_dExitMaxRotAdj ; // massima rotazione di aggiustamento uscita da geometria a descrizione cinematica
double m_dAngDeltaMinForHome ; // minima differenza angolare da valore precedente per scegliere di stare vicino a home
int m_nMultiProcess ; // flag di macchina multi-processo con stima speciale prima di generazione e simulazione ad hoc
INTVECTOR m_vLinkedRawParts ; // elenco dei grezzi agganciati a gruppi della macchina
INTVECTOR m_vLinkedFixtures ; // elenco dei bloccaggi agganciati a gruppi della macchina
INTVECTOR m_vLinkedParts ; // elenco dei pezzi agganciati a gruppi della macchina
@@ -305,6 +321,10 @@ class Machine
KINAXISVECTOR m_vCalcLinAx ; // vettore assi lineari attivi per calcoli
KINAXISVECTOR m_vCalcRotAx ; // vettore assi rotanti attivi per calcoli
Frame3d m_frLinAx ; // sistema di riferimento definito dagli assi lineari
Frame3d m_frRobot ; // sistema di riferimento canonico del robot
int m_nCalcChainType ; // tipologia testa attiva (nulla, centro di lavoro o robot)
Point3d m_ptWristCen ; // centro del polso sferico nel riferimento testa/uscita di calcolo
Vector3d m_vtWristRef ; // direzione del polso sferico nel riferimento testa/uscita di calcolo
mutable OutStroke m_OutstrokeInfo ; // informazioni su ultima extra corsa
// stato di visualizzazione
int m_nMachineLook ; // stato di visualizzazione della macchina
@@ -323,6 +343,8 @@ class Machine
static int LuaEmtMultiHead( lua_State* L) ;
static int LuaEmtSpecialHead( lua_State* L) ;
static int LuaEmtTcPos( lua_State* L) ;
static int LuaEmtStdTcPos( lua_State* L) ;
static int LuaEmtMultiTcPos( lua_State* L) ;
static int LuaEmtModifyAxisPosition( lua_State* L) ;
static int LuaEmtModifyAxisDirection( lua_State* L) ;
static int LuaEmtModifyAxisStroke( lua_State* L) ;
@@ -356,8 +378,9 @@ class Machine
static int LuaEmtOnCollision( lua_State* L) ;
static int LuaEmtSetToolForVmill( lua_State* L) ;
static int LuaEmtAddToolForVmill( lua_State* L) ;
static int LuaEmtEnableToolsForVmill( lua_State* L) ;
static int LuaEmtMoveAxes( lua_State* L) ;
static int LuaEmtSaveCmd( lua_State* L) ;
} ;
//----------------------------------------------------------------------------
MachineAxes.cpp
+19 -5
View File
@@ -19,9 +19,26 @@
#include "/EgtDev/Include/EGkGeoVector3d.h"
#include "/EgtDev/Include/EGnStringUtils.h"
#include "/EgtDev/Include/EGnFileUtils.h"
#include "/EgtDev/Include/EgtNumUtils.h"
using namespace std ;
//----------------------------------------------------------------------------
bool
Machine::GetAllAxesNames( STRVECTOR& vNames) const
{
// reset lista nomi
vNames.clear() ;
// ricerca degli assi
for ( const auto& snGro : m_mapGroups) {
if ( IsAxisGroup( snGro.second))
vNames.push_back( snGro.first) ;
}
// ordino alfabeticamente
sort( vNames.begin(), vNames.end()) ;
return true ;
}
//----------------------------------------------------------------------------
bool
Machine::GetAxisToken( const string& sAxis, string& sToken) const
@@ -88,7 +105,7 @@ Machine::GetAxisType( const string& sAxis, bool& bLinear) const
//----------------------------------------------------------------------------
bool
Machine::SetAxisPos( const string& sAxis, double dVal, double* pdNewVal)
Machine::SetAxisPos( const string& sAxis, double dVal, bool bInStroke, double* pdNewVal)
{
// controllo GeomDB
if ( m_pGeomDB == nullptr)
@@ -114,10 +131,7 @@ Machine::SetAxisPos( const string& sAxis, double dVal, double* pdNewVal)
Vector3d vtDir = pGV->GetVector() ;
vtDir.Normalize() ;
// limito il movimento alla corsa dell'asse
if ( dVal > Stroke.Max)
dVal = Stroke.Max ;
else if ( dVal < Stroke.Min)
dVal = Stroke.Min ;
dVal = Clamp( dVal, Stroke.Min, Stroke.Max) ;
// eseguo il movimento
if ( bLinear)
m_pGeomDB->TranslateGroup( nAxGrp, vtDir * ( dVal - dCurrVal)) ;
MachineCalc.cpp
+413 -67
View File
@@ -24,11 +24,13 @@
#include "/EgtDev/Include/EGkGeoVector3d.h"
#include "/EgtDev/Include/EGnStringUtils.h"
#include "/EgtDev/Include/EGnFileUtils.h"
#include "/EgtDev/Include/EgtNumUtils.h"
using namespace std ;
//----------------------------------------------------------------------------
static const string EMC_VAR = "EMC" ; // tabella variabili locali per calcolo
static const string EVAR_VER = ".VER" ; // (string) versione della Dll
static const string EVAR_TABNAME = ".TABNAME" ; // (string) nome della tavola macchina
static const string EVAR_HEAD = ".HEAD" ; // (string) nome della testa
static const string EVAR_EXIT = ".EXIT" ; // (int) numero dell'uscita
@@ -37,6 +39,7 @@ static const string EVAR_TOTDIAM = ".TOTDIAM" ; // (num) diametro di in
static const string EVAR_TOTLEN = ".TOTLEN" ; // (num) lunghezza di ingombro dell'utensile
static const string EVAR_DIST = ".DIST" ; // (num) distanza dell'utensile (per seghe a catena)
static const string EVAR_EXITPOS = ".EXITPOS" ; // (point) posizione attuale dell'uscita
static const string EVAR_USERNOTES = ".USERNOTES" ; // (string) note utente dell'utensile
static const string EVAR_TCPOS = ".TCPOS" ; // (string) posizione nell'attrezzaggio
static const string EVAR_L1 = ".L1" ; // (num) valore del primo asse lineare
static const string EVAR_L2 = ".L2" ; // (num) valore del secondo asse lineare
@@ -68,12 +71,15 @@ Machine::SetCurrTable( const string& sTable)
m_nCalcTabId = GDB_ID_NULL ;
return false ;
}
// il gruppo tavola corrente deve essere sempre visibile
m_pGeomDB->SetStatus( m_nCalcTabId, GDB_ST_ON) ;
// lancio eventuale funzione lua di personalizzazione
if ( LuaExistsFunction( ON_SET_TABLE)) {
// salvo eventuale variabile EMC_VAR già presente
bool bOldEMC = LuaChangeNameGlobVar( EMC_VAR, EMC_VAR_BACKUP) ;
// definisco variabili
bool bOk = LuaCreateGlobTable( EMC_VAR) ;
bOk = bOk && LuaSetGlobVar( EMC_VAR + EVAR_VER, GetEMkVer()) ;
bOk = bOk && LuaSetGlobVar( EMC_VAR + EVAR_TABNAME, sTable) ;
// chiamo funzione
bOk = bOk && LuaCallFunction( ON_SET_TABLE) ;
@@ -167,17 +173,23 @@ Machine::GetCurrTableDeltaRef1( Vector3d& vtDelta1) const
//----------------------------------------------------------------------------
bool
Machine::GetCurrTableIsTilting( bool& bTilting) const
Machine::GetCurrTableIsTilting( bool& bTilting, Vector3d& vtTiltingAx) const
{
// default
bTilting = false ;
vtTiltingAx = V_NULL ;
// verifico esistenza tavola
if ( m_nCalcTabId == GDB_ID_NULL)
return false ;
// verifico se presente flag che lo forza come tale
bool bTiltingLike ;
if ( m_pGeomDB->GetInfo( m_nCalcTabId, MCH_TILTINGLIKE, bTiltingLike) && bTiltingLike) {
int nTiltingLike ;
if ( m_pGeomDB->GetInfo( m_nCalcTabId, MCH_TILTINGLIKE, nTiltingLike) && nTiltingLike != 0) {
bTilting = true ;
switch ( abs( nTiltingLike)) {
default : vtTiltingAx = X_AX ; break ;
case 2 : vtTiltingAx = Y_AX ; break ;
case 3 : vtTiltingAx = Z_AX ; break ;
}
return true ;
}
// recupero gli eventuali assi rotanti della tavola
@@ -192,6 +204,7 @@ Machine::GetCurrTableIsTilting( bool& bTilting) const
// verifico se asse rotante orizzontale
if ( pAx->GetType() == MCH_AT_ROTARY && abs( pAx->GetDir().z) < EPS_SMALL) {
bTilting = true ;
vtTiltingAx = pAx->GetDir() ;
return true ;
}
// risalgo lungo la catena
@@ -201,6 +214,31 @@ Machine::GetCurrTableIsTilting( bool& bTilting) const
return true ;
}
//----------------------------------------------------------------------------
bool
Machine::GetCurrTableCollGroups( INTVECTOR& vIds) const
{
// controllo GeomDB
if ( m_pGeomDB == nullptr)
return false ;
// recupero la tavola corrente
Table* pTab = GetTable( m_nCalcTabId) ;
if ( pTab == nullptr)
return false ;
// recupero stringhe con gruppi ausiliari di collisione
const STRVECTOR& vsColl = pTab->GetCollGroups() ;
for ( const auto& sColl : vsColl) {
string sGrp, sSub ;
Split( sColl, "/", true, sGrp, sSub) ;
int nId = GetGroup( sGrp) ;
if ( ! sSub.empty() && nId != GDB_ID_NULL)
nId = m_pGeomDB->GetFirstNameInGroup( nId, sSub) ;
if ( nId != GDB_ID_NULL)
vIds.push_back( nId) ;
}
return true ;
}
//----------------------------------------------------------------------------
bool
Machine::SetCurrTool( const string& sTool, const string& sHead, int nExit)
@@ -238,6 +276,7 @@ Machine::SetCurrTool( const string& sTool, const string& sHead, int nExit)
double dTOvLen = 0 ;
double dTOvDiam = 0 ;
double dTDist = 0 ;
string sTUserNotes = "" ;
string sTcPos = "" ;
// se definito
if ( ! sTool.empty()) {
@@ -256,7 +295,8 @@ Machine::SetCurrTool( const string& sTool, const string& sHead, int nExit)
! m_pMchMgr->TdbGetCurrToolParam( TPA_LEN, dTLen) ||
! m_pMchMgr->TdbGetCurrToolParam( TPA_DIAM, dTDiam) ||
! m_pMchMgr->TdbGetCurrToolParam( TPA_TOTLEN, dTOvLen) ||
! m_pMchMgr->TdbGetCurrToolParam( TPA_TOTDIAM, dTOvDiam))
! m_pMchMgr->TdbGetCurrToolParam( TPA_TOTDIAM, dTOvDiam) ||
! m_pMchMgr->TdbGetCurrToolParam( TPA_USERNOTES, sTUserNotes))
return false ;
m_pMchMgr->TdbGetCurrToolParam( TPA_DIST, dTDist) ; // opzionale
if ( ! m_pMchMgr->GetCurrSetupMgr().GetToolSetupPos( sTool, sTcPos))
@@ -296,6 +336,7 @@ Machine::SetCurrTool( const string& sTool, const string& sHead, int nExit)
bool bOldEMC = LuaChangeNameGlobVar( EMC_VAR, EMC_VAR_BACKUP) ;
// definisco variabili
bool bOk = LuaCreateGlobTable( EMC_VAR) ;
bOk = bOk && LuaSetGlobVar( EMC_VAR + EVAR_VER, GetEMkVer()) ;
bOk = bOk && LuaSetGlobVar( EMC_VAR + EVAR_HEAD, sHead) ;
bOk = bOk && LuaSetGlobVar( EMC_VAR + EVAR_EXIT, nExit) ;
bOk = bOk && LuaSetGlobVar( EMC_VAR + EVAR_TOOL, sTool) ;
@@ -303,6 +344,7 @@ Machine::SetCurrTool( const string& sTool, const string& sHead, int nExit)
bOk = bOk && LuaSetGlobVar( EMC_VAR + EVAR_TOTDIAM, dTOvDiam) ;
bOk = bOk && LuaSetGlobVar( EMC_VAR + EVAR_TOTLEN, dTOvLen) ;
bOk = bOk && LuaSetGlobVar( EMC_VAR + EVAR_DIST, dTDist) ;
bOk = bOk && LuaSetGlobVar( EMC_VAR + EVAR_USERNOTES, sTUserNotes) ;
bOk = bOk && LuaSetGlobVar( EMC_VAR + EVAR_TCPOS, sTcPos) ;
// chiamo funzione
bOk = bOk && LuaCallFunction( ON_SET_HEAD) ;
@@ -451,14 +493,15 @@ Machine::CalculateKinematicChain( void)
m_nHeadSpecRotAxis = -1 ;
m_vCalcLinAx.clear() ;
m_vCalcRotAx.clear() ;
m_frLinAx.Reset( false) ;
m_frRobot.Reset( false) ;
m_nCalcChainType = KIN_CHAIN_NONE ;
// recupero gli assi di tavola
if ( m_nCalcTabId == GDB_ID_NULL)
return false ;
int nTParId = m_pGeomDB->GetParentId( m_nCalcTabId) ;
if ( nTParId == GDB_ID_NULL)
return false ;
m_nTabLinAxes = 0 ;
m_nTabRotAxes = 0 ;
while ( IsAxisGroup( nTParId)) {
if ( ! AddKinematicAxis( false, nTParId))
return false ;
@@ -470,14 +513,75 @@ Machine::CalculateKinematicChain( void)
int nHParId = m_pGeomDB->GetParentId( m_nCalcHeadId) ;
if ( nHParId == GDB_ID_NULL)
return false ;
m_nHeadLinAxes = 0 ;
m_nHeadRotAxes = 0 ;
while ( IsAxisGroup( nHParId)) {
if ( ! AddKinematicAxis( true, nHParId))
return false ;
nHParId = m_pGeomDB->GetParentId( nHParId) ;
}
// se non ci sono assi, né lineari né rotanti, sicuramente errore
if ( m_nTabLinAxes == 0 && m_nHeadLinAxes == 0 &&
m_nTabRotAxes == 0 && m_nHeadRotAxes == 0) {
LOG_ERROR( GetEMkLogger(), "Errors in Axes : none have been found")
return false ;
}
// se nessun asse lineare deve essere un robot (in futuro va permesso un lineare di tavola)
if ( m_nTabLinAxes == 0 && m_nHeadLinAxes == 0) {
// verifico ci siano 6 assi rotanti tutti di testa (in futuro va permesso un rotante di tavola)
if ( m_nTabRotAxes != 0 || m_nHeadRotAxes != 6) {
LOG_ERROR( GetEMkLogger(), "Robot with errors in Rotary Axes : number or type")
return false ;
}
// riordino gli assi rotanti
swap( m_vCalcRotAx[0], m_vCalcRotAx[5]) ;
swap( m_vCalcRotAx[1], m_vCalcRotAx[4]) ;
swap( m_vCalcRotAx[2], m_vCalcRotAx[3]) ;
// determino il riferimento canonico del robot
if ( ! m_frRobot.Set( m_vCalcRotAx[0].ptPos, m_vCalcRotAx[0].vtDir, m_vCalcRotAx[3].vtDir)) {
LOG_ERROR( GetEMkLogger(), "Robot with errors in Rotary Axes : impossible canonic frame")
return false ;
}
// porto tutti gli assi cinematici e i dati testa nel riferimento canonico
for ( int i = 0 ; i < m_nHeadRotAxes ; ++ i) {
m_vCalcRotAx[i].ptPos.ToLoc( m_frRobot) ;
m_vCalcRotAx[i].vtDir.ToLoc( m_frRobot) ;
}
m_ptCalcPos.ToLoc( m_frRobot) ;
m_vtCalcDir.ToLoc( m_frRobot) ;
m_vtCalcADir.ToLoc( m_frRobot) ;
// direzione assi rotanti deve essere Z Y Y X Y X
if ( ! m_vCalcRotAx[0].vtDir.IsZ() ||
! m_vCalcRotAx[1].vtDir.IsY() ||
! m_vCalcRotAx[2].vtDir.IsY() ||
! m_vCalcRotAx[3].vtDir.IsX() ||
! m_vCalcRotAx[4].vtDir.IsY() ||
! m_vCalcRotAx[5].vtDir.IsX()) {
LOG_ERROR( GetEMkLogger(), "Robot with errors in Rotary Axes : not ZYY-XYX")
return false ;
}
// verifico che gli ultimi 3 assi formino un polso sferico (ovvero passino per uno stesso punto)
if ( abs( m_vCalcRotAx[3].ptPos.y - m_vCalcRotAx[5].ptPos.y) > EPS_SMALL ||
abs( m_vCalcRotAx[3].ptPos.z - m_vCalcRotAx[5].ptPos.z) > EPS_SMALL ||
abs( m_vCalcRotAx[4].ptPos.z - m_vCalcRotAx[3].ptPos.z) > EPS_SMALL) {
LOG_ERROR( GetEMkLogger(), "Robot with errors in Rotary Axes : not spherical Wrist")
return false ;
}
// calcolo il centro del polso in coordinate globali (R5.x, R6.y, R5.z)
Point3d ptCenG( m_vCalcRotAx[4].ptPos.x, m_vCalcRotAx[5].ptPos.y, m_vCalcRotAx[4].ptPos.z) ;
// recupero il riferimento dell'uscita (da posizione, direzione utensile e direzione ausiliaria)
Frame3d frExit ;
if ( ! frExit.Set( m_ptCalcPos, m_vtCalcDir, m_vtCalcADir))
return false ;
// calcolo il centro del polso in locale a questo riferimento
m_ptWristCen = GetToLoc( ptCenG, frExit) ;
// calcolo la direzione di riferimento del polso in locale a questo riferimento
m_vtWristRef = GetToLoc( m_vCalcRotAx[5].vtDir, frExit) ;
// dichiaro tipo robot
m_nCalcChainType = KIN_CHAIN_ROBOT ;
return true ;
}
// verifiche sugli assi lineari :
// aggiusto gli indici di ordine sulla sua catena cinematica (1-based)
for ( int i = 0 ; i < int( m_vCalcLinAx.size()) ; ++ i) {
@@ -487,8 +591,10 @@ Machine::CalculateKinematicChain( void)
m_vCalcLinAx[i].nInd *= -1 ;
}
// devono essere 3
if ( m_vCalcLinAx.size() != 3)
if ( m_vCalcLinAx.size() != 3) {
LOG_ERROR( GetEMkLogger(), "Linear Axes are not 3 in number")
return false ;
}
// devono essere ordinabili come XYZ
if ( ! m_vCalcLinAx[0].vtDir.IsX()) {
if ( m_vCalcLinAx[1].vtDir.IsX())
@@ -514,7 +620,6 @@ Machine::CalculateKinematicChain( void)
}
// verifiche sugli assi rotanti :
bool bOk = false ;
// aggiusto gli indici di ordine sulla sua catena cinematica (1-based)
for ( int i = 0 ; i < int( m_vCalcRotAx.size()) ; ++ i) {
if ( m_vCalcRotAx[i].bHead)
@@ -524,7 +629,7 @@ Machine::CalculateKinematicChain( void)
}
// se 0 o 1 va bene
if ( m_vCalcRotAx.size() <= 1)
bOk = true ;
;
// se 2 va bene
else if ( m_vCalcRotAx.size() == 2) {
// se entrambi di testa devo invertirne l'ordine
@@ -538,7 +643,6 @@ Machine::CalculateKinematicChain( void)
m_vCalcRotAx[1].stroke.Max = min( m_vCalcRotAx[1].stroke.Max, pHead->GetRot2Stroke().Max) ;
}
}
bOk = true ;
}
// se 3 va bene ( uno dovrà poi avere valore assegnato)
else if ( m_vCalcRotAx.size() == 3) {
@@ -561,10 +665,13 @@ Machine::CalculateKinematicChain( void)
m_vCalcRotAx[n2ndHeadRotAx].stroke.Max = min( m_vCalcRotAx[n2ndHeadRotAx].stroke.Max, pHead->GetRot2Stroke().Max) ;
}
}
bOk = true ;
}
if ( ! bOk)
// se più di 3
else {
// altrimenti non ancora gestito, quindi errore
LOG_ERROR( GetEMkLogger(), "Rotary Axes not manageable")
return false ;
}
// verifico esistenza eventuale asse rotante speciale di testa
if ( m_nHeadRotAxes > 0 && m_nHeadLinAxes > 0) {
// indice di posizione primo asse di testa
@@ -600,11 +707,9 @@ Machine::CalculateKinematicChain( void)
}
}
}
// dichiaro tipo centro di lavoro
m_nCalcChainType = KIN_CHAIN_CENTER ;
return true ;
// altrimenti non ancora gestito, quindi errore
LOG_ERROR( GetEMkLogger(), "Rotary Axes not manageable")
return false ;
}
//----------------------------------------------------------------------------
@@ -951,8 +1056,8 @@ Machine::GetMyAngles( const Vector3d& vtDirT, const Vector3d& vtDirA,
vtAx2.Invert() ;
// calcolo secondo angolo di rotazione
nStat = GetRotationComponent( vtDirHn, dCompTSuAxR1, vtAx1, vtAx2, dAngB1, dAngB2, bDet) ;
// se indeterminato con richiesta direzione ausiliaria esatta, ricalcolo con direzione aux
if ( nStat >= 1 && ! bDet && m_bSolChExact) {
// se indeterminato, provo ricalcolo con direzione aux
if ( nStat >= 1 && ! bDet) {
// componente versore ausiliario desiderato su direzione primo asse rotante
Vector3d vtSccDir ;
if ( GetSccDir( m_nCalcSolCh, vtDirAn, vtSccDir)) {
@@ -1002,7 +1107,7 @@ Machine::GetMyAngles( const Vector3d& vtDirT, const Vector3d& vtDirA,
// calcolo primo angolo di rotazione per seconda soluzione
bool bDet2 = true ;
if ( nStat == 2) {
if ( ! vtDirH2.GetRotation( vtDirTn, vtAx1, dAngA2, bDet2) )
if ( ! vtDirH2.GetRotation( vtDirTn, vtAx1, SIN_EPS_ANG_SMALL, dAngA2, bDet2))
nStat = 1 ;
else {
// se indeterminato, provo a determinarlo con la direzione ausiliaria
@@ -1025,7 +1130,7 @@ Machine::GetMyAngles( const Vector3d& vtDirT, const Vector3d& vtDirA,
// calcolo primo angolo di rotazione per prima soluzione
bool bDet1 = true ;
if ( nStat >= 1) {
if ( ! vtDirH1.GetRotation( vtDirTn, vtAx1, dAngA1, bDet1) )
if ( ! vtDirH1.GetRotation( vtDirTn, vtAx1, SIN_EPS_ANG_SMALL, dAngA1, bDet1))
nStat = 0 ;
else {
// se indeterminato, provo a determinarlo con la direzione ausiliaria
@@ -1070,7 +1175,7 @@ Machine::GetMyAngles( const Vector3d& vtDirT, const Vector3d& vtDirA,
}
if ( nStat >= 1) {
// se non riesco ad aggiustare, elimino
if ( ! AdjustAngleInStroke( RotAx1.stroke, dAngA1) ||
if ( ( bDet1 && ! AdjustAngleInStroke( RotAx1.stroke, dAngA1)) ||
( nNumRotAx == 2 && ! AdjustAngleInStroke( RotAx2.stroke, dAngB1))) {
-- nStat ;
// riloco eventuale soluzione rimasta
@@ -1176,6 +1281,10 @@ Machine::GetDirection( const Vector3d& vtDir, const DBLVECTOR& vAng, Vector3d& v
vtNew.Rotate( m_vCalcRotAx[i-1].vtDir, vAng[i-1]) ;
}
// nel caso di robot devo passare dal riferimento canonico robot a quello di macchina
if ( m_nCalcChainType == KIN_CHAIN_ROBOT)
vtNew.ToGlob( m_frRobot) ;
return true ;
}
@@ -1213,26 +1322,46 @@ Machine::GetNoseFromPositions( double dX, double dY, double dZ, const DBLVECTOR&
// la posizione deve essere espressa rispetto allo ZERO MACCHINA
// è espressa nel riferimento di macchina (tiene conto delle sole traslazioni e rotazioni di testa)
// aggiorno posizione testa a riposo mediante ciclo inverso sugli assi rotanti di testa
ptNose = m_ptCalcPos ;
for ( int i = int( m_vCalcRotAx.size()) - 1 ; i >= 0 ; -- i) {
// se asse di testa non speciale
if ( m_vCalcRotAx[i].bHead && i != m_nHeadSpecRotAxis)
ptNose.Rotate( m_vCalcRotAx[i].ptPos, m_vCalcRotAx[i].vtDir, vAng[i]) ;
// verifico dimensione vettore angoli rispetto al numero di assi rotanti
if ( vAng.size() < m_vCalcRotAx.size())
return false ;
// se centro di lavoro
if ( m_nCalcChainType == KIN_CHAIN_CENTER) {
// aggiorno posizione testa a riposo mediante ciclo inverso sugli assi rotanti di testa
ptNose = m_ptCalcPos ;
for ( int i = int( m_vCalcRotAx.size()) - 1 ; i >= 0 ; -- i) {
// se asse di testa non speciale
if ( m_vCalcRotAx[i].bHead && i != m_nHeadSpecRotAxis)
ptNose.Rotate( m_vCalcRotAx[i].ptPos, m_vCalcRotAx[i].vtDir, vAng[i]) ;
}
// aggiorno posizione testa con assi lineari di testa
DBLVECTOR vMov( {dX, dY, dZ}) ;
for ( int i = 0 ; i < int( m_vCalcLinAx.size()) ; ++ i) {
if ( m_vCalcLinAx[i].bHead)
ptNose += m_vCalcLinAx[i].vtDir * vMov[i] ;
}
// eseguo rotazione eventuale asse rotante speciale di testa
if ( m_nHeadSpecRotAxis != -1) {
if ( m_nHeadSpecRotAxis < 0 || m_nHeadSpecRotAxis >= int( m_vCalcRotAx.size()))
return false ;
int i = m_nHeadSpecRotAxis ;
ptNose.Rotate( m_vCalcRotAx[i].ptPos, m_vCalcRotAx[i].vtDir, vAng[i]) ;
}
}
// aggiorno posizione testa con assi lineari di testa
DBLVECTOR vMov( {dX, dY, dZ}) ;
for ( int i = 0 ; i < int( m_vCalcLinAx.size()) ; ++ i) {
if ( m_vCalcLinAx[i].bHead)
ptNose += m_vCalcLinAx[i].vtDir * vMov[i] ;
}
// eseguo rotazione eventuale asse rotante speciale di testa
if ( m_nHeadSpecRotAxis != -1) {
if ( m_nHeadSpecRotAxis < 0 || m_nHeadSpecRotAxis >= int( m_vCalcRotAx.size()))
return false ;
int i = m_nHeadSpecRotAxis ;
ptNose.Rotate( m_vCalcRotAx[i].ptPos, m_vCalcRotAx[i].vtDir, vAng[i]) ;
// se robot
else if ( m_nCalcChainType == KIN_CHAIN_ROBOT) {
// aggiorno posizione testa a riposo mediante ciclo inverso sugli assi rotanti di testa
ptNose = m_ptCalcPos ;
for ( int i = int( m_vCalcRotAx.size()) - 1 ; i >= 0 ; -- i) {
// se asse di testa
if ( m_vCalcRotAx[i].bHead)
ptNose.Rotate( m_vCalcRotAx[i].ptPos, m_vCalcRotAx[i].vtDir, vAng[i]) ;
}
}
// altrimenti errore
else
return false ;
return true ;
}
@@ -1240,38 +1369,84 @@ Machine::GetNoseFromPositions( double dX, double dY, double dZ, const DBLVECTOR&
//----------------------------------------------------------------------------
bool
Machine::GetTipFromPositions( double dX, double dY, double dZ, const DBLVECTOR& vAng,
bool bOverall, bool bBottom, Point3d& ptTip) const
bool bOverall, bool bBottom, bool bBack, Point3d& ptTip) const
{
// la posizione deve essere espressa rispetto allo ZERO MACCHINA
// è espressa nel riferimento di macchina (tiene conto delle sole rotazioni di testa)
// se bBack vero, allora è nel riferimento pezzo
// aggiorno posizione tip utensile a riposo mediante ciclo inverso sugli assi rotanti di testa
ptTip = m_ptCalcPos - m_vtCalcDir * m_dCalcTLen ;
for ( int i = int( m_vCalcRotAx.size()) - 1 ; i >= 0 ; -- i) {
// se asse di testa non speciale
if ( m_vCalcRotAx[i].bHead && i != m_nHeadSpecRotAxis)
ptTip.Rotate( m_vCalcRotAx[i].ptPos, m_vCalcRotAx[i].vtDir, vAng[i]) ;
// verifico dimensione vettore angoli rispetto al numero di assi rotanti
if ( vAng.size() < m_vCalcRotAx.size())
return false ;
// se centro di lavoro
if ( m_nCalcChainType == KIN_CHAIN_CENTER) {
// aggiorno posizione tip utensile a riposo mediante ciclo inverso sugli assi rotanti di testa
ptTip = m_ptCalcPos - m_vtCalcDir * m_dCalcTLen ;
for ( int i = int( m_vCalcRotAx.size()) - 1 ; i >= 0 ; -- i) {
// se asse di testa non speciale
if ( m_vCalcRotAx[i].bHead && i != m_nHeadSpecRotAxis)
ptTip.Rotate( m_vCalcRotAx[i].ptPos, m_vCalcRotAx[i].vtDir, vAng[i]) ;
}
// aggiorno posizione tip utensile con assi lineari di testa
DBLVECTOR vMov( {dX, dY, dZ}) ;
for ( int i = 0 ; i < int( m_vCalcLinAx.size()) ; ++ i) {
if ( m_vCalcLinAx[i].bHead)
ptTip += m_vCalcLinAx[i].vtDir * vMov[i] ;
}
// eseguo rotazione eventuale asse rotante speciale di testa
if ( m_nHeadSpecRotAxis != -1) {
if ( m_nHeadSpecRotAxis < 0 || m_nHeadSpecRotAxis >= int( m_vCalcRotAx.size()))
return false ;
int i = m_nHeadSpecRotAxis ;
ptTip.Rotate( m_vCalcRotAx[i].ptPos, m_vCalcRotAx[i].vtDir, vAng[i]) ;
}
}
// aggiorno posizione tip utensile con assi lineari di testa
DBLVECTOR vMov( {dX, dY, dZ}) ;
for ( int i = 0 ; i < int( m_vCalcLinAx.size()) ; ++ i) {
if ( m_vCalcLinAx[i].bHead)
ptTip += m_vCalcLinAx[i].vtDir * vMov[i] ;
// se robot
else if ( m_nCalcChainType == KIN_CHAIN_ROBOT) {
// aggiorno posizione tip utensile a riposo mediante ciclo inverso sugli assi rotanti di testa
ptTip = m_ptCalcPos - m_vtCalcDir * m_dCalcTLen ;
for ( int i = int( m_vCalcRotAx.size()) - 1 ; i >= 0 ; -- i) {
// se asse di testa
if ( m_vCalcRotAx[i].bHead)
ptTip.Rotate( m_vCalcRotAx[i].ptPos, m_vCalcRotAx[i].vtDir, vAng[i]) ;
}
}
// eseguo rotazione eventuale asse rotante speciale di testa
if ( m_nHeadSpecRotAxis != -1) {
if ( m_nHeadSpecRotAxis < 0 || m_nHeadSpecRotAxis >= int( m_vCalcRotAx.size()))
return false ;
int i = m_nHeadSpecRotAxis ;
ptTip.Rotate( m_vCalcRotAx[i].ptPos, m_vCalcRotAx[i].vtDir, vAng[i]) ;
// altrimenti errore
else
return false ;
// nel caso di robot devo passare dal riferimento canonico robot a quello di macchina
if ( m_nCalcChainType == KIN_CHAIN_ROBOT)
ptTip.ToGlob( m_frRobot) ;
// Se richiesto nel riferimento pezzo
if ( bBack) {
// ciclo sugli assi lineari di tavola all'indietro
DBLVECTOR vMov( {dX, dY, dZ}) ;
for ( int i = int( m_vCalcLinAx.size()) ; i > 0 ; -- i) {
if ( ! m_vCalcLinAx[i-1].bHead)
ptTip += m_vCalcLinAx[i-1].vtDir * ( vMov[i-1] - m_vCalcLinAx[i-1].dHomeVal) ;
}
// ciclo sugli assi rotanti di tavola all'indietro !!! NON VERIFICATO !!!
for ( int i = int( m_vCalcRotAx.size()) ; i > 0 ; -- i) {
if ( ! m_vCalcRotAx[i-1].bHead)
ptTip.Rotate( m_vCalcRotAx[i-1].ptPos, m_vCalcRotAx[i-1].vtDir, -vAng[i-1]) ;
}
}
// Se richiesto ingombro totale o punto sotto del tip utensile
if ( bOverall || bBottom) {
// calcolo la direzione fresa
Vector3d vtDirT ;
if ( ! GetDirection( m_vtCalcDir, vAng, vtDirT))
return false ;
if ( bBack) {
if ( ! GetBackDirection( m_vtCalcDir, vAng, vtDirT))
return false ;
}
else {
if ( ! GetDirection( m_vtCalcDir, vAng, vtDirT))
return false ;
}
// se richiesto ingombro totale
if ( bOverall)
ptTip -= vtDirT * max( m_dCalcTOvLen - m_dCalcTLen, 0.) ;
@@ -1474,10 +1649,7 @@ Machine::LimitAngleToStroke( int nInd, double& dAng) const
if ( nInd < 0 || nInd >= int( m_vCalcRotAx.size()))
return true ;
// se angolo fuori corsa, lo porto all'estremo più vicino
if ( dAng < m_vCalcRotAx[nInd].stroke.Min)
dAng = m_vCalcRotAx[nInd].stroke.Min ;
else if ( dAng > m_vCalcRotAx[nInd].stroke.Max)
dAng = m_vCalcRotAx[nInd].stroke.Max ;
dAng = Clamp( dAng, m_vCalcRotAx[nInd].stroke.Min, m_vCalcRotAx[nInd].stroke.Max) ;
return true ;
}
@@ -1572,6 +1744,7 @@ Machine::VerifyProtectedAreas( double dX, double dY, double dZ, const DBLVECTOR&
bool bOldEMC = LuaChangeNameGlobVar( EMC_VAR, EMC_VAR_BACKUP) ;
// definisco variabili
bOk = bOk && LuaCreateGlobTable( EMC_VAR) ;
bOk = bOk && LuaSetGlobVar( EMC_VAR + EVAR_VER, GetEMkVer()) ;
bOk = bOk && LuaSetGlobVar( EMC_VAR + EVAR_L1, dX) ;
bOk = bOk && LuaSetGlobVar( EMC_VAR + EVAR_L2, dY) ;
bOk = bOk && LuaSetGlobVar( EMC_VAR + EVAR_L3, dZ) ;
@@ -1702,7 +1875,7 @@ Machine::GetCurrAxisName( int nInd, string& sAxName) const
//----------------------------------------------------------------------------
bool
Machine::GetAllCurrAxesName( STRVECTOR& vAxName) const
Machine::GetAllCurrAxesNames( STRVECTOR& vAxName) const
{
vAxName.clear() ;
bool bOk = true ;
@@ -1751,7 +1924,7 @@ Machine::GetCurrAxisToken( int nInd, string& sAxToken) const
//----------------------------------------------------------------------------
bool
Machine::GetAllCurrAxesToken( STRVECTOR& vAxToken) const
Machine::GetAllCurrAxesTokens( STRVECTOR& vAxToken) const
{
vAxToken.clear() ;
bool bOk = true ;
@@ -1774,6 +1947,25 @@ Machine::GetAllCurrAxesToken( STRVECTOR& vAxToken) const
return bOk ;
}
//----------------------------------------------------------------------------
bool
Machine::GetCurrAxisType( int nInd, bool& bLinear, bool& bHead) const
{
int nLinAxes = int( m_vCalcLinAx.size()) ;
int nRotAxes = int( m_vCalcRotAx.size()) ;
if ( nInd >= 0 && nInd < nLinAxes) {
bLinear = true ;
bHead = m_vCalcLinAx[nInd].bHead ;
return true ;
}
else if ( nInd >= nLinAxes && nInd < nLinAxes + nRotAxes) {
bLinear = false ;
bHead = m_vCalcRotAx[nInd-nLinAxes].bHead ;
return true ;
}
return false ;
}
//----------------------------------------------------------------------------
bool
Machine::GetCurrAxisMin( int nInd, double& dMin) const
@@ -1820,6 +2012,52 @@ Machine::GetCurrAxisMax( int nInd, double& dMax) const
return false ;
}
//----------------------------------------------------------------------------
bool
Machine::GetCurrAxisOffset( int nInd, double& dOffset) const
{
int nLinAxes = int( m_vCalcLinAx.size()) ;
int nRotAxes = int( m_vCalcRotAx.size()) ;
if ( nInd >= 0 && nInd < nLinAxes) {
Axis* pAx = GetAxis( m_vCalcLinAx[nInd].nGrpId) ;
if ( pAx == nullptr)
return false ;
dOffset = pAx->GetOffset() ;
return true ;
}
else if ( nInd >= nLinAxes && nInd < nLinAxes + nRotAxes) {
Axis* pAx = GetAxis( m_vCalcRotAx[nInd-nLinAxes].nGrpId) ;
if ( pAx == nullptr)
return false ;
dOffset = pAx->GetOffset() ;
return true ;
}
return false ;
}
//----------------------------------------------------------------------------
bool
Machine::GetCurrAxisInvert( int nInd, bool& bInvert) const
{
int nLinAxes = int( m_vCalcLinAx.size()) ;
int nRotAxes = int( m_vCalcRotAx.size()) ;
if ( nInd >= 0 && nInd < nLinAxes) {
Axis* pAx = GetAxis( m_vCalcLinAx[nInd].nGrpId) ;
if ( pAx == nullptr)
return false ;
bInvert = pAx->GetInvert() ;
return true ;
}
else if ( nInd >= nLinAxes && nInd < nLinAxes + nRotAxes) {
Axis* pAx = GetAxis( m_vCalcRotAx[nInd-nLinAxes].nGrpId) ;
if ( pAx == nullptr)
return false ;
bInvert = pAx->GetInvert() ;
return true ;
}
return false ;
}
//----------------------------------------------------------------------------
bool
Machine::GetCurrAxisHomePos( int nInd, double& dHome) const
@@ -1867,3 +2105,111 @@ Machine::GetAllCurrAxesHomePos( DBLVECTOR& vAxHomeVal) const
}
return bOk ;
}
//----------------------------------------------------------------------------
bool
Machine::GetRobotAngles( const Point3d& ptP, const Vector3d& vtDirT, const Vector3d& vtDirA,
DBLVECTOR& vAng1, DBLVECTOR& vAng2) const
{
// pulisco il risultato
vAng1.clear() ;
vAng2.clear() ;
// porto i dati nel riferimento robot
Point3d ptPL = GetToLoc( ptP, m_frRobot) ;
Vector3d vtDirTL = GetToLoc( vtDirT, m_frRobot) ;
Vector3d vtDirAL = GetToLoc( vtDirA, m_frRobot) ;
// riferimento utensile
Frame3d frTool ;
frTool.Set( ORIG, vtDirTL, vtDirAL) ;
// deduco la posizione richiesta del centro del polso
Point3d ptCen = ptPL + m_ptWristCen.x * frTool.VersX() +
m_ptWristCen.y * frTool.VersY() +
( m_dCalcTLen + m_ptWristCen.z) * frTool.VersZ() ;
// deduco la direzione richiesta del centro del polso
Vector3d vtCen = m_vtWristRef.x * frTool.VersX() +
m_vtWristRef.y * frTool.VersY() +
m_vtWristRef.z * frTool.VersZ() ;
// calcolo il primo asse rotante
Vector3d vtArm = ptCen - m_vCalcRotAx[0].ptPos ;
double dAng1 ; bool bDet1 ;
if ( ! X_AX.GetRotation( vtArm, m_vCalcRotAx[0].vtDir, EPS_SMALL, dAng1, bDet1) || ! bDet1) {
LOG_ERROR( GetEMkLogger(), "Error : direction unreachable (robot)")
return false ;
}
vAng1.push_back( dAng1) ;
vAng2.push_back( dAng1) ;
// calcolo secondo e terzo asse rotante
Point3d ptR2 = m_vCalcRotAx[1].ptPos ;
ptR2.Rotate( m_vCalcRotAx[0].ptPos, m_vCalcRotAx[0].vtDir, dAng1) ;
Vector3d vtR2 = m_vCalcRotAx[1].vtDir ;
vtR2.Rotate( m_vCalcRotAx[0].vtDir, dAng1) ;
Vector3d vtR2Cen = ptCen - ( ptR2 + ( ptCen - ptR2) * vtR2 * vtR2) ;
double dDistR2Cen = vtR2Cen.Len() ;
double dDistR2R3 = m_vCalcRotAx[2].ptPos.z - m_vCalcRotAx[1].ptPos.z ;
Vector3d vtR3R5 = m_vCalcRotAx[4].ptPos - m_vCalcRotAx[2].ptPos ; vtR3R5.y = 0 ;
double dDistR3R5 = vtR3R5.Len() ;
double dAngR3R5 = atan2( vtR3R5.z, vtR3R5.x) * RADTODEG ;
double dCosB = ( dDistR2R3 * dDistR2R3 + dDistR2Cen * dDistR2Cen - dDistR3R5 * dDistR3R5) / ( 2 * dDistR2R3 * dDistR2Cen) ;
double dCosC = ( dDistR3R5 * dDistR3R5 + dDistR2Cen * dDistR2Cen - dDistR2R3 * dDistR2R3) / ( 2 * dDistR3R5 * dDistR2Cen) ;
if ( abs( dCosB) > 1 || abs( dCosC) > 1) {
LOG_ERROR( GetEMkLogger(), "Error : position unreachable (robot)")
return false ;
}
double dAngB = acos( dCosB) * RADTODEG ;
double dAng2 ; bool bDet2 ;
if ( ! Z_AX.GetRotation( vtR2Cen, vtR2, EPS_SMALL, dAng2, bDet2) || ! bDet2) {
LOG_ERROR( GetEMkLogger(), "Error : R2 not calculable (robot)")
return false ;
}
dAng2 -= dAngB ;
vAng1.push_back( dAng2) ;
vAng2.push_back( dAng2) ;
double dAngC = acos( dCosC) * RADTODEG ;
double dAng3 = dAngB + dAngC + dAngR3R5 - ANG_RIGHT ;
vAng1.push_back( dAng3) ;
vAng2.push_back( dAng3) ;
// calcolo i primi due assi rotanti del polso
Frame3d frWrist ;
frWrist.Set( m_vCalcRotAx[3].ptPos, m_vCalcRotAx[3].vtDir, m_vCalcRotAx[4].vtDir ^ m_vCalcRotAx[3].vtDir) ;
frWrist.Rotate( m_vCalcRotAx[2].ptPos, m_vCalcRotAx[2].vtDir, dAng3) ;
frWrist.Rotate( m_vCalcRotAx[1].ptPos, m_vCalcRotAx[1].vtDir, dAng2) ;
frWrist.Rotate( m_vCalcRotAx[0].ptPos, m_vCalcRotAx[0].vtDir, dAng1) ;
Vector3d vtCenL = GetToLoc( vtCen, frWrist) ;
double dAng4, dAng5 ;
vtCenL.ToSpherical( nullptr, &dAng5, &dAng4) ;
if ( dAng4 > ANG_STRAIGHT)
dAng4 -= ANG_FULL ;
if ( dAng4 > ANG_RIGHT) {
dAng4 -= ANG_STRAIGHT ;
dAng5 = -dAng5 ;
}
else if ( dAng4 < -ANG_RIGHT) {
dAng4 += ANG_STRAIGHT ;
dAng5 = -dAng5 ;
}
vAng1.push_back( dAng4) ;
vAng1.push_back( dAng5) ;
vAng2.push_back( dAng4 + ( dAng4 > EPS_ANG_ZERO ? -ANG_STRAIGHT : ANG_STRAIGHT)) ;
vAng2.push_back( -dAng5) ;
// calcolo il terzo asse rotante del polso
Vector3d vtR6 = m_vCalcRotAx[5].vtDir ;
for ( int i = 4; i >= 0 ; --i)
vtR6.Rotate( m_vCalcRotAx[i].vtDir, vAng1[i]) ;
Vector3d vtTool = m_vtCalcDir ;
for ( int i = 4; i >= 0 ; --i)
vtTool.Rotate( m_vCalcRotAx[i].vtDir, vAng1[i]) ;
double dAng6 ; bool bDet6 ;
if ( ! vtTool.GetRotation( vtDirTL, vtR6, EPS_SMALL, dAng6, bDet6) || ! bDet6) {
Vector3d vtAux = m_vtCalcADir ;
for ( int i = 4; i >= 0 ; --i)
vtAux.Rotate( m_vCalcRotAx[i].vtDir, vAng1[i]) ;
if ( ! vtAux.GetRotation( vtDirAL, vtR6, EPS_SMALL, dAng6, bDet6) || ! bDet6) {
LOG_ERROR( GetEMkLogger(), "Error : R6 not calculable (robot)")
return false ;
}
}
vAng1.push_back( dAng6) ;
vAng2.push_back( dAng6 + ( dAng6 > EPS_ANG_ZERO ? -ANG_STRAIGHT : ANG_STRAIGHT)) ;
return true ;
}
MachineHeads.cpp
+12
View File
@@ -98,6 +98,18 @@ Machine::GetHeadSolCh( const string& sHead) const
return pHead->GetSolCh() ;
}
//----------------------------------------------------------------------------
int
Machine::GetHeadSelectType( const string& sHead) const
{
// recupero testa
Head* pHead = GetHead( GetGroup( sHead)) ;
if ( pHead == nullptr)
return MCH_SCC_NONE ;
// recupero tipo di selezione delle uscite della testa
return pHead->GetSelectType() ;
}
//----------------------------------------------------------------------------
bool
Machine::LoadTool( const string& sHead, int nExit, const string& sTool)
MachineLua.cpp
+179 -26
View File
@@ -1,13 +1,15 @@
//----------------------------------------------------------------------------
// EgalTech 2015-2021
// EgalTech 2015-2024
//----------------------------------------------------------------------------
// File : MachineLua.cpp Data : 14.10.21 Versione : 2.3j5
// File : MachineLua.cpp Data : 01.09.24 Versione : 2.6i1
// Contenuto : Implementazione gestione macchina : funzioni Lua.
//
//
//
// Modifiche : 06.05.15 DS Creazione modulo.
// 26.04.20 DS Aggiunta gestione TcPos.
// 05.08.24 DS Aggiunta gestione SpecialEstimate.
// 01.09.24 DS SpecialEstimate è diventato MultiProcess.
//
//----------------------------------------------------------------------------
@@ -34,6 +36,7 @@ static const string FLD_AXISMAXROTADJ = "AxisMaxRotAdj" ;
static const string FLD_EXITMAXADJUST = "ExitMaxAdjust" ;
static const string FLD_EXITMAXROTADJ = "ExitMaxRotAdj" ;
static const string FLD_ANGDELTAMINFORHOME = "AngDeltaMinForHome" ;
static const string FLD_MULTIPROCESS = "MultiProcess" ;
static const string FLD_NAME = "Name" ;
static const string FLD_PARENT = "Parent" ;
static const string FLD_GEO = "Geo" ;
@@ -44,12 +47,14 @@ static const string FLD_INVERT = "Invert" ;
static const string FLD_AXIS_OFFSET = "Offset" ;
static const string FLD_REF1 = "Ref1" ;
static const string FLD_SCALE = "Scale" ;
static const string FLD_EXIT_NBR = "ExitNbr" ;
static const string FLD_POS = "Pos" ;
static const string FLD_DIR = "Dir" ;
static const string FLD_STROKE = "Stroke" ;
static const string FLD_HOME = "Home" ;
static const string FLD_ADJUSTAUX = "AdjustAux" ;
static const string FLD_HSET = "HSet" ;
static const string FLD_SEL_TYPE = "SelType" ;
static const string FLD_TDIR = "TDir" ;
static const string FLD_ADIR = "ADir" ;
static const string FLD_ROT1W = "Rot1W" ;
@@ -57,6 +62,7 @@ static const string FLD_MAXDELTAR2ON1 = "MaxDeltaR2OnFirst" ;
static const string FLD_ROT2STROKE = "Rot2Stroke" ;
static const string FLD_SOLCH = "SolCh" ;
static const string FLD_OTHCOLL = "OthColl" ;
static const string FLD_COLL = "Coll" ;
//----------------------------------------------------------------------------
Machine* Machine::m_pMchLua = nullptr ;
@@ -136,8 +142,12 @@ Machine::LuaInit( const string& sMachineName)
m_LuaMgr.RegisterFunction( "EmtSetToolForVmill", Machine::LuaEmtSetToolForVmill) ;
// registro la funzione di impostazione di utensile aggiuntivo per virtual milling in simulazione
m_LuaMgr.RegisterFunction( "EmtAddToolForVmill", Machine::LuaEmtAddToolForVmill) ;
// registro la funzione per abilitare/disabilitare l'esecuzione del virtual milling
m_LuaMgr.RegisterFunction( "EmtEnableToolsForVmill", Machine::LuaEmtEnableToolsForVmill) ;
// registro la funzione di movimento assi in simulazione
m_LuaMgr.RegisterFunction( "EmtMoveAxes", Machine::LuaEmtMoveAxes) ;
// registro la funzione di salvataggio comandi in simulazione MP
m_LuaMgr.RegisterFunction( "EmtSaveCmd", Machine::LuaEmtSaveCmd) ;
return true ;
}
@@ -337,6 +347,9 @@ Machine::LuaEmtGeneral( lua_State* L)
// lettura eventuale campo 'AngDeltaForHome' dalla tabella (default INFINITO)
double dAngDeltaMinForHome = INFINITO ;
LuaGetTabFieldParam( L, 1, FLD_ANGDELTAMINFORHOME, dAngDeltaMinForHome) ;
// lettura eventuale campo 'MultiProcess' dalla tabella (0=no, 1=si, 2=si con simulazione MP)
int nMultiProcess = 0 ;
LuaGetTabFieldParam( L, 1, FLD_MULTIPROCESS, nMultiProcess) ;
LuaClearStack( L) ;
// info
@@ -386,6 +399,9 @@ Machine::LuaEmtGeneral( lua_State* L)
// imposto minima differenza angolare da posizione precedente per stare vivino a posizione home
m_pMchLua->m_dAngDeltaMinForHome = dAngDeltaMinForHome ;
// imposto flag per macchina multiprocesso
m_pMchLua->m_nMultiProcess = nMultiProcess ;
return 0 ;
}
@@ -450,6 +466,9 @@ Machine::LuaEmtTable( lua_State* L)
// lettura eventuale campo 'Scale' dalla tabella
double vScale[3] = {1.0, 1.0, 1.0} ;
LuaGetTabFieldParam( L, 1, FLD_SCALE, vScale) ;
// lettura eventuale campo 'Coll' dalla tabella
STRVECTOR vsColl ;
LuaGetTabFieldParam( L, 1, FLD_COLL, vsColl) ;
// lettura campo 'Geo' dalla tabella
string sGeo ;
LuaCheckTabFieldParam( L, 1, FLD_GEO, sGeo)
@@ -467,7 +486,7 @@ Machine::LuaEmtTable( lua_State* L)
return luaL_error( L, " Unknown Machine") ;
// carico i dati della tavola
if ( ! m_pMchLua->LoadMachineTable( sName, sParent, nType, Ref1, vScale[0], vScale[1], vScale[2], sGeo, vsAux))
if ( ! m_pMchLua->LoadMachineTable( sName, sParent, nType, Ref1, vScale[0], vScale[1], vScale[2], vsColl, sGeo, vsAux))
return luaL_error( L, " Load Machine Table failed") ;
// restituisco l'indice della tavola
@@ -659,9 +678,12 @@ Machine::LuaEmtMultiHead( lua_State* L)
// lettura campo 'HSet' dalla tabella
string sHSet ;
LuaCheckTabFieldParam( L, 1, FLD_HSET, sHSet)
// lettura eventuale campo tipo di selezione ammessa per le uscite
int nSelectType = MCH_SLT_FIXEDEXITS ;
LuaGetTabFieldParam( L, 1, FLD_SEL_TYPE, nSelectType) ;
// lettura campo 'ExitNbr' dalla tabella
int nExitNbr ;
LuaCheckTabFieldParam( L, 1, "ExitNbr", nExitNbr)
LuaCheckTabFieldParam( L, 1, FLD_EXIT_NBR, nExitNbr)
// lettura campi 'PosN' e 'TDirN' per ogni uscita dalla tabella
MUEXITVECTOR vMuExit ;
vMuExit.reserve( nExitNbr) ;
@@ -676,7 +698,7 @@ Machine::LuaEmtMultiHead( lua_State* L)
// inserimento nell'array
vMuExit.emplace_back( ptPos, vtTDir) ;
}
// lettura campo 'ADir' dalla tabella
// lettura eventuale campo 'ADir' dalla tabella
Vector3d vtADir ;
LuaGetTabFieldParam( L, 1, FLD_ADIR, vtADir) ;
// lettura eventuale campo 'Rot1W' dalla tabella (default 1)
@@ -711,9 +733,9 @@ Machine::LuaEmtMultiHead( lua_State* L)
return luaL_error( L, " Unknown Machine") ;
// carico i dati della testa multipla
if ( ! m_pMchLua->LoadMachineMultiHead( sName, sParent, sHSet, vMuExit, vtADir,
if ( ! m_pMchLua->LoadMachineMultiHead( sName, sParent, sHSet, nSelectType, vMuExit, vtADir,
dRot1W, bMaxDeltaR2On1, Rot2Stroke, nSolCh, vsOthColl, sGeo, vsAux))
return luaL_error( L, " Load Machine Standard Head failed") ;
return luaL_error( L, " Load Machine Multi Head failed") ;
// restituisco l'indice della testa
int nHeadId = m_pMchLua->GetHeadId( sName) ;
@@ -797,6 +819,26 @@ Machine::LuaEmtSpecialHead( lua_State* L)
//----------------------------------------------------------------------------
int
Machine::LuaEmtTcPos( lua_State* L)
{
// Il parametro 1 deve essere una tabella
if ( ! lua_istable( L, 1))
return luaL_error( L, " Invalid Parameter, required a table") ;
// lettura campo opzionale 'ExitNbr' dalla tabella
int nExitNbr = 1 ;
LuaGetTabFieldParam( L, 1, FLD_EXIT_NBR, nExitNbr) ;
// Procedo alla lettura a seconda del tnumero di uscite
if ( nExitNbr == 1)
return LuaEmtStdTcPos( L) ;
else if ( nExitNbr > 1)
return LuaEmtMultiTcPos( L) ;
else
return luaL_error( L, " Tc Position type unknown") ;
}
//----------------------------------------------------------------------------
int
Machine::LuaEmtStdTcPos( lua_State* L)
{
// Il parametro 1 deve essere una tabella
if ( ! lua_istable( L, 1))
@@ -833,8 +875,70 @@ Machine::LuaEmtTcPos( lua_State* L)
return luaL_error( L, " Unknown Machine") ;
// carico i dati della posizione cambio utensile
if ( ! m_pMchLua->LoadMachineTcPos( sName, sParent, ptPos, vtTDir, vtADir, sGeo, vsAux))
return luaL_error( L, " Load Machine Tc Position failed") ;
if ( ! m_pMchLua->LoadMachineStdTcPos( sName, sParent, ptPos, vtTDir, vtADir, sGeo, vsAux))
return luaL_error( L, " Load Machine Standard Tc Position failed") ;
// restituisco l'indice della posizione cambio utensile
int nTcPosId = m_pMchLua->GetTcPosId( sName) ;
if ( nTcPosId != GDB_ID_NULL)
LuaSetParam( L, nTcPosId) ;
else
LuaSetParam( L) ;
return 1 ;
}
//----------------------------------------------------------------------------
int
Machine::LuaEmtMultiTcPos( lua_State* L)
{
// Il parametro 1 deve essere una tabella
if ( ! lua_istable( L, 1))
return luaL_error( L, " Invalid Parameter, required a table") ;
// lettura campo 'Name' dalla tabella
string sName ;
LuaCheckTabFieldParam( L, 1, FLD_NAME, sName)
// lettura campo 'Parent' dalla tabella
string sParent ;
LuaCheckTabFieldParam( L, 1, FLD_PARENT, sParent)
// lettura campo 'ExitNbr' dalla tabella
int nExitNbr ;
LuaCheckTabFieldParam( L, 1, FLD_EXIT_NBR, nExitNbr)
// lettura campi 'PosN' e 'TDirN' per ogni uscita dalla tabella
MUEXITVECTOR vMuExit ;
vMuExit.reserve( nExitNbr) ;
for ( int i = 0 ; i < nExitNbr ; ++ i) {
// lettura
string sPos = FLD_POS + ToString( i + 1) ;
Point3d ptPos ;
LuaCheckTabFieldParam( L, 1, sPos.c_str(), ptPos)
string sTDir = FLD_TDIR + ToString( i + 1) ;
Vector3d vtTDir ;
LuaCheckTabFieldParam( L, 1, sTDir.c_str(), vtTDir)
// inserimento nell'array
vMuExit.emplace_back( ptPos, vtTDir) ;
}
// lettura eventuale campo 'ADir' dalla tabella
Vector3d vtADir ;
LuaGetTabFieldParam( L, 1, FLD_ADIR, vtADir) ;
// lettura campo 'Geo' dalla tabella
string sGeo ;
LuaCheckTabFieldParam( L, 1, FLD_GEO, sGeo)
// lettura eventuale campo 'Aux' dalla tabella
STRVECTOR vsAux ;
LuaGetTabFieldParam( L, 1, FLD_AUX, vsAux) ;
LuaClearStack( L) ;
// info
string sOut = "LuaEmtTcPos : " + sName ;
LOG_DBG_INFO( GetEMkLogger(), sOut.c_str())
// verifico ci sia una macchina attiva
if ( m_pMchLua == nullptr)
return luaL_error( L, " Unknown Machine") ;
// carico i dati della posizione cambio utensile
if ( ! m_pMchLua->LoadMachineMultiTcPos( sName, sParent, vMuExit, vtADir, sGeo, vsAux))
return luaL_error( L, " Load Machine Multi Tc Position failed") ;
// restituisco l'indice della posizione cambio utensile
int nTcPosId = m_pMchLua->GetTcPosId( sName) ;
@@ -1347,7 +1451,7 @@ Machine::LuaEmtOnCollision( lua_State* L)
int
Machine::LuaEmtSetToolForVmill( lua_State* L)
{
// 4 parametri : sTool, sHead, nExit, vVmill
// 4 o 7 parametri : sTool, sHead, nExit, vVmill [, nFlag , dPar1, dPar2]
string sTool ;
LuaGetParam( L, 1, sTool) ;
string sHead ;
@@ -1356,12 +1460,19 @@ Machine::LuaEmtSetToolForVmill( lua_State* L)
LuaGetParam( L, 3, nExit) ;
INTVECTOR vVmill ;
LuaGetParam( L, 4, vVmill) ;
int nFlag = 0 ;
LuaGetParam( L, 5, nFlag) ;
double dPar1 = 0 ;
LuaGetParam( L, 6, dPar1) ;
double dPar2 = 0 ;
LuaGetParam( L, 7, dPar2) ;
LuaClearStack( L) ;
// verifico ci sia una macchina attiva
if ( m_pMchLua == nullptr)
return luaL_error( L, " Unknown Machine") ;
// imposto dati primo utensile per virtual milling in simulazione
bool bOk = ( m_pMchLua->m_pMchMgr != nullptr && m_pMchLua->m_pMchMgr->SimSetToolForVmill( sTool, sHead, nExit, vVmill, true)) ;
bool bOk = ( m_pMchLua->m_pMchMgr != nullptr &&
m_pMchLua->m_pMchMgr->SimSetToolForVmill( sTool, sHead, nExit, nFlag, dPar1, dPar2, vVmill, true)) ;
// assegno risultato
LuaSetParam( L, bOk) ;
return 1 ;
@@ -1371,7 +1482,7 @@ Machine::LuaEmtSetToolForVmill( lua_State* L)
int
Machine::LuaEmtAddToolForVmill( lua_State* L)
{
// 4 parametri : sTool, sHead, nExit, vVmill
// 4 o 7 parametri : sTool, sHead, nExit, vVmill [, nFlag, dPar1, dPar2]
string sTool ;
LuaGetParam( L, 1, sTool) ;
string sHead ;
@@ -1380,12 +1491,37 @@ Machine::LuaEmtAddToolForVmill( lua_State* L)
LuaGetParam( L, 3, nExit) ;
INTVECTOR vVmill ;
LuaGetParam( L, 4, vVmill) ;
int nFlag = 0 ;
LuaGetParam( L, 5, nFlag) ;
double dPar1 = 0 ;
LuaGetParam( L, 6, dPar1) ;
double dPar2 = 0 ;
LuaGetParam( L, 7, dPar2) ;
LuaClearStack( L) ;
// verifico ci sia una macchina attiva
if ( m_pMchLua == nullptr)
return luaL_error( L, " Unknown Machine") ;
// imposto dati utensile aggiuntivo per virtual milling in simulazione
bool bOk = ( m_pMchLua->m_pMchMgr != nullptr && m_pMchLua->m_pMchMgr->SimSetToolForVmill( sTool, sHead, nExit, vVmill, false)) ;
bool bOk = ( m_pMchLua->m_pMchMgr != nullptr &&
m_pMchLua->m_pMchMgr->SimSetToolForVmill( sTool, sHead, nExit, nFlag, dPar1, dPar2, vVmill, false)) ;
// assegno risultato
LuaSetParam( L, bOk) ;
return 1 ;
}
//----------------------------------------------------------------------------
int
Machine::LuaEmtEnableToolsForVmill( lua_State* L)
{
// 1 parametro : bEnable
bool bEnable = false ;
LuaGetParam( L, 1, bEnable) ;
LuaClearStack( L) ;
// verifico ci sia una macchina attiva
if ( m_pMchLua == nullptr)
return luaL_error( L, " Unknown Machine") ;
// imposto abilitazione utensili per virtual milling in simulazione
bool bOk = ( m_pMchLua->m_pMchMgr != nullptr && m_pMchLua->m_pMchMgr->SimEnableToolsForVmill( bEnable)) ;
// assegno risultato
LuaSetParam( L, bOk) ;
return 1 ;
@@ -1395,19 +1531,12 @@ Machine::LuaEmtAddToolForVmill( lua_State* L)
int
Machine::LuaEmtMoveAxes( lua_State* L)
{
// 4, ..., 16 parametri : nMoveType, sAx1, dPos1, dStep1 [, sAx2, dPos2, dStep2] [, sAx3, dPos3, dStep3] [, sAx4, dPos4, dStep4] [, sAx5, dPos5, dStep5]
int nMoveType ;
LuaCheckParam( L, 1, nMoveType)
string sAx1 ;
LuaCheckParam( L, 2, sAx1) ;
double dEnd1 ;
LuaCheckParam( L, 3, dEnd1) ;
double dStep1 ;
LuaCheckParam( L, 4, dStep1) ;
// 4, ..., 31 parametri : nMoveType, sAx1, dPos1, dStep1 [, sAx2, dPos2, dStep2] ... [, sAx10, dPos10, dStep10]
int nMoveType = 0 ;
LuaGetParam( L, 1, nMoveType) ;
SAMVECTOR vAxNaEpSt ;
vAxNaEpSt.emplace_back( sAx1, dEnd1, dStep1) ;
for ( int i = 0 ; i < 4 ; ++ i) {
int nInd = 5 + 3 * i ;
for ( int i = 0 ; i < 10 ; ++ i) {
int nInd = 2 + 3 * i ;
string sAxN ;
double dEndN ;
double dStepN ;
@@ -1427,7 +1556,31 @@ Machine::LuaEmtMoveAxes( lua_State* L)
// assegno risultato
if ( nRes == SIM_AXMV_RES_STOP)
return luaL_error( L, "STOP") ;
else
else {
LuaSetParam( L, ( nRes == SIM_AXMV_RES_OK)) ;
LuaSetParam( L, m_pMchLua->GetMultiProcess()) ;
}
return 2 ;
}
//----------------------------------------------------------------------------
int
Machine::LuaEmtSaveCmd( lua_State* L)
{
// parametri : nType,
int nType = 0 ;
LuaGetParam( L, 1, nType) ;
int nPar = 0 ;
LuaGetParam( L, 2, nPar) ;
string sPar ;
LuaGetParam( L, 3, sPar) ;
LuaClearStack( L) ;
// verifico ci sia una macchina attiva
if ( m_pMchLua == nullptr)
return luaL_error( L, " Unknown Machine") ;
// salvo il comando
bool bOk = ( m_pMchLua->m_pMchMgr != nullptr && m_pMchLua->m_pMchMgr->SimSaveCmd( nType, nPar, sPar)) ;
// assegno risultato
LuaSetParam( L, bOk) ;
return 1 ;
}
MachineLuaCL.cpp
+17 -4
View File
@@ -15,6 +15,7 @@
#include "stdafx.h"
#include "MachMgr.h"
#include "DllMain.h"
#include "CamData.h"
#include "/EgtDev/Include/EXeExecutor.h"
#include "/EgtDev/Include/EGkGeoPoint3d.h"
#include "/EgtDev/Include/EGkCurveLine.h"
@@ -31,7 +32,7 @@ using namespace std ;
int
Machine::LuaEmtAddRapidStart( lua_State* L)
{
// 6 parametri : nPathId, ptP, vtTool, vtCorr, vtAux, nFlag
// 6 o 7 parametri : nPathId, ptP, vtTool, vtCorr, vtAux, nFlag [, bToolShow]
int nPathId ;
LuaCheckParam( L, 1, nPathId)
Point3d ptP ;
@@ -44,6 +45,8 @@ Machine::LuaEmtAddRapidStart( lua_State* L)
LuaCheckParam( L, 5, vtAux)
int nFlag ;
LuaCheckParam( L, 6, nFlag)
bool bToolShow = false ;
LuaGetParam( L, 7, bToolShow) ;
LuaClearStack( L) ;
// verifico ci sia una macchina attiva valida
if ( m_pMchLua == nullptr ||
@@ -69,6 +72,7 @@ Machine::LuaEmtAddRapidStart( lua_State* L)
pCam->SetEndPoint( ptP) ;
pCam->SetFeed( 0) ;
pCam->SetFlag( nFlag) ;
pCam->SetToolShow( bToolShow) ;
// associo questo oggetto a quello geometrico
m_pMchLua->m_pGeomDB->SetUserObj( nId, Release( pCam)) ;
}
@@ -84,7 +88,7 @@ Machine::LuaEmtAddRapidStart( lua_State* L)
int
Machine::LuaEmtAddRapidMove( lua_State* L)
{
// 7 parametri : nPathId, ptIni, ptFin, vtTool, vtCorr, vtAux, nFlag
// 7 o 8 parametri : nPathId, ptIni, ptFin, vtTool, vtCorr, vtAux, nFlag [, bToolShow]
int nPathId ;
LuaCheckParam( L, 1, nPathId)
Point3d ptIni ;
@@ -99,6 +103,8 @@ Machine::LuaEmtAddRapidMove( lua_State* L)
LuaCheckParam( L, 6, vtAux)
int nFlag ;
LuaCheckParam( L, 7, nFlag)
bool bToolShow = false ;
LuaGetParam( L, 8, bToolShow) ;
LuaClearStack( L) ;
// verifico ci sia una macchina attiva valida
if ( m_pMchLua == nullptr ||
@@ -124,6 +130,7 @@ Machine::LuaEmtAddRapidMove( lua_State* L)
pCam->SetEndPoint( ptFin) ;
pCam->SetFeed( 0) ;
pCam->SetFlag( nFlag) ;
pCam->SetToolShow( bToolShow) ;
// associo questo oggetto a quello geometrico
m_pMchLua->m_pGeomDB->SetUserObj( nId, Release( pCam)) ;
}
@@ -139,7 +146,7 @@ Machine::LuaEmtAddRapidMove( lua_State* L)
int
Machine::LuaEmtAddLinearMove( lua_State* L)
{
// 8 parametri : nPathId, ptIni, ptFin, vtTool, vtCorr, vtAux, dFeed, nFlag
// 8 o 9 parametri : nPathId, ptIni, ptFin, vtTool, vtCorr, vtAux, dFeed, nFlag [, bToolShow]
int nPathId ;
LuaCheckParam( L, 1, nPathId)
Point3d ptIni ;
@@ -156,6 +163,8 @@ Machine::LuaEmtAddLinearMove( lua_State* L)
LuaCheckParam( L, 7, dFeed)
int nFlag ;
LuaCheckParam( L, 8, nFlag)
bool bToolShow = false ;
LuaGetParam( L, 9, bToolShow) ;
LuaClearStack( L) ;
// verifico ci sia una macchina attiva valida
if ( m_pMchLua == nullptr ||
@@ -181,6 +190,7 @@ Machine::LuaEmtAddLinearMove( lua_State* L)
pCam->SetEndPoint( ptFin) ;
pCam->SetFeed( dFeed) ;
pCam->SetFlag( nFlag) ;
pCam->SetToolShow( bToolShow) ;
// associo questo oggetto a quello geometrico
m_pMchLua->m_pGeomDB->SetUserObj( nId, Release( pCam)) ;
}
@@ -196,7 +206,7 @@ Machine::LuaEmtAddLinearMove( lua_State* L)
int
Machine::LuaEmtAddArcMove( lua_State* L)
{
// 11 parametri : nPathId, ptIni, ptFin, ptCen, dAngCen, vtN, vtTool, vtCorr, vtAux, dFeed, nFlag
// 11 o 12 parametri : nPathId, ptIni, ptFin, ptCen, dAngCen, vtN, vtTool, vtCorr, vtAux, dFeed, nFlag [, bToolShow]
int nPathId ;
LuaCheckParam( L, 1, nPathId)
Point3d ptIni ;
@@ -219,6 +229,8 @@ Machine::LuaEmtAddArcMove( lua_State* L)
LuaCheckParam( L, 10, dFeed)
int nFlag ;
LuaCheckParam( L, 11, nFlag)
bool bToolShow = false ;
LuaGetParam( L, 12, bToolShow) ;
LuaClearStack( L) ;
// verifico ci sia una macchina attiva valida
if ( m_pMchLua == nullptr ||
@@ -252,6 +264,7 @@ Machine::LuaEmtAddArcMove( lua_State* L)
pCam->SetNormDir( vtN) ;
pCam->SetFeed( dFeed) ;
pCam->SetFlag( nFlag) ;
pCam->SetToolShow( bToolShow) ;
// associo questo oggetto a quello geometrico
m_pMchLua->m_pGeomDB->SetUserObj( nId, Release( pCam)) ;
}
MachineStruConst.h
+14 -2
View File
@@ -1,7 +1,7 @@
//----------------------------------------------------------------------------
// EgalTech 2015-2015
// EgalTech 2015-2024
//----------------------------------------------------------------------------
// File : MachineStruConst.h Data : 25.05.15 Versione : 1.6e7
// File : MachineStruConst.h Data : 15.01.24 Versione : 2.5l6
// Contenuto : Strutture e costanti di macchina.
//
//
@@ -88,6 +88,18 @@ enum MchHeadType { MCH_HT_NONE = 0,
MCH_HT_MULTI = 2,
MCH_HT_SPECIAL = 3} ;
//----------------------------------------------------------------------------
// Tipo di selezione ammessa per le uscite
enum MchSelType { MCH_SLT_FIXEDEXITS = 0,
MCH_SLT_ONEEXIT = 1,
MCH_SLT_MULTIEXITS = 2} ;
//----------------------------------------------------------------------------
// Tipo della catena cinematica
enum KinChainType { KIN_CHAIN_NONE = 0,
KIN_CHAIN_CENTER = 1,
KIN_CHAIN_ROBOT = 2} ;
//----------------------------------------------------------------------------
// Identificativo iniziale riferimenti di tavola
const std::string MCH_TREF = "R" ;
Machining.cpp
+73 -10
View File
@@ -148,6 +148,15 @@ Machining::PrepareToolPreview( void) const
int nId = m_pGeomDB->CopyGlob( nHeadId, GDB_ID_NULL, nStId) ;
m_pGeomDB->SetMode( nId, GDB_MD_STD) ;
m_pGeomDB->SetStatus( nId, GDB_ST_OFF) ;
// elimino eventuali gruppi opportunamente indicati
int nSubId = m_pGeomDB->GetFirstGroupInGroup( nId) ;
while ( nSubId != GDB_ID_NULL) {
int nNextSubId = m_pGeomDB->GetNextGroup( nSubId) ;
bool bShow = true ;
if ( m_pGeomDB->GetInfo( nSubId, KEY_PREVIEWSHOW, bShow) && ! bShow)
m_pGeomDB->Erase( nSubId) ;
nSubId = nNextSubId ;
}
return ( nId != GDB_ID_NULL) ;
}
@@ -167,6 +176,42 @@ Machining::RemoveToolPreview( void) const
//----------------------------------------------------------------------------
int
Machining::GetToolPreviewStepCount( void) const
{
// verifico validità gestori DB geometrico e CAM
if ( m_pGeomDB == nullptr || m_pMchMgr == nullptr)
return 0 ;
// recupero gruppo per geometria di lavorazione (Cutter Location)
int nClId = m_pGeomDB->GetFirstNameInGroup( GetOwner(), MCH_CL) ;
if ( nClId == GDB_ID_NULL)
return 0 ;
// determino il numero di entità di tutti i sottogruppi, escludendo CLIMB e RISE
int nCount = 0 ;
int nPxId = m_pGeomDB->GetFirstGroupInGroup( nClId) ;
while ( nPxId != GDB_ID_NULL) {
// aggiungo tutte le entità del truppo
nCount += m_pGeomDB->GetGroupObjs( nPxId) ;
// tolgo le entità CLIMB
int nClimbId = m_pGeomDB->GetFirstNameInGroup( nPxId, MCH_CL_CLIMB) ;
while ( nClimbId != GDB_ID_NULL) {
-- nCount ;
nClimbId = m_pGeomDB->GetNextName( nClimbId, MCH_CL_CLIMB) ;
}
// tolgo le entità RISE
int nRiseId = m_pGeomDB->GetFirstNameInGroup( nPxId, MCH_CL_RISE) ;
while ( nRiseId != GDB_ID_NULL) {
-- nCount ;
nRiseId = m_pGeomDB->GetNextName( nRiseId, MCH_CL_RISE) ;
}
// passo al successivo sottogruppo
nPxId = m_pGeomDB->GetNextGroup( nPxId) ;
}
return nCount ;
}
//----------------------------------------------------------------------------
static int
GetToolPreviewNext( IGeomDB* pGeomDB, int nEntId, int nParentId)
{
// recupero la successiva
@@ -192,7 +237,7 @@ GetToolPreviewNext( IGeomDB* pGeomDB, int nEntId, int nParentId)
}
//----------------------------------------------------------------------------
int
static int
GetToolPreviewPrev( IGeomDB* pGeomDB, int nEntId, int nParentId)
{
// recupero la precedente
@@ -219,7 +264,7 @@ GetToolPreviewPrev( IGeomDB* pGeomDB, int nEntId, int nParentId)
//----------------------------------------------------------------------------
int
Machining::ToolPreview( int nEntId, int nFlag) const
Machining::ToolPreview( int nEntId, int nStep) const
{
// verifico validità gestori DB geometrico e CAM
if ( m_pGeomDB == nullptr || m_pMchMgr == nullptr)
@@ -239,10 +284,10 @@ Machining::ToolPreview( int nEntId, int nFlag) const
// recupero il gruppo di appartenenza
nParentId = m_pGeomDB->GetFirstGroupInGroup( nClId) ;
// se richiesta successiva
if ( nFlag == MCH_TPM_AFTER)
if ( nStep > 0)
nEntId = GetToolPreviewNext( m_pGeomDB, nEntId, nParentId) ;
// se richiesta precedente
else if ( nFlag == MCH_TPM_BEFORE)
else if ( nStep < 0)
nEntId = GetToolPreviewPrev( m_pGeomDB, nEntId, nParentId) ;
// altrimenti richiesta corrente
else
@@ -254,11 +299,29 @@ Machining::ToolPreview( int nEntId, int nFlag) const
nParentId = m_pGeomDB->GetParentId( nEntId) ;
if ( m_pGeomDB->GetParentId( nParentId) == nClId) {
// se richiesta successiva
if ( nFlag == MCH_TPM_AFTER)
nEntId = GetToolPreviewNext( m_pGeomDB, nEntId, nParentId) ;
if ( nStep > 0) {
while ( nStep > 0) {
int nOldId = nEntId ;
nEntId = GetToolPreviewNext( m_pGeomDB, nEntId, nParentId) ;
-- nStep ;
if ( nEntId == GDB_ID_NULL) {
nEntId = nOldId ;
break ;
}
}
}
// se richiesta precedente
else if ( nFlag == MCH_TPM_BEFORE)
nEntId = GetToolPreviewPrev( m_pGeomDB, nEntId, nParentId) ;
else if ( nStep < 0) {
while ( nStep < 0) {
int nOldId = nEntId ;
nEntId = GetToolPreviewPrev( m_pGeomDB, nEntId, nParentId) ;
++ nStep ;
if ( nEntId == GDB_ID_NULL) {
nEntId = nOldId ;
break ;
}
}
}
}
else
nEntId = GDB_ID_NULL ;
@@ -287,12 +350,12 @@ Machining::ToolPreview( int nEntId, int nFlag) const
Frame3d frHead ;
m_pGeomDB->GetGroupGlobFrame( nId, frHead) ;
Frame3d frRef ;
if ( vtAux.IsSmall())
if ( vtAux.IsSmall() || AreSameOrOppositeVectorApprox( vtAux, vtDir))
frRef.Set( ptOrig, vtDir) ;
else
frRef.Set( ptOrig, vtDir, vtAux) ;
Frame3d frShow ;
if ( vtBAux.IsSmall())
if ( vtBAux.IsSmall() || AreSameOrOppositeVectorApprox( vtBAux, vtTool))
frShow.Set( ptEnd + vtTool * GetToolData().m_dLen, vtTool) ;
else
frShow.Set( ptEnd + vtTool * GetToolData().m_dLen, vtTool, vtBAux) ;
Machining.h
+2 -1
View File
@@ -48,8 +48,9 @@ class Machining : public Operation
bool GetStartPoint( Point3d& ptStart) const ;
bool GetEndPoint( Point3d& ptEnd) const ;
bool PrepareToolPreview( void) const ;
int ToolPreview( int nEntId, int nFlag) const ;
bool RemoveToolPreview( void) const ;
int GetToolPreviewStepCount( void) const ;
int ToolPreview( int nEntId, int nStep) const ;
protected :
Machining( void) ;
MachiningConst.h
+10 -1
View File
@@ -103,7 +103,11 @@ GetMachiningTitle( int nMchType)
"SawRoughing",
"SawFinishing",
"GenMachining",
"Chiseling"} ;
"Chiseling",
"SurfRoughing",
"SurfFinishing",
"Waterjetting",
"5AxisMilling"} ;
switch ( nMchType) {
case MT_DRILLING : return MchTitle[1] ;
case MT_SAWING : return MchTitle[2] ;
@@ -114,6 +118,11 @@ GetMachiningTitle( int nMchType)
case MT_SAWFINISHING : return MchTitle[7] ;
case MT_GENMACHINING : return MchTitle[8] ;
case MT_CHISELING : return MchTitle[9] ;
case MT_SURFROUGHING : return MchTitle[10] ;
case MT_SURFFINISHING : return MchTitle[11] ;
case MT_WATERJETTING : return MchTitle[12] ;
case MT_FIVEAXISMILLING : return MchTitle[13] ;
}
return MchTitle[0] ;
}
MachiningsMgr.cpp
+27 -3
View File
@@ -1,7 +1,7 @@
//----------------------------------------------------------------------------
// EgalTech 2015-2022
// EgalTech 2015-2024
//----------------------------------------------------------------------------
// File : MachiningsMgr.cpp Data : 04.02.22 Versione : 2.4b1
// File : MachiningsMgr.cpp Data : 29.03.24 Versione : 2.6d1
// Contenuto : Implementazione gestore database lavorazioni.
//
//
@@ -16,6 +16,7 @@
// 22.06.20 DS Agg. per nuovi parametri attacco tagli di lama (MF_CURR_VER = 1010).
// 09.11.20 DS Agg. per nuovi parametri tagli di lama (MF_CURR_VER = 1011).
// 04.02.22 DS Agg. per nuovi parametri svuotature con epicicli (MF_CURR_VER = 1012).
// 29.03.24 DS Agg. parametro APPROX_LINTOL (MF_CURR_VER = 1013).
//
//----------------------------------------------------------------------------
@@ -42,7 +43,7 @@ const string MF_HEADER = "[HEADER]" ;
const string MF_VERSION = "VERSION" ;
const string MF_TOTAL = "TOTAL" ;
const string MF_SIZE = "SIZE" ;
const int MF_CURR_VER = 1012 ;
const int MF_CURR_VER = 1013 ;
const string MF_GENERAL = "[GENERAL]" ;
const string MF_3AXCOMP = "3AXCOMP" ;
const bool MF_CURR_3AXCOMP = false ;
@@ -64,6 +65,8 @@ const string MF_INTSAWARCMAXSIDEANG = "INTSAWARCMAXSIDEANG" ;
const double MF_CURR_INTSAWARCMAXSIDEANG = 45 ;
const string MF_SPLITARCS = "SPLITARCS" ;
const int MF_CURR_SPLITARCS = SPLAR_NEVER ;
const string MF_APPROX_LINTOL = "APPROX_LINTOL" ;
const double MF_CURR_APPROX_LINTOL = 0.05 ;
const string MF_MAXDEPTHSAFE = "MAXDEPTHSAFE" ;
const double MF_CURR_MAXDEPTHSAFE = 2.0 ;
@@ -85,6 +88,7 @@ MachiningsMgr::MachiningsMgr( void)
m_dExtSawArcMinRad = MF_CURR_EXTSAWARCMINRAD ;
m_dIntSawArcMaxSideAng = MF_CURR_INTSAWARCMAXSIDEANG ;
m_nSplitArcs = MF_CURR_SPLITARCS ;
m_dApproxLinTol = MF_CURR_APPROX_LINTOL ;
m_dMaxDepthSafe = MF_CURR_MAXDEPTHSAFE ;
}
@@ -312,6 +316,8 @@ MachiningsMgr::LoadGeneral( Scanner& TheScanner, bool& bEnd)
bOk = FromString( sVal, m_dIntSawArcMaxSideAng) ;
else if ( ToUpper( sKey) == MF_SPLITARCS)
bOk = FromString( sVal, m_nSplitArcs) ;
else if ( ToUpper( sKey) == MF_APPROX_LINTOL)
bOk = FromString( sVal, m_dApproxLinTol) ;
else if ( ToUpper( sKey) == MF_MAXDEPTHSAFE)
bOk = FromString( sVal, m_dMaxDepthSafe) ;
else
@@ -499,6 +505,10 @@ MachiningsMgr::SaveGeneral( Writer& TheWriter) const
sOut = MF_MAXDEPTHSAFE + "=" + ToString( m_dMaxDepthSafe) ;
bOk = bOk && TheWriter.OutText( sOut) ;
}
if ( m_nDbVer >= 1013) {
sOut = MF_APPROX_LINTOL + "=" + ToString( m_dApproxLinTol) ;
bOk = bOk && TheWriter.OutText( sOut) ;
}
return bOk ;
}
@@ -1175,6 +1185,20 @@ MachiningsMgr::SetSplitArcs( int nFlag)
return true ;
}
//----------------------------------------------------------------------------
bool
MachiningsMgr::SetApproxLinTol( double dLinTol)
{
// verifico non sia inferiore al minimo
dLinTol = max( dLinTol, EPS_SMALL) ;
// se cambiato, salvo e setto modifica
if ( abs( dLinTol - m_dApproxLinTol) > EPS_SMALL) {
m_dApproxLinTol = dLinTol ;
m_bModified = true ;
}
return true ;
}
//----------------------------------------------------------------------------
bool
MachiningsMgr::SetMaxDepthSafe( double dSafe)
MachiningsMgr.h
+6 -2
View File
@@ -1,7 +1,7 @@
//----------------------------------------------------------------------------
// EgalTech 2015-2015
// EgalTech 2015-2024
//----------------------------------------------------------------------------
// File : MachiningsMgr.h Data : 02.06.15 Versione : 1.6f1
// File : MachiningsMgr.h Data : 29.03.24 Versione : 2.6d1
// Contenuto : Dichiarazione della classe MachiningsMgr.
//
//
@@ -79,6 +79,9 @@ class MachiningsMgr
bool SetSplitArcs( int nFlag) ;
int GetSplitArcs( void) const
{ return m_nSplitArcs ; }
bool SetApproxLinTol( double dLinTol) ;
double GetApproxLinTol( void) const
{ return m_dApproxLinTol ; }
bool SetMaxDepthSafe( double dSafe) ;
double GetMaxDepthSafe( void) const
{ return m_dMaxDepthSafe ; }
@@ -131,5 +134,6 @@ class MachiningsMgr
double m_dExtSawArcMinRad ;
double m_dIntSawArcMaxSideAng ;
int m_nSplitArcs ;
double m_dApproxLinTol ;
double m_dMaxDepthSafe ;
} ;
Milling.cpp
+1781 -822
View File
File diff suppressed because it is too large Load Diff
Milling.h
+36 -13
View File
@@ -85,7 +85,7 @@ class Milling : public Machining
bool AdjustPathDrawForSaw( int nClPathId) ;
bool CalcPathElevation( const ICurveComposite* pCompo, const Vector3d& vtTool, double dDepth, double dRad, double& dElev) const ;
bool VerifyPathFromBottom( const ICurveComposite* pCompo, const Vector3d& vtTool) ;
bool GenerateMillingPv( int nPathId, const ICurveComposite* pCompo) ;
bool GenerateMillingPv( int nPathId, const ICurveComposite* pCompo, double dRbDist, double dDepth) ;
bool AddStandardMilling( const ICurveComposite* pCompo, const Vector3d& vtTool,
double dDepth, double dElev, bool bSplitArcs, bool bPathTabsEnable, bool bPathOscEnable) ;
bool AddZigZagMilling( const ICurveComposite* pCompo, const Vector3d& vtTool, double dDepth, double dElev,
@@ -96,21 +96,26 @@ class Milling : public Machining
double dDepth, double dElev, double dOkStep, bool bSplitArcs, bool bPathTabsEnable, bool bPathOscEnable) ;
bool AddSawZigZagMilling( const ICurveComposite* pCompo, const Vector3d& vtTool,
double dDepth, double dElev, double dOkStep, bool bSplitArcs) ;
bool AddSawOneWayMilling( const ICurveComposite* pCompo, const Vector3d& vtTool,
double dDepth, double dElev, double dOkStep, bool bSplitArcs) ;
bool AddApproach( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ, double dSafeAggrBottZ,
double dElev, double dAppr, bool bOutStart, bool bAboveStart) ;
bool AddSawBladeSideApproach( const Point3d& ptP, const Vector3d& vtAppr, double dSafeZ, double dStElev, double dAppr) ;
bool AddDirectApproach( const Point3d& ptP) ;
double dElev, double dAppr, bool bOutStart, bool bAboveStart, bool bFirst, bool bSplitArcs) ;
bool AddSawBladeSideApproach( const Point3d& ptP, const Vector3d& vtAppr, const Vector3d& vtTool,
double dSafeZ, double dSawStElev, double dStElev, double dAppr,
bool bFirst, bool bSplitArcs, bool bAddInsert = false) ;
bool AddDirectApproach( const Point3d& ptP, bool bSplitArcs) ;
bool AddRetract( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ, double dSafeAggrBottZ,
double dElev, double dAppr, bool bAboveEnd) ;
bool AddSawBladeSideRetract( const Point3d& ptP, const Vector3d& vtRetr, double dSafeZ, double dEndElev, double dAppr) ;
double dElev, double dAppr, bool bAboveEnd, bool bSplitArcs) ;
bool AddSawBladeSideRetract( const Point3d& ptP, const Vector3d& vtRetr, const Vector3d& vtTool,
double dSafeZ, double dSawEndElev, double dEndElev, double dAppr, bool bAddExtract = false) ;
bool CalcLeadInStart( const Point3d& ptStart, const Vector3d& vtStart, const Vector3d& vtTool,
double dStElev, bool bInvert, const ICurveComposite* pCompo, Point3d& ptP1) const ;
double dStElev, bool bInvert, const ICurveComposite* pCompo, Point3d& ptP1, Vector3d& vtDir1) const ;
bool AddLeadIn( const Point3d& ptP1, const Point3d& ptStart, const Vector3d& vtStart,
const Vector3d& vtTool, bool bInvert, const ICurveComposite* pCompo, bool bSplitArcs) ;
const Vector3d& vtTool, double dStElev, bool bInvert, const ICurveComposite* pCompo, bool bSplitArcs) ;
bool CalcLeadOutEnd( const Point3d& ptEnd, const Vector3d& vtEnd, const Vector3d& vtTool,
double dEndElev, bool bInvert, const ICurveComposite* pCompo, Point3d& ptP1) const ;
bool AddLeadOut( const Point3d& ptEnd, const Vector3d& vtEnd, const Vector3d& vtTool, double dEndElev,
bool bInvert, const ICurveComposite* pCompo, bool bSplitArcs, Point3d& ptP1) ;
bool bInvert, const ICurveComposite* pCompo, bool bSplitArcs, Point3d& ptP1, Vector3d& vtDir1) ;
bool AdjustOscillParams( const ICurve* pCrv, bool& bPathOscEnable, double& dRampLen, double& dFlatLen) ;
bool AddOscillLine( const ICurveLine* pLine, const Vector3d& vtTool, double dRampLen, double dFlatLen) ;
bool AddOscillArc( const ICurveArc* pArc, const Vector3d& vtTool, double dRampLen, double dFlatLen) ;
@@ -119,11 +124,14 @@ class Milling : public Machining
bool AddTabsLine( const ICurveLine* pLine, const Vector3d& vtTool, const DBLVECTOR& vdTabs, const TabData& tdTabs) ;
bool AddTabsArc( const ICurveArc* pArc, const Vector3d& vtTool, const DBLVECTOR& vdTabs, const TabData& tdTabs) ;
double GetRadiusForStartEndElevation( bool bExtra = true) const ;
bool GetPointOutOfRaw( const Point3d& ptP, const Vector3d& vtTool, const Vector3d& vtCorr, double dElev, double dSafeZ) const ;
bool GetSimplePointOutOfRaw( const Point3d& ptP, const Vector3d& vtTool, const Vector3d& vtRetr) const ;
bool GetPointOutOfRaw( const Point3d& ptP, const Vector3d& vtTool, const Vector3d& vtRetr, double dSafeZ) const ;
bool GetPointAboveRaw( const Point3d& ptP, const Vector3d& vtTool) const ;
bool CalcAndSetCorrAuxDir( const ICurveComposite* pCompo, double dU) ;
Vector3d CalcCorrDir( const ICurveComposite* pCompo, double dU) ;
bool GetPointBelowRaw( const Point3d& ptP, const Vector3d& vtTool) const ;
bool CalcAndSetCorrAuxDir( const ICurveComposite* pCompo, double dU, bool bInvertSide = false, bool bSawSpecial = false) ;
Vector3d CalcCorrDir( const ICurveComposite* pCompo, double dU, bool bInvertSide = false, bool bSawSpecial = false) ;
bool CalcOffset( ICurveComposite* pCompo, double dSignOffs) ;
bool TrimExtendCurveToClosedStm( ICurveComposite* pCompo, int nCstmId, bool bInvert) ;
private :
double GetSpeed() const
@@ -145,7 +153,17 @@ class Milling : public Machining
bool IsLeadInHelixOrZigzag() const
{ int nType = GetLeadInType() ;
return ( nType == MILL_LI_ZIGZAG || nType == MILL_LI_HELIX) ; }
friend class LeadIOStatus ;
bool IsLeadInHelixOrZigzagOrGlide() const
{ int nType = GetLeadInType() ;
return ( nType == MILL_LI_ZIGZAG || nType == MILL_LI_HELIX || nType == MILL_LI_GLIDE) ; }
bool LeadInRawIsOk( void) const
{ if ( ( m_TParams.m_nType & TF_SAWBLADE) != 0)
return false ;
if ( m_TParams.m_nType != TT_MILL_NOTIP)
return true ;
return ( IsLeadInHelixOrZigzag() &&
m_Params.m_dLiTang >= 0.9 * m_TParams.m_dDiam && m_Params.m_dLiElev <= 2) ; }
friend class LeadIOStatus ;
private :
SELVECTOR m_vId ; // identificativi entità geometriche da lavorare
@@ -160,10 +178,15 @@ class Milling : public Machining
double m_dAddedOverlap ; // overlap effettivamente aggiunto a percorso chiuso
int m_nHeadSolCh ; // criterio scelta soluzione impostato nella testa
bool m_bTiltingTab ; // flag utilizzo tavola basculante
Vector3d m_vtTiltingAx ; // versore direzione eventuale asse basculante
bool m_bAboveHead ; // flag utilizzo testa da sopra
bool m_bAggrBottom ; // flag utilizzo di aggregato da sotto
Vector3d m_vtAggrBottom ; // vettore direzione ausiliaria aggregato da sotto
AggrBottom m_AggrBottom ; // dati eventuale aggregato da sotto
double m_dCurrOscillLen ; // lunghezza corrente lungo il percorso per l'oscillazione
double m_dCurrTabsLen ; // lunghezza corrente lungo il percorso per tabs
bool m_bStartOutRaw ; // flag forzatura inizio fuori dal grezzo
bool m_bEndOutRaw ; // flag forzatura fine fuori dal grezzo
Vector3d m_vtStartDir ; // direzione iniziale del percorso in elaborazione
Vector3d m_vtEndDir ; // direzione finale del percorso in elaborazione
} ;
MillingData.h
+6 -2
View File
@@ -110,6 +110,10 @@ struct MillingData : public MachiningData
//----------------------------------------------------------------------------
inline const MillingData* GetMillingData( const MachiningData* pMdata)
{ return (dynamic_cast<const MillingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_MILLING)
return nullptr ;
return ( static_cast<const MillingData*>( pMdata)) ; }
inline MillingData* GetMillingData( MachiningData* pMdata)
{ return (dynamic_cast<MillingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_MILLING)
return nullptr ;
return ( static_cast<MillingData*>( pMdata)) ; }
Mortising.cpp
+34 -11
View File
@@ -634,6 +634,9 @@ Mortising::Update( bool bPostApply)
return true ;
}
// elimino le entità CLIMB, RISE e HOME della lavorazione, potrebbero falsare i calcoli degli assi (in ogni casi vengono riaggiunte dopo)
RemoveClimbRiseHome() ;
// imposto eventuale asse bloccato da lavorazione
SetBlockedRotAxis( m_Params.m_sBlockedAxis) ;
@@ -641,7 +644,7 @@ Mortising::Update( bool bPostApply)
string sHint = ExtractHint( m_Params.m_sUserNotes) ;
if ( ! m_Params.m_sInitAngs.empty())
sHint = m_Params.m_sInitAngs ;
if ( ! CalculateAxesValues( sHint, true)) {
if ( ! CalculateAxesValues( sHint, true, true)) {
string sInfo = m_pMchMgr->GetOutstrokeInfo() ;
if ( sInfo.empty())
m_pMchMgr->SetLastError( 2507, "Error in Mortising : axes values not calculable") ;
@@ -816,11 +819,31 @@ Mortising::UpdateToolData( bool* pbChanged)
const ToolData* pTdata = pTMgr->GetTool( m_Params.m_ToolUuid) ;
if ( pTdata == nullptr)
return false ;
// verifico se sono diversi (ad esclusione del nome)
m_TParams.m_sName = pTdata->m_sName ;
bool bChanged = ! SameTool( m_TParams, *pTdata) ;
// salvo posizione TC, testa e uscita originali
string sOrigTcPos = m_TParams.m_sTcPos ;
string sOrigHead = m_TParams.m_sHead ;
int nOrigExit = m_TParams.m_nExit ;
// verifico se sono diversi (ad esclusione di nome, posizione TC, testa e uscita)
bool bChanged = ( ! SameTool( m_TParams, *pTdata, false)) ;
// aggiorno comunque i parametri
m_TParams = *pTdata ;
// se definito attrezzaggio, aggiorno i parametri che ne possono derivare
string sTcPos ; string sHead ; int nExit ;
if ( m_pMchMgr->GetCurrSetupMgr().GetToolData( m_TParams.m_sName, sTcPos, sHead, nExit)) {
if ( sOrigTcPos != sTcPos ||
sOrigHead != sHead ||
nOrigExit != nExit)
bChanged = true ;
m_TParams.m_sTcPos = sTcPos ;
m_TParams.m_sHead = sHead ;
m_TParams.m_nExit = nExit ;
}
else {
if ( sOrigTcPos != pTdata->m_sTcPos ||
sOrigHead != pTdata->m_sHead ||
nOrigExit != pTdata->m_nExit)
bChanged = true ;
}
// eventuali segnalazioni
if ( ! EqualNoCase( m_Params.m_sToolName, m_TParams.m_sName)) {
string sInfo = "Warning in Mortising : tool name changed (" +
@@ -993,7 +1016,7 @@ Mortising::GetCurve( SelData Id)
else
nToolDir = TOOL_PAR_SLANT ;
int nFaceUse = ( m_Params.m_nFaceUse & 31) ;
AdjustCurveFromSurf( pCrvCompo, nToolDir, nFaceUse, m_TParams.m_dThick, 2) ;
AdjustCurveFromSurf( pCrvCompo, nToolDir, nFaceUse, V_NULL, m_TParams.m_dThick, 2) ;
// la restituisco
return Release( pCrvCompo) ;
}
@@ -1534,11 +1557,11 @@ Mortising::GenerateOnePlungeCl( const Point3d& ptStart, const Point3d& ptEnd, co
double dDelta = dElev - dDepth ;
// determino se l'inizio dell'attacco è esattamente sotto il grezzo, nel qual caso ricalcolo l'elevazione
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() + m_pMchMgr->GetDeltaSafeZ( m_TParams.m_sHead) ;
double dSafeZ = GetSafeZ() + GetDeltaSafeZ( vtTool) ;
double dStartElev = 0 ;
Point3d ptLi = ( nPlunge != MORTISE_PLUNGE_END ? ptStart : ptEnd) + vtTool * dDelta ;
bool bUnderStart = GetPointUnderRaw( ptLi, vtTool, 0,
GetRadiusForStartEndElevation(), m_TParams.m_dLen, false, dSafeZ, vtTool, dStartElev) ;
bool bUnderStart = GetAhPointUnderRaw( ptLi, vtTool, 0,
GetRadiusForStartEndElevation(), m_TParams.m_dLen, false, dSafeZ, vtTool, dStartElev) ;
// altrimenti ridetermino elevazione su inizio percorso di lavoro
if ( ! bUnderStart)
GetElevation( m_nPhase, ptLi, vtTool, GetRadiusForStartEndElevation(), vtTool, dStartElev) ;
@@ -1547,7 +1570,7 @@ Mortising::GenerateOnePlungeCl( const Point3d& ptStart, const Point3d& ptEnd, co
int nFirstFlag = ( bFirst ? 1 : 0) ;
SetFlag( nFirstFlag) ;
Point3d ptP1 = ( nPlunge != MORTISE_PLUNGE_END ? ptStart : ptEnd) + vtTool * ( dDelta + dStartElev + dSafeZ) ;
int nStart = ( bFirst ? AddRapidStart( ptP1) : AddRapidMove( ptP1)) ;
int nStart = AddRapidStartOrMove( ptP1, bFirst) ;
if ( nStart == GDB_ID_NULL)
return false ;
SetFlag( 0) ;
@@ -1643,8 +1666,8 @@ Mortising::GenerateOnePlungeCl( const Point3d& ptStart, const Point3d& ptEnd, co
// determino se la fine dell'uscita è esattamente sotto il grezzo, nel qual caso ricalcolo l'elevazione
double dEndElev = 0 ;
Point3d ptLo = ptLast + vtTool * dDelta ;
bool bUnderEnd = GetPointUnderRaw( ptLo, vtTool, 0,
GetRadiusForStartEndElevation(), m_TParams.m_dLen, false, dSafeZ, vtTool, dEndElev) ;
bool bUnderEnd = GetAhPointUnderRaw( ptLo, vtTool, 0,
GetRadiusForStartEndElevation(), m_TParams.m_dLen, false, dSafeZ, vtTool, dEndElev) ;
// altrimenti ridetermino elevazione su fine percorso di lavoro
if ( ! bUnderEnd)
GetElevation( m_nPhase, ptLo, vtTool, GetRadiusForStartEndElevation(), vtTool, dEndElev) ;
MortisingData.h
+6 -2
View File
@@ -77,6 +77,10 @@ struct MortisingData : public MachiningData
//----------------------------------------------------------------------------
inline const MortisingData* GetMortisingData( const MachiningData* pMdata)
{ return (dynamic_cast<const MortisingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_MORTISING)
return nullptr ;
return ( static_cast<const MortisingData*>( pMdata)) ; }
inline MortisingData* GetMortisingData( MachiningData* pMdata)
{ return (dynamic_cast<MortisingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_MORTISING)
return nullptr ;
return ( static_cast<MortisingData*>( pMdata)) ; }
Operation.cpp
+1932 -706
View File
File diff suppressed because it is too large Load Diff
Operation.h
+126 -16
View File
@@ -14,14 +14,15 @@
#pragma once
#include "MachMgr.h"
#include "MachConst.h"
#include "MachineStruConst.h"
#include "CamData.h"
#include "/EgtDev/Include/EGkPoint3d.h"
#include "/EgtDev/Include/EGkUserObj.h"
#include "/EgtDev/Include/EGkSelection.h"
#include "/EgtDev/Include/EgtNumCollection.h"
class MachMgr ;
class CamData ;
class ICurve ;
class ICurveComposite ;
@@ -43,7 +44,7 @@ class Operation : public IUserObj
virtual int GetPhase( void) const
{ return m_nPhase ; }
virtual bool RemoveHome( void) ;
std::string GetName( void) const ;
std::string GetName( void) const ;
public :
virtual int GetType( void) const = 0 ;
@@ -61,6 +62,54 @@ class Operation : public IUserObj
{ return true ; }
virtual bool AdjustArcCenterForAxesCalc( const CamData* pCamData, Point3d& ptCen) const
{ return true ; }
virtual bool NeedSplit( bool bSplit = true, bool bFeed = true) const
{ return ( bSplit && ( m_pMchMgr == nullptr || m_pMchMgr->GetCurrIsRobot())) ; }
virtual double GetMaxSplitLen( bool bSplit = true, bool bFeed = true) const
{ return ( bSplit && ( m_pMchMgr == nullptr || m_pMchMgr->GetCurrIsRobot()) ? ( bFeed ? 5 : 50) : 0) ; }
virtual double GetSafeZ( void) const
{ if ( m_pMchMgr == nullptr || m_pMchMgr->GetCurrMachiningsMgr() == nullptr)
return 100 ; // MF_CURR_SAFEZ in MachiningsMgr
return m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ; }
virtual double GetSafeAggrBottZ( void) const
{ if ( m_pMchMgr == nullptr || m_pMchMgr->GetCurrMachiningsMgr() == nullptr)
return 10 ; // MF_CURR_SAFEAGGRBOTTZ in MachiningsMgr
return m_pMchMgr->GetCurrMachiningsMgr()->GetSafeAggrBottZ() ; }
virtual double GetExtraLOnCutRegion( void) const
{ if ( m_pMchMgr == nullptr || m_pMchMgr->GetCurrMachiningsMgr() == nullptr)
return 0 ; // MF_CURR_EXTRALCR in MachiningsMgr
return m_pMchMgr->GetCurrMachiningsMgr()->GetExtraLOnCutRegion() ; }
virtual double GetExtraROnDrillRegion( void) const
{ if ( m_pMchMgr == nullptr || m_pMchMgr->GetCurrMachiningsMgr() == nullptr)
return 0 ; // MF_CURR_EXTRARDR in MachiningsMgr
return m_pMchMgr->GetCurrMachiningsMgr()->GetExtraROnDrillRegion() ; }
virtual double GetHoleDiamToler( void) const
{ if ( m_pMchMgr == nullptr || m_pMchMgr->GetCurrMachiningsMgr() == nullptr)
return 10 * EPS_SMALL ; // MF_CURR_HOLEDTOL in MachiningsMgr
return m_pMchMgr->GetCurrMachiningsMgr()->GetHoleDiamToler() ; }
virtual double GetExtSawArcMinRad( void) const
{ if ( m_pMchMgr == nullptr || m_pMchMgr->GetCurrMachiningsMgr() == nullptr)
return 200 ; // MF_CURR_EXTSAWARCMINRAD in MachiningsMgr
return m_pMchMgr->GetCurrMachiningsMgr()->GetExtSawArcMinRad() ; }
virtual double GetIntSawArcMaxSideAng( void) const
{ if ( m_pMchMgr == nullptr || m_pMchMgr->GetCurrMachiningsMgr() == nullptr)
return 45 ; // MF_CURR_INTSAWARCMAXSIDEANG in MachiningsMgr
return m_pMchMgr->GetCurrMachiningsMgr()->GetIntSawArcMaxSideAng() ; }
virtual bool GetSplitArcs( const Vector3d& vtTool) const
{ if ( m_pMchMgr == nullptr || m_pMchMgr->GetCurrIsRobot() ||
m_pMchMgr->GetCurrMachiningsMgr() == nullptr)
return true ;
int nSplitArcs = m_pMchMgr->GetCurrMachiningsMgr()->GetSplitArcs() ;
return ( nSplitArcs == SPLAR_ALWAYS ||
( nSplitArcs == SPLAR_NO_XY_PLANE && ! vtTool.IsZplus()) ||
( nSplitArcs == SPLAR_GEN_PLANE && vtTool.IsGeneric())) ; }
virtual double GetApproxLinTol( void) const
{ if ( m_pMchMgr == nullptr || m_pMchMgr->GetCurrMachiningsMgr() == nullptr)
return 50 * EPS_SMALL ; // MF_APPROX_LINTOL in MachiningsMgr
return m_pMchMgr->GetCurrMachiningsMgr()->GetApproxLinTol() ; }
virtual double GetMaxDepthSafe( void) const
{ if ( m_pMchMgr == nullptr || m_pMchMgr->GetCurrMachiningsMgr() == nullptr)
return 2 ; // MF_CURR_MAXDEPTHSAFE in MachiningsMgr
return m_pMchMgr->GetCurrMachiningsMgr()->GetMaxDepthSafe() ; }
protected :
Operation( void) ;
@@ -71,15 +120,28 @@ class Operation : public IUserObj
const Vector3d& vtDir, double& dElev) const ;
bool GetElevation( int nPhase, const Point3d& ptP,
const Vector3d& vtDir, double& dElev, Vector3d& vtNorm) const ;
bool GetElevation( int nPhase, const Point3d& ptP,
const Vector3d& vtDir, double& dElev, INTVECTOR& vRawStmId) const ;
bool GetElevation( int nPhase, const Point3d& ptP,
const Vector3d& vtDir, double& dElev, Vector3d& vtNorm, INTVECTOR& vRawStmId) const ;
bool GetElevation( int nPhase, const Point3d& ptP1, const Point3d& ptP2,
const Vector3d& vtDir, double& dElev) const ;
bool GetElevation( int nPhase, const Point3d& ptP1, const Point3d& ptP2, const Point3d& ptP3,
const Vector3d& vtDir, double& dElev) const ;
bool GetElevation( int nPhase, const Point3d& ptP, const Vector3d& vtTool, double dRad,
const Vector3d& vtDir, double& dElev) const ;
bool GetPointUnderRaw( const Point3d& ptP, const Vector3d& vtTool, double dToolRad, double dToolRadForElev,
double dToolLen, bool bIsSaw, double dSafeZ, const Vector3d& vtDir, double& dElev) const ;
bool GetElevation( int nPhase, const Point3d& ptP, const Vector3d& vtTool, double dRad, double dLen,
const Vector3d& vtDir, double& dElev) const ;
bool GetElevation( int nPhase, const Point3d& ptP, const Vector3d& vtTool, double dRad, double dLen, double dSafeDist,
const Vector3d& vtDir, double& dElev) const ;
bool GetElevation( int nPhase, const Point3d& ptS, const Point3d& ptE, const Vector3d& vtTool, double dRad, double dLen,
const Vector3d& vtDir, double& dElev) const ;
bool GetAhPointUnderRaw( const Point3d& ptP, const Vector3d& vtTool, double dToolRad, double dToolRadForElev,
double dToolLen, bool bIsSaw, double dSafeZ, const Vector3d& vtDir, double& dElev) const ;
bool GetUhPointAboveRaw( const Point3d& ptP, const Vector3d& vtTool, double dToolRad, double dToolRadForElev,
double dToolLen, bool bIsSaw, double dSafeZ, const Vector3d& vtDir, double& dElev) const ;
bool GetDistanceFromRawSide( int nPhase, const Point3d& ptP, const Vector3d& vtDir, double& dDist) const ;
bool GetAggrBottDistanceFromRawSide( int nPhase, const Point3d& ptP, const Vector3d& vtDir, double dEncSafeH, double& dDist) const ;
bool GetMinDistanceFromRawSide( int nPhase, const Point3d& ptP, double dExpand,
double& dDist, Vector3d& vtDir) const ;
bool GetMinDistanceFromRawSide( int nPhase, const Point3d& ptP, double dExpand,
@@ -89,18 +151,21 @@ class Operation : public IUserObj
{ double dDummy ;
return GetDistanceFromRawBottom( nPhase, nPathId, dToler, dRbDist, dDummy) ; }
bool GetDistanceFromRawBottom( int nPhase, int nPathId, double dToler, double& dRbDist, double& dAllRbDist) const ;
bool GetDistanceFromRawBottom( int nPhase, BBox3d& b3Test, double dToler, double& dRbDist, double& dAllRbDist) const;
bool GetRawGlobBox( int nPhase, int nPathId, double dToler, BBox3d& b3Raw) const ;
bool GetRawGlobBox( int nPhase, const BBox3d& b3Test, double dToler, BBox3d& b3Raw) const ;
bool GetCurrRawsGlobBox( BBox3d& b3Raw) const ;
bool AdjustCurveFromSurf( ICurveComposite* pCrvCompo, int nToolDir, int nFaceUse, double dToolThick, int nGrade = 3) ;
bool AdjustCurveFromSurf( ICurveComposite* pCrvCompo, int nToolDir, int nFaceUse, const Vector3d& vtFaceUse,
double dToolThick, int nGrade = 3) ;
bool ApproxWithArcsIfUseful( ICurveComposite* pCompo, bool bCareTempProp = false) const ;
bool ApproxWithLines( ICurveComposite* pCompo) const ;
bool ApproxWithLines( ICurveComposite* pCompo, bool bFeed = true) const ;
bool VerifyArcs( ICurveComposite* pCompo, double dMaxAngCen = MAX_ANG_CEN) const ;
bool CalcAndSetBBox( int nClId) ;
bool CalcAndSetAxesBBox( void) ;
bool CalcMirrorByDouble( int nClId, const std::string& sUserNotes) ;
bool GetInitialAxesValues( bool bSkipClimb, DBLVECTOR& vAxVal) const ;
bool GetClPathInitialAxesValues( int nClPathId, bool bSkipClimb, DBLVECTOR& vAxVal) const ;
bool GetFinalAxesValues( bool bSkipRise, DBLVECTOR& vAxVal) const ;
@@ -116,9 +181,22 @@ class Operation : public IUserObj
std::string ExtractInfo( const std::string& sNotes, const std::string& sKey) const ;
std::string ExtractHint( const std::string& sNotes) const ;
bool SetBlockedRotAxis( const std::string& sBlockedAxis) const ;
bool CalculateAxesValues( const std::string& sHint, bool bSolChExact = false) ;
bool CalculateClPathAxesValues( int nClPathId, int nLinAxes, int nRotAxes, double dRot1W, bool bMaxDeltaR2OnFirst,
double dAngDeltaMinForHome, const DBLVECTOR& vAxRotHome, DBLVECTOR& vAxRotPrec, int& nOutStrC) ;
bool CalculateAxesValues( const std::string& sHint, bool bRotContOnNext = true, bool bSolChExact = false) ;
bool CalculateClPathCenterAxesValues( int nClPathId, int nLinAxes, int nRotAxes, double dRot1W,
bool bMaxDeltaR2OnFirst, bool bRotContOnNext, double dAngDeltaMinForHome,
const DBLVECTOR& vAxRotHome, DBLVECTOR& vAxRotPrec) ;
bool CalculateClPathAxesValues( int nClPathId, int nLinAxes, int nRotAxes, double dRot1W,
bool bMaxDeltaR2OnFirst, bool bRotContOnNext, double dAngDeltaMinForHome,
const DBLVECTOR& vAxRotHome, DBLVECTOR& vAxRotPrec, int& nOutStrC) ;
bool CalculateRotAxesValues( bool bFirst, const Vector3d& vtTool, const Vector3d& vtAux,
double dRot1W, bool bMaxDeltaR2OnFirst, bool bRotContOnNext, double dAngDeltaMinForHome,
const DBLVECTOR& vAxRotHome, const DBLVECTOR& vAxRotPrec, DBLVECTOR& vAxRot) ;
bool VerifyLineMidPoint( const Point3d& ptPrec, const Vector3d& vtDirPrec, const Vector3d& vtAuxPrec, const Vector3d& vtCorrPrec, const DBLVECTOR& vAxPrec,
const Point3d& ptP, const Vector3d& vtDir, const Vector3d& vtAux, const Vector3d& vtCorr, const DBLVECTOR& vAxVal,
int nCnt, int nEntId, double dRot1W, int nMoveType, bool& bAdded, bool& bAxError) ;
bool CalculateClPathRobotAxesValues( int nClPathId, int nLinAxes, int nRotAxes, double dRot1W,
bool bMaxDeltaR2OnFirst, bool bRotContOnNext, double dAngDeltaMinForHome,
const DBLVECTOR& vAxRotHome, DBLVECTOR& vAxRotPrec) ;
bool AdjustStartEndMovements( bool bVerifyPreviousLink = true) ;
bool AdjustOneStartMovement( int nClPathId, int nPrevClPathId, Operation* pPrevOp, const DBLVECTOR& vAxPrev, bool bMaxZ) ;
bool ToolChangeNeeded( const Operation& Op1, const Operation& Op2) const ;
@@ -127,22 +205,35 @@ class Operation : public IUserObj
bool AddSpecialRise( const DBLVECTOR& vAxVal, bool bOk = true, int nClPathId = GDB_ID_NULL, int nFlag = 0) ;
bool RemoveRise( int nClPathId = GDB_ID_NULL) ;
bool AddHome( void) ;
bool RemoveClimbRiseHome( void) ;
bool AddRobotClimb( int nEntId, double dDeltaZ) ;
bool CalcRobotAxesAbovePos( const Point3d& ptP, const Vector3d& vtT, const Vector3d& vtA, double dDeltaZ,
DBLVECTOR& vAx, double* pdNewDeltaZ = nullptr) const ;
bool CalcDeltaZForHeadRotation( const DBLVECTOR& vAxStart, const DBLVECTOR& vAxEnd, double& dDeltaZ) const ;
bool GetExtraZ( const DBLVECTOR& vAx1, const Vector3d& vtTool1,
const DBLVECTOR& vAx2, const Vector3d& vtTool2,
double dSafeZ, double& dExtraZ) const ;
double dHomeZ, double& dExtraZ) const ;
bool SpecialGetMaxZ( const DBLVECTOR& vAx1, const Vector3d& vtTool1,
const DBLVECTOR& vAx2, const Vector3d& vtTool2,
double& dMaxZ) const ;
bool GetRotationAtZmax( void) const ;
bool ForcedZmax( const DBLVECTOR& vAxStart, const DBLVECTOR& vAxEnd) const ;
bool ForcedZmax( const DBLVECTOR& vAxStart, const DBLVECTOR& vAxEnd, const BBox3d& b3Raws) const ;
int GetUserNotesZmax( void) const ;
double GetDeltaSafeZ( const Vector3d& vtTool) const ;
bool GetZHomeDown( void) const ;
bool TestCollisionAvoid( const DBLVECTOR& vAxStart, const DBLVECTOR& vAxEnd) const ;
bool SpecialMoveZup( DBLVECTOR& vAx, Vector3d& vtTool, int& nFlag, int& nFlag2, bool& bModif) ;
int SpecialTestCollisionAvoid( const DBLVECTOR& vAxStart, const DBLVECTOR& vAxEnd) const ;
bool SpecialMoveZup( DBLVECTOR& vAx, Vector3d& vtTool, int& nFlag, int& nFlag2, bool& bModif) ;
bool SpecialMoveRapid( const DBLVECTOR& vAxStart, const DBLVECTOR& vAxEnd, DBLVECTOR& vAxNew, bool& bModif) ;
bool GetAggrBottomData( const std::string& sHead, AggrBottom& agbData) const ;
bool IsAggrBottom( const std::string& sHead) const ;
private :
bool GetAxisMidForTestCollisionAvoid( const DBLVECTOR& vAxStart, const DBLVECTOR& vAxEnd, int nAxisOrder, Machine* pMch,
DBLVECTOR& vAxMid) const ;
bool OneMoveTestCollisionAvoid( const STRVECTOR& vAxName, const DBLVECTOR& vAxStart, const DBLVECTOR& vAxEnd,
Machine* pMch, const INTVECTOR& vRawId, const INTVECTOR& vFxtId) const ;
protected :
int m_nOwnerId ; // identificativo dell'oggetto geometrico possessore
@@ -158,6 +249,7 @@ class Operation : public IUserObj
bool SetCorrAuxDir( const Vector3d& vtDir) ;
bool SetFeed( double dFeed) ;
bool SetFlag( int nFlag) ;
bool SetFlagOnLastMove( int nFlag) ;
bool SetFlag2( int nFlag2) ;
bool SetIndex( int nIndex) ;
bool GetCurrPos( Point3d& ptCurr) const
@@ -172,12 +264,26 @@ class Operation : public IUserObj
int AddRapidStart( const Point3d& ptP, const std::string& sName) ;
int AddRapidMove( const Point3d& ptP) ;
int AddRapidMove( const Point3d& ptP, const std::string& sName) ;
int AddRapidMove( const Point3d& ptP, bool bSplit) ;
int AddRapidMove( const Point3d& ptP, bool bSplit, const std::string& sName) ;
int AddRapidStartOrMove( const Point3d& ptP, bool bFirst)
{ return ( bFirst ? AddRapidStart( ptP) : AddRapidMove( ptP)) ; }
int AddRapidStartOrMove( const Point3d& ptP, bool bFirst, const std::string& sName)
{ return ( bFirst ? AddRapidStart( ptP, sName) : AddRapidMove( ptP, sName)) ; }
int AddRapidStartOrMove( const Point3d& ptP, bool bFirst, bool bSplit)
{ return ( bFirst ? AddRapidStart( ptP) : AddRapidMove( ptP, bSplit)) ; }
int AddRapidStartOrMove( const Point3d& ptP, bool bFirst, bool bSplit, const std::string& sName)
{ return ( bFirst ? AddRapidStart( ptP, sName) : AddRapidMove( ptP, bSplit, sName)) ; }
int AddLinearMove( const Point3d& ptP) ;
int AddLinearMove( const Point3d& ptP, const std::string& sName) ;
int AddLinearMove( const Point3d& ptP, bool bSplit) ;
int AddLinearMove( const Point3d& ptP, bool bSplit, const std::string& sName) ;
int AddArcMove( const Point3d& ptP, const Point3d& ptCen, double dAngCen, const Vector3d& vtN) ;
int AddArcMove( const Point3d& ptP, const Point3d& ptCen, double dAngCen, const Vector3d& vtN, const std::string& sName) ;
int AddCurveMove( const ICurve* pCrv, bool bOnlySimple = false) ;
int AddCurveMove( const ICurve* pCrv, const std::string& sName, bool bOnlySimple = false) ;
int AddCurveMove( const ICurve* pCrv) ;
int AddCurveMove( const ICurve* pCrv, const std::string& sName) ;
int AddCurveMove( const ICurve* pCrv, bool bSplit) ;
int AddCurveMove( const ICurve* pCrv, bool bSplit, const std::string& sName) ;
bool ResetMoveData( void) ;
protected :
@@ -203,4 +309,8 @@ inline Operation* GetOperation( IUserObj* pUserObj)
// tipo posizione utensile
enum { TOOL_PARAL = 1, TOOL_ORTHO = 2, TOOL_ORTUP = 3, TOOL_PAR_SLANT= 4} ;
// tipo di utilizzo contorno faccia
enum { FACE_DOWN = 1, FACE_TOP = 2, FACE_FRONT = 3, FACE_BACK = 4, FACE_LEFT = 5, FACE_RIGHT = 6, FACE_CONT = 7} ;
enum { FACE_DOWN = 1, FACE_TOP = 2, FACE_FRONT = 3, FACE_BACK = 4, FACE_LEFT = 5, FACE_RIGHT = 6, FACE_CONT = 7, FACE_VERSOR = 8} ;
// risultato di SpecialTestCollisionAvoid
enum { SCAV_ERROR = -1, SCAV_COLLIDE = 0, SCAV_AVOID = 1, SCAV_TOTEST = 2} ;
// ordine di movimento assi nei link
enum { LKAO_INTERP = 0, LKAO_HEAD_BEFORE = -1, LKAO_HEAD_AFTER = +1, LKAO_HEAD_BOTH = 11} ;
OperationCL.cpp
+123 -6
View File
@@ -82,6 +82,18 @@ Operation::SetFlag( int nFlag)
return true ;
}
//----------------------------------------------------------------------------
bool
Operation::SetFlagOnLastMove( int nFlag)
{
int nLastEntId = m_pGeomDB->GetLastInGroup( m_nPathId) ;
CamData* pCamData = GetCamData( m_pGeomDB->GetUserObj( nLastEntId)) ;
if ( pCamData == nullptr)
return false ;
pCamData->SetFlag( nFlag) ;
return true ;
}
//----------------------------------------------------------------------------
bool
Operation::SetFlag2( int nFlag2)
@@ -200,6 +212,46 @@ Operation::AddRapidMove( const Point3d& ptP, const string& sName)
return nId ;
}
//----------------------------------------------------------------------------
int
Operation::AddRapidMove( const Point3d& ptP, bool bSplit)
{
// se non richiesta spezzatura con massima lunghezza, emissione normale
if ( ! NeedSplit( bSplit))
return AddRapidMove( ptP) ;
// altrimenti opportuna spezzatura
Point3d ptS ;
if ( ! GetCurrPos( ptS))
return GDB_ID_NULL ;
double dLen = Dist( ptS, ptP) ;
double dStep = GetMaxSplitLen( true, false) ;
int nStep = int( dLen / dStep + 0.999) ;
int nFirstId = GDB_ID_NULL ;
for ( int i = 1 ; i <= nStep ; ++ i) {
int nId = AddRapidMove( Media( ptS, ptP, i * 1.0 / nStep)) ;
if ( nId == GDB_ID_NULL)
return GDB_ID_NULL ;
if ( nFirstId == GDB_ID_NULL)
nFirstId = nId ;
SetFlag( 0) ;
SetFlag2( 0) ;
}
return nFirstId ;
}
//----------------------------------------------------------------------------
int
Operation::AddRapidMove( const Point3d& ptP, bool bSplit, const string& sName)
{
int nFirstId = AddRapidMove( ptP, bSplit) ;
int nId = nFirstId ;
while ( nId != GDB_ID_NULL) {
m_pGeomDB->SetName( nId, sName) ;
nId = m_pGeomDB->GetNext( nId) ;
}
return nFirstId ;
}
//----------------------------------------------------------------------------
int
Operation::AddLinearMove( const Point3d& ptP)
@@ -258,6 +310,44 @@ Operation::AddLinearMove( const Point3d& ptP, const string& sName)
return nId ;
}
//----------------------------------------------------------------------------
int
Operation::AddLinearMove( const Point3d& ptP, bool bSplit)
{
// se non richiesta spezzatura con massima lunghezza, emissione normale
if ( ! NeedSplit( bSplit))
return AddLinearMove( ptP) ;
// altrimenti opportuna spezzatura
Point3d ptS ;
if ( ! GetCurrPos( ptS))
return GDB_ID_NULL ;
double dLen = Dist( ptS, ptP) ;
double dStep = GetMaxSplitLen( true, true) ;
int nStep = int( dLen / dStep + 0.999) ;
int nFirstId = GDB_ID_NULL ;
for ( int i = 1 ; i <= nStep ; ++ i) {
int nId = AddLinearMove( Media( ptS, ptP, i * 1.0 / nStep)) ;
if ( nId == GDB_ID_NULL)
return GDB_ID_NULL ;
if ( nFirstId == GDB_ID_NULL)
nFirstId = nId ;
}
return nFirstId ;
}
//----------------------------------------------------------------------------
int
Operation::AddLinearMove( const Point3d& ptP, bool bSplit, const string& sName)
{
int nFirstId = AddLinearMove( ptP, bSplit) ;
int nId = nFirstId ;
while ( nId != GDB_ID_NULL) {
m_pGeomDB->SetName( nId, sName) ;
nId = m_pGeomDB->GetNext( nId) ;
}
return nFirstId ;
}
//----------------------------------------------------------------------------
int
Operation::AddArcMove( const Point3d& ptP, const Point3d& ptCen, double dAngCen, const Vector3d& vtN)
@@ -334,7 +424,7 @@ Operation::AddArcMove( const Point3d& ptP, const Point3d& ptCen, double dAngCen,
//----------------------------------------------------------------------------
int
Operation::AddCurveMove( const ICurve* pCrv, bool bOnlySimple)
Operation::AddCurveMove( const ICurve* pCrv)
{
// verifico che la curva esista
if ( pCrv == nullptr)
@@ -355,8 +445,8 @@ Operation::AddCurveMove( const ICurve* pCrv, bool bOnlySimple)
pArc->GetEndPoint( ptP3) ;
return AddArcMove( ptP3, ptCen, dAngCen, vtN) ;
}
// se ammesse curve composite
else if ( ! bOnlySimple) {
// se arco o curva composita
else if ( pCrv->GetType() == CRV_ARC || pCrv->GetType() == CRV_COMPO) {
// in ogni caso, converto in archi e rette
PtrOwner<ICurveComposite> pCompo( CreateCurveComposite()) ;
if ( ! pCompo->AddCurve( *pCrv))
@@ -395,16 +485,43 @@ Operation::AddCurveMove( const ICurve* pCrv, bool bOnlySimple)
}
return nFirstId ;
}
// altrimenti
// altre curve non ammesse
else
return GDB_ID_NULL ;
}
//----------------------------------------------------------------------------
int
Operation::AddCurveMove( const ICurve* pCrv, const string& sName, bool bOnlySimple)
Operation::AddCurveMove( const ICurve* pCrv, const string& sName)
{
int nFirstId = AddCurveMove( pCrv, bOnlySimple) ;
int nFirstId = AddCurveMove( pCrv) ;
int nId = nFirstId ;
while ( nId != GDB_ID_NULL) {
m_pGeomDB->SetName( nId, sName) ;
nId = m_pGeomDB->GetNext( nId) ;
}
return nFirstId ;
}
//----------------------------------------------------------------------------
int
Operation::AddCurveMove( const ICurve* pCrv, bool bSplit)
{
// se non richiesta spezzatura, emissione normale
if ( ! bSplit)
return AddCurveMove( pCrv) ;
// altrimenti opportuna spezzatura
PtrOwner<ICurveComposite> pCompo ;
if ( ! pCompo.Set( ConvertCurveToComposite( pCrv->Clone())) || ! ApproxWithLines( pCompo))
return false ;
return AddCurveMove( pCompo) ;
}
//----------------------------------------------------------------------------
int
Operation::AddCurveMove( const ICurve* pCrv, bool bSplit, const string& sName)
{
int nFirstId = AddCurveMove( pCrv, bSplit) ;
int nId = nFirstId ;
while ( nId != GDB_ID_NULL) {
m_pGeomDB->SetName( nId, sName) ;
OperationConst.h
+9 -4
View File
@@ -1,7 +1,7 @@
//----------------------------------------------------------------------------
// EgalTech 2017-2019
// EgalTech 2017-2024
//----------------------------------------------------------------------------
// File : OperationConst.h Data : 08.07.19 Versione : 2.1g2
// File : OperationConst.h Data : 22.05.24 Versione : 2.6e5
// Contenuto : Costanti per le operazioni.
//
//
@@ -9,6 +9,7 @@
// Modifiche : 17.08.17 DS Creazione modulo.
// 25.05.19 DS Aggiunte SurfRoughing e SurfFinishing.
// 25.05.19 DS Aggiunta WaterJetting.
// 22.05.24 DS Aggiunta FiveAxisMilling.
//
//----------------------------------------------------------------------------
@@ -32,7 +33,8 @@ static const std::string s_OpeClass[] = {"",
"EMkChiseling",
"EMkSurfRoughing",
"EMkSurfFinishing",
"EMkWaterJetting"} ;
"EMkWaterJetting",
"EMkFiveAxisMilling"} ;
//----------------------------------------------------------------------------
// Dal tipo numerico restituisce la classe della operazione
@@ -53,6 +55,7 @@ GetOperationClass( int nOpeType)
case OPER_SURFROUGHING : return s_OpeClass[11] ;
case OPER_SURFFINISHING : return s_OpeClass[12] ;
case OPER_WATERJETTING : return s_OpeClass[13] ;
case OPER_FIVEAXISMILLING : return s_OpeClass[14] ;
}
return s_OpeClass[0] ;
}
@@ -88,6 +91,8 @@ GetOperationType( const std::string& sOpeClass)
return OPER_SURFFINISHING ;
else if ( sOpeClass == s_OpeClass[13])
return OPER_WATERJETTING ;
else if ( sOpeClass == s_OpeClass[14])
return OPER_FIVEAXISMILLING ;
else
return OPER_NULL ;
}
}
OutputConst.h
+157 -44
View File
@@ -60,6 +60,7 @@ static const std::string GVAR_TOOL = ".TOOL" ; // (string) nome uten
static const std::string GVAR_HEAD = ".HEAD" ; // (string) nome testa
static const std::string GVAR_EXIT = ".EXIT" ; // (int) indice uscita
static const std::string GVAR_TCPOS = ".TCPOS" ; // (string) eventuale posizione utensile nel TC
static const std::string GVAR_TTYPE = ".TTYPE" ; // (int) tipo utensile
static const std::string GVAR_TCOMP = ".TCOMP" ; // (int) numero correttore utensile
static const std::string GVAR_TDIAM = ".TDIAM" ; // (num) diametro utensile
static const std::string GVAR_TTOTDIAM = ".TTOTDIAM" ; // (num) diametro totale utensile
@@ -102,6 +103,9 @@ static const std::string GVAR_R1 = ".R1" ; // (num) valore de
static const std::string GVAR_R2 = ".R2" ; // (num) valore del secondo asse rotante
static const std::string GVAR_R3 = ".R3" ; // (num) valore del terzo asse rotante
static const std::string GVAR_R4 = ".R4" ; // (num) valore del quarto asse rotante
static const std::string GVAR_R5 = ".R5" ; // (num) valore del quinto asse rotante
static const std::string GVAR_R6 = ".R6" ; // (num) valore del sesto asse rotante
static const std::string GVAR_R7 = ".R7" ; // (num) valore del settimo asse rotante
static const std::string GVAR_C1 = ".C1" ; // (num) valore del primo asse lineare per centro arco
static const std::string GVAR_C2 = ".C2" ; // (num) valore del secondo asse lineare per centro arco
static const std::string GVAR_C3 = ".C3" ; // (num) valore del terzo asse lineare per centro arco
@@ -117,6 +121,20 @@ static const std::string GVAR_R1P = ".R1p" ; // (num) valore pr
static const std::string GVAR_R2P = ".R2p" ; // (num) valore precedente del secondo asse rotante
static const std::string GVAR_R3P = ".R3p" ; // (num) valore precedente del terzo asse rotante
static const std::string GVAR_R4P = ".R4p" ; // (num) valore precedente del quarto asse rotante
static const std::string GVAR_R5P = ".R5p" ; // (num) valore precedente del quinto asse rotante
static const std::string GVAR_R6P = ".R6p" ; // (num) valore precedente del sesto asse rotante
static const std::string GVAR_R7P = ".R7p" ; // (num) valore precedente del settimo asse rotante
static const std::string GVAR_MOVESUCC = ".MOVESUCC" ; // (int) tipo del movimento successivo (0,1,2,3)
static const std::string GVAR_L1S = ".L1s" ; // (num) valore successivo del primo asse lineare
static const std::string GVAR_L2S = ".L2s" ; // (num) valore successivo del secondo asse lineare
static const std::string GVAR_L3S = ".L3s" ; // (num) valore successivo del terzo asse lineare
static const std::string GVAR_R1S = ".R1s" ; // (num) valore successivo del primo asse rotante
static const std::string GVAR_R2S = ".R2s" ; // (num) valore successivo del secondo asse rotante
static const std::string GVAR_R3S = ".R3s" ; // (num) valore successivo del terzo asse rotante
static const std::string GVAR_R4S = ".R4s" ; // (num) valore successivo del quarto asse rotante
static const std::string GVAR_R5S = ".R5s" ; // (num) valore successivo del quinto asse rotante
static const std::string GVAR_R6S = ".R6s" ; // (num) valore successivo del sesto asse rotante
static const std::string GVAR_R7S = ".R7s" ; // (num) valore successivo del settimo asse rotante
static const std::string GVAR_L1T = ".L1t" ; // (string) token del primo asse lineare
static const std::string GVAR_L2T = ".L2t" ; // (string) token del secondo asse lineare
static const std::string GVAR_L3T = ".L3t" ; // (string) token del terzo asse lineare
@@ -124,6 +142,9 @@ static const std::string GVAR_R1T = ".R1t" ; // (string) token del
static const std::string GVAR_R2T = ".R2t" ; // (string) token del secondo asse rotante
static const std::string GVAR_R3T = ".R3t" ; // (string) token del terzo asse rotante
static const std::string GVAR_R4T = ".R4t" ; // (string) token del quarto asse rotante
static const std::string GVAR_R5T = ".R5t" ; // (string) token del quinto asse rotante
static const std::string GVAR_R6T = ".R6t" ; // (string) token del sesto asse rotante
static const std::string GVAR_R7T = ".R7t" ; // (string) token del settimo asse rotante
static const std::string GVAR_C1T = ".C1t" ; // (string) token del primo asse lineare per centro arco
static const std::string GVAR_C2T = ".C2t" ; // (string) token del secondo asse lineare per centro arco
static const std::string GVAR_C3T = ".C3t" ; // (string) token del terzo asse lineare per centro arco
@@ -138,6 +159,9 @@ static const std::string GVAR_R1N = ".R1n" ; // (string) nome del
static const std::string GVAR_R2N = ".R2n" ; // (string) nome del secondo asse rotante
static const std::string GVAR_R3N = ".R3n" ; // (string) nome del terzo asse rotante
static const std::string GVAR_R4N = ".R4n" ; // (string) nome del quarto asse rotante
static const std::string GVAR_R5N = ".R5n" ; // (string) nome del quinto asse rotante
static const std::string GVAR_R6N = ".R6n" ; // (string) nome del sesto asse rotante
static const std::string GVAR_R7N = ".R7n" ; // (string) nome del settimo asse rotante
static const std::string GVAR_MASK = ".MASK" ; // (int) mask associato ai movimenti in rapido
static const std::string GVAR_FLAG = ".FLAG" ; // (int) flag associato ad ogni movimento
static const std::string GVAR_FLAG2 = ".FLAG2" ; // (int) secondo flag associato ad ogni movimento
@@ -160,6 +184,7 @@ static const std::string GVAR_SIMUISTAT = ".SIMUISTAT" ; // (num) stato sim
static const std::string GVAR_SAFEDIST = ".SAFEDIST" ; // (num) distanza di sicurezza per verifica di collisione
static const std::string GVAR_SIMVMID = ".SIMVMID" ; // (int) identificativo grezzo Vmill in collisione
static const std::string GVAR_SIMCOBIND = ".SIMCOBIND" ; // (int) indice oggetto in collisione
static const std::string GVAR_MPSIM = ".MPSIM" ; // (bool) flag simulazione multiprocesso
// Funzioni generazione
static const std::string ON_START = "OnStart" ;
static const std::string ON_END = "OnEnd" ;
@@ -205,6 +230,8 @@ static const std::string ON_ESTIM_RAPID = "OnEstimRapid" ;
static const std::string ON_ESTIM_LINEAR = "OnEstimLinear" ;
static const std::string ON_ESTIM_ARC = "OnEstimArc" ;
// Funzioni simulazione
static const std::string ON_SIMUL_INIT = "OnSimulInit" ;
static const std::string ON_SIMUL_EXIT = "OnSimulExit" ;
static const std::string ON_SIMUL_START = "OnSimulStart" ;
static const std::string ON_SIMUL_END = "OnSimulEnd" ;
static const std::string ON_SIMUL_DISPOSITION_STARTING = "OnSimulDispositionStarting" ;
@@ -226,64 +253,150 @@ static const std::string ON_RESET_MACHINE = "OnResetMachine" ;
//----------------------------------------------------------------------------
inline std::string
GetGlobVarAxisValue( int nAx, const std::string& sVar = GLOB_VAR)
GetGlobVarAxisValue( int nAx, const std::string& sVar = GLOB_VAR, bool bIsRobot = false)
{
switch ( nAx) {
case 1 : return ( sVar + GVAR_L1) ;
case 2 : return ( sVar + GVAR_L2) ;
case 3 : return ( sVar + GVAR_L3) ;
case 4 : return ( sVar + GVAR_R1) ;
case 5 : return ( sVar + GVAR_R2) ;
case 6 : return ( sVar + GVAR_R3) ;
case 7 : return ( sVar + GVAR_R4) ;
default : return "" ;
}
if ( ! bIsRobot) {
switch ( nAx) {
case 1 : return ( sVar + GVAR_L1) ;
case 2 : return ( sVar + GVAR_L2) ;
case 3 : return ( sVar + GVAR_L3) ;
case 4 : return ( sVar + GVAR_R1) ;
case 5 : return ( sVar + GVAR_R2) ;
case 6 : return ( sVar + GVAR_R3) ;
case 7 : return ( sVar + GVAR_R4) ;
default : return "" ;
}
}
else {
switch ( nAx) {
case 1 : return ( sVar + GVAR_R1) ;
case 2 : return ( sVar + GVAR_R2) ;
case 3 : return ( sVar + GVAR_R3) ;
case 4 : return ( sVar + GVAR_R4) ;
case 5 : return ( sVar + GVAR_R5) ;
case 6 : return ( sVar + GVAR_R6) ;
case 7 : return ( sVar + GVAR_R7) ;
default : return "" ;
}
}
}
//----------------------------------------------------------------------------
inline std::string
GetGlobVarAxisPrev( int nAx, const std::string& sVar = GLOB_VAR)
GetGlobVarAxisPrev( int nAx, const std::string& sVar = GLOB_VAR, bool bIsRobot = false)
{
switch ( nAx) {
case 1 : return ( sVar + GVAR_L1P) ;
case 2 : return ( sVar + GVAR_L2P) ;
case 3 : return ( sVar + GVAR_L3P) ;
case 4 : return ( sVar + GVAR_R1P) ;
case 5 : return ( sVar + GVAR_R2P) ;
case 6 : return ( sVar + GVAR_R3P) ;
case 7 : return ( sVar + GVAR_R4P) ;
default : return "" ;
}
if ( ! bIsRobot) {
switch ( nAx) {
case 1 : return ( sVar + GVAR_L1P) ;
case 2 : return ( sVar + GVAR_L2P) ;
case 3 : return ( sVar + GVAR_L3P) ;
case 4 : return ( sVar + GVAR_R1P) ;
case 5 : return ( sVar + GVAR_R2P) ;
case 6 : return ( sVar + GVAR_R3P) ;
case 7 : return ( sVar + GVAR_R4P) ;
default : return "" ;
}
}
else {
switch ( nAx) {
case 1 : return ( sVar + GVAR_R1P) ;
case 2 : return ( sVar + GVAR_R2P) ;
case 3 : return ( sVar + GVAR_R3P) ;
case 4 : return ( sVar + GVAR_R4P) ;
case 5 : return ( sVar + GVAR_R5P) ;
case 6 : return ( sVar + GVAR_R6P) ;
case 7 : return ( sVar + GVAR_R7P) ;
default : return "" ;
}
}
}
//----------------------------------------------------------------------------
inline std::string
GetGlobVarAxisToken( int nAx)
GetGlobVarAxisNext( int nAx, const std::string& sVar = GLOB_VAR, bool bIsRobot = false)
{
switch ( nAx) {
case 1 : return ( GLOB_VAR + GVAR_L1T) ;
case 2 : return ( GLOB_VAR + GVAR_L2T) ;
case 3 : return ( GLOB_VAR + GVAR_L3T) ;
case 4 : return ( GLOB_VAR + GVAR_R1T) ;
case 5 : return ( GLOB_VAR + GVAR_R2T) ;
case 6 : return ( GLOB_VAR + GVAR_R3T) ;
case 7 : return ( GLOB_VAR + GVAR_R4T) ;
default : return "" ;
}
if ( ! bIsRobot) {
switch ( nAx) {
case 1 : return ( sVar + GVAR_L1S) ;
case 2 : return ( sVar + GVAR_L2S) ;
case 3 : return ( sVar + GVAR_L3S) ;
case 4 : return ( sVar + GVAR_R1S) ;
case 5 : return ( sVar + GVAR_R2S) ;
case 6 : return ( sVar + GVAR_R3S) ;
case 7 : return ( sVar + GVAR_R4S) ;
default : return "" ;
}
}
else {
switch ( nAx) {
case 1 : return ( sVar + GVAR_R1S) ;
case 2 : return ( sVar + GVAR_R2S) ;
case 3 : return ( sVar + GVAR_R3S) ;
case 4 : return ( sVar + GVAR_R4S) ;
case 5 : return ( sVar + GVAR_R5S) ;
case 6 : return ( sVar + GVAR_R6S) ;
case 7 : return ( sVar + GVAR_R7S) ;
default : return "" ;
}
}
}
//----------------------------------------------------------------------------
inline std::string
GetGlobVarAxisName( int nAx)
GetGlobVarAxisToken( int nAx, bool bIsRobot = false)
{
switch ( nAx) {
case 1 : return ( GLOB_VAR + GVAR_L1N) ;
case 2 : return ( GLOB_VAR + GVAR_L2N) ;
case 3 : return ( GLOB_VAR + GVAR_L3N) ;
case 4 : return ( GLOB_VAR + GVAR_R1N) ;
case 5 : return ( GLOB_VAR + GVAR_R2N) ;
case 6 : return ( GLOB_VAR + GVAR_R3N) ;
case 7 : return ( GLOB_VAR + GVAR_R4N) ;
default : return "" ;
}
if ( ! bIsRobot) {
switch ( nAx) {
case 1 : return ( GLOB_VAR + GVAR_L1T) ;
case 2 : return ( GLOB_VAR + GVAR_L2T) ;
case 3 : return ( GLOB_VAR + GVAR_L3T) ;
case 4 : return ( GLOB_VAR + GVAR_R1T) ;
case 5 : return ( GLOB_VAR + GVAR_R2T) ;
case 6 : return ( GLOB_VAR + GVAR_R3T) ;
case 7 : return ( GLOB_VAR + GVAR_R4T) ;
default : return "" ;
}
}
else {
switch ( nAx) {
case 1 : return ( GLOB_VAR + GVAR_R1T) ;
case 2 : return ( GLOB_VAR + GVAR_R2T) ;
case 3 : return ( GLOB_VAR + GVAR_R3T) ;
case 4 : return ( GLOB_VAR + GVAR_R4T) ;
case 5 : return ( GLOB_VAR + GVAR_R5T) ;
case 6 : return ( GLOB_VAR + GVAR_R6T) ;
case 7 : return ( GLOB_VAR + GVAR_R7T) ;
default : return "" ;
}
}
}
//----------------------------------------------------------------------------
inline std::string
GetGlobVarAxisName( int nAx, bool bIsRobot = false)
{
if ( ! bIsRobot) {
switch ( nAx) {
case 1 : return ( GLOB_VAR + GVAR_L1N) ;
case 2 : return ( GLOB_VAR + GVAR_L2N) ;
case 3 : return ( GLOB_VAR + GVAR_L3N) ;
case 4 : return ( GLOB_VAR + GVAR_R1N) ;
case 5 : return ( GLOB_VAR + GVAR_R2N) ;
case 6 : return ( GLOB_VAR + GVAR_R3N) ;
case 7 : return ( GLOB_VAR + GVAR_R4N) ;
default : return "" ;
}
}
else {
switch ( nAx) {
case 1 : return ( GLOB_VAR + GVAR_R1N) ;
case 2 : return ( GLOB_VAR + GVAR_R2N) ;
case 3 : return ( GLOB_VAR + GVAR_R3N) ;
case 4 : return ( GLOB_VAR + GVAR_R4N) ;
case 5 : return ( GLOB_VAR + GVAR_R5N) ;
case 6 : return ( GLOB_VAR + GVAR_R6N) ;
case 7 : return ( GLOB_VAR + GVAR_R7N) ;
default : return "" ;
}
}
}
Pocketing.cpp
+1906 -4275
View File
File diff suppressed because it is too large Load Diff
Pocketing.h
+43 -67
View File
@@ -19,7 +19,6 @@
#include "/EgtDev/Include/EGkCurveComposite.h"
#include "/EgtDev/Include/EGkCurveLine.h"
#include "/EgtDev/Include/EgtNumUtils.h"
#include "/EgtDev/Include/EGkSurfFlatRegion.h"
//----------------------------------------------------------------------------
class Pocketing : public Machining
@@ -69,64 +68,38 @@ class Pocketing : public Machining
private :
bool VerifyGeometry( SelData Id, int& nSubs, int& nType) ;
bool GetCurves( SelData Id, ICURVEPLIST& lstPC) ;
bool SetCurveAllTempProp( int nCrvId, ICurve* pCurve) ;
bool SetCurveAllTempProp( int nCrvId, bool bForcedClose, ICurve* pCurve, bool* pbSomeOpen = nullptr) ;
bool ResetCurveAllTempProp( ICurve* pCurve) ;
bool Chain( int nGrpDestId) ;
bool ProcessPath( int nPathId, int nPvId, int nClId) ;
bool CalcRegionElevation( const ICurveComposite* pCompo, const Vector3d& vtTool, double dDepth, double dRad, double& dElev) const ;
bool VerifyPathFromBottom( const ISurfFlatRegion* pSrf, const Vector3d& vtTool) ;
bool GeneratePocketingPv( int nPathId, const ISurfFlatRegion* pSrfPock) ;
bool ModifyCurveToSmooted( ICurveComposite* pCrvOffset, double dRightPer, double dleftPer) ;
// ===== ZigZag =====
bool AddZigZag( const ISurfFlatRegion* pSrfPock, const Vector3d& vtTool, const Vector3d& vtExtr, double dDepth, double dElev, double dOkStep,
bool bSplitArcs, int nPathId) ;
bool CalcZigZag( const ISurfFlatRegion* pSrfZigZag, ICRVCOMPOPOVECTOR& vpCrvs) ;
bool CalcBoundedZigZagLink( ICurveLine* pCrv1, ICurveLine* pCrv2, ICRVCOMPOPOVECTOR& vOffIslands, ICurveComposite* pCrvLink, int nIndexCut = 3) ;
bool OptimizedZigZag( ISurfFlatRegion* pSrf, const Vector3d & vtTool, double dDepth, double dSafeZ, Frame3d & frPocket, bool & bOptimizedZigZag,
ICRVCOMPOPOVECTOR & vpCrvs) ;
bool ZigZagOptimizedNoClosedEdges( ICurveComposite* pCrvPocket, bool& bOptimizedZigZag, Vector3d& vtDir) ;
bool ZigZagOptimizedOneClosedEdge( ICurveComposite* pCrvPocket, int nClosedId, bool& bOptimizedZigZag, Vector3d& vtDir) ;
bool CalcRegionElevation( const ICurveComposite* pCompo, const Vector3d& vtTool, double dDepth, double dRad, double dLen, double& dElev) const ;
bool VerifyPathFromBottom( const ICurveComposite* pCompo, const Vector3d& vtTool) ;
bool GeneratePocketingPv( int nPathId, const ICurveComposite* pCompo) ;
bool AddZigZag( const ICurveComposite* pCompo, const Vector3d& vtTool, const Vector3d& vtExtr,
double dDepth, double dElev, double dOkStep, bool bSplitArcs, int nPathId) ;
bool CalcZigZag( const ICurveComposite* pOffs, ICRVCOMPOPOVECTOR& vpCrvs) ;
bool OptimizedZigZag( int nPathId, const Vector3d& vtTool, double dDepth, double dSafeZ,
Frame3d& frPocket, bool& bOptimizedZigZag, ICRVCOMPOPOVECTOR& vpCrvs, double& dOffs) ;
bool ZigZagOptimizedNoClosedEdges( ICurveComposite* pCrvPocket, bool& bOptimizedZigZag, Vector3d& vtDir, double& dOffs) ;
bool ZigZagOptimizedOneClosedEdge( ICurveComposite* pCrvPocket, int nClosedId, bool& bOptimizedZigZag, Vector3d& vtDir, double& dOffs) ;
bool ZigZagOptimizedTwoClosedEdges( ICurveComposite* pCrvPocket, const INTVECTOR& vnClosedIds, bool& bOptimizedZigZag,
bool& bOpposite, Vector3d& vtDir) ;
bool& bOpposite, Vector3d& vtDir, double& dOffs) ;
bool ZigZagOptimizedThreeClosedEdges( ICurveComposite* pCrvPocket, const INTVECTOR& vnClosedIds, bool& bOptimizedZigZag,
bool& bOpposite, Vector3d& vtDir) ;
bool& bOpposite, Vector3d& vtDir, double& dOffs) ;
bool ZigZagOptimizedComputeOffset( ICurveComposite* pCrvPocket, const Vector3d& vtMainDir, int nOffsettedEdgesOnY,
const INTVECTOR& vnClosedIds) ;
const INTVECTOR& vnClosedIds, double& dOffs) ;
bool CutCurveWithLine( ICurveComposite* pCrvA, const ICurveLine* pCrvB) ;
bool GetUnclearedRegion( ICRVCOMPOPOVECTOR& vFirstOffs, ICRVCOMPOPOVECTOR& vCrvs, ICURVEPOVECTOR& vLinks, ISurfFlatRegion* pSrfToCut) ;
// ==================
// ==== OneWay ======
bool AddOneWay( const ISurfFlatRegion* pSrfPock, const Vector3d& vtTool, const Vector3d& vtExtr, double dDepth, double dElev, double dOkStep, bool bSplitArcs) ;
// ==================
// ==== SpiralIn/Out ====
bool AddSpiralIn( const ISurfFlatRegion* pSrfPock, const PNTVECTOR vPtStart, const Vector3d& vtTool, const Vector3d& vtExtr, double dDepth,
double dElev, double dOkStep, bool bSplitArcs, BOOLVECTOR vbMidOpen, PNTVECTOR vPtMidOpen, VCT3DVECTOR vVtMidOut, int nPathId) ;
bool AddSpiralOut( const ISurfFlatRegion* pSrfpock, const PNTVECTOR vPtStart, const Vector3d& vtTool, const Vector3d& vtExtr, double dDepth, double dElev,
double dOkStep, bool bSplitArcs, int nPathId) ;
bool CalcSpiral( const ISurfFlatRegion* pSrfChunk, int nReg, Point3d ptStart, bool bSplitArcs, ICurveComposite* pMCrv, ICurveComposite* pRCrv, int nPathId,
bool& bOptimizedTrap) ;
bool RemoveExtraParts( ISurfFlatRegion* pSrfToCut, ICRVCOMPOPOVECTOR& vOffs, ICRVCOMPOPOVECTOR& vOffsClosedCurves, ICRVCOMPOPOVECTOR& vOffsFirstCurve,
ICURVEPOVECTOR& vLinks) ;
bool RemoveExtraPartByMedialAxis( ISurfFlatRegion* pChunkToCut, ICRVCOMPOPOVECTOR& vOffsFirstCurve, int& nOptFlag, Point3d& ptCentroid,
ICurveComposite* pCrvPath) ;
bool CalcBoundedLink( const Point3d& ptStart, const Point3d& ptEnd, ICRVCOMPOPOVECTOR& vOffIslands, ICurveComposite* pCrvLink) ;
bool CalcBoundedSmootedLink( const Point3d& ptStart, const Vector3d& vtStart, const Point3d& ptEnd, const Vector3d& vtEnd, double dParMeet,
ICRVCOMPOPOVECTOR& vOffIslands, ICurveComposite* pCrvLink) ;
bool ModifyBiArc( ICurve* pCrvBiArc, double dCutToll, ICurveComposite* pNewCrv) ;
bool CutCurveByOffsets( ICurveComposite* pCurve, ICRVCOMPOPOVECTOR& vOffs) ;
bool GetCurveWeightInfo( ICurveComposite* pCrvCompo, double dMaxLen, double& dToTRot, int& nSmallArcs, int& nSmallLines) ;
bool ChoosePath( ICurveComposite* pCrv1, ICurveComposite* pCrv2, int nP, double dPerP, double dMaxLen, int& nC) ;
bool CutCurveToConnect( ICurveComposite* pCrvS, ICurveComposite* pCrvE, ICRVCOMPOPOVECTOR& vOffs, ICRVCOMPOPOVECTOR& vOffIslands,
ICurveComposite* pCrvLink, double dLenPercS = 0.01, double dLenPercE = 0.01, int nMaxIter = 2) ;
bool GetNewCurvetWithCentroid( ICurveComposite* pCrvH1, ICurveComposite* pCrvH2, Point3d& ptC, bool bCir, ICRVCOMPOPOVECTOR& VFirstOff,
ICurveComposite* pCrvNewCurve) ;
bool GetNewCurvetWithPath( ICurveComposite* pCrvH1, ICurveComposite* pCrvH2, ICurveComposite* pCrvPath, ICRVCOMPOPOVECTOR& VFirstOff, ICRVCOMPOPOVECTOR& VoffsCl,
ICurveComposite* pCrvNewCurve) ;
bool ManageSmoothAndAutoInters( ICurveComposite* pCrv, ICurveComposite* pCrvPath, ICurveComposite* pPath1, ICurveComposite* pPath2, ICRVCOMPOPOVECTOR& vOffsCL) ;
bool AddOneWay( const ICurveComposite* pCompo, const Vector3d& vtTool, const Vector3d& vtExtr,
double dDepth, double dElev, double dOkStep, bool bSplitArcs) ;
bool AddSpiralIn( const ICurveComposite* pCompo, const Vector3d& vtTool, const Vector3d& vtExtr,
double dDepth, double dElev, double dOkStep, bool bSplitArcs, bool bMidOpen,
const Point3d& ptMidOpen, const Vector3d& vtMidOut, int nPathId) ;
bool AddSpiralOut( const ICurveComposite* pCompo, const Vector3d& vtTool, const Vector3d& vtExtr,
double dDepth, double dElev, double dOkStep, bool bSplitArcs, int nPathId) ;
bool CalcSpiral( const ICurveComposite* pCompo, int nReg, bool bSplitArcs,
ICurveComposite* pMCrv, ICurveComposite* pRCrv, int nPathId, bool& bOptimizedTrap) ;
bool CalcBoundedLink( const Point3d& ptStart, const Point3d& ptEnd, const ICurve* pCrvBound,
ICurveComposite* pCrvLink) ;
bool CalcBoundedLinkWithBiArcs( const Point3d& ptStart, const Vector3d& vtStart, const Point3d& ptEnd, const Vector3d& vtEnd,
const ICurve* pCrvBound, ICurveComposite* pCrvLink) ;
bool CalcCircleSpiral( const Point3d& ptCen, const Vector3d& vtN, double dOutRad, double dIntRad,
@@ -139,33 +112,35 @@ class Pocketing : public Machining
bool SpecialAdjustTrapezoidSpiralForAngles( ICurveComposite* pMCrv, const ICurveComposite* pCrvPocket) ;
bool AdjustTrapezoidSpiralForLeadInLeadOut( ICurveComposite * pCompo, ICurveComposite * pRCrv, const Vector3d& vtTool,
double dDepth, int& nOutsideRaw) ;
bool ComputeTrapezoidSpiralLeadInLeadOut( ICurveComposite * pCompo, const Vector3d& vtMainDir, bool bLeadIn, const Vector3d& vtTool, double dDepth,
bool& bIsOutsideRaw) ;
// ==================
bool ComputeTrapezoidSpiralLeadInLeadOut( ICurveComposite * pCompo, const Vector3d& vtMainDir, bool bLeadIn, const Vector3d& vtTool, double dDepth, bool& bIsOutsideRaw) ;
bool ComputePolishingPath( ICurveComposite* pMCrv, ICurveComposite* pRCrv, bool bSplitArcs) ;
bool AddEpicycles( ICurveComposite * pCompo, ICurveComposite * pCrv, ICurveComposite * pCrvBound = nullptr) ;
bool AddApproach( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ, double dSafeAggrBottZ,
double dElev, double dAppr, bool bOutStart) ;
double dElev, double dAppr, bool bSplitArcs, bool bOutStart) ;
bool AddLinkApproach( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ, double dSafeAggrBottZ,
double dElev, double dAppr, bool bOutStart = false) ;
double dElev, double dAppr, bool bSplitArcs, bool bOutStart = false) ;
bool AddLinkRetract( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ, double dSafeAggrBottZ,
double dElev, double dAppr) ;
double dElev, double dAppr, bool bSplitArcs) ;
bool AddRetract( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ, double dSafeAggrBottZ,
double dElev, double dAppr) ;
double dElev, double dAppr, bool bSplitArcs) ;
bool CalcLeadInStart( const Point3d& ptStart, const Vector3d& vtStart, const Vector3d& vtN,
const ICurveComposite* pRCrv, Point3d& ptP1) const ;
bool AddLeadIn( const Point3d& ptP1, const Point3d& ptStart, const Vector3d& vtStart, const Vector3d& vtN,
ISurfFlatRegion* pSrfChunk, const ICurveComposite* pRCrv, bool bAtLeft, bool bSplitArcs,
bool AddLeadIn( const Point3d& ptP1, const Point3d& ptStart, const Vector3d& vtStart, const Vector3d& vtN,
const ICurveComposite* pCompo, const ICurveComposite* pRCrv, bool bAtLeft, bool bSplitArcs,
bool bNoneForced = false, bool bSkipControl = false) ;
bool AddLeadOut( const Point3d& ptEnd, const Vector3d& vtEnd, const Vector3d& vtN,
const ICurveComposite* pRCrv, bool bSplitArcs, Point3d& ptP1, double& dElev, bool bNoneForced = false) ;
const ICurveComposite* pRCrv, bool bSplitArcs, bool bNoneForced,
Point3d& ptP1, double& dElev) ;
bool AddLeadOut( const Point3d& ptEnd, const Vector3d& vtEnd, const Vector3d& vtN,
const ICurveComposite* pRCrv, bool bSplitArcs, bool bNoneForced,
Point3d& ptP1, double& dElev, bool& bOppositeHome) ;
double GetRadiusForStartEndElevation( void) const ;
bool GetForcedClosed( void) ;
bool GetMidOfLongestOpenSide( const ICurveComposite* pCompo, Point3d& ptMid, Vector3d& vtMidOut) ;
bool AdjustContourWithOpenEdges( ICurveComposite* pCompo) ;
bool AdjustContourStart( ICurveComposite* pCompo) ;
bool VerifyLeadInHelix( ISurfFlatRegion* pSrfChunk, const Point3d& ptCen, double dRad) const ;
bool VerifyLeadInZigZag( ISurfFlatRegion* pSrfChunk, const Point3d& ptPa, const Point3d& ptPb) const ;
bool VerifyLeadInHelix( const ICurveComposite* pCompo, const Point3d& ptCen, double dRad) const ;
bool VerifyLeadInZigZag( const ICurveComposite* pCompo, const Point3d& ptPa, const Point3d& ptPb) const ;
bool CalcDistanceFromRawSurface( int nPhase, const Point3d& ptP, const Vector3d& vtDir, double& dDist, Vector3d& vtNorm) ;
private :
@@ -191,7 +166,7 @@ class Pocketing : public Machining
if ( m_Params.m_nLeadInType != POCKET_LI_GLIDE && m_Params.m_dLiElev < 10 * EPS_SMALL)
return POCKET_LI_NONE ;
return m_Params.m_nLeadInType ; }
int LeadInIsOk( void) const
bool LeadInRawIsOk( void) const
{ if ( m_TParams.m_nType != TT_MILL_NOTIP)
return true ;
return (( GetLeadInType() == POCKET_LI_ZIGZAG || GetLeadInType() == POCKET_LI_HELIX) &&
@@ -212,10 +187,11 @@ class Pocketing : public Machining
int m_nStatus ; // stato di aggiornamento della lavorazione
int m_nPockets ; // numero di percorsi di svuotatura generati
bool m_bTiltingTab ; // flag utilizzo tavola basculante
Vector3d m_vtTiltingAx ; // versore direzione eventuale asse basculante
bool m_bAboveHead ; // flag utilizzo testa da sopra
bool m_bAggrBottom ; // flag di utilizzo dell'aggregato da sotto
Vector3d m_vtAggrBottom ; // vettore direzione ausiliaria aggregato da sotto
AggrBottom m_AggrBottom ; // dati eventuale aggregato da sotto
bool m_bOpenOutRaw ; // flag forzatura lati aperti sempre fuori dal grezzo
POLYLINEVECTOR m_VplIsland ; // vettore che contiene le curve che descrivono le isole
double m_dOpenMinSafe ; // minima distanza di sicurezza di attacco su lato aperto
} ;
PocketingData.cpp
+2 -1
View File
@@ -397,7 +397,8 @@ bool
PocketingData::VerifySubType( int nVal) const
{
return ( nVal == POCKET_SUB_ZIGZAG || nVal == POCKET_SUB_ONEWAY ||
nVal == POCKET_SUB_SPIRALIN || nVal == POCKET_SUB_SPIRALOUT) ;
nVal == POCKET_SUB_SPIRALIN || nVal == POCKET_SUB_SPIRALOUT ||
nVal == POCKET_SUB_CONFORMAL_ZIGZAG || nVal == POCKET_SUB_CONFORMAL_ONEWAY) ;
}
//----------------------------------------------------------------------------
PocketingData.h
+6 -2
View File
@@ -83,6 +83,10 @@ struct PocketingData : public MachiningData
//----------------------------------------------------------------------------
inline const PocketingData* GetPocketingData( const MachiningData* pMdata)
{ return (dynamic_cast<const PocketingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_POCKETING)
return nullptr ;
return ( static_cast<const PocketingData*>( pMdata)) ; }
inline PocketingData* GetPocketingData( MachiningData* pMdata)
{ return (dynamic_cast<PocketingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_POCKETING)
return nullptr ;
return ( static_cast<PocketingData*>( pMdata)) ; }
Processor.cpp
+89 -24
View File
@@ -84,6 +84,9 @@ Processor::Run( const string& sOutFile, const string& sInfo)
if ( ! VerifySetup())
return false ;
// imposto la fase iniziale come corrente
m_pMchMgr->SetCurrPhase( 1) ;
// evento inizio esecuzione
bool bOk = true ;
if ( ! OnStart()) {
@@ -145,6 +148,9 @@ Processor::Run( const string& sOutFile, const string& sInfo)
LOG_ERROR( GetEMkLogger(), "OnEnd error") ;
}
// imposto la fase iniziale come corrente
m_pMchMgr->SetCurrPhase( 1) ;
return bOk ;
}
@@ -184,8 +190,8 @@ Processor::ProcessDisposition( int nOpId, int nOpInd)
bool bEmpty = pDisp->IsEmpty() ;
bool bSomeByHand = pDisp->GetSomeByHand() ;
// Se disposizione con movimenti macchina
if ( ! pDisp->IsEmpty()) {
// Se disposizione con movimenti autonomi e utensile associato
if ( ! pDisp->IsEmpty() && pDisp->IsWithTool()) {
// Recupero l'utensile della disposizione corrente
string sTool ; string sHead ; int nExit ; string sTcPos ;
if ( ! pDisp->GetToolData( sTool, sHead, nExit, sTcPos))
@@ -408,7 +414,7 @@ Processor::ProcessClPath( int nClPathId, int nClPathInd, int nOpId, int nOpInd)
// processo l'entità
if ( ! ProcessClEnt( nEntId, nEntInd, nClPathId, nClPathInd, nOpId, nOpInd))
bOk = false ;
// passo all'entità successivo
// passo all'entità successiva
nEntId = m_pGeomDB->GetNext( nEntId) ;
}
@@ -443,19 +449,24 @@ Processor::ProcessClEnt( int nEntId, int nEntInd, int nClPathId, int nClPathInd,
if ( pCamData == nullptr || pCamData->GetAxesStatus() != CamData::AS_OK)
return false ;
const DBLVECTOR& AxesEnd = pCamData->GetAxesVal() ;
// Emetto movimento
int nMove = pCamData->GetMoveType() ;
// Recupero i dati Cam del movimento successivo del percorso (se esiste)
CamData* pNextCamData = GetCamData( m_pGeomDB->GetUserObj( m_pGeomDB->GetNext( nEntId))) ;
int nMoveNext = ( pNextCamData != nullptr ? pNextCamData->GetMoveType() : -1) ;
DBLVECTOR AxesNull ;
const DBLVECTOR& AxesNext = ( pNextCamData != nullptr ? pNextCamData->GetAxesVal() : AxesNull) ;
// Emetto movimento
switch ( nMove) {
case 0 : // rapido
if ( ! OnRapid( nEntId, nEntInd, nMove, AxesEnd, pCamData->GetAxesMask(),
pCamData->GetToolDir(), pCamData->GetCorrDir(), pCamData->GetBackAuxDir(),
pCamData->GetFlag(), pCamData->GetFlag2(), pCamData->GetIndex()))
pCamData->GetFlag(), pCamData->GetFlag2(), pCamData->GetIndex(), nMoveNext, AxesNext))
return false ;
break ;
case 1 : // linea
if ( ! OnLinear( nEntId, nEntInd, nMove, AxesEnd,
pCamData->GetToolDir(), pCamData->GetCorrDir(), pCamData->GetBackAuxDir(),
pCamData->GetFeed(), pCamData->GetFlag(), pCamData->GetFlag2(), pCamData->GetIndex()))
pCamData->GetFeed(), pCamData->GetFlag(), pCamData->GetFlag2(), pCamData->GetIndex(), nMoveNext, AxesNext))
return false ;
break ;
case 2 : // arco CW
@@ -465,7 +476,7 @@ Processor::ProcessClEnt( int nEntId, int nEntInd, int nClPathId, int nClPathInd,
if ( ! OnArc( nEntId, nEntInd, nMove, AxesEnd,
pCamData->GetAxesCen(), ptMid, pCamData->GetAxesRad(), pCamData->GetAxesAngCen(),
pCamData->GetToolDir(), pCamData->GetCorrDir(), pCamData->GetBackAuxDir(),
pCamData->GetFeed(), pCamData->GetFlag(), pCamData->GetFlag2(), pCamData->GetIndex()))
pCamData->GetFeed(), pCamData->GetFlag(), pCamData->GetFlag2(), pCamData->GetIndex(), nMoveNext, AxesNext))
return false ;
break ;
}
@@ -515,8 +526,8 @@ bool
Processor::UpdateAxes( void)
{
// Carico i nomi degli assi macchina attivi
return m_pMachine->GetAllCurrAxesName( m_AxesName) &&
m_pMachine->GetAllCurrAxesToken( m_AxesToken) ;
return m_pMachine->GetAllCurrAxesNames( m_AxesName) &&
m_pMachine->GetAllCurrAxesTokens( m_AxesToken) ;
}
//----------------------------------------------------------------------------
@@ -603,6 +614,7 @@ Processor::ProcessToolData( void)
string sHead ;
int nExit ;
string sTcPos ;
int nType ;
int nComp ;
double dDiam ;
double dTDiam ;
@@ -611,7 +623,7 @@ Processor::ProcessToolData( void)
double dDist ;
double dMaxSpeed ;
MyToolData( void)
: sName(), sHead(), nExit( 0), sTcPos(), nComp(0), dDiam( 0), dLen( 0), dDist( 0), dMaxSpeed( 0) {}
: sName(), sHead(), nExit( 0), sTcPos(), nType(0), nComp(0), dDiam( 0), dLen( 0), dDist( 0), dMaxSpeed( 0) {}
} ;
typedef vector<MyToolData> TDATAVECTOR ;
TDATAVECTOR vTdata ;
@@ -636,6 +648,7 @@ Processor::ProcessToolData( void)
m_pMchMgr->TdbGetCurrToolParam( TPA_HEAD, Tdata.sHead) ;
m_pMchMgr->TdbGetCurrToolParam( TPA_EXIT, Tdata.nExit) ;
m_pMchMgr->TdbGetCurrToolParam( TPA_TCPOS, Tdata.sTcPos) ;
m_pMchMgr->TdbGetCurrToolParam( TPA_TYPE, Tdata.nType) ;
m_pMchMgr->TdbGetCurrToolParam( TPA_CORR, Tdata.nComp) ;
m_pMchMgr->TdbGetCurrToolParam( TPA_DIAM, Tdata.dDiam) ;
m_pMchMgr->TdbGetCurrToolParam( TPA_TOTDIAM, Tdata.dTDiam) ;
@@ -674,7 +687,8 @@ Processor::ProcessToolData( void)
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_EXIT, nExit) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_TCPOS, sTcPos) ;
if ( m_pMchMgr->TdbSetCurrTool( sTool)) {
int nComp ; double dDiam ; double dTDiam ; double dLen ; double dTLen ; double dDist ; double dMaxSpeed ;
int nType ; int nComp ; double dDiam ; double dTDiam ; double dLen ; double dTLen ; double dDist ; double dMaxSpeed ;
m_pMchMgr->TdbGetCurrToolParam( TPA_TYPE, nType) ;
m_pMchMgr->TdbGetCurrToolParam( TPA_CORR, nComp) ;
m_pMchMgr->TdbGetCurrToolParam( TPA_DIAM, dDiam) ;
m_pMchMgr->TdbGetCurrToolParam( TPA_TOTDIAM, dTDiam) ;
@@ -682,6 +696,7 @@ Processor::ProcessToolData( void)
m_pMchMgr->TdbGetCurrToolParam( TPA_TOTLEN, dTLen) ;
m_pMchMgr->TdbGetCurrToolParam( TPA_DIST, dDist) ;
m_pMchMgr->TdbGetCurrToolParam( TPA_MAXSPEED, dMaxSpeed) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_TTYPE, nType) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_TCOMP, nComp) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_TDIAM, dDiam) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_TTOTDIAM, dTDiam) ;
@@ -721,6 +736,7 @@ Processor::ProcessToolData( void)
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_HEAD, vTdata[i].sHead) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_EXIT, vTdata[i].nExit) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_TCPOS, vTdata[i].sTcPos) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_TTYPE, vTdata[i].nType) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_TCOMP, vTdata[i].nComp) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_TDIAM, vTdata[i].dDiam) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_TTOTDIAM, vTdata[i].dTDiam) ;
@@ -832,15 +848,16 @@ Processor::OnToolSelect( const string& sTool, const string& sHead, int nExit, co
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_EXIT, nExit) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_TCPOS, sTcPos) ;
// assegno il token e il nome degli assi
bool bIsRobot = m_pMchMgr->GetCurrIsRobot() ;
int nNumAxes = int( m_AxesName.size()) ;
for ( int i = 1 ; i <= MAX_AXES ; ++ i) {
if ( i <= nNumAxes) {
bOk = bOk && m_pMachine->LuaSetGlobVar( GetGlobVarAxisToken(i), m_AxesToken[i-1]) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GetGlobVarAxisName(i), m_AxesName[i-1]) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GetGlobVarAxisToken( i, bIsRobot), m_AxesToken[i-1]) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GetGlobVarAxisName( i, bIsRobot), m_AxesName[i-1]) ;
}
else {
bOk = bOk && m_pMachine->LuaResetGlobVar( GetGlobVarAxisToken(i)) ;
bOk = bOk && m_pMachine->LuaResetGlobVar( GetGlobVarAxisName(i)) ;
bOk = bOk && m_pMachine->LuaResetGlobVar( GetGlobVarAxisToken( i, bIsRobot)) ;
bOk = bOk && m_pMachine->LuaResetGlobVar( GetGlobVarAxisName( i, bIsRobot)) ;
}
}
// chiamo la funzione di selezione utensile
@@ -962,7 +979,7 @@ Processor::OnPathEndAux( int nInd, const string& sAE)
bool
Processor::OnRapid( int nEntId, int nEntInd, int nMove, const DBLVECTOR& AxesEnd, int nAxesMask,
const Vector3d& vtTool, const Vector3d& vtCorr, const Vector3d& vtAux,
int nFlag, int nFlag2, int nIndex)
int nFlag, int nFlag2, int nIndex, int nMoveNext, const DBLVECTOR& AxesNext)
{
// cancello variabili estranee
ResetArcData() ;
@@ -972,12 +989,13 @@ Processor::OnRapid( int nEntId, int nEntInd, int nMove, const DBLVECTOR& AxesEnd
// assegno il tipo di movimento
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_MOVE, nMove) ;
// assegno il valore degli assi
bool bIsRobot = m_pMchMgr->GetCurrIsRobot() ;
int nNumAxes = int( AxesEnd.size()) ;
for ( int i = 1 ; i <= MAX_AXES ; ++ i) {
if ( i <= nNumAxes)
bOk = bOk && m_pMachine->LuaSetGlobVar( GetGlobVarAxisValue(i), AxesEnd[i-1]) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GetGlobVarAxisValue( i, GLOB_VAR, bIsRobot), AxesEnd[i-1]) ;
else
bOk = bOk && m_pMachine->LuaResetGlobVar( GetGlobVarAxisValue(i)) ;
bOk = bOk && m_pMachine->LuaResetGlobVar( GetGlobVarAxisValue( i, GLOB_VAR, bIsRobot)) ;
}
// assegno la mascheratura degli assi
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_MASK, nAxesMask) ;
@@ -993,6 +1011,21 @@ Processor::OnRapid( int nEntId, int nEntInd, int nMove, const DBLVECTOR& AxesEnd
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_FLAG2, nFlag2) ;
// assegno il valore dell'indice
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_INDEX, nIndex) ;
// anticipazione di alcuni dati dell'eventuale movimento successivo dello stesso percorso
if ( nMoveNext != -1) {
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_MOVESUCC, nMoveNext) ;
for ( int i = 1 ; i <= MAX_AXES ; ++ i) {
if ( i <= nNumAxes)
bOk = bOk && m_pMachine->LuaSetGlobVar( GetGlobVarAxisNext( i, GLOB_VAR, bIsRobot), AxesNext[i-1]) ;
else
bOk = bOk && m_pMachine->LuaResetGlobVar( GetGlobVarAxisNext( i, GLOB_VAR, bIsRobot)) ;
}
}
else {
bOk = bOk && m_pMachine->LuaResetGlobVar( GLOB_VAR + GVAR_MOVESUCC) ;
for ( int i = 1 ; i <= MAX_AXES ; ++ i)
bOk = bOk && m_pMachine->LuaResetGlobVar( GetGlobVarAxisNext( i, GLOB_VAR, bIsRobot)) ;
}
// chiamo la funzione di movimento in rapido
bOk = bOk && CallOnRapid() ;
return bOk ;
@@ -1002,7 +1035,7 @@ Processor::OnRapid( int nEntId, int nEntInd, int nMove, const DBLVECTOR& AxesEnd
bool
Processor::OnLinear( int nEntId, int nEntInd, int nMove, const DBLVECTOR& AxesEnd,
const Vector3d& vtTool, const Vector3d& vtCorr, const Vector3d& vtAux,
double dFeed, int nFlag, int nFlag2, int nIndex)
double dFeed, int nFlag, int nFlag2, int nIndex, int nMoveNext, const DBLVECTOR& AxesNext)
{
// cancello variabili estranee
ResetArcData() ;
@@ -1012,12 +1045,13 @@ Processor::OnLinear( int nEntId, int nEntInd, int nMove, const DBLVECTOR& AxesEn
// assegno il tipo di movimento
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_MOVE, nMove) ;
// assegno il valore degli assi
bool bIsRobot = m_pMchMgr->GetCurrIsRobot() ;
int nNumAxes = int( AxesEnd.size()) ;
for ( int i = 1 ; i <= MAX_AXES ; ++ i) {
if ( i <= nNumAxes)
bOk = bOk && m_pMachine->LuaSetGlobVar( GetGlobVarAxisValue(i), AxesEnd[i-1]) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GetGlobVarAxisValue( i, GLOB_VAR, bIsRobot), AxesEnd[i-1]) ;
else
bOk = bOk && m_pMachine->LuaResetGlobVar( GetGlobVarAxisValue(i)) ;
bOk = bOk && m_pMachine->LuaResetGlobVar( GetGlobVarAxisValue( i, GLOB_VAR, bIsRobot)) ;
}
// assegno il valore del versore utensile
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_TDIR, vtTool) ;
@@ -1033,6 +1067,21 @@ Processor::OnLinear( int nEntId, int nEntInd, int nMove, const DBLVECTOR& AxesEn
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_FLAG2, nFlag2) ;
// assegno il valore dell'indice
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_INDEX, nIndex) ;
// anticipazione di alcuni dati dell'eventuale movimento successivo dello stesso percorso
if ( nMoveNext != -1) {
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_MOVESUCC, nMoveNext) ;
for ( int i = 1 ; i <= MAX_AXES ; ++ i) {
if ( i <= nNumAxes)
bOk = bOk && m_pMachine->LuaSetGlobVar( GetGlobVarAxisNext( i, GLOB_VAR, bIsRobot), AxesNext[i-1]) ;
else
bOk = bOk && m_pMachine->LuaResetGlobVar( GetGlobVarAxisNext( i, GLOB_VAR, bIsRobot)) ;
}
}
else {
bOk = bOk && m_pMachine->LuaResetGlobVar( GLOB_VAR + GVAR_MOVESUCC) ;
for ( int i = 1 ; i <= MAX_AXES ; ++ i)
bOk = bOk && m_pMachine->LuaResetGlobVar( GetGlobVarAxisNext( i, GLOB_VAR, bIsRobot)) ;
}
// chiamo la funzione di movimento in rapido
bOk = bOk && CallOnLinear() ;
return bOk ;
@@ -1043,7 +1092,7 @@ bool
Processor::OnArc( int nEntId, int nEntInd, int nMove, const DBLVECTOR& AxesEnd,
const Point3d& ptCen, const Point3d& ptMid, double dRad, double dAngCen,
const Vector3d& vtTool, const Vector3d& vtCorr, const Vector3d& vtAux,
double dFeed, int nFlag, int nFlag2, int nIndex)
double dFeed, int nFlag, int nFlag2, int nIndex, int nMoveNext, const DBLVECTOR& AxesNext)
{
// assegno Id e indice entità di movimento
bool bOk = m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_MOVEID, nEntId) ;
@@ -1051,12 +1100,13 @@ Processor::OnArc( int nEntId, int nEntInd, int nMove, const DBLVECTOR& AxesEnd,
// assegno il tipo di movimento
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_MOVE, nMove) ;
// assegno il valore degli assi
bool bIsRobot = m_pMchMgr->GetCurrIsRobot() ;
int nNumAxes = int( AxesEnd.size()) ;
for ( int i = 1 ; i <= MAX_AXES ; ++ i) {
if ( i <= nNumAxes)
bOk = bOk && m_pMachine->LuaSetGlobVar( GetGlobVarAxisValue(i), AxesEnd[i-1]) ;
bOk = bOk && m_pMachine->LuaSetGlobVar( GetGlobVarAxisValue( i, GLOB_VAR, bIsRobot), AxesEnd[i-1]) ;
else
bOk = bOk && m_pMachine->LuaResetGlobVar( GetGlobVarAxisValue(i)) ;
bOk = bOk && m_pMachine->LuaResetGlobVar( GetGlobVarAxisValue( i, GLOB_VAR, bIsRobot)) ;
}
// assegno le coordinate del centro
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_C1, ptCen.x) ;
@@ -1084,6 +1134,21 @@ Processor::OnArc( int nEntId, int nEntInd, int nMove, const DBLVECTOR& AxesEnd,
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_FLAG2, nFlag2) ;
// assegno il valore dell'indice
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_INDEX, nIndex) ;
// anticipazione di alcuni dati dell'eventuale movimento successivo dello stesso percorso
if ( nMoveNext != -1) {
bOk = bOk && m_pMachine->LuaSetGlobVar( GLOB_VAR + GVAR_MOVESUCC, nMoveNext) ;
for ( int i = 1 ; i <= MAX_AXES ; ++ i) {
if ( i <= nNumAxes)
bOk = bOk && m_pMachine->LuaSetGlobVar( GetGlobVarAxisNext( i, GLOB_VAR, bIsRobot), AxesNext[i-1]) ;
else
bOk = bOk && m_pMachine->LuaResetGlobVar( GetGlobVarAxisNext( i, GLOB_VAR, bIsRobot)) ;
}
}
else {
bOk = bOk && m_pMachine->LuaResetGlobVar( GLOB_VAR + GVAR_MOVESUCC) ;
for ( int i = 1 ; i <= MAX_AXES ; ++ i)
bOk = bOk && m_pMachine->LuaResetGlobVar( GetGlobVarAxisNext( i, GLOB_VAR, bIsRobot)) ;
}
// chiamo la funzione di movimento in rapido
bOk = bOk && CallOnArc() ;
return bOk ;
Processor.h
+3 -3
View File
@@ -61,14 +61,14 @@ class Processor
bool OnPathEndAux( int nInd, const std::string& sAE) ;
bool OnRapid( int nEntId, int nEntInd, int nMove, const DBLVECTOR& AxesEnd, int nAxesMask,
const Vector3d& vtTool, const Vector3d& vtCorr, const Vector3d& vtAux,
int nFlag, int nFlag2, int nIndex) ;
int nFlag, int nFlag2, int nIndex, int nMoveNext, const DBLVECTOR& AxesNext) ;
bool OnLinear( int nEntId, int nEntInd, int nMove, const DBLVECTOR& AxesEnd,
const Vector3d& vtTool, const Vector3d& vtCorr, const Vector3d& vtAux,
double dFeed, int nFlag, int nFlag2, int nIndex) ;
double dFeed, int nFlag, int nFlag2, int nIndex, int nMoveNext, const DBLVECTOR& AxesNext) ;
bool OnArc( int nEntId, int nEntInd, int nMove, const DBLVECTOR& AxesEnd,
const Point3d& ptCen, const Point3d& ptMid, double dRad, double dAngCen,
const Vector3d& vtTool, const Vector3d& vtCorr, const Vector3d& vtAux,
double dFeed, int nFlag, int nFlag2, int nIndex) ;
double dFeed, int nFlag, int nFlag2, int nIndex, int nMoveNext, const DBLVECTOR& AxesNext) ;
bool ResetArcData( void) ;
protected :
SawFinishing.cpp
+46 -25
View File
@@ -607,6 +607,9 @@ SawFinishing::Update( bool bPostApply)
return true ;
}
// elimino le entità CLIMB, RISE e HOME della lavorazione, potrebbero falsare i calcoli degli assi (in ogni casi vengono riaggiunte dopo)
RemoveClimbRiseHome() ;
// imposto eventuale asse bloccato da lavorazione
SetBlockedRotAxis( m_Params.m_sBlockedAxis) ;
@@ -795,11 +798,31 @@ SawFinishing::UpdateToolData( bool* pbChanged)
const ToolData* pTdata = pTMgr->GetTool( m_Params.m_ToolUuid) ;
if ( pTdata == nullptr)
return false ;
// verifico se sono diversi (ad esclusione del nome)
m_TParams.m_sName = pTdata->m_sName ;
bool bChanged = ! SameTool( m_TParams, *pTdata) ;
// salvo posizione TC, testa e uscita originali
string sOrigTcPos = m_TParams.m_sTcPos ;
string sOrigHead = m_TParams.m_sHead ;
int nOrigExit = m_TParams.m_nExit ;
// verifico se sono diversi (ad esclusione di nome, posizione TC, testa e uscita)
bool bChanged = ( ! SameTool( m_TParams, *pTdata, false)) ;
// aggiorno comunque i parametri
m_TParams = *pTdata ;
// se definito attrezzaggio, aggiorno i parametri che ne possono derivare
string sTcPos ; string sHead ; int nExit ;
if ( m_pMchMgr->GetCurrSetupMgr().GetToolData( m_TParams.m_sName, sTcPos, sHead, nExit)) {
if ( sOrigTcPos != sTcPos ||
sOrigHead != sHead ||
nOrigExit != nExit)
bChanged = true ;
m_TParams.m_sTcPos = sTcPos ;
m_TParams.m_sHead = sHead ;
m_TParams.m_nExit = nExit ;
}
else {
if ( sOrigTcPos != pTdata->m_sTcPos ||
sOrigHead != pTdata->m_sHead ||
nOrigExit != pTdata->m_nExit)
bChanged = true ;
}
// eventuali segnalazioni
if ( ! EqualNoCase( m_Params.m_sToolName, m_TParams.m_sName)) {
string sInfo = "Warning in SawFinishing : tool name changed (" +
@@ -959,15 +982,15 @@ SawFinishing::AdjustGeometry( int nAuxId)
if ( ! pGuide->IsFlat( plPlane, false, 10 * EPS_SMALL) || ! AreSameOrOppositeVectorApprox( plPlane.GetVersN(), Z_AX))
return false ;
// verifiche sulla curva (che trasformo in composita)
PtrOwner<ICurveComposite> pCompo( CreateCurveComposite()) ;
if ( IsNull( pCompo) || ! pCompo->AddCurve( Release( pGuide)))
PtrOwner<ICurveComposite> pCompo ;
if ( ! pCompo.Set( ConvertCurveToComposite( Release( pGuide))))
return false ;
// converto in archi e rette
pCompo->ArcsBezierCurvesToArcsPerpExtr( LIN_TOL_MID, ANG_TOL_STD_DEG) ;
// verifiche sull'ampiezza dell'angolo al centro degli eventuali archi
VerifyArcs( pCompo) ;
// reinserisco nella curva originale
pGuide.Set( Release( pCompo)) ;
pGuide.Set( pCompo) ;
}
// deve iniziare in comune con la prima sezione ed essere ivi perpendicolare
Vector3d vtGdDir ;
@@ -1302,7 +1325,7 @@ SawFinishing::CalculateStraightAcrossToolPath( int nAuxId, int nClId)
// se ZigZag aggiungo risalita
if ( m_Params.m_nStepType == SAWFIN_ST_ZIGZAG) {
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
// aggiungo retrazione
@@ -1623,7 +1646,7 @@ SawFinishing::CalculateCurvedAcrossToolPath( int nAuxId, int nClId)
double dEndElev = 0 ;
GetElevation( m_nPhase, ptPrev, vtPrev, dEndElev) ;
// aggiungo retrazione
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
double dAppr = m_Params.m_dStartPos ;
if ( ! AddRetract( ptPrev, vtPrev, dSafeZ, dEndElev, dAppr))
return false ;
@@ -1647,7 +1670,7 @@ SawFinishing::CalculateCurvedAcrossToolPath( int nAuxId, int nClId)
// se ZigZag aggiungo risalita
if ( m_Params.m_nStepType == SAWFIN_ST_ZIGZAG) {
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
// recupero punto e versore correzione finali
@@ -1857,7 +1880,6 @@ SawFinishing::ClassifySection( ICurve* pCrv, INTVECTOR& vnClass)
{
const ICurveComposite* pCompo = GetCurveComposite( pCrv) ;
if ( pCompo != nullptr) {
int Ind = 0 ;
const ICurve* pSimpCrv = pCompo->GetFirstCurve() ;
while ( pSimpCrv != nullptr) {
// analizzo la curva
@@ -1875,7 +1897,6 @@ SawFinishing::ClassifySection( ICurve* pCrv, INTVECTOR& vnClass)
else
vnClass.push_back( CCL_FALL) ;
// passo alla curva successiva
++ Ind ;
pSimpCrv = pCompo->GetNextCurve() ;
}
}
@@ -1968,7 +1989,7 @@ SawFinishing::CalcAlongVerticalCuts( ICurve* pSect, int nUmin, int nUmax, const
// se ZigZag e non centrato aggiungo risalita
if ( m_Params.m_nStepType == SAWFIN_ST_ZIGZAG && m_Params.m_nLeadLinkType != SAWFIN_LL_CENT) {
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
// aggiungo retrazione
@@ -2055,7 +2076,7 @@ SawFinishing::CalcAlongStdCuts( ICurve* pSect, double dUmin, double dUmax,
// se ZigZag e non centrato aggiungo risalita
if ( m_Params.m_nStepType == SAWFIN_ST_ZIGZAG && m_Params.m_nLeadLinkType != SAWFIN_LL_CENT) {
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
// aggiungo retrazione
@@ -2073,7 +2094,7 @@ SawFinishing::CalcAlongOneWayCut( const Point3d& ptStart, const Point3d& ptEnd,
const Vector3d& vtTool, const Vector3d& vtCorr, double dElev, bool bVert)
{
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
@@ -2122,7 +2143,7 @@ SawFinishing::CalcAlongZigZagCut( const Point3d& ptStart, const Point3d& ptEnd,
const Vector3d& vtTool, const Vector3d& vtCorr, double dElev, bool bVert, bool bFirst)
{
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
@@ -2239,7 +2260,7 @@ SawFinishing::CalcAcrossOneWayCut( const PolyLine& PL, const Vector3d& vtMove,
const Vector3d& vtTool, const Vector3d& vtCorr, double dRawZ, double dDepth)
{
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
@@ -2296,7 +2317,7 @@ SawFinishing::CalcAcrossZigZagCut( const PolyLine& PL, const Vector3d& vtMove,
const Vector3d& vtTool, const Vector3d& vtCorr, double dRawZ, double dDepth, bool bFirst)
{
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
@@ -2380,8 +2401,8 @@ SawFinishing::CalcCurvedAlongVerticalCuts( ICurve* pSect, int nUmin, int nUmax,
Vector3d vtMove = ( dY - m_TParams.m_dThick / 2) * Z_AX ;
OffsetCurve OffsCrv ;
OffsCrv.Make( pGuide, dOffs, ICurve::OFF_FILLET) ;
PtrOwner<ICurveComposite> pCut( CreateCurveComposite()) ;
if ( IsNull( pCut) || ! pCut->AddCurve( OffsCrv.GetLongerCurve()))
PtrOwner<ICurveComposite> pCut ;
if ( ! pCut.Set( ConvertCurveToComposite( OffsCrv.GetLongerCurve())))
return false ;
VerifyArcs( pCut) ;
pCut->SimpleOffset( SAWRF_OFFS, ICurve::OFF_FORCE_OPEN) ;
@@ -2404,7 +2425,7 @@ SawFinishing::CalcCurvedAlongVerticalCuts( ICurve* pSect, int nUmin, int nUmax,
// se ZigZag e non centrato aggiungo risalita
if ( m_Params.m_nStepType == SAWFIN_ST_ZIGZAG && m_Params.m_nLeadLinkType != SAWFIN_LL_CENT) {
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
// aggiungo retrazione
@@ -2455,8 +2476,8 @@ SawFinishing::CalcCurvedAlongStdCuts( ICurve* pSect, double dUmin, double dUmax,
Vector3d vtMove = ( ptP.y - m_TParams.m_dThick / 2) * Z_AX ;
OffsetCurve OffsCrv ;
OffsCrv.Make( pGuide, dOffs, ICurve::OFF_FILLET) ;
PtrOwner<ICurveComposite> pCut( CreateCurveComposite()) ;
if ( IsNull( pCut) || ! pCut->AddCurve( OffsCrv.GetLongerCurve()))
PtrOwner<ICurveComposite> pCut ;
if ( ! pCut.Set( ConvertCurveToComposite( OffsCrv.GetLongerCurve())))
return false ;
VerifyArcs( pCut) ;
pCut->SimpleOffset( SAWRF_OFFS, ICurve::OFF_FORCE_OPEN) ;
@@ -2479,7 +2500,7 @@ SawFinishing::CalcCurvedAlongStdCuts( ICurve* pSect, double dUmin, double dUmax,
// se ZigZag e non centrato aggiungo risalita
if ( m_Params.m_nStepType == SAWFIN_ST_ZIGZAG && m_Params.m_nLeadLinkType != SAWFIN_LL_CENT) {
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
// aggiungo retrazione
@@ -2497,7 +2518,7 @@ bool
SawFinishing::CalcCurvedAlongZigZagCut( const ICurve* pCut, const Vector3d& vtTool, bool bVert, bool bFirst, double& dEndElev)
{
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
// verifico se passata da invertire (indice dispari)
@@ -2673,7 +2694,7 @@ SawFinishing::CalcCurvedAcrossZigZagCut( const PolyLine& PL, const Vector3d& vtM
bool bFirst, bool bCorner)
{
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
SawFinishingData.h
+6 -2
View File
@@ -81,6 +81,10 @@ struct SawFinishingData : public MachiningData
//----------------------------------------------------------------------------
inline const SawFinishingData* GetSawFinishingData( const MachiningData* pMdata)
{ return (dynamic_cast<const SawFinishingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_SAWFINISHING)
return nullptr ;
return ( static_cast<const SawFinishingData*>( pMdata)) ; }
inline SawFinishingData* GetSawFinishingData( MachiningData* pMdata)
{ return (dynamic_cast<SawFinishingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_SAWFINISHING)
return nullptr ;
return ( static_cast<SawFinishingData*>( pMdata)) ; }
SawRoughing.cpp
+34 -11
View File
@@ -571,6 +571,9 @@ SawRoughing::Update( bool bPostApply)
return true ;
}
// elimino le entità CLIMB, RISE e HOME della lavorazione, potrebbero falsare i calcoli degli assi (in ogni casi vengono riaggiunte dopo)
RemoveClimbRiseHome() ;
// imposto eventuale asse bloccato da lavorazione
SetBlockedRotAxis( m_Params.m_sBlockedAxis) ;
@@ -753,11 +756,31 @@ SawRoughing::UpdateToolData( bool* pbChanged)
const ToolData* pTdata = pTMgr->GetTool( m_Params.m_ToolUuid) ;
if ( pTdata == nullptr)
return false ;
// verifico se sono diversi (ad esclusione del nome)
m_TParams.m_sName = pTdata->m_sName ;
bool bChanged = ! SameTool( m_TParams, *pTdata) ;
// salvo posizione TC, testa e uscita originali
string sOrigTcPos = m_TParams.m_sTcPos ;
string sOrigHead = m_TParams.m_sHead ;
int nOrigExit = m_TParams.m_nExit ;
// verifico se sono diversi (ad esclusione di nome, posizione TC, testa e uscita)
bool bChanged = ( ! SameTool( m_TParams, *pTdata, false)) ;
// aggiorno comunque i parametri
m_TParams = *pTdata ;
// se definito attrezzaggio, aggiorno i parametri che ne possono derivare
string sTcPos ; string sHead ; int nExit ;
if ( m_pMchMgr->GetCurrSetupMgr().GetToolData( m_TParams.m_sName, sTcPos, sHead, nExit)) {
if ( sOrigTcPos != sTcPos ||
sOrigHead != sHead ||
nOrigExit != nExit)
bChanged = true ;
m_TParams.m_sTcPos = sTcPos ;
m_TParams.m_sHead = sHead ;
m_TParams.m_nExit = nExit ;
}
else {
if ( sOrigTcPos != pTdata->m_sTcPos ||
sOrigHead != pTdata->m_sHead ||
nOrigExit != pTdata->m_nExit)
bChanged = true ;
}
// eventuali segnalazioni
if ( ! EqualNoCase( m_Params.m_sToolName, m_TParams.m_sName)) {
string sInfo = "Warning in SawRoughing : tool name changed (" +
@@ -917,15 +940,15 @@ SawRoughing::AdjustGeometry( int nAuxId)
if ( ! pGuide->IsFlat( plPlane, false, 10 * EPS_SMALL) || ! AreSameOrOppositeVectorApprox( plPlane.GetVersN(), Z_AX))
return false ;
// verifiche sulla curva (che trasformo in composita)
PtrOwner<ICurveComposite> pCompo( CreateCurveComposite()) ;
if ( IsNull( pCompo) || ! pCompo->AddCurve( Release( pGuide)))
PtrOwner<ICurveComposite> pCompo ;
if ( ! pCompo.Set( ConvertCurveToComposite( Release( pGuide))))
return false ;
// converto in archi e rette
pCompo->ArcsBezierCurvesToArcsPerpExtr( LIN_TOL_MID, ANG_TOL_STD_DEG) ;
// verifiche sull'ampiezza dell'angolo al centro degli eventuali archi
VerifyArcs( pCompo) ;
// reinserisco nella curva originale
pGuide.Set( Release( pCompo)) ;
pGuide.Set( pCompo) ;
}
// deve iniziare in comune con la prima sezione ed essere ivi perpendicolare
Vector3d vtGdDir ;
@@ -1307,8 +1330,8 @@ SawRoughing::CalculateCurvedToolPath( int nAuxId, int nClId)
// creo la curva di taglio
OffsetCurve OffsCrv ;
OffsCrv.Make( pGuide, dX, ICurve::OFF_FILLET) ;
PtrOwner<ICurveComposite> pCut( CreateCurveComposite()) ;
if ( IsNull( pCut) || ! pCut->AddCurve( OffsCrv.GetLongerCurve()))
PtrOwner<ICurveComposite> pCut ;
if ( ! pCut.Set( ConvertCurveToComposite( OffsCrv.GetLongerCurve())))
return false ;
VerifyArcs( pCut) ;
Vector3d vtMove = ( dY - m_TParams.m_dThick / 2) * Z_AX ;
@@ -1537,7 +1560,7 @@ SawRoughing::CalculateOneWayCut( const Point3d& ptStart, const Point3d& ptEnd, c
const Vector3d& vtTool, const Vector3d& vtCorr, double dElev, bool bFirst, bool bLast)
{
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
@@ -1631,7 +1654,7 @@ SawRoughing::CalculateZigZagCut( const Point3d& ptStart, const Point3d& ptEnd, c
int& nCount)
{
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
@@ -1842,7 +1865,7 @@ SawRoughing::CalculateCurvedZigZagCut( const ICurve* pCut, const Vector3d& vtToo
int& nCount)
{
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
// verifico se passata da invertire (indice dispari)
SawRoughingData.h
+6 -2
View File
@@ -78,6 +78,10 @@ struct SawRoughingData : public MachiningData
//----------------------------------------------------------------------------
inline const SawRoughingData* GetSawRoughingData( const MachiningData* pMdata)
{ return (dynamic_cast<const SawRoughingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_SAWROUGHING)
return nullptr ;
return ( static_cast<const SawRoughingData*>( pMdata)) ; }
inline SawRoughingData* GetSawRoughingData( MachiningData* pMdata)
{ return (dynamic_cast<SawRoughingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_SAWROUGHING)
return nullptr ;
return ( static_cast<SawRoughingData*>( pMdata)) ; }
Sawing.cpp
+153 -81
View File
@@ -4,7 +4,7 @@
// File : Sawing.cpp Data : 24.10.15 Versione : 1.6j3
// Contenuto : Implementazione gestione tagli con lama.
//
// Note : Questa lavorazione è sempre espressa nel riferimento globale.
// Note : Questa lavorazione è sempre espressa nel riferimento globale.
//
// Modifiche : 07.06.15 DS Creazione modulo.
//
@@ -532,15 +532,15 @@ Sawing::SetParam( int nType, const string& sVal)
bool
Sawing::SetGeometry( const SELVECTOR& vIds)
{
// verifico validità gestore DB geometrico
// verifico validità gestore DB geometrico
if ( m_pGeomDB == nullptr)
return false ;
// reset della geometria corrente
m_vId.clear() ;
// verifico che gli identificativi rappresentino delle entità ammissibili
// verifico che gli identificativi rappresentino delle entità ammissibili
int nType = GEO_NONE ;
for ( const auto& Id : vIds) {
// test sull'entità
// test sull'entità
int nSubs ;
if ( ! VerifyGeometry( Id, nSubs, nType)) {
string sInfo = "Warning in Sawing : Skipped entity " + ToString( Id) ;
@@ -563,14 +563,14 @@ Sawing::Preview( bool bRecalc)
// reset numero tagli nella lavorazione
m_nCuts = 0 ;
// verifico validità gestore DB geometrico e Id del gruppo
// verifico validità gestore DB geometrico e Id del gruppo
if ( m_pGeomDB == nullptr || ! m_pGeomDB->ExistsObj( m_nOwnerId))
return false ;
// recupero gruppo per geometria ausiliaria
int nAuxId = m_pGeomDB->GetFirstNameInGroup( m_nOwnerId, MCH_AUX) ;
bool bChain = false ;
// se non c'è, lo aggiungo
// se non c'è, lo aggiungo
if ( nAuxId == GDB_ID_NULL) {
nAuxId = m_pGeomDB->AddGroup( GDB_ID_NULL, m_nOwnerId, Frame3d()) ;
if ( nAuxId == GDB_ID_NULL)
@@ -603,7 +603,7 @@ Sawing::Preview( bool bRecalc)
// recupero gruppo per anteprima di lavorazione (PreView)
int nPvId = m_pGeomDB->GetFirstNameInGroup( m_nOwnerId, MCH_PV) ;
// se non c'è, lo aggiungo
// se non c'è, lo aggiungo
if ( nPvId == GDB_ID_NULL) {
nPvId = m_pGeomDB->AddGroup( GDB_ID_NULL, m_nOwnerId, Frame3d()) ;
if ( nPvId == GDB_ID_NULL)
@@ -633,7 +633,7 @@ Sawing::Apply( bool bRecalc, bool bPostApply)
int nCurrCuts = m_nCuts ;
m_nCuts = 0 ;
// verifico validità gestore DB geometrico e Id del gruppo
// verifico validità gestore DB geometrico e Id del gruppo
if ( m_pGeomDB == nullptr || ! m_pGeomDB->ExistsObj( m_nOwnerId))
return false ;
@@ -662,7 +662,7 @@ Sawing::Apply( bool bRecalc, bool bPostApply)
// recupero gruppo per geometria ausiliaria
int nAuxId = m_pGeomDB->GetFirstNameInGroup( m_nOwnerId, MCH_AUX) ;
bool bChain = false ;
// se non c'è, lo aggiungo
// se non c'è, lo aggiungo
if ( nAuxId == GDB_ID_NULL) {
nAuxId = m_pGeomDB->AddGroup( GDB_ID_NULL, m_nOwnerId, Frame3d()) ;
if ( nAuxId == GDB_ID_NULL)
@@ -689,7 +689,7 @@ Sawing::Apply( bool bRecalc, bool bPostApply)
// recupero gruppo per geometria di lavorazione (Cutter Location)
int nClId = m_pGeomDB->GetFirstNameInGroup( m_nOwnerId, MCH_CL) ;
// se non c'è, lo aggiungo
// se non c'è, lo aggiungo
if ( nClId == GDB_ID_NULL) {
nClId = m_pGeomDB->AddGroup( GDB_ID_NULL, m_nOwnerId, Frame3d()) ;
if ( nClId == GDB_ID_NULL)
@@ -732,7 +732,7 @@ Sawing::Apply( bool bRecalc, bool bPostApply)
bool
Sawing::Update( bool bPostApply)
{
// verifico validità gestore DB geometrico e Id del gruppo
// verifico validità gestore DB geometrico e Id del gruppo
if ( m_pGeomDB == nullptr || ! m_pGeomDB->ExistsObj( m_nOwnerId))
return false ;
@@ -742,6 +742,9 @@ Sawing::Update( bool bPostApply)
return true ;
}
// elimino le entità CLIMB, RISE e HOME della lavorazione, potrebbero falsare i calcoli degli assi (in ogni casi vengono riaggiunte dopo)
RemoveClimbRiseHome() ;
// imposto eventuale asse bloccato da lavorazione
SetBlockedRotAxis( m_Params.m_sBlockedAxis) ;
@@ -791,7 +794,7 @@ Sawing::Update( bool bPostApply)
bool
Sawing::AdjustFeeds( void)
{
// controlli su GeomDB e simili non ripetuti perchè già fatti
// controlli su GeomDB e simili non ripetuti perchè già fatti
// recupero gruppo della geometria di lavorazione (Cutter Location)
int nClId = m_pGeomDB->GetFirstNameInGroup( GetOwner(), MCH_CL) ;
@@ -801,11 +804,11 @@ Sawing::AdjustFeeds( void)
// ciclo sui gruppi CL
int nClPathId = m_pGeomDB->GetFirstGroupInGroup( nClId) ;
while ( nClPathId != GDB_ID_NULL) {
// ciclo su tutte le entità del percorso CL
// ciclo su tutte le entità del percorso CL
for ( int nEntId = m_pGeomDB->GetFirstInGroup( nClPathId) ;
nEntId != GDB_ID_NULL ;
nEntId = m_pGeomDB->GetNext( nEntId)) {
// recupero i dati Cam dell'entità
// recupero i dati Cam dell'entità
CamData* pCamData = GetCamData( m_pGeomDB->GetUserObj( nEntId)) ;
if ( pCamData == nullptr)
continue ;
@@ -1025,11 +1028,31 @@ Sawing::UpdateToolData( bool* pbChanged)
const ToolData* pTdata = pTMgr->GetTool( m_Params.m_ToolUuid) ;
if ( pTdata == nullptr)
return false ;
// verifico se sono diversi (ad esclusione del nome)
m_TParams.m_sName = pTdata->m_sName ;
bool bChanged = ! SameTool( m_TParams, *pTdata) ;
// salvo posizione TC, testa e uscita originali
string sOrigTcPos = m_TParams.m_sTcPos ;
string sOrigHead = m_TParams.m_sHead ;
int nOrigExit = m_TParams.m_nExit ;
// verifico se sono diversi (ad esclusione di nome, posizione TC, testa e uscita)
bool bChanged = ( ! SameTool( m_TParams, *pTdata, false)) ;
// aggiorno comunque i parametri
m_TParams = *pTdata ;
// se definito attrezzaggio, aggiorno i parametri che ne possono derivare
string sTcPos ; string sHead ; int nExit ;
if ( m_pMchMgr->GetCurrSetupMgr().GetToolData( m_TParams.m_sName, sTcPos, sHead, nExit)) {
if ( sOrigTcPos != sTcPos ||
sOrigHead != sHead ||
nOrigExit != nExit)
bChanged = true ;
m_TParams.m_sTcPos = sTcPos ;
m_TParams.m_sHead = sHead ;
m_TParams.m_nExit = nExit ;
}
else {
if ( sOrigTcPos != pTdata->m_sTcPos ||
sOrigHead != pTdata->m_sHead ||
nOrigExit != pTdata->m_nExit)
bChanged = true ;
}
// eventuali segnalazioni
if ( ! EqualNoCase( m_Params.m_sToolName, m_TParams.m_sName)) {
string sInfo = "Warning in Sawing : tool name changed (" +
@@ -1052,7 +1075,7 @@ Sawing::UpdateToolData( bool* pbChanged)
bool
Sawing::GetGeometry( SELVECTOR& vIds) const
{
// restituisco l'elenco delle entità
// restituisco l'elenco delle entità
vIds = m_vId ;
return true ;
}
@@ -1075,7 +1098,7 @@ Sawing::VerifyGeometry( SelData Id, int& nSubs, int& nType)
const IGeoObj* pGObj = m_pGeomDB->GetGeoObj( Id.nId) ;
if ( pGObj == nullptr)
return false ;
// se ammesse curve ed è tale
// se ammesse curve ed è tale
if ( ( nType == GEO_NONE || nType == GEO_CURVE) && ( pGObj->GetType() & GEO_CURVE) != 0) {
nType = GEO_CURVE ;
const ICurve* pCurve = nullptr ;
@@ -1099,7 +1122,7 @@ Sawing::VerifyGeometry( SelData Id, int& nSubs, int& nType)
}
return ( pCurve != nullptr) ;
}
// se altrimenti ammesse superfici trimesh ed è tale
// se altrimenti ammesse superfici trimesh ed è tale
else if ( ( nType == GEO_NONE || nType == GEO_SURF) && pGObj->GetType() == SRF_TRIMESH) {
nType = GEO_SURF ;
const ISurfTriMesh* pSurf = ::GetSurfTriMesh( pGObj) ;
@@ -1119,7 +1142,7 @@ Sawing::VerifyGeometry( SelData Id, int& nSubs, int& nType)
}
return true ;
}
// se altrimenti ammesse regioni ed è tale
// se altrimenti ammesse regioni ed è tale
else if ( ( nType == GEO_NONE || nType == GEO_SURF) && pGObj->GetType() == SRF_FLATRGN) {
nType = GEO_SURF ;
const ISurfFlatRegion* pReg = ::GetSurfFlatRegion( pGObj) ;
@@ -1222,7 +1245,7 @@ Sawing::GetCurve( SelData Id)
pCrvCompo->ToGlob( frGlob) ;
vtN.ToGlob( frGlob) ;
// sistemazioni varie
AdjustCurveFromSurf( pCrvCompo, TOOL_ORTUP, FACE_DOWN, 0, 1) ;
AdjustCurveFromSurf( pCrvCompo, TOOL_ORTUP, FACE_DOWN, V_NULL, 0, 1) ;
// aggiusto lato lavoro e inverti, angolo di fianco e lato mandrino
if ( m_Params.m_nWorkSide == SAW_WS_CENTER)
m_Params.m_nWorkSide = SAW_WS_RIGHT ;
@@ -1256,8 +1279,8 @@ Sawing::GetCurve( SelData Id)
// recupero l'indice del chunk
int nChunk = ( ( Id.nSub == SEL_SUB_ALL) ? 0 : Id.nSub) ;
// recupero il contorno esterno del chunk
PtrOwner<ICurveComposite> pCrvCompo( CreateCurveComposite()) ;
if ( IsNull( pCrvCompo) || ! pCrvCompo->AddCurve( pReg->GetLoop( nChunk, 0)))
PtrOwner<ICurveComposite> pCrvCompo ;
if ( ! pCrvCompo.Set( ConvertCurveToComposite( pReg->GetLoop( nChunk, 0))))
return nullptr ;
// recupero la normale della regione
Vector3d vtN = pReg->GetNormVersor() ;
@@ -1271,7 +1294,7 @@ Sawing::GetCurve( SelData Id)
pCrvCompo->ToGlob( frGlob) ;
vtN.ToGlob( frGlob) ;
// sistemazioni varie
AdjustCurveFromSurf( pCrvCompo, TOOL_ORTUP, FACE_DOWN, 0, 1) ;
AdjustCurveFromSurf( pCrvCompo, TOOL_ORTUP, FACE_DOWN, V_NULL, 0, 1) ;
// aggiusto lato lavoro e inverti, angolo di fianco e lato mandrino
if ( m_Params.m_nWorkSide == SAW_WS_CENTER)
m_Params.m_nWorkSide = SAW_WS_RIGHT ;
@@ -1312,7 +1335,7 @@ Sawing::Chain( int nGrpDestId)
for ( const auto& Id : m_vId) {
// prendo curva
vpCrvs.emplace_back( GetCurve( Id)) ;
// ne verifico la validità
// ne verifico la validità
if ( IsNull( vpCrvs.back())) {
string sInfo = "Warning in Sawing : Skipped entity " + ToString( Id) ;
m_pMchMgr->SetWarning( 2251, sInfo) ;
@@ -1454,7 +1477,7 @@ Sawing::ProcessPath( int nPathId, int nPvId, int nClId)
// recupero gruppo per geometria temporanea
const string GRP_TEMP = "Temp" ;
int nTempId = m_pGeomDB->GetFirstNameInGroup( m_nOwnerId, GRP_TEMP) ;
// se non c'è, lo aggiungo
// se non c'è, lo aggiungo
if ( nTempId == GDB_ID_NULL) {
nTempId = m_pGeomDB->AddGroup( GDB_ID_NULL, m_nOwnerId, Frame3d()) ;
if ( nTempId == GDB_ID_NULL)
@@ -1478,7 +1501,7 @@ Sawing::ProcessPath( int nPathId, int nPvId, int nClId)
ICurveComposite* pCompo = GetCurveComposite( m_pGeomDB->GetGeoObj( nCopyId)) ;
// unisco le parti allineate
if ( ! pCompo->MergeCurves( 10 * EPS_SMALL, 10 * EPS_ANG_SMALL))
if ( ! pCompo->MergeCurves( 100 * EPS_SMALL, 100 * EPS_ANG_SMALL))
return false ;
// eventuale inversione percorso
@@ -1519,7 +1542,7 @@ Sawing::ProcessPath( int nPathId, int nPvId, int nClId)
// elaboro la curva composita e la esplodo nelle curve componenti
if ( m_Params.m_nCurveUse == SAW_CRV_APPROX ||
m_Params.m_nCurveUse == SAW_CRV_CONVEX) {
// calcolo l'approssimazione lineare con eventuale convessità
// calcolo l'approssimazione lineare con eventuale convessità
PolyLine PL ;
int nType = ICurve::APL_STD ;
if ( m_Params.m_nWorkSide == SAW_WS_LEFT)
@@ -1608,7 +1631,7 @@ Sawing::ProcessPath( int nPathId, int nPvId, int nClId)
// flag di curva chiusa
bool bClosed = pCompo->IsClosed() ;
// calcolo gli eventuali punti di perdita di tangenza e di cambio di concavità
// calcolo gli eventuali punti di perdita di tangenza e di cambio di concavità
DBLVECTOR vU ;
const double ANG_PERD_TG = 1.0 ;
const ICurveArc* pArc = ( bClosed ? GetCurveArc( pCompo->GetLastCurve()) : nullptr) ;
@@ -1624,7 +1647,7 @@ Sawing::ProcessPath( int nPathId, int nPvId, int nClId)
nCurrConv = 0 ;
continue ;
}
// verifico cambio di concavità e/o lavorazione interna
// verifico cambio di concavità e/o lavorazione interna
const ICurve* pCrv = pCompo->GetCurve( i) ;
if ( pCrv->GetType() == CRV_ARC) {
if ( GetCurveArc( pCrv)->GetAngCenter() > 0) {
@@ -1706,7 +1729,7 @@ Sawing::ProcessEntity( const ICurve* pCrvP, const ICurve* pCrvC, const ICurve* p
// altrimenti
else {
if ( m_Params.m_nCurveUse == SAW_CRV_KEEP) {
// determino la convessità
// determino la convessità
int nConv = 0 ;
for ( int i = 0 ; i < pCompo->GetCurveCount() ; ++ i) {
const ICurveArc* pArc = GetCurveArc( pCompo->GetCurve( i)) ;
@@ -1807,7 +1830,7 @@ Sawing::ProcessLine( const ICurve* pCrvP, const ICurveLine* pLineC, const ICurve
( m_Params.m_nWorkSide == SAW_WS_RIGHT && dAngCN < - EPS_ANG_SMALL))
bExtAngCN = false ;
}
// verifico eventuale attacco speciale a step (se parametri validi e su entità linea singola)
// verifico eventuale attacco speciale a step (se parametri validi e su entità linea singola)
double dLiStep = 0 ;
double dLiElev = 0 ;
if ( m_Params.m_dLiTang > 10 * EPS_SMALL && m_Params.m_dLiElev > 10 * EPS_SMALL &&
@@ -1828,13 +1851,13 @@ Sawing::ProcessLine( const ICurve* pCrvP, const ICurveLine* pLineC, const ICurve
return true ;
}
// Eventuale variazioni di velocità all'inizio e alla fine del percorso
// Eventuale variazioni di velocità all'inizio e alla fine del percorso
FseVar FvVar ;
if ( pCrvP == nullptr) {
string sFsta = ExtractInfo( m_Params.m_sUserNotes, "Fsta:") ;
string sFsta = ExtractInfo( m_Params.m_sUserNotes, "Fsta=") ;
if ( ! sFsta.empty()) {
string sLen, sPu ;
SplitFirst( sFsta, "=", sLen, sPu) ;
SplitFirst( sFsta, ",", sLen, sPu) ;
FromString( sLen, FvVar.dLenStart) ;
FvVar.dLenStart = max( FvVar.dLenStart, 0.) ;
FromString( sPu, FvVar.dPuStart) ;
@@ -1842,10 +1865,10 @@ Sawing::ProcessLine( const ICurve* pCrvP, const ICurveLine* pLineC, const ICurve
}
}
if ( pCrvN == nullptr) {
string sFend = ExtractInfo( m_Params.m_sUserNotes, "Fend:") ;
string sFend = ExtractInfo( m_Params.m_sUserNotes, "Fend=") ;
if ( ! sFend.empty()) {
string sLen, sPu ;
SplitFirst( sFend, "=", sLen, sPu) ;
SplitFirst( sFend, ",", sLen, sPu) ;
FromString( sLen, FvVar.dLenEnd) ;
FvVar.dLenEnd = max( FvVar.dLenEnd, 0.) ;
FromString( sPu, FvVar.dPuEnd) ;
@@ -1939,7 +1962,7 @@ Sawing::GenerateLinePv( const ICurveLine* pLine, const Vector3d& vtTool, const V
m_pGeomDB->SetMaterial( nId3, BLUE) ;
// valore di allungamento
double dExtraL = m_pMchMgr->GetCurrMachiningsMgr()->GetExtraLOnCutRegion() ;
double dExtraL = GetExtraLOnCutRegion() ;
// punti notevoli per regioni
Point3d ptRIni = ptIni ;
@@ -1976,7 +1999,7 @@ Sawing::GenerateLinePv( const ICurveLine* pLine, const Vector3d& vtTool, const V
ptREnd + vtDir * ( dDtEnd + dExtraL) , RTY_LOC) ;
m_pGeomDB->SetName( nReId, MCH_PV_RLOCUT) ;
m_pGeomDB->SetMaterial( nReId, INVISIBLE) ;
// eventuali ripetizioni in basso per tagli inclinati
if ( abs( m_Params.m_dSideAngle) > EPS_ANG_SMALL) {
// lunghezza movimento
@@ -2034,6 +2057,23 @@ Sawing::GenerateLinePv( const ICurveLine* pLine, const Vector3d& vtTool, const V
}
}
// creo regioni di lavorazione che interessano le superfici superiore e inferiore del grezzo considerando anche gli
// allungamenti dei baffi
int nSurfUpId = ExeCreateSurfFrRectangle3P( nPxId, ptIni - vtDir * ( dStartWhiskExt + 5 * EPS_SMALL),
ptCross + vtDir * ( dEndWhiskExt + 5 * EPS_SMALL),
ptEnd + vtDir * ( dEndWhiskExt + 5 * EPS_SMALL), RTY_LOC) ;
m_pGeomDB->SetName( nSurfUpId, MCH_PV_UP_RAWCUT) ;
m_pGeomDB->SetMaterial( nSurfUpId, INVISIBLE) ;
// solo se la lavorazione interessa il fondo del grezzo creo la superficie down
if ( dRbHeight < EPS_SMALL) {
int nSurfDownId = m_pGeomDB->CopyGlob( nSurfUpId, GDB_ID_NULL, nPxId) ;
double dMove = dElev + dRbHeight / cos( m_Params.m_dSideAngle * DEGTORAD) ;
Vector3d vtMove = - dMove * vtCorr ; vtMove.z = 0 ;
ExeMove( {nSurfDownId}, vtMove, RTY_LOC) ;
m_pGeomDB->SetName( nSurfDownId, MCH_PV_DOWN_RAWCUT) ;
m_pGeomDB->SetMaterial( nSurfDownId, INVISIBLE) ;
}
// salvo in info gruppo : larghezza XY del taglio, distanza XY tra centro e bordo taglio, extra taglio e quota minima della lama
m_pGeomDB->SetInfo( nPxId, MCH_PV_KEY_WT, vtToolH.LenXY()) ;
if ( dLiElev > EPS_SMALL)
@@ -2072,7 +2112,7 @@ Sawing::GenerateLineCl( const ICurveLine* pLine, const Vector3d& vtTool, const V
SetToolDir( vtTool) ;
SetCorrAuxDir( vtCorr) ;
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// distanza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
// flag di taglio inclinato
@@ -2256,17 +2296,16 @@ Sawing::GenerateLineCl( const ICurveLine* pLine, const Vector3d& vtTool, const V
Point3d ptP3 = pLine->GetEnd() + vtCorr * dDelta ;
if ( AddLinearMove( ptP3) == GDB_ID_NULL)
return false ;
// se non è ultimo passo
// se non è ultimo passo
if ( i != 0) {
// movimento di risalita sopra il punto finale
SetFeed( GetEndFeed()) ;
Point3d ptP4 = pLine->GetEnd() + vtCorr * ( dElev + dAppr / vtCorr.z) ;
if ( AddLinearMove( ptP4) == GDB_ID_NULL)
return false ;
// movimento di ritorno spora il punto iniziale
SetFeed( GetEndFeed()) ;
// movimento di ritorno in rapido sopra il punto iniziale
Point3d ptP5 = pLine->GetStart() + vtCorr * ( dElev + dAppr / vtCorr.z) ;
if ( AddLinearMove( ptP5) == GDB_ID_NULL)
if ( AddRapidMove( ptP5) == GDB_ID_NULL)
return false ;
}
}
@@ -2299,7 +2338,7 @@ Sawing::ProcessExtCurve( const ICurve* pCrvP, const ICurveComposite* pCrvC, cons
dMinRad = dRad ;
}
}
if ( dMinRad < m_pMchMgr->GetCurrMachiningsMgr()->GetExtSawArcMinRad()) {
if ( dMinRad < GetExtSawArcMinRad()) {
m_pMchMgr->SetWarning( 2258, "Warning in Sawing : Radius too small in ExtSawArc") ;
return true ;
}
@@ -2452,8 +2491,8 @@ Sawing::GenerateExtCurvePv( const ICurveComposite* pCrv, double dOffs,
if ( abs( m_Params.m_dSideAngle) > EPS_ANG_SMALL)
colCut = FUCHSIA ;
// dimensione da aggiungere alle regioni nelle parti in cui la lama è inclinata
double dExtraL = m_pMchMgr->GetCurrMachiningsMgr()->GetExtraLOnCutRegion() ;
// dimensione da aggiungere alle regioni nelle parti in cui la lama è inclinata
double dExtraL = GetExtraLOnCutRegion() ;
// lunghezza taglio parziale
double dDeltaT = (( dElev < 0.5 * m_TParams.m_dDiam) ? sqrt( dElev * m_TParams.m_dDiam - dElev * dElev) : 0) ;
@@ -2600,6 +2639,17 @@ Sawing::GenerateExtCurvePv( const ICurveComposite* pCrv, double dOffs,
return false ;
if ( ! ExeSurfFrAdd( nRId, nRsId) || ! ExeSurfFrAdd( nRId, nReId))
return false ;
// creo regioni di lavorazione che interessano le superfici superiore e inferiore del grezzo
int nSurfUpId = m_pGeomDB->CopyGlob( nRrId, GDB_ID_NULL, nPxId) ;
m_pGeomDB->SetName( nSurfUpId, MCH_PV_UP_RAWCUT) ;
m_pGeomDB->SetMaterial( nSurfUpId, INVISIBLE) ;
// solo se lavorazione interessa il fondo del grezzo creo la superficie down
if ( dRbHeight < EPS_SMALL) {
int nSurfDownId = m_pGeomDB->CopyGlob( nSurfUpId, GDB_ID_NULL, nPxId) ;
m_pGeomDB->SetName( nSurfDownId, MCH_PV_DOWN_RAWCUT) ;
m_pGeomDB->SetMaterial( nSurfDownId, INVISIBLE) ;
}
}
// altrimenti errore
@@ -2814,7 +2864,7 @@ Sawing::GenerateExtCurveCl( const ICurveComposite* pCrv,
SetPathId( nPxId) ;
SetCorrAuxDir( vtStaCorr) ;
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
@@ -2845,7 +2895,7 @@ Sawing::GenerateExtCurveCl( const ICurveComposite* pCrv,
CalculateToolAndCorrVersors( vtCurrDir, m_Params.m_nHeadSide, m_Params.m_nWorkSide, m_Params.m_dSideAngle, vtCurrTool, vtCurrCorr) ;
SetToolDir( vtCurrTool) ;
SetCorrAuxDir( vtCurrCorr) ;
if ( AddCurveMove( pSmpCrv, true) == GDB_ID_NULL)
if ( AddCurveMove( pSmpCrv) == GDB_ID_NULL)
return false ;
}
// 4 -> retrazione
@@ -2923,7 +2973,7 @@ Sawing::GenerateExtCurveCl( const ICurveComposite* pCrv,
pCopy->SimpleOffset( dOffs) ;
}
// emissione
if ( AddCurveMove( pCopy, true) == GDB_ID_NULL)
if ( AddCurveMove( pCopy) == GDB_ID_NULL)
return false ;
}
}
@@ -2956,7 +3006,7 @@ Sawing::GenerateExtCurveCl( const ICurveComposite* pCrv,
// inversione
pCopy->Invert() ;
// emissione
if ( AddCurveMove( pCopy, true) == GDB_ID_NULL)
if ( AddCurveMove( pCopy) == GDB_ID_NULL)
return false ;
}
}
@@ -3023,10 +3073,10 @@ Sawing::GenerateExtCurveCl( const ICurveComposite* pCrv,
pCopy->SimpleOffset( dOffs) ;
}
// emissione
if ( AddCurveMove( pCopy, true) == GDB_ID_NULL)
if ( AddCurveMove( pCopy) == GDB_ID_NULL)
return false ;
}
// se non è ultimo passo
// se non è ultimo passo
if ( i != 0) {
// ricavo punto di risalita e punto iniziale
Point3d ptP4 ;
@@ -3074,7 +3124,7 @@ Sawing::ProcessIntArc( const ICurve* pCrvP, const ICurveArc* pArcC, const ICurve
if ( IsNull( pArc))
return false ;
// determino l'inclinazione per ottenere il raggio e ne verifico il limite
double dMaxSideAng = m_pMchMgr->GetCurrMachiningsMgr()->GetIntSawArcMaxSideAng()+ EPS_ANG_SMALL ;
double dMaxSideAng = GetIntSawArcMaxSideAng() + EPS_ANG_SMALL ;
double dSawRad = m_TParams.m_dDiam / 2 ;
double dRad = pArc->GetRadius() ;
double dSinA = dSawRad / dRad ;
@@ -3170,7 +3220,7 @@ Sawing::ProcessIntArc( const ICurve* pCrvP, const ICurveArc* pArcC, const ICurve
m_pMchMgr->SetWarning( 2257, "Warning in Sawing : skipped Entity too small") ;
return true ;
}
// ricalcolo i versori fresa alle estremità (potrebbero essere cambiate)
// ricalcolo i versori fresa alle estremità (potrebbero essere cambiate)
pArc->GetStartDir( vtStaDirC) ;
pArc->GetMidDir( vtMidDirC) ;
pArc->GetEndDir( vtEndDirC) ;
@@ -3262,8 +3312,8 @@ Sawing::GenerateIntArcPv( const ICurveArc* pArc,
m_pGeomDB->SetName( nId3, MCH_PV_POST_CUT) ;
m_pGeomDB->SetMaterial( nId3, BLUE) ;
// dimensione da aggiungere alle regioni nelle parti in cui la lama è inclinata
double dExtraL = m_pMchMgr->GetCurrMachiningsMgr()->GetExtraLOnCutRegion() ;
// dimensione da aggiungere alle regioni nelle parti in cui la lama è inclinata
double dExtraL = GetExtraLOnCutRegion() ;
// regione ridotta di taglio per nesting (escluse parti iniziali e finali)
PtrOwner<ICurveComposite> pCmpRr( GenerateIntArcPvTrueCut( pArc, dDeltaInt, dDeltaExt, dExtraL)) ;
@@ -3316,6 +3366,17 @@ Sawing::GenerateIntArcPv( const ICurveArc* pArc,
if ( ! ExeSurfFrAdd( nRId, nRsId) || ! ExeSurfFrAdd( nRId, nReId))
return false ;
// creo regioni di lavorazione che interessano le superfici superiore e inferiore del grezzo
int nSurfUpId = m_pGeomDB->CopyGlob( nRrId, GDB_ID_NULL, nPxId) ;
m_pGeomDB->SetName( nSurfUpId, MCH_PV_UP_RAWCUT) ;
m_pGeomDB->SetMaterial( nSurfUpId, INVISIBLE) ;
// solo se lavorazione interessa il fondo del grezzo creo la superficie down
if ( dRbHeight < EPS_SMALL) {
int nSurfDownId = m_pGeomDB->CopyGlob( nSurfUpId, GDB_ID_NULL, nPxId) ;
m_pGeomDB->SetName( nSurfDownId, MCH_PV_DOWN_RAWCUT) ;
m_pGeomDB->SetMaterial( nSurfDownId, INVISIBLE) ;
}
// salvo in info gruppo : larghezza XY del taglio, distanza XY tra centro e bordo taglio, extra taglio e quota minima della lama
m_pGeomDB->SetInfo( nPxId, MCH_PV_KEY_WT, dDeltaInt + dDeltaExt) ;
m_pGeomDB->SetInfo( nPxId, MCH_PV_KEY_DT, dDeltaT * dLenCoeff) ;
@@ -3510,7 +3571,7 @@ Sawing::GenerateIntArcCl( const ICurveArc* pArc,
// Imposto dati comuni
SetPathId( nPxId) ;
// recupero distanza di sicurezza
double dSafeZ = m_pMchMgr->GetCurrMachiningsMgr()->GetSafeZ() ;
double dSafeZ = GetSafeZ() ;
// lunghezza di approccio/retrazione
double dAppr = m_Params.m_dStartPos ;
@@ -3548,12 +3609,12 @@ Sawing::GenerateIntArcCl( const ICurveArc* pArc,
else {
Point3d ptMid ;
pArc->GetMidPoint( ptMid) ;
// prima metà arco
// prima metà arco
SetToolDir( vtMidTool) ;
SetCorrAuxDir( vtMidCorr) ;
if ( AddArcMove( ptMid, ptCen, dAngCen / 2, vtN) == GDB_ID_NULL)
return false ;
// seconda metà arco
// seconda metà arco
SetToolDir( vtEndTool) ;
SetCorrAuxDir( vtEndCorr) ;
if ( AddArcMove( ptP3, ptCen, dAngCen / 2, vtN) == GDB_ID_NULL)
@@ -3634,12 +3695,12 @@ Sawing::GenerateIntArcCl( const ICurveArc* pArc,
pArc->GetMidPoint( ptMid) ;
ptMid += Z_AX * dDelta ;
double dCurrAngCen = dAngCen / 2 * ((( i % 2) == 0) ? -1 : 1) ;
// prima metà arco
// prima metà arco
SetToolDir( vtMidTool) ;
SetCorrAuxDir( vtMidCorr) ;
if ( AddArcMove( ptMid, ptCen, dCurrAngCen, vtN) == GDB_ID_NULL)
return false ;
// seconda metà arco
// seconda metà arco
SetToolDir( ( ( i % 2) == 0) ? vtStaTool : vtEndTool) ;
SetCorrAuxDir( ( ( i % 2) == 0) ? vtStaCorr : vtEndCorr) ;
if ( AddArcMove( ptP3, ptCen, dCurrAngCen, vtN) == GDB_ID_NULL)
@@ -3723,18 +3784,18 @@ Sawing::GenerateIntArcCl( const ICurveArc* pArc,
Point3d ptMid ;
pArc->GetMidPoint( ptMid) ;
ptMid += Z_AX * dDelta ;
// prima metà arco
// prima metà arco
SetToolDir( vtMidTool) ;
SetCorrAuxDir( vtMidCorr) ;
if ( AddArcMove( ptMid, ptCen, dAngCen / 2, vtN) == GDB_ID_NULL)
return false ;
// seconda metà arco
// seconda metà arco
SetToolDir( vtEndTool) ;
SetCorrAuxDir( vtEndCorr) ;
if ( AddArcMove( ptP3, ptCen, dAngCen / 2, vtN) == GDB_ID_NULL)
return false ;
}
// se non è ultimo passo
// se non è ultimo passo
if ( i != 0) {
// movimento di risalita sopra il punto finale
SetFeed( GetEndFeed()) ;
@@ -3812,29 +3873,40 @@ bool
Sawing::CalculateToolAndCorrVersors( const Vector3d& vtTang, int nHeadSide, int nWorkSide, double dSideAng,
Vector3d& vtTool, Vector3d& vtCorr)
{
// Versore fresa : annullo la componente in Z e normalizzo
vtTool = vtTang ;
vtTool.z = 0 ;
if ( ! vtTool.Normalize())
// Direzione tangente nel piano XY
Vector3d vtXYTg = vtTang ;
vtXYTg.z = 0 ;
double dLenXYTg = vtXYTg.Len() ;
if ( dLenXYTg < EPS_SMALL)
return false ;
// ruoto attorno a Zglob+ a seconda del lato mandrino
vtXYTg /= dLenXYTg ;
// se direzione tangente inclinata in Z e SideAng non nullo devo calcolare la vera tangente nel piano XY
if ( abs( vtTang.z) > EPS_SMALL && abs( dSideAng) > EPS_ANG_SMALL) {
double dSinDelta = vtTang.z * tan( dSideAng * DEGTORAD) / dLenXYTg ;
double dCosDelta = sqrt( 1 - dSinDelta * dSinDelta) ;
if ( nHeadSide == SAW_HS_LEFT)
vtXYTg.Rotate( Z_AX, dCosDelta, dSinDelta) ;
else
vtXYTg.Rotate( Z_AX, dCosDelta, -dSinDelta) ;
}
// Versore fresa : ruoto direzione nel piano XY attorno a Zglob+ a seconda del lato mandrino
vtTool = vtXYTg ;
if ( nHeadSide == SAW_HS_LEFT)
vtTool.Rotate( Z_AX, 0, 1) ;
else
vtTool.Rotate( Z_AX, 0, -1) ;
// Versore correzione
// Versore correzione : se lama sbandata devo aggiustare
vtCorr = Z_AX ;
// Se lama sbandata
if ( abs( dSideAng) > EPS_ANG_SMALL) {
if ( nWorkSide == SAW_WS_RIGHT) {
vtTool.Rotate( vtTang, - dSideAng) ;
vtCorr.Rotate( vtTang, - dSideAng) ;
vtTool.Rotate( vtXYTg, - dSideAng) ;
vtCorr.Rotate( vtXYTg, - dSideAng) ;
}
else {
vtTool.Rotate( vtTang, dSideAng) ;
vtCorr.Rotate( vtTang, dSideAng) ;
vtTool.Rotate( vtXYTg, dSideAng) ;
vtCorr.Rotate( vtXYTg, dSideAng) ;
}
}
@@ -3845,7 +3917,7 @@ Sawing::CalculateToolAndCorrVersors( const Vector3d& vtTang, int nHeadSide, int
bool
Sawing::AdjustForSide( ICurve* pCurve)
{
// se lato lavoro e lato mandrino coincidono, non devo fare alcunché
// se lato lavoro e lato mandrino coincidono, non devo fare alcunché
if ( ( m_Params.m_nWorkSide == SAW_WS_LEFT && m_Params.m_nHeadSide == SAW_HS_LEFT) ||
( m_Params.m_nWorkSide == SAW_WS_RIGHT && m_Params.m_nHeadSide == SAW_HS_RIGHT))
return true ;
@@ -4014,7 +4086,7 @@ Sawing::AdjustLineForEdges( ICurveLine* pLine, double dElev, const Vector3d& vtC
dDeltaLoExt = dDeltaF ;
}
}
// controllo se lunghezza entità accettabile
// controllo se lunghezza entità accettabile
const double MIN_LEN = 1 ;
double dLenXY = DistXY( pLine->GetStart(), pLine->GetEnd()) ;
if ( dDeltaI + dLenXY + dDeltaF < MIN_LEN) {
@@ -4085,7 +4157,7 @@ Sawing::AdjustCurveForEdges( ICurve* pCrv, double dElev, double dLenCoeff,
dDeltaF = dDeltaT ;
}
dDeltaF *= dLenCoeff ;
// controllo se lunghezza entità accettabile
// controllo se lunghezza entità accettabile
const double MIN_LEN = 1 ;
double dLenXY ;
pCrv->GetLength( dLenXY) ;
SawingData.h
+6 -2
View File
@@ -99,6 +99,10 @@ struct SawingData : public MachiningData
//----------------------------------------------------------------------------
inline const SawingData* GetSawingData( const MachiningData* pMdata)
{ return (dynamic_cast<const SawingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_SAWING)
return nullptr ;
return ( static_cast<const SawingData*>( pMdata)) ; }
inline SawingData* GetSawingData( MachiningData* pMdata)
{ return (dynamic_cast<SawingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_SAWING)
return nullptr ;
return ( static_cast<SawingData*>( pMdata)) ; }
SetupMgr.cpp
+21 -11
View File
@@ -181,16 +181,12 @@ SetupMgr::Import( const string& sFileName)
m_pMchMgr->GetCurrMachGroup() == GDB_ID_NULL)
return false ;
// recupero il gruppo di setup
int nSetupId = m_pMchMgr->GetCurrSetupGroupId() ;
// inizializzo lo scanner
Scanner TheScanner ;
if ( ! TheScanner.Init( sFileName, ";"))
return false ;
// eseguo la lettura dei campi di attrezzaggio
int nPos = 1 ;
string sLine ;
while ( TheScanner.GetLine( sLine)) {
// salto dichiarazione sezione
@@ -228,8 +224,6 @@ SetupMgr::Import( const string& sFileName)
stuData.m_nExit = 0 ;
m_vStuData.emplace_back( stuData) ;
}
// passo alla successiva posizione
++ nPos ;
}
return true ;
@@ -277,14 +271,20 @@ SetupMgr::GetPosData( int nPos, string& sTcPos, string& sHead, int& nExit, strin
bool
SetupMgr::GetToolData( const string& sName, string& sTcPos, string& sHead, int& nExit, int* pnPos) const
{
// reset valori di ritorno
sTcPos.clear() ;
sHead.clear() ;
nExit = 0 ;
if ( pnPos != nullptr)
*pnPos = 0 ;
// verifico validità utensile
if ( IsEmptyOrSpaces( sName))
return false ;
// cerco l'utensile
int nI = - 1 ;
for ( size_t i = 0 ; i < m_vStuData.size() ; ++ i) {
for ( int i = 0 ; i < int( m_vStuData.size()) ; ++ i) {
if ( m_vStuData[i].m_nExit > 0 && EqualNoCase( sName, m_vStuData[i].m_sName)) {
nI = int( i) ;
nI = i ;
break ;
}
}
@@ -318,11 +318,21 @@ SetupMgr::GetToolName( const string& sHead, int nExit, string& sName) const
bool
SetupMgr::GetToolsInSetupPos( const string& sTcPos, STRVECTOR& vsTools) const
{
// default vettore vuoto
vsTools.clear() ;
// eseguo ricerca
// verifico macchina
if ( m_pMachine == nullptr)
return false ;
// eseguo ricerca (con inserimento nel vettore secondo indice dell'uscita)
for ( int i = 0 ; i < int( m_vStuData.size()) ; ++ i) {
if ( EqualNoCase( sTcPos, m_vStuData[i].m_sTcPos)) {
vsTools.emplace_back( m_vStuData[i].m_sName) ;
if ( ! IsEmptyOrSpaces( m_vStuData[i].m_sHead) && EqualNoCase( sTcPos, m_vStuData[i].m_sTcPos)) {
if ( vsTools.empty()) {
int nExitCnt = m_pMachine->GetHeadExitCount( m_vStuData[i].m_sHead) ;
vsTools.resize( nExitCnt) ;
}
int nExit = m_vStuData[i].m_nExit ;
if ( nExit > 0 && nExit <= int( vsTools.size()))
vsTools[nExit - 1] = m_vStuData[i].m_sName ;
}
}
return true ;
Simulator.h
+28 -148
View File
@@ -1,25 +1,24 @@
//----------------------------------------------------------------------------
// EgalTech 2015-2023
// EgalTech 2015-2024
//----------------------------------------------------------------------------
// File : Simulator.h Data : 16.01.23 Versione : 2.5a2
// Contenuto : Dichiarazione della classe Simulator.
// File : Simulator.h Data : 01.09.24 Versione : 2.6i1
// Contenuto : Dichiarazione della classe interfaccia ISimulator.
//
//
//
// Modifiche : 19.10.15 DS Creazione modulo.
// Modifiche : 01.09.24 DS Creazione modulo.
//
//
//----------------------------------------------------------------------------
#pragma once
#include "CamData.h"
#include "/EgtDev/Include/EGkVector3d.h"
#include "/EgtDev/Include/EMkSimuGenConst.h"
#include "/EgtDev/Include/EgtNumCollection.h"
#include <string>
class MachMgr ;
class IGeomDB ;
class Machine ;
class PerformanceCounter ;
//------------------------ Struttura per movimento esterno assi --------------
struct SimAxMv
@@ -38,146 +37,27 @@ enum SimAxMvRes { SIM_AXMV_RES_STOP = -1,
SIM_AXMV_RES_OK = 1} ;
//----------------------------------------------------------------------------
class Simulator
class __declspec( novtable) ISimulator
{
public :
Simulator( void) ;
~Simulator( void) ;
bool Init( MachMgr* pMchMgr) ;
bool Start( bool bFirst) ;
bool Move( int& nStatus) ;
bool GoHome( void) ;
bool SetStep( double dStep) ;
bool SetUiStatus( int nUiStatus) ;
bool GetAxisInfoPos( int nI, std::string& sName, std::string& sToken, bool& bLinear, double& dVal) const ;
bool GetToolInfo( std::string& sName, double& dSpeed) const ;
bool GetOperationInfo( std::string& sName, int& nType) const ;
bool GetMoveInfo( int& nGmove, double& dFeed) const ;
bool AddCollisionObj( int nInd, bool bToolOn, int nFrameId, int nType, const Vector3d& vtMove, double dPar1, double dPar2, double dPar3) ;
bool ExecCollisionCheck( int& nCdInd, int& nObjInd, int nMoveType) ;
bool OnCollision( int nCdInd, int nObjInd, int& nErr) ;
bool SetToolForVmill( const std::string& sTool, const std::string& sHead, int nExit, const INTVECTOR& vVmill, bool bFirst) ;
int MoveAxes( int nMoveType, const SAMVECTOR& vAxNaEpSt) ;
private :
bool UpdateTool( bool bFirst, int& nErr) ;
bool UpdateAxes( void) ;
bool UpdateAxesPos( void) ;
bool ResetInterpolation( void) ;
bool ResetAxes( void) ;
bool ResetAuxAxes( void) ;
private :
bool VerifySetup( void) ;
bool FindAndManageOperationStart( bool bStart, bool bFirst, int& nStatus) ;
bool ManageOperationEnd( int& nStatus) ;
bool FindAndManagePathStart( int& nStatus) ;
bool ManagePathEnd( int& nStatus) ;
bool ManagePathStartAux( int& nStatus) ;
bool ManagePathEndAux( int& nStatus) ;
bool ManageMove( int& nStatus) ;
bool ManageSingleMove( int& nStatus, double& dMove) ;
int CalcStatusOnError( int nErr) ;
bool GetHeadCurrPosDirAux( const std::string& sHead, int nExit, Point3d& ptH, Vector3d& vtH, Vector3d& vtA) ;
bool ExecLineVmill( int nVmId, int nCurrTool, double dVmTdOffs, double dVmAdOffs,
const Point3d& ptHi, const Vector3d& vtHi, const Vector3d& vtAi, const Frame3d& frVzmI,
const Point3d& ptHf, const Vector3d& vtHf, const Vector3d& vtAf, const Frame3d& frVzmF) ;
bool NeedCollisionCheck( void) const
{ return ( ! m_CollObj.empty() && ! m_CdId.empty()) ; }
bool Stopped( void)
{ return ( m_nUiStatus == MCH_UISIM_STOP) ; }
bool OnStart( bool bFirst) ;
bool OnEnd( void) ;
bool OnDispositionStarting( int nOpId, int nOpInd, int nPhase,
const std::string& sTable, const Point3d& ptOri1, bool bEmpty, bool bSomeByHand) ;
bool OnDispositionStart( int nOpId, int nOpInd, int nPhase,
const std::string& sTable, const Point3d& ptOri1, bool bEmpty, bool bSomeByHand) ;
bool OnDispositionEnd( void) ;
bool OnToolSelect( const std::string& sTool, const std::string& sHead, int nExit, const std::string& sTcPos, bool bFirst, int& nErr) ;
bool OnToolDeselect( const std::string& sNextTool, const std::string& sNextHead, int nNextExit, const std::string& sNextTcPos, int& nErr) ;
bool OnMachiningStart( int nOpId, int nOpInd, const Point3d& ptMin, const Point3d& ptMax,
const DBLVECTOR& vAxMin, const DBLVECTOR& vAxMax) ;
bool OnMachiningEnd( void) ;
bool OnPathStartAux( int nInd, const std::string& sAS, int& nErr) ;
bool OnPathEndAux( int nInd, const std::string& sAE, int& nErr) ;
bool OnPathStart( int nClPathId, int nClPathInd, int nAS, const Point3d& ptStart, const Point3d& ptEnd,
const Vector3d& vtExtr, const Point3d& ptMin, const Point3d& ptMax,
const DBLVECTOR& vAxMin, const DBLVECTOR& vAxMax, double dElev) ;
bool OnPathEnd( int nAE) ;
bool OnMoveStart( const CamData* pCamData, int& nErr) ;
bool OnMoveEnd( int& nErr) ;
bool OnResetMachine( void) ;
private :
struct CollObj {
int nInd ;
bool bToolOn ;
int nFrameId ;
int nType ;
Vector3d vtMove ;
double dPar1 ;
double dPar2 ;
double dPar3 ;
CollObj( void) : nInd( 0), bToolOn( false), nFrameId( -1), nType( 0), vtMove(), dPar1( 0), dPar2( 0), dPar3( 0) {}
CollObj( int nI, bool bTOn, int nF, int nT, const Vector3d& vtM, double dP1, double dP2, double dP3)
: nInd( nI), bToolOn( bTOn), nFrameId( nF), nType( nT), vtMove( vtM), dPar1( dP1), dPar2( dP2), dPar3( dP3) {}
} ;
typedef std::vector<CollObj> COBVECTOR ;
struct VmTool
{
std::string sName ;
std::string sHead ;
int nExit ;
double dTdOffs ;
double dAdOffs ;
VmTool( void) : nExit( 0), dTdOffs( 0), dAdOffs( 0) {}
VmTool( std::string sN, std::string sH, int nE, double dT, double dA)
: sName( sN), sHead( sH), nExit( nE), dTdOffs( dT), dAdOffs( dA) {}
} ;
typedef std::vector<VmTool> VMTVECTOR ;
private :
MachMgr* m_pMchMgr ; // puntatore al gestore di tutte le lavorazioni
IGeomDB* m_pGeomDB ; // puntatore al DB geometrico
Machine* m_pMachine ; // puntatore alla macchina
PerformanceCounter* m_pPerfCnt ; // timer per calcolo FPS
double m_dStep ; // lunghezza di riferimento per la velocità di simulazione
int m_nUiStatus ; // stato simulazione a livello utente
int m_nOpId ; // identificativo della operazione (lavoraz.) corrente
int m_nOpInd ; // contatore della operazione (lavoraz.) corrente
int m_nCLPathId ; // identificativo del percorso di lavoro corrente
int m_nCLPathInd ; // contatore del percorso di lavoro corrente nell'operazione
int m_nEntId ; // identificativo dell'entità corrente
int m_nEntInd ; // contatore dell'entità corrente nel percorso di lavoro
double m_dCoeff ; // coefficiente di esecuzione del movimento corrente (0...1)
int m_nAuxSTot ; // numero totale movimenti ausiliari di inizio percorso
int m_nAuxSInd ; // indice del movimento ausiliario di inizio percorso corrente
int m_nAuxETot ; // numero totale movimenti ausiliari di fine percorso
int m_nAuxEInd ; // indice del movimento ausiliario di fine percorso corrente
std::string m_sTool ; // nome dell'utensile corrente
std::string m_sHead ; // nome della testa corrente
int m_nExit ; // indice dell'uscita corrente
double m_dTDiam ; // diametro dell'utensile corrente
INTVECTOR m_VmId ; // vettore identificativi Zmap per Virtual Milling
INTVECTOR m_CdId ; // vettore identificativi Zmap per Collision Detection
VMTVECTOR m_VmTool ; // vettore utensili attivi per virtual milling
COBVECTOR m_CollObj ; // vettore oggetti da testare per collisione con grezzo
double m_dSafeDist ; // distanza di sicurezza per verifica collisioni
int m_nAxesMask ; // maschera a bit di abilitazione movimento assi (solo se rapido)
bool m_bEnabAxes ; // flag abilitazione movimento assi attivi
bool m_bShowAxes ; // flag visualizzazione assi attivi
STRVECTOR m_AxesName ; // nomi degli assi macchina attivi
STRVECTOR m_AxesToken ; // token degli assi macchina attivi
BOOLVECTOR m_AxesInvert ; // flag di asse con verso invertito degli assi macchina attivi
DBLVECTOR m_AxesOffset ; // valore di offset delgli assi macchina ttivi
BOOLVECTOR m_AxesLinear ; // flag di lineare degli assi macchina attivi
DBLVECTOR m_AxesVal ; // valori degli assi macchina all'inizio del movimento corrente
STRVECTOR m_AuxAxesName ; // nomi degli assi macchina ausiliari abilitati
STRVECTOR m_AuxAxesToken ; // token degli assi macchina ausiliari abilitati
BOOLVECTOR m_AuxAxesInvert ; // flag di asse con verso invertito degli assi macchina ausiliari abilitati
DBLVECTOR m_AuxAxesOffset ; // valore di offset degli assi macchina ausiliari abilitati
BOOLVECTOR m_AuxAxesLinear ; // flag di lineare degli assi macchina ausiliari abilitati
DBLVECTOR m_AuxAxesVal ; // valori degli assi macchina ausiliari all'inizio del movimento corrente
DBLVECTOR m_AuxAxesEnd ; // valori degli assi macchina ausiliari alla fine del movimento corrente
INTVECTOR m_AuxAxesLink ; // indice + 1 asse principale di aggancio (negativo valore opposto, 0 nessuno)
virtual ~ISimulator( void) {}
virtual bool Init( MachMgr* pMchMgr) = 0 ;
virtual bool Start( bool bFirst) = 0 ;
virtual bool Move( int& nStatus) = 0 ;
virtual bool GoHome( void) = 0 ;
virtual bool SetStep( double dStep) = 0 ;
virtual bool SetUiStatus( int nUiStatus) = 0 ;
virtual bool GetAxisInfoPos( int nI, std::string& sName, std::string& sToken, bool& bLinear, double& dVal) const = 0 ;
virtual bool GetToolInfo( std::string& sName, double& dSpeed) const = 0 ;
virtual bool GetOperationInfo( std::string& sName, int& nType) const = 0 ;
virtual bool GetMoveInfo( int& nGmove, double& dFeed) const = 0 ;
virtual bool AddCollisionObj( int nInd, bool bToolOn, int nFrameId, int nType,
const Vector3d& vtMove, double dPar1, double dPar2, double dPar3) = 0 ;
virtual bool ExecCollisionCheck( int& nCdInd, int& nObjInd, int nMoveType) = 0 ;
virtual bool OnCollision( int nCdInd, int nObjInd, int& nErr) = 0 ;
virtual bool SetToolForVmill( const std::string& sTool, const std::string& sHead, int nExit, int nFlag,
double dPar1, double dPar2, const INTVECTOR& vVmill, bool bFirst) = 0 ;
virtual bool EnableToolsForVmill( bool bEnable) = 0 ;
virtual int MoveAxes( int nMoveType, const SAMVECTOR& vAxNaEpSt) = 0 ;
virtual bool SaveCmd( int nType, int nPar, const std::string& sPar) = 0 ;
} ;
SimulatorMP.cpp
+2573
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SimulatorMP.h
+209
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@@ -0,0 +1,209 @@
//----------------------------------------------------------------------------
// EgalTech 2024-2024
//----------------------------------------------------------------------------
// File : SimulatorMP.h Data : 01.09.24 Versione : 2.6i1
// Contenuto : Dichiarazione della classe SimulatorMP.
// Simulatore multi-processo.
//
//
// Modifiche : 01.09.24 DS Creazione modulo.
//
//
//----------------------------------------------------------------------------
#pragma once
#include "Simulator.h"
#include "CamData.h"
class IGeomDB ;
class Machine ;
class PerformanceCounter ;
//----------------------------------------------------------------------------
ISimulator* CreateSimulatorMP( void) ;
//----------------------------------------------------------------------------
class SimulatorMP : public ISimulator
{
public : // ISimulator
~SimulatorMP( void) override ;
bool Init( MachMgr* pMchMgr) override ;
bool Start( bool bFirst) override ;
bool Move( int& nStatus) override ;
bool GoHome( void) override ;
bool SetStep( double dStep) override ;
bool SetUiStatus( int nUiStatus) override ;
bool GetAxisInfoPos( int nI, std::string& sName, std::string& sToken, bool& bLinear, double& dVal) const override ;
bool GetToolInfo( std::string& sName, double& dSpeed) const override ;
bool GetOperationInfo( std::string& sName, int& nType) const override ;
bool GetMoveInfo( int& nGmove, double& dFeed) const override ;
bool AddCollisionObj( int nInd, bool bToolOn, int nFrameId, int nType,
const Vector3d& vtMove, double dPar1, double dPar2, double dPar3) override ;
bool ExecCollisionCheck( int& nCdInd, int& nObjInd, int nMoveType) override ;
bool OnCollision( int nCdInd, int nObjInd, int& nErr) override ;
bool SetToolForVmill( const std::string& sTool, const std::string& sHead, int nExit, int nFlag,
double dPar1, double dPar2, const INTVECTOR& vVmill, bool bFirst) override ;
bool EnableToolsForVmill( bool bEnable) override ;
int MoveAxes( int nMoveType, const SAMVECTOR& vAxNaEpSt) override ;
bool SaveCmd( int nType, int nPar, const std::string& sPar) override ;
public :
SimulatorMP( void) ;
private :
bool UpdateMachiningTool( bool bFirst, bool& bDeselect, int& nErr) ;
bool UpdateDispositionTool( bool bFirst, int& nErr) ;
bool UpdateAxes( void) ;
bool UpdateAxesPos( void) ;
bool ResetInterpolation( void) ;
bool ResetAxes( void) ;
bool ResetAuxAxes( void) ;
private :
bool VerifySetup( void) ;
bool FindAndManageOperationStart( bool bStart, bool bFirst, bool& bChangedTool, int& nStatus) ;
bool ManageOperationEnd( int& nStatus) ;
bool FindAndManagePathStart( int& nStatus) ;
bool ManagePathEnd( int& nStatus) ;
bool ManagePathStartAux( int& nStatus) ;
bool ManagePathEndAux( int& nStatus) ;
bool ManageMove( int& nStatus) ;
bool ManageSingleMove( int& nStatus, double& dMove) ;
int CalcStatusOnError( int nErr) ;
bool GetHeadCurrPosDirAux( const std::string& sHead, int nExit, Point3d& ptH, Vector3d& vtH, Vector3d& vtA) ;
bool ExecLineVmill( int nVmId, int nCurrTool, double dVmTdOffs, double dVmAdOffs,
const Point3d& ptHi, const Vector3d& vtHi, const Vector3d& vtAi, const Frame3d& frVzmI,
const Point3d& ptHf, const Vector3d& vtHf, const Vector3d& vtAf, const Frame3d& frVzmF) ;
bool NeedCollisionCheck( void) const
{ return ( ! m_CollObj.empty() && ! m_CdId.empty()) ; }
bool Stopped( void)
{ return ( m_nUiStatus == MCH_UISIM_STOP) ; }
bool SetCollisionMark( int nCdInd, int nObjInd) ;
bool ResetCollisionMark( void) ;
bool OnInit( void) ;
bool OnExit( void) ;
bool OnProgramStart( bool bFirst) ;
bool OnProgramEnd( void) ;
bool OnDispositionStarting( int nOpId, int nOpInd, int nPhase,
const std::string& sTable, const Point3d& ptOri1, bool bEmpty, bool bSomeByHand) ;
bool OnDispositionStart( int nOpId, int nOpInd, int nPhase,
const std::string& sTable, const Point3d& ptOri1, bool bEmpty, bool bSomeByHand) ;
bool OnDispositionEnd( void) ;
bool OnToolSelect( const std::string& sTool, const std::string& sHead, int nExit, const std::string& sTcPos, bool bFirst, int& nErr) ;
bool OnToolDeselect( const std::string& sNextTool, const std::string& sNextHead, int nNextExit, const std::string& sNextTcPos, int& nErr) ;
bool OnMachiningStart( int nOpId, int nOpInd, const Point3d& ptMin, const Point3d& ptMax,
const DBLVECTOR& vAxMin, const DBLVECTOR& vAxMax) ;
bool OnMachiningEnd( void) ;
bool OnPathStartAux( int nInd, const std::string& sAS, int& nErr) ;
bool OnPathEndAux( int nInd, const std::string& sAE, int& nErr) ;
bool OnPathStart( int nClPathId, int nClPathInd, int nAS, const Point3d& ptStart, const Point3d& ptEnd,
const Vector3d& vtExtr, const Point3d& ptMin, const Point3d& ptMax,
const DBLVECTOR& vAxMin, const DBLVECTOR& vAxMax, double dElev) ;
bool OnPathEnd( int nAE) ;
bool OnMoveStart( const CamData* pCamData, const CamData* pNextCamData, int& nErr) ;
bool OnMoveEnd( int& nErr) ;
bool OnResetMachine( void) ;
bool ExecCmdData( int& nStatus) ;
bool ExecAllCmdData( int& nStatus) ;
private :
struct CollObj {
int nInd ;
bool bToolOn ;
int nFrameId ;
int nType ;
Vector3d vtMove ;
double dPar1 ;
double dPar2 ;
double dPar3 ;
CollObj( void) : nInd( 0), bToolOn( false), nFrameId( -1), nType( 0), vtMove(), dPar1( 0), dPar2( 0), dPar3( 0) {}
CollObj( int nI, bool bTOn, int nF, int nT, const Vector3d& vtM, double dP1, double dP2, double dP3)
: nInd( nI), bToolOn( bTOn), nFrameId( nF), nType( nT), vtMove( vtM), dPar1( dP1), dPar2( dP2), dPar3( dP3) {}
} ;
typedef std::vector<CollObj> COBVECTOR ;
struct VmTool
{
std::string sName ;
std::string sHead ;
int nExit ;
double dTdOffs ;
double dAdOffs ;
VmTool( void) : nExit( 0), dTdOffs( 0), dAdOffs( 0) {}
VmTool( std::string sN, std::string sH, int nE, double dT, double dA)
: sName( sN), sHead( sH), nExit( nE), dTdOffs( dT), dAdOffs( dA) {}
} ;
typedef std::vector<VmTool> VMTVECTOR ;
enum { SIS_CREATED = 0,
SIS_INITIALIZED = 1,
SIS_READYTOSTART = 2,
SIS_READYTORUN = 3} ;
private :
struct CmdData {
int nType ;
int nMoveType ;
SAMVECTOR vAxNaEpSt ;
int nPar ;
std::string sPar ;
CmdData( void) : nType(0) {}
CmdData( int nM, const SAMVECTOR& vAx)
: nType( 1), nMoveType( nM), vAxNaEpSt( vAx) {}
CmdData( int nT, int nP, const std::string& sP)
: nType( nT), nPar( nP), sPar( sP) {}
} ;
typedef std::vector<CmdData> CMDVECTOR ;
private :
MachMgr* m_pMchMgr ; // puntatore al gestore di tutte le lavorazioni
IGeomDB* m_pGeomDB ; // puntatore al DB geometrico
Machine* m_pMachine ; // puntatore alla macchina
PerformanceCounter* m_pPerfCnt ; // timer per calcolo FPS
int m_nStatus ; // stato interno del simulatore (creato, inizializzato, pronto al movimento)
double m_dStep ; // lunghezza di riferimento per la velocità di simulazione
int m_nUiStatus ; // stato simulazione a livello utente
int m_nOpId ; // identificativo della operazione (lavoraz.) corrente
int m_nOpInd ; // contatore della operazione (lavoraz.) corrente
int m_nCLPathId ; // identificativo del percorso di lavoro corrente
int m_nCLPathInd ; // contatore del percorso di lavoro corrente nell'operazione
int m_nEntId ; // identificativo dell'entità corrente
int m_nEntInd ; // contatore dell'entità corrente nel percorso di lavoro
double m_dCoeff ; // coefficiente di esecuzione del movimento corrente (0...1)
bool m_bChangedTool ; // flag di utensile appena scaricato
int m_nAuxSTot ; // numero totale movimenti ausiliari di inizio percorso
int m_nAuxSInd ; // indice del movimento ausiliario di inizio percorso corrente
int m_nAuxETot ; // numero totale movimenti ausiliari di fine percorso
int m_nAuxEInd ; // indice del movimento ausiliario di fine percorso corrente
std::string m_sTool ; // nome dell'utensile corrente
std::string m_sHead ; // nome della testa corrente
int m_nExit ; // indice dell'uscita corrente
double m_dTDiam ; // diametro dell'utensile corrente
bool m_bCutOnTip ; // flag capacità di lavorare di testa dell'utensile corrente
bool m_bEnableVm ; // flag abilitazione Virtual Milling
INTVECTOR m_VmId ; // vettore identificativi Zmap per Virtual Milling
INTVECTOR m_CdId ; // vettore identificativi Zmap per Collision Detection
VMTVECTOR m_VmTool ; // vettore utensili attivi per virtual milling
COBVECTOR m_CollObj ; // vettore oggetti da testare per collisione con grezzo
double m_dSafeDist ; // distanza di sicurezza per verifica collisioni
INTVECTOR m_nCollMarkId ; // elenco oggetti marcati per visualizzare meglio la collisione rilevata
int m_nAxesMask ; // maschera a bit di abilitazione movimento assi (solo se rapido)
bool m_bEnabAxes ; // flag abilitazione movimento assi attivi
bool m_bShowAxes ; // flag visualizzazione assi attivi
STRVECTOR m_AxesName ; // nomi degli assi macchina attivi
STRVECTOR m_AxesToken ; // token degli assi macchina attivi
BOOLVECTOR m_AxesInvert ; // flag di asse con verso invertito degli assi macchina attivi
DBLVECTOR m_AxesOffset ; // valore di offset delgli assi macchina ttivi
BOOLVECTOR m_AxesLinear ; // flag di lineare degli assi macchina attivi
DBLVECTOR m_AxesVal ; // valori degli assi macchina all'inizio del movimento corrente
STRVECTOR m_AuxAxesName ; // nomi degli assi macchina ausiliari abilitati
STRVECTOR m_AuxAxesToken ; // token degli assi macchina ausiliari abilitati
BOOLVECTOR m_AuxAxesInvert ; // flag di asse con verso invertito degli assi macchina ausiliari abilitati
DBLVECTOR m_AuxAxesOffset ; // valore di offset degli assi macchina ausiliari abilitati
BOOLVECTOR m_AuxAxesLinear ; // flag di lineare degli assi macchina ausiliari abilitati
DBLVECTOR m_AuxAxesVal ; // valori degli assi macchina ausiliari all'inizio del movimento corrente
DBLVECTOR m_AuxAxesEnd ; // valori degli assi macchina ausiliari alla fine del movimento corrente
INTVECTOR m_AuxAxesLink ; // indice + 1 asse principale di aggancio (negativo valore opposto, 0 nessuno)
CMDVECTOR m_CmdData ; // vettore comandi in attesa di esecuzione
int m_nCmdInd ; // indice prossimo comando da eseguire
double m_dCmdCoeff ; // coefficiente di movimento nel comando
} ;
Simulator.cpp → SimulatorSP.cpp
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SimulatorSP.h
+188
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//----------------------------------------------------------------------------
// EgalTech 2015-2024
//----------------------------------------------------------------------------
// File : SimulatorSP.h Data : 16.01.23 Versione : 2.5a2
// Contenuto : Dichiarazione della classe Simulator.
//
//
//
// Modifiche : 19.10.15 DS Creazione modulo.
//
//
//----------------------------------------------------------------------------
#pragma once
#include "Simulator.h"
#include "CamData.h"
class IGeomDB ;
class Machine ;
class PerformanceCounter ;
//----------------------------------------------------------------------------
ISimulator* CreateSimulatorSP( void) ;
//----------------------------------------------------------------------------
class SimulatorSP : public ISimulator
{
public :
~SimulatorSP( void) override ;
bool Init( MachMgr* pMchMgr) override ;
bool Start( bool bFirst) override ;
bool Move( int& nStatus) override ;
bool GoHome( void) override ;
bool SetStep( double dStep) override ;
bool SetUiStatus( int nUiStatus) override ;
bool GetAxisInfoPos( int nI, std::string& sName, std::string& sToken, bool& bLinear, double& dVal) const override ;
bool GetToolInfo( std::string& sName, double& dSpeed) const override ;
bool GetOperationInfo( std::string& sName, int& nType) const override ;
bool GetMoveInfo( int& nGmove, double& dFeed) const override ;
bool AddCollisionObj( int nInd, bool bToolOn, int nFrameId, int nType,
const Vector3d& vtMove, double dPar1, double dPar2, double dPar3) override ;
bool ExecCollisionCheck( int& nCdInd, int& nObjInd, int nMoveType) override ;
bool OnCollision( int nCdInd, int nObjInd, int& nErr) override ;
bool SetToolForVmill( const std::string& sTool, const std::string& sHead, int nExit, int nFlag,
double dPar1, double dPar2, const INTVECTOR& vVmill, bool bFirst) override ;
bool EnableToolsForVmill( bool bEnable) override ;
int MoveAxes( int nMoveType, const SAMVECTOR& vAxNaEpSt) override ;
bool SaveCmd( int nType, int nPar, const std::string& sPar) override
{ return false ; }
public :
SimulatorSP( void) ;
private :
bool UpdateTool( bool bFirst, int& nErr) ;
bool UpdateAxes( void) ;
bool UpdateAxesPos( void) ;
bool ResetInterpolation( void) ;
bool ResetAxes( void) ;
bool ResetAuxAxes( void) ;
private :
bool VerifySetup( void) ;
bool FindAndManageOperationStart( bool bStart, bool bFirst, int& nStatus) ;
bool ManageOperationEnd( int& nStatus) ;
bool FindAndManagePathStart( int& nStatus) ;
bool ManagePathEnd( int& nStatus) ;
bool ManagePathStartAux( int& nStatus) ;
bool ManagePathEndAux( int& nStatus) ;
bool ManageMove( int& nStatus) ;
bool ManageSingleMove( int& nStatus, double& dMove) ;
int CalcStatusOnError( int nErr) ;
bool GetHeadCurrPosDirAux( const std::string& sHead, int nExit, Point3d& ptH, Vector3d& vtH, Vector3d& vtA) ;
bool ExecLineVmill( int nVmId, int nCurrTool, double dVmTdOffs, double dVmAdOffs,
const Point3d& ptHi, const Vector3d& vtHi, const Vector3d& vtAi, const Frame3d& frVzmI,
const Point3d& ptHf, const Vector3d& vtHf, const Vector3d& vtAf, const Frame3d& frVzmF) ;
bool NeedCollisionCheck( void) const
{ return ( ! m_CollObj.empty() && ! m_CdId.empty()) ; }
bool Stopped( void)
{ return ( m_nUiStatus == MCH_UISIM_STOP) ; }
bool SetCollisionMark( int nCdInd, int nObjInd) ;
bool ResetCollisionMark( void) ;
bool OnInit( void) ;
bool OnExit( void) ;
bool OnProgramStart( bool bFirst) ;
bool OnProgramEnd( void) ;
bool OnDispositionStarting( int nOpId, int nOpInd, int nPhase,
const std::string& sTable, const Point3d& ptOri1, bool bEmpty, bool bSomeByHand) ;
bool OnDispositionStart( int nOpId, int nOpInd, int nPhase,
const std::string& sTable, const Point3d& ptOri1, bool bEmpty, bool bSomeByHand) ;
bool OnDispositionEnd( void) ;
bool OnToolSelect( const std::string& sTool, const std::string& sHead, int nExit, const std::string& sTcPos, bool bFirst, int& nErr) ;
bool OnToolDeselect( const std::string& sNextTool, const std::string& sNextHead, int nNextExit, const std::string& sNextTcPos, int& nErr) ;
bool OnMachiningStart( int nOpId, int nOpInd, const Point3d& ptMin, const Point3d& ptMax,
const DBLVECTOR& vAxMin, const DBLVECTOR& vAxMax) ;
bool OnMachiningEnd( void) ;
bool OnPathStartAux( int nInd, const std::string& sAS, int& nErr) ;
bool OnPathEndAux( int nInd, const std::string& sAE, int& nErr) ;
bool OnPathStart( int nClPathId, int nClPathInd, int nAS, const Point3d& ptStart, const Point3d& ptEnd,
const Vector3d& vtExtr, const Point3d& ptMin, const Point3d& ptMax,
const DBLVECTOR& vAxMin, const DBLVECTOR& vAxMax, double dElev) ;
bool OnPathEnd( int nAE) ;
bool OnMoveStart( const CamData* pCamData, const CamData* pNextCamData, int& nErr) ;
bool OnMoveEnd( int& nErr) ;
bool OnResetMachine( void) ;
private :
struct CollObj {
int nInd ;
bool bToolOn ;
int nFrameId ;
int nType ;
Vector3d vtMove ;
double dPar1 ;
double dPar2 ;
double dPar3 ;
CollObj( void) : nInd( 0), bToolOn( false), nFrameId( -1), nType( 0), vtMove(), dPar1( 0), dPar2( 0), dPar3( 0) {}
CollObj( int nI, bool bTOn, int nF, int nT, const Vector3d& vtM, double dP1, double dP2, double dP3)
: nInd( nI), bToolOn( bTOn), nFrameId( nF), nType( nT), vtMove( vtM), dPar1( dP1), dPar2( dP2), dPar3( dP3) {}
} ;
typedef std::vector<CollObj> COBVECTOR ;
struct VmTool
{
std::string sName ;
std::string sHead ;
int nExit ;
double dTdOffs ;
double dAdOffs ;
VmTool( void) : nExit( 0), dTdOffs( 0), dAdOffs( 0) {}
VmTool( std::string sN, std::string sH, int nE, double dT, double dA)
: sName( sN), sHead( sH), nExit( nE), dTdOffs( dT), dAdOffs( dA) {}
} ;
typedef std::vector<VmTool> VMTVECTOR ;
enum { SIS_CREATED = 0,
SIS_INITIALIZED = 1,
SIS_READYTOSTART = 2,
SIS_READYTORUN = 3} ;
private :
MachMgr* m_pMchMgr ; // puntatore al gestore di tutte le lavorazioni
IGeomDB* m_pGeomDB ; // puntatore al DB geometrico
Machine* m_pMachine ; // puntatore alla macchina
PerformanceCounter* m_pPerfCnt ; // timer per calcolo FPS
int m_nStatus ; // stato interno del simulatore (creato, inizializzato, pronto al movimento)
double m_dStep ; // lunghezza di riferimento per la velocità di simulazione
int m_nUiStatus ; // stato simulazione a livello utente
int m_nOpId ; // identificativo della operazione (lavoraz.) corrente
int m_nOpInd ; // contatore della operazione (lavoraz.) corrente
int m_nCLPathId ; // identificativo del percorso di lavoro corrente
int m_nCLPathInd ; // contatore del percorso di lavoro corrente nell'operazione
int m_nEntId ; // identificativo dell'entità corrente
int m_nEntInd ; // contatore dell'entità corrente nel percorso di lavoro
double m_dCoeff ; // coefficiente di esecuzione del movimento corrente (0...1)
int m_nAuxSTot ; // numero totale movimenti ausiliari di inizio percorso
int m_nAuxSInd ; // indice del movimento ausiliario di inizio percorso corrente
int m_nAuxETot ; // numero totale movimenti ausiliari di fine percorso
int m_nAuxEInd ; // indice del movimento ausiliario di fine percorso corrente
std::string m_sTool ; // nome dell'utensile corrente
std::string m_sHead ; // nome della testa corrente
int m_nExit ; // indice dell'uscita corrente
double m_dTDiam ; // diametro dell'utensile corrente
bool m_bCutOnTip ; // flag capacità di lavorare di testa dell'utensile corrente
bool m_bEnableVm ; // flag abilitazione Virtual Milling
INTVECTOR m_VmId ; // vettore identificativi Zmap per Virtual Milling
INTVECTOR m_CdId ; // vettore identificativi Zmap per Collision Detection
VMTVECTOR m_VmTool ; // vettore utensili attivi per virtual milling
COBVECTOR m_CollObj ; // vettore oggetti da testare per collisione con grezzo
double m_dSafeDist ; // distanza di sicurezza per verifica collisioni
INTVECTOR m_nCollMarkId ; // elenco oggetti marcati per visualizzare meglio la collisione rilevata
int m_nAxesMask ; // maschera a bit di abilitazione movimento assi (solo se rapido)
bool m_bEnabAxes ; // flag abilitazione movimento assi attivi
bool m_bShowAxes ; // flag visualizzazione assi attivi
STRVECTOR m_AxesName ; // nomi degli assi macchina attivi
STRVECTOR m_AxesToken ; // token degli assi macchina attivi
BOOLVECTOR m_AxesInvert ; // flag di asse con verso invertito degli assi macchina attivi
DBLVECTOR m_AxesOffset ; // valore di offset delgli assi macchina ttivi
BOOLVECTOR m_AxesLinear ; // flag di lineare degli assi macchina attivi
DBLVECTOR m_AxesVal ; // valori degli assi macchina all'inizio del movimento corrente
STRVECTOR m_AuxAxesName ; // nomi degli assi macchina ausiliari abilitati
STRVECTOR m_AuxAxesToken ; // token degli assi macchina ausiliari abilitati
BOOLVECTOR m_AuxAxesInvert ; // flag di asse con verso invertito degli assi macchina ausiliari abilitati
DBLVECTOR m_AuxAxesOffset ; // valore di offset degli assi macchina ausiliari abilitati
BOOLVECTOR m_AuxAxesLinear ; // flag di lineare degli assi macchina ausiliari abilitati
DBLVECTOR m_AuxAxesVal ; // valori degli assi macchina ausiliari all'inizio del movimento corrente
DBLVECTOR m_AuxAxesEnd ; // valori degli assi macchina ausiliari alla fine del movimento corrente
INTVECTOR m_AuxAxesLink ; // indice + 1 asse principale di aggancio (negativo valore opposto, 0 nessuno)
} ;
SurfFinishing.cpp
+903 -643
View File
File diff suppressed because it is too large Load Diff
SurfFinishing.h
+17 -12
View File
@@ -21,6 +21,7 @@
#include "/EgtDev/Include/EgtNumUtils.h"
class ICAvToolSurfTm ;
class ISurfFlatRegion ;
//----------------------------------------------------------------------------
class SurfFinishing : public Machining
@@ -73,22 +74,24 @@ class SurfFinishing : public Machining
bool GetCurves( SelData Id, ICURVEPLIST& lstPC) ;
bool Chain( int nGrpDestId) ;
bool ProcessPath( int nPathId, int nPvId, int nClId) ;
bool AddZigZag( ICAvToolSurfTm* pCAvTlStm, const Frame3d& frSurf,
const ICurveComposite* pCompo, const Vector3d& vtTool, const Vector3d& vtExtr,
double dDepth, double dElev) ;
bool CalcZigZag( const ICurveComposite* pOffs, ICRVCOMPOPOVECTOR& vpCrvs) ;
bool AddSpiral( ICAvToolSurfTm* pCAvTlStm, const Frame3d& frSurf,
const ICurveComposite* pCompo, const Vector3d& vtTool, const Vector3d& vtExtr,
double dDepth, double dElev, bool bInVsOut) ;
bool CalcSpiral( const ICurveComposite* pCompo, bool bSplitArcs,
ICurveComposite* pMCrv, ICurveComposite* pRCrv) ;
bool AddZigZag( ICAvToolSurfTm* pCAvTlStm, const Frame3d& frSurf, const ISurfFlatRegion* pSfrPock,
const Vector3d& vtTool, double dDepth, double dElev, bool bSplitArcs) ;
bool AddOneWay( ICAvToolSurfTm* pCAvTlStm, const Frame3d& frSurf, const ISurfFlatRegion* pSfrPock,
const Vector3d& vtTool, double dDepth, double dElev, bool bSplitArcs) ;
bool AddSpiral( ICAvToolSurfTm* pCAvTlStm, const Frame3d& frSurf, const ISurfFlatRegion* pSfrPock,
const Vector3d& vtTool, double dDepth, double dElev, bool bSplitArcs, bool bInVsOut) ;
bool AddApproach( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ, double dElev, double dAppr) ;
bool AddLinkApproach( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ, double dElev, double dAppr) ;
bool AddLinkRetract( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ, double dElev, double dAppr) ;
bool AddRetract( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ, double dElev, double dAppr) ;
bool CalcLeadInStart( const Point3d& ptStart, const Vector3d& vtStart, const Vector3d& vtN, Point3d& ptP1) const ;
bool AddLeadIn( const Point3d& ptP1, const Point3d& ptStart, const Vector3d& vtStart, const Vector3d& vtN) ;
bool AddLeadOut( const Point3d& ptEnd, const Vector3d& vtEnd, const Vector3d& vtN, Point3d& ptP1) ;
bool CalcLeadInStart( const Point3d& ptStart, const Vector3d& vtStart, const Vector3d& vtTool, const Vector3d& vtNorm, Point3d& ptP1) const ;
bool AddLeadIn( const Point3d& ptP1, const Point3d& ptStart, const Vector3d& vtStart, const Vector3d& vtTool, bool bSplitArcs) ;
bool CalcLeadOutEnd( const Point3d& ptEnd, const Vector3d& vtEnd, const Vector3d& vtTool, const Vector3d& vtNorm, Point3d& ptP1) const ;
bool AddLeadOut( const Point3d& ptEnd, const Vector3d& vtEnd, const Point3d& ptP1, const Vector3d& vtTool, bool bSplitArcs) ;
bool GetLastGoodPoint( ICAvToolSurfTm* pCAvTlStm, const Frame3d& frSurf,
const Point3d& ptStart, const Point3d& ptEnd, const Vector3d& vtTool, Point3d& ptP1) const ;
bool GetSurfaceNormalAtPoint( ICAvToolSurfTm* pCAvTlStm, const Frame3d& frSurf,
const Point3d& ptTool, const Vector3d& vtTool, Vector3d& vtNorm) const ;
bool GetActiveSurfaces( INTVECTOR& vSurfId) const ;
double GetRightFeed( const Vector3d& vtMove, const Vector3d& vtTool) const ;
double GetRadiusForStartEndElevation( void) const ;
@@ -108,6 +111,8 @@ class SurfFinishing : public Machining
{ return ( IsUnknownValue( m_Params.m_dOffsR) ? m_TParams.m_dOffsR : m_Params.m_dOffsR) ; }
double GetSideStep( void) const
{ return Clamp( m_Params.m_dSideStep, 0.1, m_TParams.m_dTDiam) ; }
int GetLeadInType( void) const ;
int GetLeadOutType( void) const ;
private :
SELVECTOR m_vId ; // identificativi entità geometriche da lavorare
SurfFinishingData.cpp
+2 -19
View File
@@ -147,7 +147,6 @@ SurfFinishingData::CopyFrom( const MachiningData* pMdata)
m_nLeadOutType = pSdata->m_nLeadOutType ;
m_dLoTang = pSdata->m_dLoTang ;
m_dLoPerp = pSdata->m_dLoPerp ;
m_nLeadLinkType = pSdata->m_nLeadLinkType ;
m_dApprox = pSdata->m_dApprox ;
m_sSysNotes = pSdata->m_sSysNotes ;
m_sUserNotes = pSdata->m_sUserNotes ;
@@ -192,7 +191,6 @@ SurfFinishingData::SameAs(const MachiningData* pMdata) const
m_nLeadOutType == pSdata->m_nLeadOutType &&
abs( m_dLoTang - pSdata->m_dLoTang) < EPS_MACH_LEN_PAR &&
abs( m_dLoPerp - pSdata->m_dLoPerp) < EPS_MACH_LEN_PAR &&
m_nLeadLinkType == pSdata->m_nLeadLinkType &&
abs( m_dApprox - pSdata->m_dApprox) < EPS_MACH_LEN_PAR &&
m_sSysNotes == pSdata->m_sSysNotes &&
m_sUserNotes == pSdata->m_sUserNotes) ;
@@ -273,7 +271,7 @@ SurfFinishingData::FromString( const string& sString, int& nKey)
bOk = ::FromString( sVal, m_nLeadInType) ;
break ;
case KEY_LLTY :
bOk = ::FromString( sVal, m_nLeadLinkType) ;
// campo non più usato
break ;
case KEY_LOPR :
bOk = ::FromString( sVal, m_dLoPerp) ;
@@ -351,7 +349,7 @@ SurfFinishingData::ToString( int nInd) const
case KEY_LIPR : return ( sSurfFinishingKey[KEY_LIPR] + "=" + ::ToString( m_dLiPerp)) ;
case KEY_LITG : return ( sSurfFinishingKey[KEY_LITG] + "=" + ::ToString( m_dLiTang)) ;
case KEY_LITY : return ( sSurfFinishingKey[KEY_LITY] + "=" + ::ToString( m_nLeadInType)) ;
case KEY_LLTY : return ( sSurfFinishingKey[KEY_LLTY] + "=" + ::ToString( m_nLeadLinkType)) ;
case KEY_LLTY : return ( sSurfFinishingKey[KEY_LLTY] + "=" + ::ToString( 0)) ;
case KEY_LOPR : return ( sSurfFinishingKey[KEY_LOPR] + "=" + ::ToString( m_dLoPerp)) ;
case KEY_LOTG : return ( sSurfFinishingKey[KEY_LOTG] + "=" + ::ToString( m_dLoTang)) ;
case KEY_LOTY : return ( sSurfFinishingKey[KEY_LOTY] + "=" + ::ToString( m_nLeadOutType)) ;
@@ -403,13 +401,6 @@ SurfFinishingData::VerifyLeadInType( int nVal) const
nVal == SURFFIN_LI_TANGENT) ;
}
//----------------------------------------------------------------------------
bool
SurfFinishingData::VerifyLeadLinkType( int nVal) const
{
return ( nVal == SURFFIN_LL_STD || nVal == SURFFIN_LL_CENT) ;
}
//----------------------------------------------------------------------------
bool
SurfFinishingData::VerifyLeadOutType( int nVal) const
@@ -464,11 +455,6 @@ SurfFinishingData::SetParam( int nType, int nVal)
return false ;
m_nLeadInType = nVal ;
return true ;
case MPA_LEADLINKTYPE :
if ( ! VerifyLeadInType( nVal))
return false ;
m_nLeadLinkType = nVal ;
return true ;
case MPA_LEADOUTTYPE :
if ( ! VerifyLeadOutType( nVal))
return false ;
@@ -615,9 +601,6 @@ SurfFinishingData::GetParam( int nType, int& nVal) const
case MPA_LEADINTYPE :
nVal = m_nLeadInType ;
return true ;
case MPA_LEADLINKTYPE :
nVal = m_nLeadLinkType ;
return true ;
case MPA_LEADOUTTYPE :
nVal = m_nLeadOutType ;
return true ;
SurfFinishingData.h
+7 -5
View File
@@ -42,7 +42,6 @@ struct SurfFinishingData : public MachiningData
int m_nLeadOutType ; // tipo di uscita (come attacco, nessuno, lineare, tangente, inseguimento)
double m_dLoTang ; // distanza tangente verso fine uscita
double m_dLoPerp ; // distanza perpendicolare verso fine uscita
int m_nLeadLinkType ; // tipo di collegamento ( centro, fuori)
double m_dApprox ; // valore di approssimazione per superfici
std::string m_sSysNotes ; // note interne
std::string m_sUserNotes ; // note dell'utente
@@ -52,7 +51,7 @@ struct SurfFinishingData : public MachiningData
m_dOffsR( UNKNOWN_PAR), m_bInvert( false),
m_dStartPos( 0), m_dOverlap(0), m_dSideStep( 0), m_nSubType( 0), m_dSideAngle( 0),
m_nLeadInType( 0), m_dLiTang( 0), m_dLiPerp( 0),
m_nLeadOutType( 0), m_dLoTang( 0), m_dLoPerp( 0), m_nLeadLinkType( 0), m_dApprox( 0) {}
m_nLeadOutType( 0), m_dLoTang( 0), m_dLoPerp( 0), m_dApprox( 0) {}
SurfFinishingData* Clone( void) const override ;
bool CopyFrom( const MachiningData* pMdata) override ;
bool SameAs(const MachiningData* pMdata) const override ;
@@ -77,12 +76,15 @@ struct SurfFinishingData : public MachiningData
bool VerifySolCh( int nVal) const ;
bool VerifySubType( int nVal) const ;
bool VerifyLeadInType( int nVal) const ;
bool VerifyLeadLinkType( int nVal) const ;
bool VerifyLeadOutType( int nVal) const ;
} ;
//----------------------------------------------------------------------------
inline const SurfFinishingData* GetSurfFinishingData( const MachiningData* pMdata)
{ return (dynamic_cast<const SurfFinishingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_SURFFINISHING)
return nullptr ;
return ( static_cast<const SurfFinishingData*>( pMdata)) ; }
inline SurfFinishingData* GetSurfFinishingData( MachiningData* pMdata)
{ return (dynamic_cast<SurfFinishingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_SURFFINISHING)
return nullptr ;
return ( static_cast<SurfFinishingData*>( pMdata)) ; }
SurfRoughing.cpp
+3229
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File diff suppressed because it is too large Load Diff
SurfRoughing.h
+189
View File
@@ -0,0 +1,189 @@
//----------------------------------------------------------------------------
// EgalTech 2024-2024
//----------------------------------------------------------------------------
// File : SurfRoughing.h Data : 24.05.24 Versione : 2.6e5
// Contenuto : Dichiarazione della classe SurfRoughing.
//
//
//
// Modifiche : 24.05.24 DS Creazione modulo.
//
//
//----------------------------------------------------------------------------
#pragma once
#include "Machining.h"
#include "SurfRoughingData.h"
#include "ToolData.h"
#include "MachiningConst.h"
#include "/EgtDev/Include/EGkCurveComposite.h"
#include "/EgtDev/Include/EgtNumUtils.h"
#include "/EgtDev/Include/EGkSurfFlatRegion.h"
#include "/EgtDev/Include/EGkSurfTriMesh.h"
#include "/EgtDev/Include/EGkIntersPlaneSurfTm.h"
class ICAvToolSurfTm ;
// struttura informazioni sui singoli percorsi
struct PathInfo {
bool bOutStart ; // flag per entrata da fuori
bool bSingleCrv ; // se percorso formato da una curva singola ( in generale per SubSteps)
bool bOptTrap ; // flag per casi ottimizzati a trapezio ( per Spiral)
bool bIsZigZagOneWayBorder ; // curve di bordo dei lati chiusi ( per ZigZag e OneWay)
PtrOwner<ICurveComposite> pCrvPath ; // percorso del centro utensile
PtrOwner<ICurveComposite> pCvrRet ; // curva di ritorno per LeadIn/Out a guida
} ;
// tipo percorso
typedef std::vector<PathInfo> PATHINFOVECTOR ;
// struttura informazioni per Step/SubSteps complessivi
struct StepInfo {
double dDepth ; // profondità dello step attuale
double dRelativeDepth ; // profondità relativa allo step al di sopra
double dZlocCoeffFeed ; // coeffiziente riduzione Feed lungo Zloc
int nSubType ; // tipo di lavorazione dello Step corrente
bool bIsSubStep ; // step/SubStep
bool bInverted ; // se percorsi invertiti
PtrOwner<ISurfFlatRegion> pSfrPock ; // regione piana di svuotatura
PtrOwner<ISurfFlatRegion> pSfrLimit ; // regione piana da non svuotare
PtrOwner<ICurveComposite> pCompo ; // curva selezionata per sgrossatura
PATHINFOVECTOR vPaths ; // percorsi di Pocketing
} ;
// tipo step
typedef std::vector<StepInfo> STEPINFOVECTOR ;
//----------------------------------------------------------------------------
class SurfRoughing : public Machining
{
public : // IUserObj
SurfRoughing* Clone( void) const override ;
const std::string& GetClassName( void) const override ;
bool Dump( std::string& sOut, bool bMM = true, const char* szNewLine = "\n") const override ;
bool ToSave( void) const override
{ return true ; }
bool Save( int nBaseId, STRVECTOR& vString) const override ;
bool Load( const STRVECTOR& vString, int nBaseGdbId) override ;
public : // Operation
int GetType( void) const override
{ return OPER_SURFROUGHING ; }
bool IsEmpty( void) const override
{ return ( m_nPaths == 0) ; }
bool UpdateStatus( int nModif) override
{ m_nStatus |= nModif ; return true ; }
protected : // Operation
int GetSolCh( void) const override
{ return m_Params.m_nSolCh ; }
bool AdjustEndPointForAxesCalc( const CamData* pCamData, Point3d& ptP) const override ;
public : // Machining
bool Prepare( const std::string& sSawName) override ;
bool SetParam( int nType, bool bVal) override ;
bool SetParam( int nType, int nVal) override ;
bool SetParam( int nType, double dVal) override ;
bool SetParam( int nType, const std::string& sVal) override ;
bool SetGeometry( const SELVECTOR& vIds) override ;
bool Preview( bool bRecalc) override ;
bool Apply( bool bRecalc, bool bPostApply) override ;
bool Update( bool bPostApply) override ;
bool GetParam( int nType, bool& bVal) const override ;
bool GetParam( int nType, int& nVal) const override ;
bool GetParam( int nType, double& dVal) const override ;
bool GetParam( int nType, std::string& sVal) const override ;
bool UpdateToolData( bool* pbChanged = nullptr) override ;
const ToolData& GetToolData( void) const override ;
bool GetGeometry( SELVECTOR& vIds) const override ;
public :
SurfRoughing( void) ;
private :
bool VerifyGeometry( SelData Id, int& nSubs) ;
bool GetCurves( SelData Id, ICURVEPLIST& lstPC) ;
bool Chain( int nGrpDestId) ;
bool ProcessPath( int nPathId, int nTempId, int nPvId, int nClId) ;
bool CalcPaths( const INTINTVECTOR& vPocket, const ICRVCOMPOPOVECTOR& vCrvPocketCompo, STEPINFOVECTOR& vStepInfo) const ;
bool AddPocket( const INTINTVECTOR& vPocket, const Vector3d& vtTool, const ICRVCOMPOPOVECTOR& vCrvPocketCompo,
double dElev, double dStep, double dSubStep, bool bSplitArcs) ;
bool AddApproach( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ, double dElev, double dAppr) ;
bool AddLinkApproach( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ, double dElev, double dAppr, bool bOutMove) ;
bool AddLinkRetract( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ, double dElev, double dAppr) ;
bool AddRetract( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ, double dElev, double dAppr) ;
bool CalcLeadInStart( const Point3d& ptStart, const Vector3d& vtTool, const ICurveComposite* pCrvPath, Point3d& ptP1) const ;
bool VerifyLeadInLeadOut( const ICurve* pCrv, const ICurveComposite* pCrvPock, bool& bSkip) const ;
bool AddLeadIn( const Point3d& ptP1, const Point3d& ptStart, const Vector3d& vtStart, const Vector3d& vtN,
const ISurfFlatRegion* pSfr, const ICurveComposite* pRCrv, bool bAtLeft, bool bSplitArcs,
bool bNoneForced, bool bSkipControl) ;
bool AddLeadOut( const Point3d& ptEnd, const Vector3d& vtEnd, const Vector3d& vtN,
const ICurveComposite* pRCrv, bool bSplitArcs, bool bNoneForced, Point3d& ptP1) ;
ISurfTriMesh* GetRaw( void) const ;
ISurfFlatRegion* GetSfrByStmIntersection( const IntersParPlanesSurfTm& IPPStm, double dDist, double dSmallOffs = 0) const ;
bool GetActiveSurfaces( INTVECTOR& vSurfId) const ;
double GetRightFeed( const Vector3d& vtMove, const Vector3d& vtTool) const ;
double GetRadiusForStartEndElevation( void) const ;
bool AdjustPathForLeadInLeadOut( ICurveComposite* pCrvCompo, int nSubType, const ICurveComposite* pCrvPocket, bool& bOutStart,
bool& bSingleCrv, bool& bOptTrap, bool& bIsZigZagOneWayBorder) const ;
bool AssignOpenEdgesForPocketCrvCompo( ICurveComposite* pCrvCompo, const ISurfFlatRegion* pSfr) const ;
bool ResetCurveAllTempProp( ICurve* pCurve) const ;
bool RemoveChunksUnderTolerance( ISurfFlatRegion* pSfr) const ;
bool CloseOpenEdgesUnderTolerance( ISurfFlatRegion* pSfr, double dToler) ;
bool ModifySurfRefForOpenCloseEdges( ISurfFlatRegion* pSfrRef, const ICurveComposite* pCrvCompo) const ;
bool ChooseCloseOrOpenEdge( ISurfFlatRegion* pSfr, const ISurfFlatRegion* pSfrRef) const ;
bool SimplifyCurve( ICurveComposite* pCompo) const ;
bool SimplyfySfr( ISurfFlatRegion* pSfr) const ;
bool CheckSafetyLinearLink( const Point3d& ptCurr, const ISurfFlatRegion* pSfrLimit, const Vector3d& vtTool,
const Point3d& ptDest, bool& bSafe) const ;
bool GetHomogeneousParts( const ICurveComposite* pCrvCompo, ICRVCOMPOPOVECTOR& vpCrvs) const ;
bool VerifyLeadInHelix( const ISurfFlatRegion* pSfr, const Point3d& ptStart, const Point3d& ptCen, double dHelixRad) const ;
bool VerifyLeadInZigZag( const ISurfFlatRegion* pSfr, const Point3d& ptStart, const Point3d& ptPa, const Point3d& ptPb) const ;
private :
double GetSpeed() const
{ return ( IsNullAngValue( m_Params.m_dSpeed) ? m_TParams.m_dSpeed : m_Params.m_dSpeed) ; }
double GetFeed() const
{ return ( IsNullLenValue( m_Params.m_dFeed) ? m_TParams.m_dFeed : m_Params.m_dFeed) ; }
double GetAdaptedCoeffFeed( bool bSubStep, int nNumStep, double dStep, double dSubStep) const
{ return ( 1. + ( bSubStep ? ( nNumStep + 1) * dSubStep / dStep : 0.)) ; }
double GetStartFeed() const
{ return ( IsNullLenValue( m_Params.m_dStartFeed) ? m_TParams.m_dStartFeed : m_Params.m_dStartFeed) ; }
double GetEndFeed() const
{ return ( IsNullLenValue( m_Params.m_dEndFeed) ? m_TParams.m_dEndFeed : m_Params.m_dEndFeed) ; }
double GetTipFeed() const
{ return ( IsNullLenValue( m_Params.m_dTipFeed) ? m_TParams.m_dTipFeed : m_Params.m_dTipFeed) ; }
double GetOffsR() const
{ double dCurrOffsR = IsUnknownValue( m_Params.m_dOffsR) ? m_TParams.m_dOffsR : m_Params.m_dOffsR ;
return std::max( 0.1, dCurrOffsR) ; }
double GetOffsL() const
{ return ( IsUnknownValue( m_Params.m_dOffsL) ? m_TParams.m_dOffsL : m_Params.m_dOffsL) ; }
double GetSideStep( void) const
{ return Clamp( m_Params.m_dSideStep, 0.1, m_TParams.m_dTDiam) ; }
int GetLeadInType( void) const
{ if ( m_Params.m_dLiTang < std::min( 0.1 * m_TParams.m_dDiam, 1.0))
return SURFROU_LI_NONE ;
if ( m_Params.m_nLeadInType != SURFROU_LI_GLIDE && m_Params.m_dLiElev < 10 * EPS_SMALL)
return SURFROU_LI_NONE ;
return m_Params.m_nLeadInType ; }
int GetLeadOutType( void) const
{ if ( m_Params.m_dLoTang < std::min( 0.1 * m_TParams.m_dDiam, 1.0))
return SURFROU_LO_NONE ;
return m_Params.m_nLeadOutType ; }
/* debug functions */
void DrawLoopsSurf( const ISurfFlatRegion* pSfr, bool bWithSurf, Color Col, bool bAlphaCoverage, int nStep) ;
void DrawFeed( const ICurveComposite* pCrv, int nStep) ;
/* end debug functions */
private :
SELVECTOR m_vId ; // identificativi entità geometriche da lavorare
SurfRoughingData m_Params ; // parametri lavorazione
ToolData m_TParams ; // parametri utensile
double m_dTHoldBase ; // posizione base del porta-utensile
double m_dTHoldLen ; // lunghezza del porta-utensile
double m_dTHoldDiam ; // diametro del porta-utensile
int m_nStatus ; // stato di aggiornamento della lavorazione
int m_nPaths ; // numero di percorsi di lavoro generati
double m_dMaxHelixRad ; // raggio massimo attacco ad elica nel caso di cerchi
double m_dSubStepToler ; // tolleranza di rimozione chunk per SubSteps
} ;
SurfRoughingData.cpp
+713
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@@ -0,0 +1,713 @@
//----------------------------------------------------------------------------
// EgalTech 2024-2024
//----------------------------------------------------------------------------
// File : SurfRoughingData.cpp Data : 24.05.24 Versione : 2.6e5
// Contenuto : Implementazione struttura dati lavorazione sgrossatura superfici.
//
//
//
// Modifiche : 24.05.24 DS Creazione modulo.
//
//
//----------------------------------------------------------------------------
//--------------------------- Include ----------------------------------------
#include "stdafx.h"
#include "SurfRoughingData.h"
#include "MachiningDataFactory.h"
#include "MachiningConst.h"
#include "/EgtDev/Include/EmkToolConst.h"
#include "/EgtDev/Include/EmkSimuGenConst.h"
#include "/EgtDev/Include/EGnStringUtils.h"
#include <array>
#include <cassert>
using namespace std ;
//----------------------------------------------------------------------------
enum nSurfRoughingKey {
KEY_AB = 0,
KEY_AI,
KEY_APPR,
KEY_DH,
KEY_F,
KEY_FE,
KEY_FS,
KEY_FT,
KEY_INV,
KEY_LIEL,
KEY_LITG,
KEY_LITY,
KEY_LOTG,
KEY_LOTY,
KEY_NAME,
KEY_NNS,
KEY_NNU,
KEY_OL,
KEY_OR,
KEY_PS,
KEY_S,
KEY_SA,
KEY_SCC,
KEY_SS,
KEY_SST,
KEY_ST,
KEY_SUBTYPE,
KEY_TNAME,
KEY_TUUID,
KEY_UUID,
KEY_ZZZ} ; // rappresenta il numero di elementi
static const array<string,KEY_ZZZ> sSurfRoughingKey = {
"AB",
"AI",
"APPR",
"DH",
"F",
"FE",
"FS",
"FT",
"INV",
"LIEL",
"LITG",
"LITY",
"LOTG",
"LOTY",
"NAME",
"NNS",
"NNU",
"OL",
"OR",
"PS",
"S",
"SA",
"SCC",
"SS",
"SST",
"ST",
"SUB",
"TN",
"TU",
"UUID"} ;
//----------------------------------------------------------------------------
MCHDATA_REGISTER( MT_SURFROUGHING, "SURFROUGHING", SurfRoughingData) ;
//----------------------------------------------------------------------------
SurfRoughingData*
SurfRoughingData::Clone( void) const
{
// alloco oggetto
SurfRoughingData* pMdata = new(nothrow) SurfRoughingData ;
// copio i dati
if ( pMdata != nullptr) {
if ( ! pMdata->CopyFrom( this)) {
delete pMdata ;
return nullptr ;
}
}
return pMdata ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::CopyFrom( const MachiningData* pMdata)
{
// è inutile copiare se sorgente coincide con destinazione
if ( pMdata == this)
return true ;
// la sorgente deve essere dello stesso tipo
const SurfRoughingData* pSdata = GetSurfRoughingData( pMdata) ;
if ( pSdata == nullptr)
return false ;
// eseguo copia
m_Uuid = pSdata->m_Uuid ;
m_sName = pSdata->m_sName ;
m_ToolUuid = pSdata->m_ToolUuid ;
m_sToolName = pSdata->m_sToolName ;
m_sBlockedAxis = pSdata->m_sBlockedAxis ;
m_sInitAngs = pSdata->m_sInitAngs ;
m_nSolCh = pSdata->m_nSolCh ;
m_dSpeed = pSdata->m_dSpeed ;
m_dFeed = pSdata->m_dFeed ;
m_dEndFeed = pSdata->m_dEndFeed ;
m_dStartFeed = pSdata->m_dStartFeed ;
m_dTipFeed = pSdata->m_dTipFeed ;
m_dOffsR = pSdata->m_dOffsR ;
m_dOffsL = pSdata->m_dOffsL ;
m_bInvert = pSdata->m_bInvert ;
m_sDepth = pSdata->m_sDepth ;
m_dStartPos = pSdata->m_dStartPos ;
m_dStep = pSdata->m_dStep ;
m_dSubStep = pSdata->m_dSubStep ;
m_dSideStep = pSdata->m_dSideStep ;
m_nSubType = pSdata->m_nSubType ;
m_dSideAngle = pSdata->m_dSideAngle ;
m_nLeadInType = pSdata->m_nLeadInType ;
m_dLiElev = pSdata->m_dLiElev ;
m_dLiTang = pSdata->m_dLiTang ;
m_nLeadOutType = pSdata->m_nLeadOutType ;
m_dLoTang = pSdata->m_dLoTang ;
m_dApprox = pSdata->m_dApprox ;
m_sSysNotes = pSdata->m_sSysNotes ;
m_sUserNotes = pSdata->m_sUserNotes ;
return true ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::SameAs(const MachiningData* pMdata) const
{
// se coincide con altro -> uguali
if ( pMdata == this)
return true ;
// se sono di tipo diverso -> diversi
const SurfRoughingData* pSdata = GetSurfRoughingData( pMdata) ;
if ( pSdata == nullptr)
return false ;
// confronto termine a termine
return ( m_Uuid == pSdata->m_Uuid &&
m_sName == pSdata->m_sName &&
m_ToolUuid == pSdata->m_ToolUuid &&
m_sToolName == pSdata->m_sToolName &&
m_sBlockedAxis == pSdata->m_sBlockedAxis &&
m_sInitAngs == pSdata->m_sInitAngs &&
m_nSolCh == pSdata->m_nSolCh &&
abs( m_dSpeed - pSdata->m_dSpeed) < EPS_MACH_ANG_PAR &&
abs( m_dFeed - pSdata->m_dFeed) < EPS_MACH_LEN_PAR &&
abs( m_dEndFeed - pSdata->m_dEndFeed) < EPS_MACH_LEN_PAR &&
abs( m_dStartFeed - pSdata->m_dStartFeed) < EPS_MACH_LEN_PAR &&
abs( m_dTipFeed - pSdata->m_dTipFeed) < EPS_MACH_LEN_PAR &&
abs( m_dOffsR - pSdata->m_dOffsR) < EPS_MACH_LEN_PAR &&
abs( m_dOffsL - pSdata->m_dOffsL) < EPS_MACH_LEN_PAR &&
m_bInvert == pSdata->m_bInvert &&
m_sDepth == pSdata->m_sDepth &&
abs( m_dStartPos - pSdata->m_dStartPos) < EPS_MACH_LEN_PAR &&
abs( m_dStep - pSdata->m_dStep) < EPS_MACH_LEN_PAR &&
abs( m_dSubStep - pSdata->m_dSubStep) < EPS_MACH_LEN_PAR &&
abs( m_dSideStep - pSdata->m_dSideStep) < EPS_MACH_LEN_PAR &&
m_nSubType == pSdata->m_nSubType &&
abs( m_dSideAngle - pSdata->m_dSideAngle) < EPS_MACH_ANG_PAR &&
m_nLeadInType == pSdata->m_nLeadInType &&
abs( m_dLiElev - pSdata->m_dLiElev) < EPS_MACH_LEN_PAR &&
abs( m_dLiTang - pSdata->m_dLiTang) < EPS_MACH_LEN_PAR &&
m_nLeadOutType == pSdata->m_nLeadOutType &&
abs( m_dLoTang - pSdata->m_dLoTang) < EPS_MACH_LEN_PAR &&
abs( m_dApprox - pSdata->m_dApprox) < EPS_MACH_LEN_PAR &&
m_sSysNotes == pSdata->m_sSysNotes &&
m_sUserNotes == pSdata->m_sUserNotes) ;
}
//----------------------------------------------------------------------------
int
SurfRoughingData::GetSize( void) const
{
// in debug verifico validità ultimo campo
assert( sSurfRoughingKey[KEY_UUID] == "UUID") ;
return KEY_ZZZ ;
}
//----------------------------------------------------------------------------
string
SurfRoughingData::GetTitle( void) const
{
return MCHDATA_GETNAME( SurfRoughingData) ;
}
//----------------------------------------------------------------------------
int
FindSurfRoughingKey( const string& sKey)
{
auto TheRange = equal_range( sSurfRoughingKey.cbegin(), sSurfRoughingKey.cend(), sKey) ;
if ( TheRange.first == TheRange.second)
return -1 ;
return int( TheRange.first - sSurfRoughingKey.cbegin()) ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::FromString( const string& sString, int& nKey)
{
// separo chiave da valore
string sKey, sVal ;
SplitFirst( sString, "=", sKey, sVal) ;
// riconosco la chiave
nKey = FindSurfRoughingKey( ToUpper( sKey)) ;
bool bOk = ( nKey >= 0) ;
switch ( nKey) {
case KEY_AB :
m_sBlockedAxis = sVal ;
break ;
case KEY_AI :
m_sInitAngs = sVal ;
break ;
case KEY_APPR :
bOk = ::FromString( sVal, m_dApprox) ;
break ;
case KEY_DH :
m_sDepth = sVal ;
if ( m_sDepth.empty())
m_sDepth = "0" ;
break ;
case KEY_F :
bOk = ::FromString( sVal, m_dFeed) ;
break ;
case KEY_FE :
bOk = ::FromString( sVal, m_dEndFeed) ;
break ;
case KEY_FS :
bOk = ::FromString( sVal, m_dStartFeed) ;
break ;
case KEY_FT :
bOk = ::FromString( sVal, m_dTipFeed) ;
break ;
case KEY_INV :
bOk = ::FromString( sVal, m_bInvert) ;
break ;
case KEY_LIEL :
bOk = ::FromString( sVal, m_dLiElev) ;
break ;
case KEY_LITG :
bOk = ::FromString( sVal, m_dLiTang) ;
break ;
case KEY_LITY :
bOk = ::FromString( sVal, m_nLeadInType) ;
break ;
case KEY_LOTG :
bOk = ::FromString( sVal, m_dLoTang) ;
break ;
case KEY_LOTY :
bOk = ::FromString( sVal, m_nLeadOutType) ;
break ;
case KEY_NAME :
m_sName = sVal ;
bOk = ! m_sName.empty() ;
break ;
case KEY_NNS :
m_sSysNotes = sVal ;
break ;
case KEY_NNU :
m_sUserNotes = sVal ;
break ;
case KEY_OR :
bOk = ::FromString( sVal, m_dOffsR) ;
break ;
case KEY_OL :
bOk = ::FromString( sVal, m_dOffsL) ;
break ;
case KEY_PS :
bOk = ::FromString( sVal, m_dStartPos) ;
break ;
case KEY_S :
bOk = ::FromString( sVal, m_dSpeed) ;
break ;
case KEY_SA :
bOk = ::FromString( sVal, m_dSideAngle) ;
break ;
case KEY_SCC :
bOk = ::FromString( sVal, m_nSolCh) ;
break ;
case KEY_SST :
bOk = ::FromString( sVal, m_dSubStep) ;
break ;
case KEY_SS :
bOk = ::FromString( sVal, m_dSideStep) ;
break ;
case KEY_ST :
bOk = ::FromString( sVal, m_dStep) ;
break ;
case KEY_SUBTYPE :
bOk = ::FromString( sVal, m_nSubType) ;
break ;
case KEY_TNAME :
m_sToolName = sVal ;
break ;
case KEY_TUUID :
bOk = ::FromString( sVal, m_ToolUuid) ;
break ;
case KEY_UUID :
bOk = ::FromString( sVal, m_Uuid) ;
break ;
default :
bOk = false ;
break ;
}
return bOk ;
}
//----------------------------------------------------------------------------
string
SurfRoughingData::ToString( int nInd) const
{
switch ( nInd) {
case KEY_AB : return ( sSurfRoughingKey[KEY_AB] + "=" + m_sBlockedAxis) ;
case KEY_AI : return ( sSurfRoughingKey[KEY_AI] + "=" + m_sInitAngs) ;
case KEY_APPR : return ( sSurfRoughingKey[KEY_APPR] + "=" + ::ToString(m_dApprox)) ;
case KEY_DH : return ( sSurfRoughingKey[KEY_DH] + "=" + m_sDepth) ;
case KEY_F : return ( sSurfRoughingKey[KEY_F] + "=" + ::ToString( m_dFeed)) ;
case KEY_FE : return ( sSurfRoughingKey[KEY_FE] + "=" + ::ToString( m_dEndFeed)) ;
case KEY_FS : return ( sSurfRoughingKey[KEY_FS] + "=" + ::ToString( m_dStartFeed)) ;
case KEY_FT : return ( sSurfRoughingKey[KEY_FT] + "=" + ::ToString( m_dTipFeed)) ;
case KEY_INV : return ( sSurfRoughingKey[KEY_INV] + "=" + ::ToString( m_bInvert)) ;
case KEY_LIEL : return ( sSurfRoughingKey[KEY_LIEL] + "=" + ::ToString( m_dLiElev)) ;
case KEY_LITG : return ( sSurfRoughingKey[KEY_LITG] + "=" + ::ToString( m_dLiTang)) ;
case KEY_LITY : return ( sSurfRoughingKey[KEY_LITY] + "=" + ::ToString( m_nLeadInType)) ;
case KEY_LOTG : return ( sSurfRoughingKey[KEY_LOTG] + "=" + ::ToString( m_dLoTang)) ;
case KEY_LOTY : return ( sSurfRoughingKey[KEY_LOTY] + "=" + ::ToString( m_nLeadOutType)) ;
case KEY_NAME : return ( sSurfRoughingKey[KEY_NAME] + "=" + m_sName) ;
case KEY_NNS : return ( sSurfRoughingKey[KEY_NNS] + "=" + m_sSysNotes) ;
case KEY_NNU : return ( sSurfRoughingKey[KEY_NNU] + "=" + m_sUserNotes) ;
case KEY_OL : return ( sSurfRoughingKey[KEY_OL] + "=" + ::ToString( m_dOffsL)) ;
case KEY_OR : return ( sSurfRoughingKey[KEY_OR] + "=" + ::ToString( m_dOffsR)) ;
case KEY_PS : return ( sSurfRoughingKey[KEY_PS] + "=" + ::ToString( m_dStartPos)) ;
case KEY_S : return ( sSurfRoughingKey[KEY_S] + "=" + ::ToString( m_dSpeed)) ;
case KEY_SA : return ( sSurfRoughingKey[KEY_SA] + "=" + ::ToString( m_dSideAngle)) ;
case KEY_SCC : return ( sSurfRoughingKey[KEY_SCC] + "=" + ::ToString( m_nSolCh)) ;
case KEY_SST : return ( sSurfRoughingKey[KEY_SST] + "=" + ::ToString( m_dSubStep)) ;
case KEY_SS : return ( sSurfRoughingKey[KEY_SS] + "=" + ::ToString( m_dSideStep)) ;
case KEY_ST : return ( sSurfRoughingKey[KEY_ST] + "=" + ::ToString( m_dStep)) ;
case KEY_SUBTYPE : return ( sSurfRoughingKey[KEY_SUBTYPE] + "=" + ::ToString( m_nSubType)) ;
case KEY_TNAME : return ( sSurfRoughingKey[KEY_TNAME] + "=" + m_sToolName) ;
case KEY_TUUID : return ( sSurfRoughingKey[KEY_TUUID] + "=" + ::ToString( m_ToolUuid)) ;
case KEY_UUID : return ( sSurfRoughingKey[KEY_UUID] + "=" + ::ToString( m_Uuid)) ;
default : return "" ;
}
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::IsOptional( int nKey) const
{
return ( nKey == KEY_LIEL || nKey == KEY_SST) ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::VerifySolCh( int nVal) const
{
return IsValidOperationScc( nVal) ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::VerifySubType( int nVal) const
{
return ( nVal == SURFROU_SUB_ZIGZAG || nVal == SURFROU_SUB_ONEWAY ||
nVal == SURFROU_SUB_SPIRALIN || nVal == SURFROU_SUB_SPIRALOUT ||
nVal == SURFROU_SUB_CONFORMAL_ZIGZAG || nVal == SURFROU_SUB_CONFORMAL_ONEWAY) ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::VerifyLeadInType( int nVal) const
{
return ( nVal == SURFROU_LI_NONE || nVal == SURFROU_LI_GLIDE ||
nVal == SURFROU_LI_ZIGZAG || nVal == SURFROU_LI_HELIX) ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::VerifyLeadOutType( int nVal) const
{
return ( nVal == SURFROU_LO_NONE || nVal == SURFROU_LO_GLIDE) ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::VerifyTool( const ToolsMgr* pToolsMgr, const string& sVal, const ToolData*& pTdata) const
{
if ( pToolsMgr == nullptr)
return false ;
pTdata = pToolsMgr->GetTool( sVal) ;
if ( pTdata == nullptr)
return false ;
if ( ( pTdata->m_nType & TF_MILL) == 0)
return false ;
return true ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::GetTool( const ToolsMgr* pToolsMgr, const ToolData*& pTdata) const
{
if ( pToolsMgr == nullptr)
return false ;
pTdata = pToolsMgr->GetTool( m_ToolUuid) ;
return ( pTdata != nullptr) ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::SetParam( int nType, bool bVal)
{
switch ( nType) {
case MPA_INVERT :
m_bInvert = bVal ;
return true ;
}
return false ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::SetParam( int nType, int nVal)
{
switch ( nType) {
case MPA_LEADINTYPE :
if ( ! VerifyLeadInType( nVal))
return false ;
m_nLeadInType = nVal ;
return true ;
case MPA_LEADOUTTYPE :
if ( ! VerifyLeadOutType( nVal))
return false ;
m_nLeadOutType = nVal ;
return true ;
case MPA_SCC :
if ( ! VerifySolCh( nVal))
return false ;
m_nSolCh = nVal ;
return true ;
case MPA_SUBTYPE :
if ( ! VerifySubType( nVal))
return false ;
m_nSubType = nVal ;
return true ;
}
return false ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::SetParam( int nType, double dVal)
{
switch ( nType) {
case MPA_SPEED :
m_dSpeed = dVal ;
return true ;
case MPA_FEED :
m_dFeed = dVal ;
return true ;
case MPA_STARTFEED :
m_dStartFeed = dVal ;
return true ;
case MPA_ENDFEED :
m_dEndFeed = dVal ;
return true ;
case MPA_TIPFEED :
m_dTipFeed = dVal ;
return true ;
case MPA_OFFSR :
m_dOffsR = dVal ;
return true ;
case MPA_OFFSL :
m_dOffsL = dVal ;
return true ;
case MPA_DEPTH :
m_sDepth = ::ToString( dVal) ;
return true ;
case MPA_STARTPOS :
m_dStartPos = dVal ;
return true ;
case MPA_STEP :
m_dStep = dVal ;
return true ;
case MPA_SUBSTEP :
m_dSubStep = dVal ;
return true ;
case MPA_SIDESTEP :
m_dSideStep = dVal ;
return true ;
case MPA_SIDEANGLE :
m_dSideAngle = dVal ;
return true ;
case MPA_LIELEV :
m_dLiElev = dVal ;
return true ;
case MPA_LITANG :
m_dLiTang = dVal ;
return true ;
case MPA_LOTANG :
m_dLoTang = dVal ;
return true ;
case MPA_APPROX :
m_dApprox = dVal ;
return true ;
}
return false ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::SetParam( int nType, const string& sVal)
{
switch ( nType) {
case MPA_NAME :
m_sName = sVal ;
return true ;
case MPA_TOOL :
m_sToolName = sVal ;
return true ;
case MPA_DEPTH_STR :
m_sDepth = sVal ;
return true ;
case MPA_TUUID :
return ::FromString( sVal, m_ToolUuid) ;
case MPA_UUID :
return ::FromString( sVal, m_Uuid) ;
case MPA_SYSNOTES :
m_sSysNotes = sVal ;
return true ;
case MPA_USERNOTES :
m_sUserNotes = sVal ;
return true ;
case MPA_INITANGS :
m_sInitAngs = sVal ;
return true ;
case MPA_BLOCKEDAXIS :
m_sBlockedAxis = sVal ;
return true ;
}
return false ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::ResetTool( void)
{
m_sToolName.clear() ;
m_ToolUuid.Clear() ;
return true ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::GetParam( int nType, bool& bVal) const
{
switch ( nType) {
case MPA_INVERT :
bVal = m_bInvert ;
return true ;
}
bVal = false ;
return false ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::GetParam( int nType, int& nVal) const
{
switch ( nType) {
case MPA_TYPE :
nVal = MT_SURFROUGHING ;
return true ;
case MPA_SUBTYPE :
nVal = m_nSubType ;
return true ;
case MPA_LEADINTYPE :
nVal = m_nLeadInType ;
return true ;
case MPA_LEADOUTTYPE :
nVal = m_nLeadOutType ;
return true ;
case MPA_SCC :
nVal = m_nSolCh ;
return true ;
}
nVal = 0 ;
return false ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::GetParam( int nType, double& dVal) const
{
switch ( nType) {
case MPA_SPEED :
dVal = m_dSpeed ;
return true ;
case MPA_FEED :
dVal = m_dFeed ;
return true ;
case MPA_STARTFEED :
dVal = m_dStartFeed ;
return true ;
case MPA_ENDFEED :
dVal = m_dEndFeed ;
return true ;
case MPA_TIPFEED :
dVal = m_dTipFeed ;
return true ;
case MPA_OFFSR :
dVal = m_dOffsR ;
return true ;
case MPA_OFFSL :
dVal = m_dOffsL ;
return true ;
case MPA_STARTPOS :
dVal = m_dStartPos ;
return true ;
case MPA_STEP :
dVal = m_dStep ;
return true ;
case MPA_SUBSTEP :
dVal = m_dSubStep ;
return true ;
case MPA_SIDESTEP :
dVal = m_dSideStep ;
return true ;
case MPA_SIDEANGLE :
dVal = m_dSideAngle ;
return true ;
case MPA_LIELEV :
dVal = m_dLiElev ;
return true ;
case MPA_LITANG :
dVal = m_dLiTang ;
return true ;
case MPA_LOTANG :
dVal = m_dLoTang ;
return true ;
case MPA_APPROX :
dVal = m_dApprox ;
return true ;
}
dVal = 0 ;
return false ;
}
//----------------------------------------------------------------------------
bool
SurfRoughingData::GetParam( int nType, string& sVal) const
{
switch ( nType) {
case MPA_NAME :
sVal = m_sName ;
return true ;
case MPA_TOOL :
sVal = m_sToolName ;
return true ;
case MPA_DEPTH_STR :
sVal = m_sDepth ;
return true ;
case MPA_TUUID :
sVal = ::ToString( m_ToolUuid) ;
return true ;
case MPA_UUID :
sVal = ::ToString( m_Uuid) ;
return true ;
case MPA_SYSNOTES :
sVal = m_sSysNotes ;
return true ;
case MPA_USERNOTES :
sVal = m_sUserNotes ;
return true ;
case MPA_INITANGS :
sVal = m_sInitAngs ;
return true ;
case MPA_BLOCKEDAXIS :
sVal = m_sBlockedAxis ;
return true ;
}
sVal = "" ;
return false ;
}
SurfRoughingData.h
+92
View File
@@ -0,0 +1,92 @@
//----------------------------------------------------------------------------
// EgalTech 2024-2024
//----------------------------------------------------------------------------
// File : SurfRoughingData.h Data : 24.05.24 Versione : 2.6e5
// Contenuto : Dichiarazione della struct SurfRoughingData e costanti associate.
//
//
//
// Modifiche : 24.05.24 DS Creazione modulo.
//
//
//----------------------------------------------------------------------------
#pragma once
#include "MachiningData.h"
//----------------------------------------------------------------------------
struct SurfRoughingData : public MachiningData
{
EgtUUID m_ToolUuid ; // identificativo universale dell'utensile
std::string m_sToolName ; // nome dell'utensile
std::string m_sInitAngs ; // angoli iniziali suggeriti (Nome1=val1,Nome2=val2)
std::string m_sBlockedAxis ; // eventuale asse rotante bloccato (Nome=val)
int m_nSolCh ; // criterio scelta soluzione (quando possibili molteplici)
double m_dSpeed ; // velocità di rotazione (+ se CCW, - se CW) ( se 0 da utensile)
double m_dFeed ; // velocità di lavorazione normale ( se 0 da utensile)
double m_dStartFeed ; // velocità di lavorazione iniziale ( se 0 da utensile)
double m_dEndFeed ; // velocità di lavorazione finale ( se 0 da utensile)
double m_dTipFeed ; // velocità di lavorazione di testa ( se 0 da utensile)
double m_dOffsR ; // offset radiale ( se UNKNOWN_PAR da utensile)
double m_dOffsL ; // offset longitudinale ( se UNKNOWN_PAR da utensile)
bool m_bInvert ; // flag di inversione direzione lavorazione
std::string m_sDepth ; // affondamento massimo (espressione numerica)
double m_dStartPos ; // quota di inizio lavorazione (sempre >= 0)
double m_dStep ; // passo di affondamento (0=nessun passo)
double m_dSideStep ; // distanza tra le passate
double m_dSubStep ; // distanza tra le passate intermedie
int m_nSubType ; // tipo di lavorazione ( ZigZag, OneWay, SpiralIn, SpiralOut)
double m_dSideAngle ; // angolo dello ZigZag da X+ locale
int m_nLeadInType ; // tipo di attacco (nessuno, lineare, tangente, inseguimento)
double m_dLiTang ; // distanza tangente da inizio attacco
double m_dLiElev ; // elevazione di uno step di attacco
int m_nLeadOutType ; // tipo di uscita (come attacco, nessuno, lineare, tangente, inseguimento)
double m_dLoTang ; // distanza tangente verso fine uscita
double m_dApprox ; // valore di approssimazione per superfici
std::string m_sSysNotes ; // note interne
std::string m_sUserNotes ; // note dell'utente
SurfRoughingData( void)
: m_ToolUuid(), m_nSolCh( 0), m_dSpeed( 0), m_dFeed( 0), m_dStartFeed( 0), m_dEndFeed( 0), m_dTipFeed( 0),
m_dOffsR( UNKNOWN_PAR), m_dOffsL( UNKNOWN_PAR), m_bInvert( false),
m_dStartPos( 0), m_dStep( 0), m_dSideStep( 0), m_dSubStep( 0), m_nSubType( 0), m_dSideAngle( 0),
m_nLeadInType( 0), m_dLiTang( 0), m_dLiElev( 0),
m_nLeadOutType( 0), m_dLoTang( 0), m_dApprox( 0) {}
SurfRoughingData* Clone( void) const override ;
bool CopyFrom( const MachiningData* pMdata) override ;
bool SameAs(const MachiningData* pMdata) const override ;
int GetType( void) const override
{ return MT_SURFROUGHING ; }
int GetSize( void) const override ;
std::string GetTitle( void) const override ;
bool FromString( const std::string& sString, int& nKey) override ;
std::string ToString( int nInd) const override ;
bool IsOptional( int nKey) const override ;
bool SetParam( int nType, bool bVal) override ;
bool SetParam( int nType, int nVal) override ;
bool SetParam( int nType, double dVal) override ;
bool SetParam( int nType, const std::string& sVal) override ;
bool ResetTool( void) override ;
bool GetParam( int nType, bool& bVal) const override;
bool GetParam( int nType, int& nVal) const override ;
bool GetParam( int nType, double& dVal) const override ;
bool GetParam( int nType, std::string& sVal) const override ;
bool GetTool( const ToolsMgr* pToolsMgr, const ToolData*& pTdata) const override ;
bool VerifyTool( const ToolsMgr* pToolsMgr, const std::string& sVal, const ToolData*& pTdata) const override ;
bool VerifySolCh( int nVal) const ;
bool VerifySubType( int nVal) const ;
bool VerifyLeadInType( int nVal) const ;
bool VerifyLeadLinkType( int nVal) const ;
bool VerifyLeadOutType( int nVal) const ;
} ;
//----------------------------------------------------------------------------
inline const SurfRoughingData* GetSurfRoughingData( const MachiningData* pMdata)
{ if ( pMdata == nullptr || pMdata->GetType() != MT_SURFROUGHING)
return nullptr ;
return ( static_cast<const SurfRoughingData*>( pMdata)) ; }
inline SurfRoughingData* GetSurfRoughingData( MachiningData* pMdata)
{ if ( pMdata == nullptr || pMdata->GetType() != MT_SURFROUGHING)
return nullptr ;
return ( static_cast<SurfRoughingData*>( pMdata)) ; }
Table.cpp
+9 -4
View File
@@ -1,7 +1,7 @@
//----------------------------------------------------------------------------
// EgalTech 2015-2015
// EgalTech 2015-2024
//----------------------------------------------------------------------------
// File : Table.cpp Data : 25.05.15 Versione : 1.6e7
// File : Table.cpp Data : 19.03.24 Versione : 2.6c2
// Contenuto : Oggetto tavola per gruppo tavola di macchina.
//
//
@@ -45,6 +45,7 @@ Table::Clone( void) const
pTab->m_sName = m_sName ;
pTab->m_nType = m_nType ;
pTab->m_ptRef1 = m_ptRef1 ;
pTab->m_vsColl = m_vsColl ;
}
catch( ...) {
delete pTab ;
@@ -63,7 +64,10 @@ Table::Dump( string& sOut, bool bMM, const char* szNewLine) const
sOut += "Id=" + ToString( m_nOwnerId) + szNewLine ;
sOut += "Name=" + m_sName + szNewLine ;
sOut += "Type=" + ToString( m_nType) + szNewLine ;
sOut += "Ref1=(" + ToString( GetInUiUnits(m_ptRef1, bMM), 4) + ")" + szNewLine ;
sOut += "Ref1=(" + ToString( GetInUiUnits( m_ptRef1, bMM), 4) + ")" + szNewLine ;
sOut += "Area1=(" + ToString( GetInUiUnits( m_b3Area1.GetMin(), bMM), 4) + ";" +
ToString( GetInUiUnits( m_b3Area1.GetMax(), bMM), 4) + szNewLine ;
sOut += "Coll=" + ToString( m_vsColl) + szNewLine ;
return true ;
}
@@ -99,11 +103,12 @@ Table::Table( void)
//----------------------------------------------------------------------------
bool
Table::Set( const string& sName, int nType, const Point3d& ptRef1, const BBox3d& b3Area1)
Table::Set( const string& sName, int nType, const Point3d& ptRef1, const BBox3d& b3Area1, const STRVECTOR& vsColl)
{
m_sName = sName ;
m_nType = nType ;
m_ptRef1 = ptRef1 ;
m_b3Area1 = b3Area1 ;
m_vsColl = vsColl ;
return true ;
}
Table.h
+4 -1
View File
@@ -30,7 +30,7 @@ class Table : public IUserObj
public :
Table( void) ;
bool Set( const std::string& sName, int nType, const Point3d& ptRef1, const BBox3d& b3Area1) ;
bool Set( const std::string& sName, int nType, const Point3d& ptRef1, const BBox3d& b3Area1, const STRVECTOR& vsColl) ;
const std::string& GetName( void)
{ return m_sName ; }
int GetType( void)
@@ -39,6 +39,8 @@ class Table : public IUserObj
{ return m_ptRef1 ; }
const BBox3d& GetArea1( void)
{ return m_b3Area1 ; }
const STRVECTOR& GetCollGroups( void) const
{ return m_vsColl ; }
private :
int m_nOwnerId ;
@@ -47,4 +49,5 @@ class Table : public IUserObj
int m_nType ;
Point3d m_ptRef1 ;
BBox3d m_b3Area1 ;
STRVECTOR m_vsColl ;
} ;
ToolData.h
+6 -6
View File
@@ -72,7 +72,7 @@ struct ToolData
//----------------------------------------------------------------------------
inline bool
SameTool( const ToolData& Td1, const ToolData& Td2)
SameTool( const ToolData& Td1, const ToolData& Td2, bool bAlsoNameTcPosHeadExit = true)
{
const double EPS_TOOL_LEN = 10 * EPS_SMALL ;
const double EPS_TOOL_ANG = 10 * EPS_ANG_SMALL ;
@@ -80,11 +80,11 @@ SameTool( const ToolData& Td1, const ToolData& Td2)
const double EPS_FEED = 0.5 ;
const double EPS_ABSORP = 0.5 ;
return ( Td1.m_Uuid == Td2.m_Uuid &&
Td1.m_sName == Td2.m_sName &&
( Td1.m_sName == Td2.m_sName || ! bAlsoNameTcPosHeadExit) &&
Td1.m_sDraw == Td2.m_sDraw &&
Td1.m_sTcPos == Td2.m_sTcPos &&
Td1.m_sHead == Td2.m_sHead &&
Td1.m_nExit == Td2.m_nExit &&
( Td1.m_sTcPos == Td2.m_sTcPos || ! bAlsoNameTcPosHeadExit) &&
( Td1.m_sHead == Td2.m_sHead || ! bAlsoNameTcPosHeadExit) &&
( Td1.m_nExit == Td2.m_nExit || ! bAlsoNameTcPosHeadExit) &&
Td1.m_nCorr == Td2.m_nCorr &&
Td1.m_nType == Td2.m_nType &&
abs( Td1.m_dMaxSpeed - Td2.m_dMaxSpeed) < EPS_SPEED &&
@@ -108,4 +108,4 @@ SameTool( const ToolData& Td1, const ToolData& Td2)
abs( Td1.m_dMinFeed - Td2.m_dMinFeed) < EPS_FEED &&
Td1.m_sSysNotes == Td2.m_sSysNotes &&
Td1.m_sUserNotes == Td2.m_sUserNotes) ;
}
}
ToolsMgr.cpp
+21 -12
View File
@@ -551,6 +551,11 @@ ToolsMgr::SaveCurrTool( void)
m_suData.emplace( m_tdCurrTool.m_sName, m_tdCurrTool.m_Uuid) ;
}
}
// se fresa adatto sottotipo a seconda della capacità di lavorare di testa
if ( m_tdCurrTool.m_nType == TT_MILL_STD && m_tdCurrTool.m_dTipFeed < EPS_SMALL)
m_tdCurrTool.m_nType = TT_MILL_NOTIP ;
else if ( m_tdCurrTool.m_nType == TT_MILL_NOTIP && m_tdCurrTool.m_dTipFeed > EPS_SMALL)
m_tdCurrTool.m_nType = TT_MILL_STD ;
// eseguo salvataggio
m_bModified = true ;
if ( find( m_utModified.begin(), m_utModified.end(), m_tdCurrTool.m_Uuid) == m_utModified.end())
@@ -694,12 +699,16 @@ ToolsMgr::GetCurrToolMaxDepth( double dSafe, double& dMaxDepth) const
GetValInNotes( m_tdCurrTool.m_sSysNotes, TSI_THLEN, dTHoldLen) ;
GetValInNotes( m_tdCurrTool.m_sSysNotes, TSI_THDIAM, dTHoldDiam) ;
}
// calcolo il massimo affondamento
// calcolo il massimo affondamento per le limitazioni dal portautensili
dMaxDepth = m_tdCurrTool.m_dLen - dSafe ;
if ( m_tdCurrTool.m_dDiam > dTHoldDiam)
dMaxDepth -= dTHoldBase ;
else
if ( dTHoldDiam > m_tdCurrTool.m_dDiam + EPS_SMALL)
dMaxDepth -= dTHoldLen ;
else
dMaxDepth -= dTHoldBase ;
// recupero l'eventuale diametro gambo utensile (definito se non nullo)
double dStemDiam ; m_tdCurrTool.GetParam( TPA_STEMDIAM, dStemDiam) ;
if ( dStemDiam > m_tdCurrTool.m_dDiam + EPS_SMALL)
dMaxDepth = min( dMaxDepth, m_tdCurrTool.m_dMaxMat) ;
return true ;
}
// se mortasatrice o sega a catena
@@ -734,10 +743,11 @@ ToolsMgr::GetCurrToolThDiam( double& dThDiam) const
if ( ! m_bCurrTool)
return false ;
// se punta a forare, lama, fresa o scalpello
// se punta a forare, lama, fresa, mortasatrice/sega a catena o scalpello
if ( ( m_tdCurrTool.m_nType & TF_DRILLBIT) != 0 ||
( m_tdCurrTool.m_nType & TF_SAWBLADE) != 0 ||
( m_tdCurrTool.m_nType & TF_MILL) != 0 ||
( m_tdCurrTool.m_nType & TF_MORTISE) != 0 ||
( m_tdCurrTool.m_nType & TF_CHISEL) != 0) {
// recupero le dimensioni del porta utensili
double dTHoldBase = 0 ;
@@ -757,9 +767,8 @@ ToolsMgr::GetCurrToolThDiam( double& dThDiam) const
dThDiam = dTHoldDiam ;
return true ;
}
// se mortasatrice/sega a catena o waterjet
else if ( ( m_tdCurrTool.m_nType & TF_MORTISE) != 0 ||
( m_tdCurrTool.m_nType & TF_WATERJET) != 0) {
// se waterjet
else if ( ( m_tdCurrTool.m_nType & TF_WATERJET) != 0) {
dThDiam = 0 ;
return true ;
}
@@ -775,10 +784,11 @@ ToolsMgr::GetCurrToolThLength( double& dThLen) const
if ( ! m_bCurrTool)
return false ;
// se punta a forare, lama, fresa o scalpello
// se punta a forare, lama, fresa, mortasatrice/sega a catena o scalpello
if ( ( m_tdCurrTool.m_nType & TF_DRILLBIT) != 0 ||
( m_tdCurrTool.m_nType & TF_SAWBLADE) != 0 ||
( m_tdCurrTool.m_nType & TF_MILL) != 0 ||
( m_tdCurrTool.m_nType & TF_MORTISE) != 0 ||
( m_tdCurrTool.m_nType & TF_CHISEL) != 0) {
// recupero le dimensioni del porta utensili
double dTHoldBase = 0 ;
@@ -798,9 +808,8 @@ ToolsMgr::GetCurrToolThLength( double& dThLen) const
dThLen = dTHoldLen ;
return true ;
}
// se mortasatrice/sega a catena o waterjet
else if ( ( m_tdCurrTool.m_nType & TF_MORTISE) != 0 ||
( m_tdCurrTool.m_nType & TF_WATERJET) != 0) {
// se waterjet
else if ( ( m_tdCurrTool.m_nType & TF_WATERJET) != 0) {
dThLen = 0 ;
return true ;
}
WaterJetting.cpp
+335 -270
View File
File diff suppressed because it is too large Load Diff
WaterJetting.h
+3 -5
View File
@@ -80,9 +80,9 @@ class WaterJetting : public Machining
bool AddLeadInPreview( const ICurveComposite* pCompo, ISurfFlatRegion* pSPV) ;
bool AddLeadOutPreview( const ICurveComposite* pCompo, ISurfFlatRegion* pSPV) ;
bool AddLoopsPreview( const ICurveComposite* pCompo, ISurfFlatRegion* pSPV) ;
bool AddStandardWj( const ICurveComposite* pCompo, const Vector3d& vtTool, bool bSplitArcs) ;
bool AddApproach( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ) ;
bool AddRetract( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ) ;
bool AddStandardWj( const ICurveComposite* pCompo, const Vector3d& vtTool, bool bSplitArcs, double dAddedOverlap) ;
bool AddApproach( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ, bool bSplit) ;
bool AddRetract( const Point3d& ptP, const Vector3d& vtTool, double dSafeZ, bool bSplit) ;
bool CalcLeadInStart( const Point3d& ptStart, const Vector3d& vtStart, const Vector3d& vtN,
const ICurveComposite* pCompo, Point3d& ptP1) const ;
bool AddLeadIn( const Point3d& ptP1, const Point3d& ptStart, const Vector3d& vtStart,
@@ -90,8 +90,6 @@ class WaterJetting : public Machining
bool AddLeadOut( const Point3d& ptEnd, const Vector3d& vtEnd, const Vector3d& vtN,
bool bSplitArcs, Point3d& ptP1) ;
double GetRadiusForStartEndElevation( void) const ;
bool GetPointOutOfRaw( const Point3d& ptP, const Vector3d& vtTool, double dElev) const ;
bool GetPointAboveRaw( const Point3d& ptP) const ;
bool SetToolCorrAuxDir( const Vector3d& vtTool, const Vector3d& vtCorr) ;
bool CalcAndSetToolCorrAuxDir( const ICurveComposite* pCompo, double dU) ;
Vector3d CalcToolDir( const ICurveComposite* pCompo, double dU) ;
WaterJettingData.cpp
+3 -3
View File
@@ -133,7 +133,7 @@ WaterJettingData::Clone( void) const
bool
WaterJettingData::CopyFrom( const MachiningData* pMdata)
{
// è inutile copiare se sorgente coincide con destinazione
// è inutile copiare se sorgente coincide con destinazione
if ( pMdata == this)
return true ;
// la sorgente deve essere dello stesso tipo
@@ -242,7 +242,7 @@ WaterJettingData::SameAs( const MachiningData* pMdata) const
int
WaterJettingData::GetSize( void) const
{
// in debug verifico validità ultimo campo
// in debug verifico validità ultimo campo
assert( sWaterJettingKey[KEY_WS] == "WS") ;
return KEY_ZZZ ;
}
@@ -486,7 +486,7 @@ WaterJettingData::VerifyExtCornerType( int nVal) const
bool
WaterJettingData::VerifyIntCornerType( int nVal) const
{
return ( nVal == WJET_IC_NONE || nVal == WJET_IC_SLOW) ;
return ( nVal == WJET_IC_NONE || nVal == WJET_IC_SLOW || nVal == WJET_IC_SLOW_FULL) ;
}
//----------------------------------------------------------------------------
WaterJettingData.h
+6 -2
View File
@@ -102,6 +102,10 @@ struct WaterJettingData : public MachiningData
//----------------------------------------------------------------------------
inline const WaterJettingData* GetWaterJettingData( const MachiningData* pMdata)
{ return (dynamic_cast<const WaterJettingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_WATERJETTING)
return nullptr ;
return ( static_cast<const WaterJettingData*>( pMdata)) ; }
inline WaterJettingData* GetWaterJettingData( MachiningData* pMdata)
{ return (dynamic_cast<WaterJettingData*>( pMdata)) ; }
{ if ( pMdata == nullptr || pMdata->GetType() != MT_WATERJETTING)
return nullptr ;
return ( static_cast<WaterJettingData*>( pMdata)) ; }