hwdrv_apci3200.c revision 3019b4106bf8c2658343a84361f4f1abb6280633
1/** 2@verbatim 3 4Copyright (C) 2004,2005 ADDI-DATA GmbH for the source code of this module. 5 6 ADDI-DATA GmbH 7 Dieselstrasse 3 8 D-77833 Ottersweier 9 Tel: +19(0)7223/9493-0 10 Fax: +49(0)7223/9493-92 11 http://www.addi-data-com 12 info@addi-data.com 13 14This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. 15 16This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. 17 18You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA 19 20You shoud also find the complete GPL in the COPYING file accompanying this source code. 21 22@endverbatim 23*/ 24/* 25 26 +-----------------------------------------------------------------------+ 27 | (C) ADDI-DATA GmbH Dieselstraße 3 D-77833 Ottersweier | 28 +-----------------------------------------------------------------------+ 29 | Tel : +49 (0) 7223/9493-0 | email : info@addi-data.com | 30 | Fax : +49 (0) 7223/9493-92 | Internet : http://www.addi-data.com | 31 +-------------------------------+---------------------------------------+ 32 | Project : APCI-3200 | Compiler : GCC | 33 | Module name : hwdrv_apci3200.c| Version : 2.96 | 34 +-------------------------------+---------------------------------------+ 35 | Project manager: Eric Stolz | Date : 02/12/2002 | 36 +-------------------------------+---------------------------------------+ 37 | Description : Hardware Layer Acces For APCI-3200 | 38 +-----------------------------------------------------------------------+ 39 | UPDATES | 40 +----------+-----------+------------------------------------------------+ 41 | Date | Author | Description of updates | 42 +----------+-----------+------------------------------------------------+ 43 | 02.07.04 | J. Krauth | Modification from the driver in order to | 44 | | | correct some errors when using several boards. | 45 | | | | 46 | | | | 47 +----------+-----------+------------------------------------------------+ 48 | 26.10.04 | J. Krauth | - Update for COMEDI 0.7.68 | 49 | | | - Read eeprom value | 50 | | | - Append APCI-3300 | 51 +----------+-----------+------------------------------------------------+ 52*/ 53 54/* 55 +----------------------------------------------------------------------------+ 56 | Included files | 57 +----------------------------------------------------------------------------+ 58*/ 59#include "hwdrv_apci3200.h" 60//Begin JK 21.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 61#include "addi_amcc_S5920.h" 62//#define PRINT_INFO 63 64//End JK 21.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 65 66//BEGIN JK 06.07.04: Management of sevrals boards 67/* 68 INT i_CJCAvailable=1; 69 INT i_CJCPolarity=0; 70 INT i_CJCGain=2;//changed from 0 to 2 71 INT i_InterruptFlag=0; 72 INT i_ADDIDATAPolarity; 73 INT i_ADDIDATAGain; 74 INT i_AutoCalibration=0; //: auto calibration 75 INT i_ADDIDATAConversionTime; 76 INT i_ADDIDATAConversionTimeUnit; 77 INT i_ADDIDATAType; 78 INT i_ChannelNo; 79 INT i_ChannelCount=0; 80 INT i_ScanType; 81 INT i_FirstChannel; 82 INT i_LastChannel; 83 INT i_Sum=0; 84 INT i_Offset; 85 UINT ui_Channel_num=0; 86 static int i_Count=0; 87 INT i_Initialised=0; 88 UINT ui_InterruptChannelValue[96]; //Buffer 89*/ 90str_BoardInfos s_BoardInfos[100]; // 100 will be the max number of boards to be used 91//END JK 06.07.04: Management of sevrals boards 92 93//Begin JK 21.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 94 95/*+----------------------------------------------------------------------------+*/ 96/*| Function Name : INT i_AddiHeaderRW_ReadEeprom |*/ 97/*| (INT i_NbOfWordsToRead, |*/ 98/*| DWORD dw_PCIBoardEepromAddress, |*/ 99/*| WORD w_EepromStartAddress, |*/ 100/*| PWORD pw_DataRead) |*/ 101/*+----------------------------------------------------------------------------+*/ 102/*| Task : Read word from the 5920 eeprom. |*/ 103/*+----------------------------------------------------------------------------+*/ 104/*| Input Parameters : INT i_NbOfWordsToRead : Nbr. of word to read |*/ 105/*| DWORD dw_PCIBoardEepromAddress : Address of the eeprom |*/ 106/*| WORD w_EepromStartAddress : Eeprom strat address |*/ 107/*+----------------------------------------------------------------------------+*/ 108/*| Output Parameters : PWORD pw_DataRead : Read data |*/ 109/*+----------------------------------------------------------------------------+*/ 110/*| Return Value : - |*/ 111/*+----------------------------------------------------------------------------+*/ 112 113INT i_AddiHeaderRW_ReadEeprom(INT i_NbOfWordsToRead, 114 DWORD dw_PCIBoardEepromAddress, 115 WORD w_EepromStartAddress, PWORD pw_DataRead) 116{ 117 DWORD dw_eeprom_busy = 0; 118 INT i_Counter = 0; 119 INT i_WordCounter; 120 INT i; 121 BYTE pb_ReadByte[1]; 122 BYTE b_ReadLowByte = 0; 123 BYTE b_ReadHighByte = 0; 124 BYTE b_SelectedAddressLow = 0; 125 BYTE b_SelectedAddressHigh = 0; 126 WORD w_ReadWord = 0; 127 128 for (i_WordCounter = 0; i_WordCounter < i_NbOfWordsToRead; 129 i_WordCounter++) { 130 do { 131 dw_eeprom_busy = 132 inl(dw_PCIBoardEepromAddress + 133 AMCC_OP_REG_MCSR); 134 dw_eeprom_busy = dw_eeprom_busy & EEPROM_BUSY; 135 } 136 while (dw_eeprom_busy == EEPROM_BUSY); 137 138 for (i_Counter = 0; i_Counter < 2; i_Counter++) { 139 b_SelectedAddressLow = (w_EepromStartAddress + i_Counter) % 256; //Read the low 8 bit part 140 b_SelectedAddressHigh = (w_EepromStartAddress + i_Counter) / 256; //Read the high 8 bit part 141 142 //Select the load low address mode 143 outb(NVCMD_LOAD_LOW, 144 dw_PCIBoardEepromAddress + AMCC_OP_REG_MCSR + 145 3); 146 147 //Wait on busy 148 do { 149 dw_eeprom_busy = 150 inl(dw_PCIBoardEepromAddress + 151 AMCC_OP_REG_MCSR); 152 dw_eeprom_busy = dw_eeprom_busy & EEPROM_BUSY; 153 } 154 while (dw_eeprom_busy == EEPROM_BUSY); 155 156 //Load the low address 157 outb(b_SelectedAddressLow, 158 dw_PCIBoardEepromAddress + AMCC_OP_REG_MCSR + 159 2); 160 161 //Wait on busy 162 do { 163 dw_eeprom_busy = 164 inl(dw_PCIBoardEepromAddress + 165 AMCC_OP_REG_MCSR); 166 dw_eeprom_busy = dw_eeprom_busy & EEPROM_BUSY; 167 } 168 while (dw_eeprom_busy == EEPROM_BUSY); 169 170 //Select the load high address mode 171 outb(NVCMD_LOAD_HIGH, 172 dw_PCIBoardEepromAddress + AMCC_OP_REG_MCSR + 173 3); 174 175 //Wait on busy 176 do { 177 dw_eeprom_busy = 178 inl(dw_PCIBoardEepromAddress + 179 AMCC_OP_REG_MCSR); 180 dw_eeprom_busy = dw_eeprom_busy & EEPROM_BUSY; 181 } 182 while (dw_eeprom_busy == EEPROM_BUSY); 183 184 //Load the high address 185 outb(b_SelectedAddressHigh, 186 dw_PCIBoardEepromAddress + AMCC_OP_REG_MCSR + 187 2); 188 189 //Wait on busy 190 do { 191 dw_eeprom_busy = 192 inl(dw_PCIBoardEepromAddress + 193 AMCC_OP_REG_MCSR); 194 dw_eeprom_busy = dw_eeprom_busy & EEPROM_BUSY; 195 } 196 while (dw_eeprom_busy == EEPROM_BUSY); 197 198 //Select the READ mode 199 outb(NVCMD_BEGIN_READ, 200 dw_PCIBoardEepromAddress + AMCC_OP_REG_MCSR + 201 3); 202 203 //Wait on busy 204 do { 205 dw_eeprom_busy = 206 inl(dw_PCIBoardEepromAddress + 207 AMCC_OP_REG_MCSR); 208 dw_eeprom_busy = dw_eeprom_busy & EEPROM_BUSY; 209 } 210 while (dw_eeprom_busy == EEPROM_BUSY); 211 212 //Read data into the EEPROM 213 *pb_ReadByte = 214 inb(dw_PCIBoardEepromAddress + 215 AMCC_OP_REG_MCSR + 2); 216 217 //Wait on busy 218 do { 219 dw_eeprom_busy = 220 inl(dw_PCIBoardEepromAddress + 221 AMCC_OP_REG_MCSR); 222 dw_eeprom_busy = dw_eeprom_busy & EEPROM_BUSY; 223 } 224 while (dw_eeprom_busy == EEPROM_BUSY); 225 226 //Select the upper address part 227 if (i_Counter == 0) { 228 b_ReadLowByte = pb_ReadByte[0]; 229 } else { 230 b_ReadHighByte = pb_ReadByte[0]; 231 } 232 233 //Sleep 234 for (i = 0; i < 10000; i++) ; 235 236 } 237 w_ReadWord = 238 (b_ReadLowByte | (((unsigned short)b_ReadHighByte) * 239 256)); 240 241 pw_DataRead[i_WordCounter] = w_ReadWord; 242 243 w_EepromStartAddress += 2; // to read the next word 244 245 } // for (...) i_NbOfWordsToRead 246 return (0); 247} 248 249/*+----------------------------------------------------------------------------+*/ 250/*| Function Name : void v_GetAPCI3200EepromCalibrationValue (void) |*/ 251/*+----------------------------------------------------------------------------+*/ 252/*| Task : Read calibration value from the APCI-3200 eeprom. |*/ 253/*+----------------------------------------------------------------------------+*/ 254/*| Input Parameters : - |*/ 255/*+----------------------------------------------------------------------------+*/ 256/*| Output Parameters : - |*/ 257/*+----------------------------------------------------------------------------+*/ 258/*| Return Value : - |*/ 259/*+----------------------------------------------------------------------------+*/ 260 261void v_GetAPCI3200EepromCalibrationValue(DWORD dw_PCIBoardEepromAddress, 262 str_BoardInfos * BoardInformations) 263{ 264 WORD w_AnalogInputMainHeaderAddress; 265 WORD w_AnalogInputComponentAddress; 266 WORD w_NumberOfModuls = 0; 267 WORD w_CurrentSources[2]; 268 WORD w_ModulCounter = 0; 269 WORD w_FirstHeaderSize = 0; 270 WORD w_NumberOfInputs = 0; 271 WORD w_CJCFlag = 0; 272 WORD w_NumberOfGainValue = 0; 273 WORD w_SingleHeaderAddress = 0; 274 WORD w_SingleHeaderSize = 0; 275 WORD w_Input = 0; 276 WORD w_GainFactorAddress = 0; 277 WORD w_GainFactorValue[2]; 278 WORD w_GainIndex = 0; 279 WORD w_GainValue = 0; 280 281 /*****************************************/ 282 /** Get the Analog input header address **/ 283 /*****************************************/ 284 i_AddiHeaderRW_ReadEeprom(1, //i_NbOfWordsToRead 285 dw_PCIBoardEepromAddress, 0x116, //w_EepromStartAddress: Analog input header address 286 &w_AnalogInputMainHeaderAddress); 287 288 /*******************************************/ 289 /** Compute the real analog input address **/ 290 /*******************************************/ 291 w_AnalogInputMainHeaderAddress = w_AnalogInputMainHeaderAddress + 0x100; 292 293 /******************************/ 294 /** Get the number of moduls **/ 295 /******************************/ 296 i_AddiHeaderRW_ReadEeprom(1, //i_NbOfWordsToRead 297 dw_PCIBoardEepromAddress, w_AnalogInputMainHeaderAddress + 0x02, //w_EepromStartAddress: Number of conponment 298 &w_NumberOfModuls); 299 300 for (w_ModulCounter = 0; w_ModulCounter < w_NumberOfModuls; 301 w_ModulCounter++) { 302 /***********************************/ 303 /** Compute the component address **/ 304 /***********************************/ 305 w_AnalogInputComponentAddress = 306 w_AnalogInputMainHeaderAddress + 307 (w_FirstHeaderSize * w_ModulCounter) + 0x04; 308 309 /****************************/ 310 /** Read first header size **/ 311 /****************************/ 312 i_AddiHeaderRW_ReadEeprom(1, //i_NbOfWordsToRead 313 dw_PCIBoardEepromAddress, w_AnalogInputComponentAddress, // Address of the first header 314 &w_FirstHeaderSize); 315 316 w_FirstHeaderSize = w_FirstHeaderSize >> 4; 317 318 /***************************/ 319 /** Read number of inputs **/ 320 /***************************/ 321 i_AddiHeaderRW_ReadEeprom(1, //i_NbOfWordsToRead 322 dw_PCIBoardEepromAddress, w_AnalogInputComponentAddress + 0x06, // Number of inputs for the first modul 323 &w_NumberOfInputs); 324 325 w_NumberOfInputs = w_NumberOfInputs >> 4; 326 327 /***********************/ 328 /** Read the CJC flag **/ 329 /***********************/ 330 i_AddiHeaderRW_ReadEeprom(1, //i_NbOfWordsToRead 331 dw_PCIBoardEepromAddress, w_AnalogInputComponentAddress + 0x08, // CJC flag 332 &w_CJCFlag); 333 334 w_CJCFlag = (w_CJCFlag >> 3) & 0x1; // Get only the CJC flag 335 336 /*******************************/ 337 /** Read number of gain value **/ 338 /*******************************/ 339 i_AddiHeaderRW_ReadEeprom(1, //i_NbOfWordsToRead 340 dw_PCIBoardEepromAddress, w_AnalogInputComponentAddress + 0x44, // Number of gain value 341 &w_NumberOfGainValue); 342 343 w_NumberOfGainValue = w_NumberOfGainValue & 0xFF; 344 345 /***********************************/ 346 /** Compute single header address **/ 347 /***********************************/ 348 w_SingleHeaderAddress = 349 w_AnalogInputComponentAddress + 0x46 + 350 (((w_NumberOfGainValue / 16) + 1) * 2) + 351 (6 * w_NumberOfGainValue) + 352 (4 * (((w_NumberOfGainValue / 16) + 1) * 2)); 353 354 /********************************************/ 355 /** Read current sources value for input 1 **/ 356 /********************************************/ 357 i_AddiHeaderRW_ReadEeprom(1, //i_NbOfWordsToRead 358 dw_PCIBoardEepromAddress, w_SingleHeaderAddress, //w_EepromStartAddress: Single header address 359 &w_SingleHeaderSize); 360 361 w_SingleHeaderSize = w_SingleHeaderSize >> 4; 362 363 /*************************************/ 364 /** Read gain factor for the module **/ 365 /*************************************/ 366 w_GainFactorAddress = w_AnalogInputComponentAddress; 367 368 for (w_GainIndex = 0; w_GainIndex < w_NumberOfGainValue; 369 w_GainIndex++) { 370 /************************************/ 371 /** Read gain value for the module **/ 372 /************************************/ 373 i_AddiHeaderRW_ReadEeprom(1, //i_NbOfWordsToRead 374 dw_PCIBoardEepromAddress, w_AnalogInputComponentAddress + 70 + (2 * (1 + (w_NumberOfGainValue / 16))) + (0x02 * w_GainIndex), // Gain value 375 &w_GainValue); 376 377 BoardInformations->s_Module[w_ModulCounter]. 378 w_GainValue[w_GainIndex] = w_GainValue; 379 380# ifdef PRINT_INFO 381 printk("\n Gain value = %d", 382 BoardInformations->s_Module[w_ModulCounter]. 383 w_GainValue[w_GainIndex]); 384# endif 385 386 /*************************************/ 387 /** Read gain factor for the module **/ 388 /*************************************/ 389 i_AddiHeaderRW_ReadEeprom(2, //i_NbOfWordsToRead 390 dw_PCIBoardEepromAddress, w_AnalogInputComponentAddress + 70 + ((2 * w_NumberOfGainValue) + (2 * (1 + (w_NumberOfGainValue / 16)))) + (0x04 * w_GainIndex), // Gain factor 391 w_GainFactorValue); 392 393 BoardInformations->s_Module[w_ModulCounter]. 394 ul_GainFactor[w_GainIndex] = 395 (w_GainFactorValue[1] << 16) + 396 w_GainFactorValue[0]; 397 398# ifdef PRINT_INFO 399 printk("\n w_GainFactorValue [%d] = %lu", w_GainIndex, 400 BoardInformations->s_Module[w_ModulCounter]. 401 ul_GainFactor[w_GainIndex]); 402# endif 403 } 404 405 /***************************************************************/ 406 /** Read current source value for each channels of the module **/ 407 /***************************************************************/ 408 for (w_Input = 0; w_Input < w_NumberOfInputs; w_Input++) { 409 /********************************************/ 410 /** Read current sources value for input 1 **/ 411 /********************************************/ 412 i_AddiHeaderRW_ReadEeprom(2, //i_NbOfWordsToRead 413 dw_PCIBoardEepromAddress, 414 (w_Input * w_SingleHeaderSize) + 415 w_SingleHeaderAddress + 0x0C, w_CurrentSources); 416 417 /************************************/ 418 /** Save the current sources value **/ 419 /************************************/ 420 BoardInformations->s_Module[w_ModulCounter]. 421 ul_CurrentSource[w_Input] = 422 (w_CurrentSources[0] + 423 ((w_CurrentSources[1] & 0xFFF) << 16)); 424 425# ifdef PRINT_INFO 426 printk("\n Current sources [%d] = %lu", w_Input, 427 BoardInformations->s_Module[w_ModulCounter]. 428 ul_CurrentSource[w_Input]); 429# endif 430 } 431 432 /***************************************/ 433 /** Read the CJC current source value **/ 434 /***************************************/ 435 i_AddiHeaderRW_ReadEeprom(2, //i_NbOfWordsToRead 436 dw_PCIBoardEepromAddress, 437 (w_Input * w_SingleHeaderSize) + w_SingleHeaderAddress + 438 0x0C, w_CurrentSources); 439 440 /************************************/ 441 /** Save the current sources value **/ 442 /************************************/ 443 BoardInformations->s_Module[w_ModulCounter]. 444 ul_CurrentSourceCJC = 445 (w_CurrentSources[0] + 446 ((w_CurrentSources[1] & 0xFFF) << 16)); 447 448# ifdef PRINT_INFO 449 printk("\n Current sources CJC = %lu", 450 BoardInformations->s_Module[w_ModulCounter]. 451 ul_CurrentSourceCJC); 452# endif 453 } 454} 455 456INT i_APCI3200_GetChannelCalibrationValue(struct comedi_device * dev, 457 unsigned int ui_Channel_num, unsigned int * CJCCurrentSource, 458 unsigned int * ChannelCurrentSource, unsigned int * ChannelGainFactor) 459{ 460 int i_DiffChannel = 0; 461 int i_Module = 0; 462 463#ifdef PRINT_INFO 464 printk("\n Channel = %u", ui_Channel_num); 465#endif 466 467 //Test if single or differential mode 468 if (s_BoardInfos[dev->minor].i_ConnectionType == 1) { 469 //if diff 470 471 if ((ui_Channel_num >= 0) && (ui_Channel_num <= 1)) 472 i_DiffChannel = ui_Channel_num, i_Module = 0; 473 else if ((ui_Channel_num >= 2) && (ui_Channel_num <= 3)) 474 i_DiffChannel = ui_Channel_num - 2, i_Module = 1; 475 else if ((ui_Channel_num >= 4) && (ui_Channel_num <= 5)) 476 i_DiffChannel = ui_Channel_num - 4, i_Module = 2; 477 else if ((ui_Channel_num >= 6) && (ui_Channel_num <= 7)) 478 i_DiffChannel = ui_Channel_num - 6, i_Module = 3; 479 480 } else { 481 // if single 482 if ((ui_Channel_num == 0) || (ui_Channel_num == 1)) 483 i_DiffChannel = 0, i_Module = 0; 484 else if ((ui_Channel_num == 2) || (ui_Channel_num == 3)) 485 i_DiffChannel = 1, i_Module = 0; 486 else if ((ui_Channel_num == 4) || (ui_Channel_num == 5)) 487 i_DiffChannel = 0, i_Module = 1; 488 else if ((ui_Channel_num == 6) || (ui_Channel_num == 7)) 489 i_DiffChannel = 1, i_Module = 1; 490 else if ((ui_Channel_num == 8) || (ui_Channel_num == 9)) 491 i_DiffChannel = 0, i_Module = 2; 492 else if ((ui_Channel_num == 10) || (ui_Channel_num == 11)) 493 i_DiffChannel = 1, i_Module = 2; 494 else if ((ui_Channel_num == 12) || (ui_Channel_num == 13)) 495 i_DiffChannel = 0, i_Module = 3; 496 else if ((ui_Channel_num == 14) || (ui_Channel_num == 15)) 497 i_DiffChannel = 1, i_Module = 3; 498 } 499 500 //Test if thermocouple or RTD mode 501 *CJCCurrentSource = 502 s_BoardInfos[dev->minor].s_Module[i_Module].ul_CurrentSourceCJC; 503#ifdef PRINT_INFO 504 printk("\n CJCCurrentSource = %lu", *CJCCurrentSource); 505#endif 506 507 *ChannelCurrentSource = 508 s_BoardInfos[dev->minor].s_Module[i_Module]. 509 ul_CurrentSource[i_DiffChannel]; 510#ifdef PRINT_INFO 511 printk("\n ChannelCurrentSource = %lu", *ChannelCurrentSource); 512#endif 513 // } 514 // } 515 516 //Channle gain factor 517 *ChannelGainFactor = 518 s_BoardInfos[dev->minor].s_Module[i_Module]. 519 ul_GainFactor[s_BoardInfos[dev->minor].i_ADDIDATAGain]; 520#ifdef PRINT_INFO 521 printk("\n ChannelGainFactor = %lu", *ChannelGainFactor); 522#endif 523 //End JK 21.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 524 525 return (0); 526} 527 528//End JK 21.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 529 530/* 531 +----------------------------------------------------------------------------+ 532 | Function Name : int i_APCI3200_ReadDigitalInput | 533 | (struct comedi_device *dev,struct comedi_subdevice *s, | 534 | struct comedi_insn *insn,unsigned int *data) | 535 +----------------------------------------------------------------------------+ 536 | Task : Read value of the selected channel or port | 537 +----------------------------------------------------------------------------+ 538 | Input Parameters : struct comedi_device *dev : Driver handle | 539 | UINT ui_NoOfChannels : No Of Channels To read for Port 540 Channel Numberfor single channel 541 | UINT data[0] : 0: Read single channel 542 1: Read port value 543 data[1] Port number 544 +----------------------------------------------------------------------------+ 545 | Output Parameters : -- data[0] :Read status value 546 +----------------------------------------------------------------------------+ 547 | Return Value : TRUE : No error occur | 548 | : FALSE : Error occur. Return the error | 549 | | 550 +----------------------------------------------------------------------------+ 551*/ 552 553INT i_APCI3200_ReadDigitalInput(struct comedi_device * dev, struct comedi_subdevice * s, 554 struct comedi_insn * insn, unsigned int * data) 555{ 556 UINT ui_Temp = 0; 557 UINT ui_NoOfChannel = 0; 558 ui_NoOfChannel = CR_CHAN(insn->chanspec); 559 ui_Temp = data[0]; 560 *data = inl(devpriv->i_IobaseReserved); 561 562 if (ui_Temp == 0) { 563 *data = (*data >> ui_NoOfChannel) & 0x1; 564 } //if (ui_Temp==0) 565 else { 566 if (ui_Temp == 1) { 567 if (data[1] < 0 || data[1] > 1) { 568 printk("\nThe port number is in error\n"); 569 return -EINVAL; 570 } //if(data[1] < 0 || data[1] >1) 571 switch (ui_NoOfChannel) { 572 573 case 2: 574 *data = (*data >> (2 * data[1])) & 0x3; 575 break; 576 case 3: 577 *data = (*data & 15); 578 break; 579 default: 580 comedi_error(dev, " chan spec wrong"); 581 return -EINVAL; // "sorry channel spec wrong " 582 583 } //switch(ui_NoOfChannels) 584 } //if (ui_Temp==1) 585 else { 586 printk("\nSpecified channel not supported \n"); 587 } //elseif (ui_Temp==1) 588 } 589 return insn->n; 590} 591 592/* 593 +----------------------------------------------------------------------------+ 594 | Function Name : int i_APCI3200_ConfigDigitalOutput | 595 | (struct comedi_device *dev,struct comedi_subdevice *s, | 596 | struct comedi_insn *insn,unsigned int *data) | 597 +----------------------------------------------------------------------------+ 598 | Task : Configures The Digital Output Subdevice. | 599 +----------------------------------------------------------------------------+ 600 | Input Parameters : struct comedi_device *dev : Driver handle | 601 | data[0] :1 Memory enable 602 0 Memory Disable 603 +----------------------------------------------------------------------------+ 604 | Output Parameters : -- | 605 +----------------------------------------------------------------------------+ 606 | Return Value : TRUE : No error occur | 607 | : FALSE : Error occur. Return the error | 608 | | 609 +----------------------------------------------------------------------------+ 610*/ 611int i_APCI3200_ConfigDigitalOutput(struct comedi_device * dev, struct comedi_subdevice * s, 612 struct comedi_insn * insn, unsigned int * data) 613{ 614 615 if ((data[0] != 0) && (data[0] != 1)) { 616 comedi_error(dev, 617 "Not a valid Data !!! ,Data should be 1 or 0\n"); 618 return -EINVAL; 619 } //if ( (data[0]!=0) && (data[0]!=1) ) 620 if (data[0]) { 621 devpriv->b_OutputMemoryStatus = ADDIDATA_ENABLE; 622 } // if (data[0]) 623 else { 624 devpriv->b_OutputMemoryStatus = ADDIDATA_DISABLE; 625 } //else if (data[0]) 626 return insn->n; 627} 628 629/* 630 +----------------------------------------------------------------------------+ 631 | Function Name : int i_APCI3200_WriteDigitalOutput | 632 | (struct comedi_device *dev,struct comedi_subdevice *s, | 633 | struct comedi_insn *insn,unsigned int *data) | 634 +----------------------------------------------------------------------------+ 635 | Task : writes To the digital Output Subdevice | 636 +----------------------------------------------------------------------------+ 637 | Input Parameters : struct comedi_device *dev : Driver handle | 638 | struct comedi_subdevice *s : Subdevice Pointer | 639 | struct comedi_insn *insn : Insn Structure Pointer | 640 | unsigned int *data : Data Pointer contains | 641 | configuration parameters as below | 642 | data[0] :Value to output 643 data[1] : 0 o/p single channel 644 1 o/p port 645 data[2] : port no 646 data[3] :0 set the digital o/p on 647 1 set the digital o/p off 648 +----------------------------------------------------------------------------+ 649 | Output Parameters : -- | 650 +----------------------------------------------------------------------------+ 651 | Return Value : TRUE : No error occur | 652 | : FALSE : Error occur. Return the error | 653 | | 654 +----------------------------------------------------------------------------+ 655*/ 656INT i_APCI3200_WriteDigitalOutput(struct comedi_device * dev, struct comedi_subdevice * s, 657 struct comedi_insn * insn, unsigned int * data) 658{ 659 UINT ui_Temp = 0, ui_Temp1 = 0; 660 UINT ui_NoOfChannel = CR_CHAN(insn->chanspec); // get the channel 661 if (devpriv->b_OutputMemoryStatus) { 662 ui_Temp = inl(devpriv->i_IobaseAddon); 663 664 } //if(devpriv->b_OutputMemoryStatus ) 665 else { 666 ui_Temp = 0; 667 } //if(devpriv->b_OutputMemoryStatus ) 668 if (data[3] == 0) { 669 if (data[1] == 0) { 670 data[0] = (data[0] << ui_NoOfChannel) | ui_Temp; 671 outl(data[0], devpriv->i_IobaseAddon); 672 } //if(data[1]==0) 673 else { 674 if (data[1] == 1) { 675 switch (ui_NoOfChannel) { 676 677 case 2: 678 data[0] = 679 (data[0] << (2 * 680 data[2])) | ui_Temp; 681 break; 682 case 3: 683 data[0] = (data[0] | ui_Temp); 684 break; 685 } //switch(ui_NoOfChannels) 686 687 outl(data[0], devpriv->i_IobaseAddon); 688 } // if(data[1]==1) 689 else { 690 printk("\nSpecified channel not supported\n"); 691 } //else if(data[1]==1) 692 } //elseif(data[1]==0) 693 } //if(data[3]==0) 694 else { 695 if (data[3] == 1) { 696 if (data[1] == 0) { 697 data[0] = ~data[0] & 0x1; 698 ui_Temp1 = 1; 699 ui_Temp1 = ui_Temp1 << ui_NoOfChannel; 700 ui_Temp = ui_Temp | ui_Temp1; 701 data[0] = (data[0] << ui_NoOfChannel) ^ 0xf; 702 data[0] = data[0] & ui_Temp; 703 outl(data[0], devpriv->i_IobaseAddon); 704 } //if(data[1]==0) 705 else { 706 if (data[1] == 1) { 707 switch (ui_NoOfChannel) { 708 709 case 2: 710 data[0] = ~data[0] & 0x3; 711 ui_Temp1 = 3; 712 ui_Temp1 = 713 ui_Temp1 << 2 * data[2]; 714 ui_Temp = ui_Temp | ui_Temp1; 715 data[0] = 716 ((data[0] << (2 * 717 data 718 [2])) ^ 719 0xf) & ui_Temp; 720 721 break; 722 case 3: 723 break; 724 725 default: 726 comedi_error(dev, 727 " chan spec wrong"); 728 return -EINVAL; // "sorry channel spec wrong " 729 } //switch(ui_NoOfChannels) 730 731 outl(data[0], devpriv->i_IobaseAddon); 732 } // if(data[1]==1) 733 else { 734 printk("\nSpecified channel not supported\n"); 735 } //else if(data[1]==1) 736 } //elseif(data[1]==0) 737 } //if(data[3]==1); 738 else { 739 printk("\nSpecified functionality does not exist\n"); 740 return -EINVAL; 741 } //if else data[3]==1) 742 } //if else data[3]==0) 743 return insn->n; 744} 745 746/* 747 +----------------------------------------------------------------------------+ 748 | Function Name : int i_APCI3200_ReadDigitalOutput | 749 | (struct comedi_device *dev,struct comedi_subdevice *s, | 750 | struct comedi_insn *insn,unsigned int *data) | 751 +----------------------------------------------------------------------------+ 752 | Task : Read value of the selected channel or port | 753 +----------------------------------------------------------------------------+ 754 | Input Parameters : struct comedi_device *dev : Driver handle | 755 | UINT ui_NoOfChannels : No Of Channels To read | 756 | UINT *data : Data Pointer to read status | 757 data[0] :0 read single channel 758 1 read port value 759 data[1] port no 760 761 +----------------------------------------------------------------------------+ 762 | Output Parameters : -- | 763 +----------------------------------------------------------------------------+ 764 | Return Value : TRUE : No error occur | 765 | : FALSE : Error occur. Return the error | 766 | | 767 +----------------------------------------------------------------------------+ 768*/ 769INT i_APCI3200_ReadDigitalOutput(struct comedi_device * dev, struct comedi_subdevice * s, 770 struct comedi_insn * insn, unsigned int * data) 771{ 772 UINT ui_Temp; 773 UINT ui_NoOfChannel; 774 ui_NoOfChannel = CR_CHAN(insn->chanspec); 775 ui_Temp = data[0]; 776 *data = inl(devpriv->i_IobaseAddon); 777 if (ui_Temp == 0) { 778 *data = (*data >> ui_NoOfChannel) & 0x1; 779 } // if (ui_Temp==0) 780 else { 781 if (ui_Temp == 1) { 782 if (data[1] < 0 || data[1] > 1) { 783 printk("\nThe port selection is in error\n"); 784 return -EINVAL; 785 } //if(data[1] <0 ||data[1] >1) 786 switch (ui_NoOfChannel) { 787 case 2: 788 *data = (*data >> (2 * data[1])) & 3; 789 break; 790 791 case 3: 792 break; 793 794 default: 795 comedi_error(dev, " chan spec wrong"); 796 return -EINVAL; // "sorry channel spec wrong " 797 break; 798 } // switch(ui_NoOfChannels) 799 } // if (ui_Temp==1) 800 else { 801 printk("\nSpecified channel not supported \n"); 802 } // else if (ui_Temp==1) 803 } // else if (ui_Temp==0) 804 return insn->n; 805} 806 807/* 808 +----------------------------------------------------------------------------+ 809 | Function Name : INT i_APCI3200_ConfigAnalogInput | 810 | (struct comedi_device *dev,struct comedi_subdevice *s, | 811 | struct comedi_insn *insn,unsigned int *data) | 812 +----------------------------------------------------------------------------+ 813 | Task : Configures The Analog Input Subdevice | 814 +----------------------------------------------------------------------------+ 815 | Input Parameters : struct comedi_device *dev : Driver handle | 816 | struct comedi_subdevice *s : Subdevice Pointer | 817 | struct comedi_insn *insn : Insn Structure Pointer | 818 | unsigned int *data : Data Pointer contains | 819 | configuration parameters as below | 820 | | 821 | data[0] 822 | 0:Normal AI | 823 | 1:RTD | 824 | 2:THERMOCOUPLE | 825 | data[1] : Gain To Use | 826 | | 827 | data[2] : Polarity 828 | 0:Bipolar | 829 | 1:Unipolar | 830 | | 831 | data[3] : Offset Range 832 | | 833 | data[4] : Coupling 834 | 0:DC Coupling | 835 | 1:AC Coupling | 836 | | 837 | data[5] :Differential/Single 838 | 0:Single | 839 | 1:Differential | 840 | | 841 | data[6] :TimerReloadValue 842 | | 843 | data[7] :ConvertingTimeUnit 844 | | 845 | data[8] :0 Analog voltage measurement 846 1 Resistance measurement 847 2 Temperature measurement 848 | data[9] :Interrupt 849 | 0:Disable 850 | 1:Enable 851 data[10] :Type of Thermocouple 852 | data[11] : 0: single channel 853 Module Number 854 | 855 | data[12] 856 | 0:Single Read 857 | 1:Read more channel 858 2:Single scan 859 | 3:Continous Scan 860 data[13] :Number of channels to read 861 | data[14] :RTD connection type 862 :0:RTD not used 863 1:RTD 2 wire connection 864 2:RTD 3 wire connection 865 3:RTD 4 wire connection 866 | | 867 | | 868 | | 869 +----------------------------------------------------------------------------+ 870 | Output Parameters : -- | 871 +----------------------------------------------------------------------------+ 872 | Return Value : TRUE : No error occur | 873 | : FALSE : Error occur. Return the error | 874 | | 875 +----------------------------------------------------------------------------+ 876*/ 877INT i_APCI3200_ConfigAnalogInput(struct comedi_device * dev, struct comedi_subdevice * s, 878 struct comedi_insn * insn, unsigned int * data) 879{ 880 881 UINT ul_Config = 0, ul_Temp = 0; 882 UINT ui_ChannelNo = 0; 883 UINT ui_Dummy = 0; 884 INT i_err = 0; 885 886 //Begin JK 21.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 887 888#ifdef PRINT_INFO 889 INT i = 0, i2 = 0; 890#endif 891 //End JK 21.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 892 893 //BEGIN JK 06.07.04: Management of sevrals boards 894 // Initialize the structure 895 if (s_BoardInfos[dev->minor].b_StructInitialized != 1) { 896 s_BoardInfos[dev->minor].i_CJCAvailable = 1; 897 s_BoardInfos[dev->minor].i_CJCPolarity = 0; 898 s_BoardInfos[dev->minor].i_CJCGain = 2; //changed from 0 to 2 899 s_BoardInfos[dev->minor].i_InterruptFlag = 0; 900 s_BoardInfos[dev->minor].i_AutoCalibration = 0; //: auto calibration 901 s_BoardInfos[dev->minor].i_ChannelCount = 0; 902 s_BoardInfos[dev->minor].i_Sum = 0; 903 s_BoardInfos[dev->minor].ui_Channel_num = 0; 904 s_BoardInfos[dev->minor].i_Count = 0; 905 s_BoardInfos[dev->minor].i_Initialised = 0; 906 s_BoardInfos[dev->minor].b_StructInitialized = 1; 907 908 //Begin JK 21.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 909 s_BoardInfos[dev->minor].i_ConnectionType = 0; 910 //End JK 21.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 911 912 //Begin JK 21.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 913 memset(s_BoardInfos[dev->minor].s_Module, 0, 914 sizeof(s_BoardInfos[dev->minor].s_Module[MAX_MODULE])); 915 916 v_GetAPCI3200EepromCalibrationValue(devpriv->i_IobaseAmcc, 917 &s_BoardInfos[dev->minor]); 918 919#ifdef PRINT_INFO 920 for (i = 0; i < MAX_MODULE; i++) { 921 printk("\n s_Module[%i].ul_CurrentSourceCJC = %lu", i, 922 s_BoardInfos[dev->minor].s_Module[i]. 923 ul_CurrentSourceCJC); 924 925 for (i2 = 0; i2 < 5; i2++) { 926 printk("\n s_Module[%i].ul_CurrentSource [%i] = %lu", i, i2, s_BoardInfos[dev->minor].s_Module[i].ul_CurrentSource[i2]); 927 } 928 929 for (i2 = 0; i2 < 8; i2++) { 930 printk("\n s_Module[%i].ul_GainFactor [%i] = %lu", i, i2, s_BoardInfos[dev->minor].s_Module[i].ul_GainFactor[i2]); 931 } 932 933 for (i2 = 0; i2 < 8; i2++) { 934 printk("\n s_Module[%i].w_GainValue [%i] = %u", 935 i, i2, 936 s_BoardInfos[dev->minor].s_Module[i]. 937 w_GainValue[i2]); 938 } 939 } 940#endif 941 //End JK 21.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 942 } 943 944 if (data[0] != 0 && data[0] != 1 && data[0] != 2) { 945 printk("\nThe selection of acquisition type is in error\n"); 946 i_err++; 947 } //if(data[0]!=0 && data[0]!=1 && data[0]!=2) 948 if (data[0] == 1) { 949 if (data[14] != 0 && data[14] != 1 && data[14] != 2 950 && data[14] != 4) { 951 printk("\n Error in selection of RTD connection type\n"); 952 i_err++; 953 } //if(data[14]!=0 && data[14]!=1 && data[14]!=2 && data[14]!=4) 954 } //if(data[0]==1 ) 955 if (data[1] < 0 || data[1] > 7) { 956 printk("\nThe selection of gain is in error\n"); 957 i_err++; 958 } // if(data[1]<0 || data[1]>7) 959 if (data[2] != 0 && data[2] != 1) { 960 printk("\nThe selection of polarity is in error\n"); 961 i_err++; 962 } //if(data[2]!=0 && data[2]!=1) 963 if (data[3] != 0) { 964 printk("\nThe selection of offset range is in error\n"); 965 i_err++; 966 } // if(data[3]!=0) 967 if (data[4] != 0 && data[4] != 1) { 968 printk("\nThe selection of coupling is in error\n"); 969 i_err++; 970 } //if(data[4]!=0 && data[4]!=1) 971 if (data[5] != 0 && data[5] != 1) { 972 printk("\nThe selection of single/differential mode is in error\n"); 973 i_err++; 974 } //if(data[5]!=0 && data[5]!=1) 975 if (data[8] != 0 && data[8] != 1 && data[2] != 2) { 976 printk("\nError in selection of functionality\n"); 977 } //if(data[8]!=0 && data[8]!=1 && data[2]!=2) 978 if (data[12] == 0 || data[12] == 1) { 979 if (data[6] != 20 && data[6] != 40 && data[6] != 80 980 && data[6] != 160) { 981 printk("\nThe selection of conversion time reload value is in error\n"); 982 i_err++; 983 } // if (data[6]!=20 && data[6]!=40 && data[6]!=80 && data[6]!=160 ) 984 if (data[7] != 2) { 985 printk("\nThe selection of conversion time unit is in error\n"); 986 i_err++; 987 } // if(data[7]!=2) 988 } 989 if (data[9] != 0 && data[9] != 1) { 990 printk("\nThe selection of interrupt enable is in error\n"); 991 i_err++; 992 } //if(data[9]!=0 && data[9]!=1) 993 if (data[11] < 0 || data[11] > 4) { 994 printk("\nThe selection of module is in error\n"); 995 i_err++; 996 } //if(data[11] <0 || data[11]>1) 997 if (data[12] < 0 || data[12] > 3) { 998 printk("\nThe selection of singlechannel/scan selection is in error\n"); 999 i_err++; 1000 } //if(data[12] < 0 || data[12]> 3) 1001 if (data[13] < 0 || data[13] > 16) { 1002 printk("\nThe selection of number of channels is in error\n"); 1003 i_err++; 1004 } // if(data[13] <0 ||data[13] >15) 1005 1006 //BEGIN JK 06.07.04: Management of sevrals boards 1007 /* 1008 i_ChannelCount=data[13]; 1009 i_ScanType=data[12]; 1010 i_ADDIDATAPolarity = data[2]; 1011 i_ADDIDATAGain=data[1]; 1012 i_ADDIDATAConversionTime=data[6]; 1013 i_ADDIDATAConversionTimeUnit=data[7]; 1014 i_ADDIDATAType=data[0]; 1015 */ 1016 1017 // Save acquisition configuration for the actual board 1018 s_BoardInfos[dev->minor].i_ChannelCount = data[13]; 1019 s_BoardInfos[dev->minor].i_ScanType = data[12]; 1020 s_BoardInfos[dev->minor].i_ADDIDATAPolarity = data[2]; 1021 s_BoardInfos[dev->minor].i_ADDIDATAGain = data[1]; 1022 s_BoardInfos[dev->minor].i_ADDIDATAConversionTime = data[6]; 1023 s_BoardInfos[dev->minor].i_ADDIDATAConversionTimeUnit = data[7]; 1024 s_BoardInfos[dev->minor].i_ADDIDATAType = data[0]; 1025 //Begin JK 19.10.2004: APCI-3200 Driver update 0.7.57 -> 0.7.68 1026 s_BoardInfos[dev->minor].i_ConnectionType = data[5]; 1027 //End JK 19.10.2004: APCI-3200 Driver update 0.7.57 -> 0.7.68 1028 //END JK 06.07.04: Management of sevrals boards 1029 1030 //Begin JK 19.10.2004: APCI-3200 Driver update 0.7.57 -> 0.7.68 1031 memset(s_BoardInfos[dev->minor].ui_ScanValueArray, 0, (7 + 12) * sizeof(unsigned int)); // 7 is the maximal number of channels 1032 //End JK 19.10.2004: APCI-3200 Driver update 0.7.57 -> 0.7.68 1033 1034 //BEGIN JK 02.07.04 : This while can't be do, it block the process when using severals boards 1035 //while(i_InterruptFlag==1) 1036 while (s_BoardInfos[dev->minor].i_InterruptFlag == 1) { 1037#ifndef MSXBOX 1038 udelay(1); 1039#else 1040 // In the case where the driver is compiled for the MSX-Box 1041 // we used a printk to have a little delay because udelay 1042 // seems to be broken under the MSX-Box. 1043 // This solution hat to be studied. 1044 printk(""); 1045#endif 1046 } 1047 //END JK 02.07.04 : This while can't be do, it block the process when using severals boards 1048 1049 ui_ChannelNo = CR_CHAN(insn->chanspec); // get the channel 1050 //BEGIN JK 06.07.04: Management of sevrals boards 1051 //i_ChannelNo=ui_ChannelNo; 1052 //ui_Channel_num =ui_ChannelNo; 1053 1054 s_BoardInfos[dev->minor].i_ChannelNo = ui_ChannelNo; 1055 s_BoardInfos[dev->minor].ui_Channel_num = ui_ChannelNo; 1056 1057 //END JK 06.07.04: Management of sevrals boards 1058 1059 if (data[5] == 0) { 1060 if (ui_ChannelNo < 0 || ui_ChannelNo > 15) { 1061 printk("\nThe Selection of the channel is in error\n"); 1062 i_err++; 1063 } // if(ui_ChannelNo<0 || ui_ChannelNo>15) 1064 } //if(data[5]==0) 1065 else { 1066 if (data[14] == 2) { 1067 if (ui_ChannelNo < 0 || ui_ChannelNo > 3) { 1068 printk("\nThe Selection of the channel is in error\n"); 1069 i_err++; 1070 } // if(ui_ChannelNo<0 || ui_ChannelNo>3) 1071 } //if(data[14]==2) 1072 else { 1073 if (ui_ChannelNo < 0 || ui_ChannelNo > 7) { 1074 printk("\nThe Selection of the channel is in error\n"); 1075 i_err++; 1076 } // if(ui_ChannelNo<0 || ui_ChannelNo>7) 1077 } //elseif(data[14]==2) 1078 } //elseif(data[5]==0) 1079 if (data[12] == 0 || data[12] == 1) { 1080 switch (data[5]) { 1081 case 0: 1082 if (ui_ChannelNo >= 0 && ui_ChannelNo <= 3) { 1083 //BEGIN JK 06.07.04: Management of sevrals boards 1084 //i_Offset=0; 1085 s_BoardInfos[dev->minor].i_Offset = 0; 1086 //END JK 06.07.04: Management of sevrals boards 1087 } //if(ui_ChannelNo >=0 && ui_ChannelNo <=3) 1088 if (ui_ChannelNo >= 4 && ui_ChannelNo <= 7) { 1089 //BEGIN JK 06.07.04: Management of sevrals boards 1090 //i_Offset=64; 1091 s_BoardInfos[dev->minor].i_Offset = 64; 1092 //END JK 06.07.04: Management of sevrals boards 1093 } //if(ui_ChannelNo >=4 && ui_ChannelNo <=7) 1094 if (ui_ChannelNo >= 8 && ui_ChannelNo <= 11) { 1095 //BEGIN JK 06.07.04: Management of sevrals boards 1096 //i_Offset=128; 1097 s_BoardInfos[dev->minor].i_Offset = 128; 1098 //END JK 06.07.04: Management of sevrals boards 1099 } //if(ui_ChannelNo >=8 && ui_ChannelNo <=11) 1100 if (ui_ChannelNo >= 12 && ui_ChannelNo <= 15) { 1101 //BEGIN JK 06.07.04: Management of sevrals boards 1102 //i_Offset=192; 1103 s_BoardInfos[dev->minor].i_Offset = 192; 1104 //END JK 06.07.04: Management of sevrals boards 1105 } //if(ui_ChannelNo >=12 && ui_ChannelNo <=15) 1106 break; 1107 case 1: 1108 if (data[14] == 2) { 1109 if (ui_ChannelNo == 0) { 1110 //BEGIN JK 06.07.04: Management of sevrals boards 1111 //i_Offset=0; 1112 s_BoardInfos[dev->minor].i_Offset = 0; 1113 //END JK 06.07.04: Management of sevrals boards 1114 } //if(ui_ChannelNo ==0 ) 1115 if (ui_ChannelNo == 1) { 1116 //BEGIN JK 06.07.04: Management of sevrals boards 1117 //i_Offset=0; 1118 s_BoardInfos[dev->minor].i_Offset = 64; 1119 //END JK 06.07.04: Management of sevrals boards 1120 } // if(ui_ChannelNo ==1) 1121 if (ui_ChannelNo == 2) { 1122 //BEGIN JK 06.07.04: Management of sevrals boards 1123 //i_Offset=128; 1124 s_BoardInfos[dev->minor].i_Offset = 128; 1125 //END JK 06.07.04: Management of sevrals boards 1126 } //if(ui_ChannelNo ==2 ) 1127 if (ui_ChannelNo == 3) { 1128 //BEGIN JK 06.07.04: Management of sevrals boards 1129 //i_Offset=192; 1130 s_BoardInfos[dev->minor].i_Offset = 192; 1131 //END JK 06.07.04: Management of sevrals boards 1132 } //if(ui_ChannelNo ==3) 1133 1134 //BEGIN JK 06.07.04: Management of sevrals boards 1135 //i_ChannelNo=0; 1136 s_BoardInfos[dev->minor].i_ChannelNo = 0; 1137 //END JK 06.07.04: Management of sevrals boards 1138 ui_ChannelNo = 0; 1139 break; 1140 } //if(data[14]==2) 1141 if (ui_ChannelNo >= 0 && ui_ChannelNo <= 1) { 1142 //BEGIN JK 06.07.04: Management of sevrals boards 1143 //i_Offset=0; 1144 s_BoardInfos[dev->minor].i_Offset = 0; 1145 //END JK 06.07.04: Management of sevrals boards 1146 } //if(ui_ChannelNo >=0 && ui_ChannelNo <=1) 1147 if (ui_ChannelNo >= 2 && ui_ChannelNo <= 3) { 1148 //BEGIN JK 06.07.04: Management of sevrals boards 1149 //i_ChannelNo=i_ChannelNo-2; 1150 //i_Offset=64; 1151 s_BoardInfos[dev->minor].i_ChannelNo = 1152 s_BoardInfos[dev->minor].i_ChannelNo - 1153 2; 1154 s_BoardInfos[dev->minor].i_Offset = 64; 1155 //END JK 06.07.04: Management of sevrals boards 1156 ui_ChannelNo = ui_ChannelNo - 2; 1157 } //if(ui_ChannelNo >=2 && ui_ChannelNo <=3) 1158 if (ui_ChannelNo >= 4 && ui_ChannelNo <= 5) { 1159 //BEGIN JK 06.07.04: Management of sevrals boards 1160 //i_ChannelNo=i_ChannelNo-4; 1161 //i_Offset=128; 1162 s_BoardInfos[dev->minor].i_ChannelNo = 1163 s_BoardInfos[dev->minor].i_ChannelNo - 1164 4; 1165 s_BoardInfos[dev->minor].i_Offset = 128; 1166 //END JK 06.07.04: Management of sevrals boards 1167 ui_ChannelNo = ui_ChannelNo - 4; 1168 } //if(ui_ChannelNo >=4 && ui_ChannelNo <=5) 1169 if (ui_ChannelNo >= 6 && ui_ChannelNo <= 7) { 1170 //BEGIN JK 06.07.04: Management of sevrals boards 1171 //i_ChannelNo=i_ChannelNo-6; 1172 //i_Offset=192; 1173 s_BoardInfos[dev->minor].i_ChannelNo = 1174 s_BoardInfos[dev->minor].i_ChannelNo - 1175 6; 1176 s_BoardInfos[dev->minor].i_Offset = 192; 1177 //END JK 06.07.04: Management of sevrals boards 1178 ui_ChannelNo = ui_ChannelNo - 6; 1179 } //if(ui_ChannelNo >=6 && ui_ChannelNo <=7) 1180 break; 1181 1182 default: 1183 printk("\n This selection of polarity does not exist\n"); 1184 i_err++; 1185 } //switch(data[2]) 1186 } //if(data[12]==0 || data[12]==1) 1187 else { 1188 switch (data[11]) { 1189 case 1: 1190 //BEGIN JK 06.07.04: Management of sevrals boards 1191 //i_Offset=0; 1192 s_BoardInfos[dev->minor].i_Offset = 0; 1193 //END JK 06.07.04: Management of sevrals boards 1194 break; 1195 case 2: 1196 //BEGIN JK 06.07.04: Management of sevrals boards 1197 //i_Offset=64; 1198 s_BoardInfos[dev->minor].i_Offset = 64; 1199 //END JK 06.07.04: Management of sevrals boards 1200 break; 1201 case 3: 1202 //BEGIN JK 06.07.04: Management of sevrals boards 1203 //i_Offset=128; 1204 s_BoardInfos[dev->minor].i_Offset = 128; 1205 //END JK 06.07.04: Management of sevrals boards 1206 break; 1207 case 4: 1208 //BEGIN JK 06.07.04: Management of sevrals boards 1209 //i_Offset=192; 1210 s_BoardInfos[dev->minor].i_Offset = 192; 1211 //END JK 06.07.04: Management of sevrals boards 1212 break; 1213 default: 1214 printk("\nError in module selection\n"); 1215 i_err++; 1216 } // switch(data[11]) 1217 } // elseif(data[12]==0 || data[12]==1) 1218 if (i_err) { 1219 i_APCI3200_Reset(dev); 1220 return -EINVAL; 1221 } 1222 //if(i_ScanType!=1) 1223 if (s_BoardInfos[dev->minor].i_ScanType != 1) { 1224 //BEGIN JK 06.07.04: Management of sevrals boards 1225 //i_Count=0; 1226 //i_Sum=0; 1227 s_BoardInfos[dev->minor].i_Count = 0; 1228 s_BoardInfos[dev->minor].i_Sum = 0; 1229 //END JK 06.07.04: Management of sevrals boards 1230 } //if(i_ScanType!=1) 1231 1232 ul_Config = 1233 data[1] | (data[2] << 6) | (data[5] << 7) | (data[3] << 8) | 1234 (data[4] << 9); 1235 //BEGIN JK 06.07.04: Management of sevrals boards 1236 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1237 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1238 12) >> 19) & 1) != 1) ; 1239 //END JK 06.07.04: Management of sevrals boards 1240 /*********************************/ 1241 /* Write the channel to configure */ 1242 /*********************************/ 1243 //BEGIN JK 06.07.04: Management of sevrals boards 1244 //outl(0 | ui_ChannelNo , devpriv->iobase+i_Offset + 0x4); 1245 outl(0 | ui_ChannelNo, 1246 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 0x4); 1247 //END JK 06.07.04: Management of sevrals boards 1248 1249 //BEGIN JK 06.07.04: Management of sevrals boards 1250 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1251 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1252 12) >> 19) & 1) != 1) ; 1253 //END JK 06.07.04: Management of sevrals boards 1254 /**************************/ 1255 /* Reset the configuration */ 1256 /**************************/ 1257 //BEGIN JK 06.07.04: Management of sevrals boards 1258 //outl(0 , devpriv->iobase+i_Offset + 0x0); 1259 outl(0, devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 0x0); 1260 //END JK 06.07.04: Management of sevrals boards 1261 1262 //BEGIN JK 06.07.04: Management of sevrals boards 1263 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1264 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1265 12) >> 19) & 1) != 1) ; 1266 //END JK 06.07.04: Management of sevrals boards 1267 1268 /***************************/ 1269 /* Write the configuration */ 1270 /***************************/ 1271 //BEGIN JK 06.07.04: Management of sevrals boards 1272 //outl(ul_Config , devpriv->iobase+i_Offset + 0x0); 1273 outl(ul_Config, 1274 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 0x0); 1275 //END JK 06.07.04: Management of sevrals boards 1276 1277 /***************************/ 1278 /*Reset the calibration bit */ 1279 /***************************/ 1280 //BEGIN JK 06.07.04: Management of sevrals boards 1281 //ul_Temp = inl(devpriv->iobase+i_Offset + 12); 1282 ul_Temp = inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 12); 1283 //END JK 06.07.04: Management of sevrals boards 1284 1285 //BEGIN JK 06.07.04: Management of sevrals boards 1286 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1287 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1288 12) >> 19) & 1) != 1) ; 1289 //END JK 06.07.04: Management of sevrals boards 1290 1291 //BEGIN JK 06.07.04: Management of sevrals boards 1292 //outl((ul_Temp & 0xFFF9FFFF) , devpriv->iobase+.i_Offset + 12); 1293 outl((ul_Temp & 0xFFF9FFFF), 1294 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 12); 1295 //END JK 06.07.04: Management of sevrals boards 1296 1297 if (data[9] == 1) { 1298 devpriv->tsk_Current = current; 1299 //BEGIN JK 06.07.04: Management of sevrals boards 1300 //i_InterruptFlag=1; 1301 s_BoardInfos[dev->minor].i_InterruptFlag = 1; 1302 //END JK 06.07.04: Management of sevrals boards 1303 } // if(data[9]==1) 1304 else { 1305 //BEGIN JK 06.07.04: Management of sevrals boards 1306 //i_InterruptFlag=0; 1307 s_BoardInfos[dev->minor].i_InterruptFlag = 0; 1308 //END JK 06.07.04: Management of sevrals boards 1309 } //else if(data[9]==1) 1310 1311 //BEGIN JK 06.07.04: Management of sevrals boards 1312 //i_Initialised=1; 1313 s_BoardInfos[dev->minor].i_Initialised = 1; 1314 //END JK 06.07.04: Management of sevrals boards 1315 1316 //BEGIN JK 06.07.04: Management of sevrals boards 1317 //if(i_ScanType==1) 1318 if (s_BoardInfos[dev->minor].i_ScanType == 1) 1319 //END JK 06.07.04: Management of sevrals boards 1320 { 1321 //BEGIN JK 06.07.04: Management of sevrals boards 1322 //i_Sum=i_Sum+1; 1323 s_BoardInfos[dev->minor].i_Sum = 1324 s_BoardInfos[dev->minor].i_Sum + 1; 1325 //END JK 06.07.04: Management of sevrals boards 1326 1327 insn->unused[0] = 0; 1328 i_APCI3200_ReadAnalogInput(dev, s, insn, &ui_Dummy); 1329 } 1330 1331 return insn->n; 1332} 1333 1334/* 1335 +----------------------------------------------------------------------------+ 1336 | Function Name : int i_APCI3200_ReadAnalogInput | 1337 | (struct comedi_device *dev,struct comedi_subdevice *s, | 1338 | struct comedi_insn *insn,unsigned int *data) | 1339 +----------------------------------------------------------------------------+ 1340 | Task : Read value of the selected channel | 1341 +----------------------------------------------------------------------------+ 1342 | Input Parameters : struct comedi_device *dev : Driver handle | 1343 | UINT ui_NoOfChannels : No Of Channels To read | 1344 | UINT *data : Data Pointer to read status | 1345 +----------------------------------------------------------------------------+ 1346 | Output Parameters : -- | 1347 | data[0] : Digital Value Of Input | 1348 | data[1] : Calibration Offset Value | 1349 | data[2] : Calibration Gain Value 1350 | data[3] : CJC value 1351 | data[4] : CJC offset value 1352 | data[5] : CJC gain value 1353 | Begin JK 21.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 1354 | data[6] : CJC current source from eeprom 1355 | data[7] : Channel current source from eeprom 1356 | data[8] : Channle gain factor from eeprom 1357 | End JK 21.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 1358 +----------------------------------------------------------------------------+ 1359 | Return Value : TRUE : No error occur | 1360 | : FALSE : Error occur. Return the error | 1361 | | 1362 +----------------------------------------------------------------------------+ 1363*/ 1364INT i_APCI3200_ReadAnalogInput(struct comedi_device * dev, struct comedi_subdevice * s, 1365 struct comedi_insn * insn, unsigned int * data) 1366{ 1367 UINT ui_DummyValue = 0; 1368 int i_ConvertCJCCalibration; 1369 int i = 0; 1370 1371 //BEGIN JK 06.07.04: Management of sevrals boards 1372 //if(i_Initialised==0) 1373 if (s_BoardInfos[dev->minor].i_Initialised == 0) 1374 //END JK 06.07.04: Management of sevrals boards 1375 { 1376 i_APCI3200_Reset(dev); 1377 return -EINVAL; 1378 } //if(i_Initialised==0); 1379 1380#ifdef PRINT_INFO 1381 printk("\n insn->unused[0] = %i", insn->unused[0]); 1382#endif 1383 1384 switch (insn->unused[0]) { 1385 case 0: 1386 1387 i_APCI3200_Read1AnalogInputChannel(dev, s, insn, 1388 &ui_DummyValue); 1389 //BEGIN JK 06.07.04: Management of sevrals boards 1390 //ui_InterruptChannelValue[i_Count+0]=ui_DummyValue; 1391 s_BoardInfos[dev->minor]. 1392 ui_InterruptChannelValue[s_BoardInfos[dev->minor]. 1393 i_Count + 0] = ui_DummyValue; 1394 //END JK 06.07.04: Management of sevrals boards 1395 1396 //Begin JK 25.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 1397 i_APCI3200_GetChannelCalibrationValue(dev, 1398 s_BoardInfos[dev->minor].ui_Channel_num, 1399 &s_BoardInfos[dev->minor]. 1400 ui_InterruptChannelValue[s_BoardInfos[dev->minor]. 1401 i_Count + 6], 1402 &s_BoardInfos[dev->minor]. 1403 ui_InterruptChannelValue[s_BoardInfos[dev->minor]. 1404 i_Count + 7], 1405 &s_BoardInfos[dev->minor]. 1406 ui_InterruptChannelValue[s_BoardInfos[dev->minor]. 1407 i_Count + 8]); 1408 1409#ifdef PRINT_INFO 1410 printk("\n s_BoardInfos [dev->minor].ui_InterruptChannelValue[s_BoardInfos [dev->minor].i_Count+6] = %lu", s_BoardInfos[dev->minor].ui_InterruptChannelValue[s_BoardInfos[dev->minor].i_Count + 6]); 1411 1412 printk("\n s_BoardInfos [dev->minor].ui_InterruptChannelValue[s_BoardInfos [dev->minor].i_Count+7] = %lu", s_BoardInfos[dev->minor].ui_InterruptChannelValue[s_BoardInfos[dev->minor].i_Count + 7]); 1413 1414 printk("\n s_BoardInfos [dev->minor].ui_InterruptChannelValue[s_BoardInfos [dev->minor].i_Count+8] = %lu", s_BoardInfos[dev->minor].ui_InterruptChannelValue[s_BoardInfos[dev->minor].i_Count + 8]); 1415#endif 1416 1417 //End JK 25.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 1418 1419 //BEGIN JK 06.07.04: Management of sevrals boards 1420 //if((i_ADDIDATAType==2) && (i_InterruptFlag == FALSE) && (i_CJCAvailable==1)) 1421 if ((s_BoardInfos[dev->minor].i_ADDIDATAType == 2) 1422 && (s_BoardInfos[dev->minor].i_InterruptFlag == FALSE) 1423 && (s_BoardInfos[dev->minor].i_CJCAvailable == 1)) 1424 //END JK 06.07.04: Management of sevrals boards 1425 { 1426 i_APCI3200_ReadCJCValue(dev, &ui_DummyValue); 1427 //BEGIN JK 06.07.04: Management of sevrals boards 1428 //ui_InterruptChannelValue[i_Count + 3]=ui_DummyValue; 1429 s_BoardInfos[dev->minor]. 1430 ui_InterruptChannelValue[s_BoardInfos[dev-> 1431 minor].i_Count + 3] = ui_DummyValue; 1432 //END JK 06.07.04: Management of sevrals boards 1433 } //if((i_ADDIDATAType==2) && (i_InterruptFlag == FALSE)) 1434 else { 1435 //BEGIN JK 06.07.04: Management of sevrals boards 1436 //ui_InterruptChannelValue[i_Count + 3]=0; 1437 s_BoardInfos[dev->minor]. 1438 ui_InterruptChannelValue[s_BoardInfos[dev-> 1439 minor].i_Count + 3] = 0; 1440 //END JK 06.07.04: Management of sevrals boards 1441 } //elseif((i_ADDIDATAType==2) && (i_InterruptFlag == FALSE) && (i_CJCAvailable==1)) 1442 1443 //BEGIN JK 06.07.04: Management of sevrals boards 1444 //if (( i_AutoCalibration == FALSE) && (i_InterruptFlag == FALSE)) 1445 if ((s_BoardInfos[dev->minor].i_AutoCalibration == FALSE) 1446 && (s_BoardInfos[dev->minor].i_InterruptFlag == FALSE)) 1447 //END JK 06.07.04: Management of sevrals boards 1448 { 1449 i_APCI3200_ReadCalibrationOffsetValue(dev, 1450 &ui_DummyValue); 1451 //BEGIN JK 06.07.04: Management of sevrals boards 1452 //ui_InterruptChannelValue[i_Count + 1]=ui_DummyValue; 1453 s_BoardInfos[dev->minor]. 1454 ui_InterruptChannelValue[s_BoardInfos[dev-> 1455 minor].i_Count + 1] = ui_DummyValue; 1456 //END JK 06.07.04: Management of sevrals boards 1457 i_APCI3200_ReadCalibrationGainValue(dev, 1458 &ui_DummyValue); 1459 //BEGIN JK 06.07.04: Management of sevrals boards 1460 //ui_InterruptChannelValue[i_Count + 2]=ui_DummyValue; 1461 s_BoardInfos[dev->minor]. 1462 ui_InterruptChannelValue[s_BoardInfos[dev-> 1463 minor].i_Count + 2] = ui_DummyValue; 1464 //END JK 06.07.04: Management of sevrals boards 1465 } //if (( i_AutoCalibration == FALSE) && (i_InterruptFlag == FALSE)) 1466 1467 //BEGIN JK 06.07.04: Management of sevrals boards 1468 //if((i_ADDIDATAType==2) && (i_InterruptFlag == FALSE)&& (i_CJCAvailable==1)) 1469 if ((s_BoardInfos[dev->minor].i_ADDIDATAType == 2) 1470 && (s_BoardInfos[dev->minor].i_InterruptFlag == FALSE) 1471 && (s_BoardInfos[dev->minor].i_CJCAvailable == 1)) 1472 //END JK 06.07.04: Management of sevrals boards 1473 { 1474 /**********************************************************/ 1475 /*Test if the Calibration channel must be read for the CJC */ 1476 /**********************************************************/ 1477 /**********************************/ 1478 /*Test if the polarity is the same */ 1479 /**********************************/ 1480 //BEGIN JK 06.07.04: Management of sevrals boards 1481 //if(i_CJCPolarity!=i_ADDIDATAPolarity) 1482 if (s_BoardInfos[dev->minor].i_CJCPolarity != 1483 s_BoardInfos[dev->minor].i_ADDIDATAPolarity) 1484 //END JK 06.07.04: Management of sevrals boards 1485 { 1486 i_ConvertCJCCalibration = 1; 1487 } //if(i_CJCPolarity!=i_ADDIDATAPolarity) 1488 else { 1489 //BEGIN JK 06.07.04: Management of sevrals boards 1490 //if(i_CJCGain==i_ADDIDATAGain) 1491 if (s_BoardInfos[dev->minor].i_CJCGain == 1492 s_BoardInfos[dev->minor].i_ADDIDATAGain) 1493 //END JK 06.07.04: Management of sevrals boards 1494 { 1495 i_ConvertCJCCalibration = 0; 1496 } //if(i_CJCGain==i_ADDIDATAGain) 1497 else { 1498 i_ConvertCJCCalibration = 1; 1499 } //elseif(i_CJCGain==i_ADDIDATAGain) 1500 } //elseif(i_CJCPolarity!=i_ADDIDATAPolarity) 1501 if (i_ConvertCJCCalibration == 1) { 1502 i_APCI3200_ReadCJCCalOffset(dev, 1503 &ui_DummyValue); 1504 //BEGIN JK 06.07.04: Management of sevrals boards 1505 //ui_InterruptChannelValue[i_Count+4]=ui_DummyValue; 1506 s_BoardInfos[dev->minor]. 1507 ui_InterruptChannelValue[s_BoardInfos 1508 [dev->minor].i_Count + 4] = 1509 ui_DummyValue; 1510 //END JK 06.07.04: Management of sevrals boards 1511 1512 i_APCI3200_ReadCJCCalGain(dev, &ui_DummyValue); 1513 1514 //BEGIN JK 06.07.04: Management of sevrals boards 1515 //ui_InterruptChannelValue[i_Count+5]=ui_DummyValue; 1516 s_BoardInfos[dev->minor]. 1517 ui_InterruptChannelValue[s_BoardInfos 1518 [dev->minor].i_Count + 5] = 1519 ui_DummyValue; 1520 //END JK 06.07.04: Management of sevrals boards 1521 } //if(i_ConvertCJCCalibration==1) 1522 else { 1523 //BEGIN JK 06.07.04: Management of sevrals boards 1524 //ui_InterruptChannelValue[i_Count+4]=0; 1525 //ui_InterruptChannelValue[i_Count+5]=0; 1526 1527 s_BoardInfos[dev->minor]. 1528 ui_InterruptChannelValue[s_BoardInfos 1529 [dev->minor].i_Count + 4] = 0; 1530 s_BoardInfos[dev->minor]. 1531 ui_InterruptChannelValue[s_BoardInfos 1532 [dev->minor].i_Count + 5] = 0; 1533 //END JK 06.07.04: Management of sevrals boards 1534 } //elseif(i_ConvertCJCCalibration==1) 1535 } //if((i_ADDIDATAType==2) && (i_InterruptFlag == FALSE)) 1536 1537 //BEGIN JK 06.07.04: Management of sevrals boards 1538 //if(i_ScanType!=1) 1539 if (s_BoardInfos[dev->minor].i_ScanType != 1) { 1540 //i_Count=0; 1541 s_BoardInfos[dev->minor].i_Count = 0; 1542 } //if(i_ScanType!=1) 1543 else { 1544 //i_Count=i_Count +6; 1545 //Begin JK 22.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 1546 //s_BoardInfos [dev->minor].i_Count=s_BoardInfos [dev->minor].i_Count +6; 1547 s_BoardInfos[dev->minor].i_Count = 1548 s_BoardInfos[dev->minor].i_Count + 9; 1549 //End JK 22.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 1550 } //else if(i_ScanType!=1) 1551 1552 //if((i_ScanType==1) &&(i_InterruptFlag==1)) 1553 if ((s_BoardInfos[dev->minor].i_ScanType == 1) 1554 && (s_BoardInfos[dev->minor].i_InterruptFlag == 1)) { 1555 //i_Count=i_Count-6; 1556 //Begin JK 22.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 1557 //s_BoardInfos [dev->minor].i_Count=s_BoardInfos [dev->minor].i_Count-6; 1558 s_BoardInfos[dev->minor].i_Count = 1559 s_BoardInfos[dev->minor].i_Count - 9; 1560 //End JK 22.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 1561 } 1562 //if(i_ScanType==0) 1563 if (s_BoardInfos[dev->minor].i_ScanType == 0) { 1564 /* 1565 data[0]= ui_InterruptChannelValue[0]; 1566 data[1]= ui_InterruptChannelValue[1]; 1567 data[2]= ui_InterruptChannelValue[2]; 1568 data[3]= ui_InterruptChannelValue[3]; 1569 data[4]= ui_InterruptChannelValue[4]; 1570 data[5]= ui_InterruptChannelValue[5]; 1571 */ 1572#ifdef PRINT_INFO 1573 printk("\n data[0]= s_BoardInfos [dev->minor].ui_InterruptChannelValue[0];"); 1574#endif 1575 data[0] = 1576 s_BoardInfos[dev->minor]. 1577 ui_InterruptChannelValue[0]; 1578 data[1] = 1579 s_BoardInfos[dev->minor]. 1580 ui_InterruptChannelValue[1]; 1581 data[2] = 1582 s_BoardInfos[dev->minor]. 1583 ui_InterruptChannelValue[2]; 1584 data[3] = 1585 s_BoardInfos[dev->minor]. 1586 ui_InterruptChannelValue[3]; 1587 data[4] = 1588 s_BoardInfos[dev->minor]. 1589 ui_InterruptChannelValue[4]; 1590 data[5] = 1591 s_BoardInfos[dev->minor]. 1592 ui_InterruptChannelValue[5]; 1593 1594 //Begin JK 22.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 1595 //printk("\n 0 - i_APCI3200_GetChannelCalibrationValue data [6] = %lu, data [7] = %lu, data [8] = %lu", data [6], data [7], data [8]); 1596 i_APCI3200_GetChannelCalibrationValue(dev, 1597 s_BoardInfos[dev->minor].ui_Channel_num, 1598 &data[6], &data[7], &data[8]); 1599 //End JK 22.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 1600 } 1601 break; 1602 case 1: 1603 1604 for (i = 0; i < insn->n; i++) { 1605 //data[i]=ui_InterruptChannelValue[i]; 1606 data[i] = 1607 s_BoardInfos[dev->minor]. 1608 ui_InterruptChannelValue[i]; 1609 } 1610 1611 //i_Count=0; 1612 //i_Sum=0; 1613 //if(i_ScanType==1) 1614 s_BoardInfos[dev->minor].i_Count = 0; 1615 s_BoardInfos[dev->minor].i_Sum = 0; 1616 if (s_BoardInfos[dev->minor].i_ScanType == 1) { 1617 //i_Initialised=0; 1618 //i_InterruptFlag=0; 1619 s_BoardInfos[dev->minor].i_Initialised = 0; 1620 s_BoardInfos[dev->minor].i_InterruptFlag = 0; 1621 //END JK 06.07.04: Management of sevrals boards 1622 } 1623 break; 1624 default: 1625 printk("\nThe parameters passed are in error\n"); 1626 i_APCI3200_Reset(dev); 1627 return -EINVAL; 1628 } //switch(insn->unused[0]) 1629 1630 return insn->n; 1631} 1632 1633/* 1634 +----------------------------------------------------------------------------+ 1635 | Function Name : int i_APCI3200_Read1AnalogInputChannel | 1636 | (struct comedi_device *dev,struct comedi_subdevice *s, | 1637 | struct comedi_insn *insn,unsigned int *data) | 1638 +----------------------------------------------------------------------------+ 1639 | Task : Read value of the selected channel | 1640 +----------------------------------------------------------------------------+ 1641 | Input Parameters : struct comedi_device *dev : Driver handle | 1642 | UINT ui_NoOfChannel : Channel No to read | 1643 | UINT *data : Data Pointer to read status | 1644 +----------------------------------------------------------------------------+ 1645 | Output Parameters : -- | 1646 | data[0] : Digital Value read | 1647 | 1648 +----------------------------------------------------------------------------+ 1649 | Return Value : TRUE : No error occur | 1650 | : FALSE : Error occur. Return the error | 1651 | | 1652 +----------------------------------------------------------------------------+ 1653*/ 1654INT i_APCI3200_Read1AnalogInputChannel(struct comedi_device * dev, 1655 struct comedi_subdevice * s, struct comedi_insn * insn, unsigned int * data) 1656{ 1657 UINT ui_EOC = 0; 1658 UINT ui_ChannelNo = 0; 1659 UINT ui_CommandRegister = 0; 1660 1661 //BEGIN JK 06.07.04: Management of sevrals boards 1662 //ui_ChannelNo=i_ChannelNo; 1663 ui_ChannelNo = s_BoardInfos[dev->minor].i_ChannelNo; 1664 1665 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1666 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1667 12) >> 19) & 1) != 1) ; 1668 /*********************************/ 1669 /* Write the channel to configure */ 1670 /*********************************/ 1671 //Begin JK 20.10.2004: Bad channel value is used when using differential mode 1672 //outl(0 | ui_Channel_num , devpriv->iobase+i_Offset + 0x4); 1673 //outl(0 | s_BoardInfos [dev->minor].ui_Channel_num , devpriv->iobase+s_BoardInfos [dev->minor].i_Offset + 0x4); 1674 outl(0 | s_BoardInfos[dev->minor].i_ChannelNo, 1675 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 0x4); 1676 //End JK 20.10.2004: Bad channel value is used when using differential mode 1677 1678 /*******************************/ 1679 /* Set the convert timing unit */ 1680 /*******************************/ 1681 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1682 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1683 12) >> 19) & 1) != 1) ; 1684 1685 //outl(i_ADDIDATAConversionTimeUnit , devpriv->iobase+i_Offset + 36); 1686 outl(s_BoardInfos[dev->minor].i_ADDIDATAConversionTimeUnit, 1687 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 36); 1688 1689 /**************************/ 1690 /* Set the convert timing */ 1691 /**************************/ 1692 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1693 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1694 12) >> 19) & 1) != 1) ; 1695 1696 //outl(i_ADDIDATAConversionTime , devpriv->iobase+i_Offset + 32); 1697 outl(s_BoardInfos[dev->minor].i_ADDIDATAConversionTime, 1698 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 32); 1699 1700 /**************************************************************************/ 1701 /* Set the start end stop index to the selected channel and set the start */ 1702 /**************************************************************************/ 1703 1704 ui_CommandRegister = ui_ChannelNo | (ui_ChannelNo << 8) | 0x80000; 1705 1706 /*********************************/ 1707 /*Test if the interrupt is enable */ 1708 /*********************************/ 1709 1710 //if (i_InterruptFlag == ADDIDATA_ENABLE) 1711 if (s_BoardInfos[dev->minor].i_InterruptFlag == ADDIDATA_ENABLE) { 1712 /************************/ 1713 /* Enable the interrupt */ 1714 /************************/ 1715 ui_CommandRegister = ui_CommandRegister | 0x00100000; 1716 } //if (i_InterruptFlag == ADDIDATA_ENABLE) 1717 1718 /******************************/ 1719 /* Write the command register */ 1720 /******************************/ 1721 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1722 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1723 12) >> 19) & 1) != 1) ; 1724 1725 //outl(ui_CommandRegister, devpriv->iobase+i_Offset + 8); 1726 outl(ui_CommandRegister, 1727 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 8); 1728 1729 /*****************************/ 1730 /*Test if interrupt is enable */ 1731 /*****************************/ 1732 //if (i_InterruptFlag == ADDIDATA_DISABLE) 1733 if (s_BoardInfos[dev->minor].i_InterruptFlag == ADDIDATA_DISABLE) { 1734 do { 1735 /*************************/ 1736 /*Read the EOC Status bit */ 1737 /*************************/ 1738 1739 //ui_EOC = inl(devpriv->iobase+i_Offset + 20) & 1; 1740 ui_EOC = inl(devpriv->iobase + 1741 s_BoardInfos[dev->minor].i_Offset + 20) & 1; 1742 1743 } while (ui_EOC != 1); 1744 1745 /***************************************/ 1746 /* Read the digital value of the input */ 1747 /***************************************/ 1748 1749 //data[0] = inl (devpriv->iobase+i_Offset + 28); 1750 data[0] = 1751 inl(devpriv->iobase + 1752 s_BoardInfos[dev->minor].i_Offset + 28); 1753 //END JK 06.07.04: Management of sevrals boards 1754 1755 } // if (i_InterruptFlag == ADDIDATA_DISABLE) 1756 return 0; 1757} 1758 1759/* 1760 +----------------------------------------------------------------------------+ 1761 | Function Name : int i_APCI3200_ReadCalibrationOffsetValue | 1762 | (struct comedi_device *dev,struct comedi_subdevice *s, | 1763 | struct comedi_insn *insn,unsigned int *data) | 1764 +----------------------------------------------------------------------------+ 1765 | Task : Read calibration offset value of the selected channel| 1766 +----------------------------------------------------------------------------+ 1767 | Input Parameters : struct comedi_device *dev : Driver handle | 1768 | UINT *data : Data Pointer to read status | 1769 +----------------------------------------------------------------------------+ 1770 | Output Parameters : -- | 1771 | data[0] : Calibration offset Value | 1772 | 1773 +----------------------------------------------------------------------------+ 1774 | Return Value : TRUE : No error occur | 1775 | : FALSE : Error occur. Return the error | 1776 | | 1777 +----------------------------------------------------------------------------+ 1778*/ 1779int i_APCI3200_ReadCalibrationOffsetValue(struct comedi_device * dev, UINT * data) 1780{ 1781 UINT ui_Temp = 0, ui_EOC = 0; 1782 UINT ui_CommandRegister = 0; 1783 1784 //BEGIN JK 06.07.04: Management of sevrals boards 1785 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1786 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1787 12) >> 19) & 1) != 1) ; 1788 /*********************************/ 1789 /* Write the channel to configure */ 1790 /*********************************/ 1791 //Begin JK 20.10.2004: This seems not necessary ! 1792 //outl(0 | ui_Channel_num , devpriv->iobase+i_Offset + 0x4); 1793 //outl(0 | s_BoardInfos [dev->minor].ui_Channel_num , devpriv->iobase+s_BoardInfos [dev->minor].i_Offset + 0x4); 1794 //End JK 20.10.2004: This seems not necessary ! 1795 1796 /*******************************/ 1797 /* Set the convert timing unit */ 1798 /*******************************/ 1799 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1800 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1801 12) >> 19) & 1) != 1) ; 1802 //outl(i_ADDIDATAConversionTimeUnit , devpriv->iobase+i_Offset + 36); 1803 outl(s_BoardInfos[dev->minor].i_ADDIDATAConversionTimeUnit, 1804 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 36); 1805 /**************************/ 1806 /* Set the convert timing */ 1807 /**************************/ 1808 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1809 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1810 12) >> 19) & 1) != 1) ; 1811 //outl(i_ADDIDATAConversionTime , devpriv->iobase+i_Offset + 32); 1812 outl(s_BoardInfos[dev->minor].i_ADDIDATAConversionTime, 1813 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 32); 1814 /*****************************/ 1815 /*Read the calibration offset */ 1816 /*****************************/ 1817 //ui_Temp = inl(devpriv->iobase+i_Offset + 12); 1818 ui_Temp = inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 12); 1819 1820 /*********************************/ 1821 /*Configure the Offset Conversion */ 1822 /*********************************/ 1823 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1824 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1825 12) >> 19) & 1) != 1) ; 1826 //outl((ui_Temp | 0x00020000), devpriv->iobase+i_Offset + 12); 1827 outl((ui_Temp | 0x00020000), 1828 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 12); 1829 /*******************************/ 1830 /*Initialise ui_CommandRegister */ 1831 /*******************************/ 1832 1833 ui_CommandRegister = 0; 1834 1835 /*********************************/ 1836 /*Test if the interrupt is enable */ 1837 /*********************************/ 1838 1839 //if (i_InterruptFlag == ADDIDATA_ENABLE) 1840 if (s_BoardInfos[dev->minor].i_InterruptFlag == ADDIDATA_ENABLE) { 1841 1842 /**********************/ 1843 /*Enable the interrupt */ 1844 /**********************/ 1845 1846 ui_CommandRegister = ui_CommandRegister | 0x00100000; 1847 1848 } //if (i_InterruptFlag == ADDIDATA_ENABLE) 1849 1850 /**********************/ 1851 /*Start the conversion */ 1852 /**********************/ 1853 ui_CommandRegister = ui_CommandRegister | 0x00080000; 1854 1855 /***************************/ 1856 /*Write the command regiter */ 1857 /***************************/ 1858 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1859 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1860 12) >> 19) & 1) != 1) ; 1861 //outl(ui_CommandRegister, devpriv->iobase+i_Offset + 8); 1862 outl(ui_CommandRegister, 1863 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 8); 1864 1865 /*****************************/ 1866 /*Test if interrupt is enable */ 1867 /*****************************/ 1868 1869 //if (i_InterruptFlag == ADDIDATA_DISABLE) 1870 if (s_BoardInfos[dev->minor].i_InterruptFlag == ADDIDATA_DISABLE) { 1871 1872 do { 1873 /*******************/ 1874 /*Read the EOC flag */ 1875 /*******************/ 1876 1877 //ui_EOC = inl (devpriv->iobase+i_Offset + 20) & 1; 1878 ui_EOC = inl(devpriv->iobase + 1879 s_BoardInfos[dev->minor].i_Offset + 20) & 1; 1880 1881 } while (ui_EOC != 1); 1882 1883 /**************************************************/ 1884 /*Read the digital value of the calibration Offset */ 1885 /**************************************************/ 1886 1887 //data[0] = inl(devpriv->iobase+i_Offset+ 28); 1888 data[0] = 1889 inl(devpriv->iobase + 1890 s_BoardInfos[dev->minor].i_Offset + 28); 1891 } //if (i_InterruptFlag == ADDIDATA_DISABLE) 1892 return 0; 1893} 1894 1895/* 1896 +----------------------------------------------------------------------------+ 1897 | Function Name : int i_APCI3200_ReadCalibrationGainValue | 1898 | (struct comedi_device *dev,struct comedi_subdevice *s, | 1899 | struct comedi_insn *insn,unsigned int *data) | 1900 +----------------------------------------------------------------------------+ 1901 | Task : Read calibration gain value of the selected channel | 1902 +----------------------------------------------------------------------------+ 1903 | Input Parameters : struct comedi_device *dev : Driver handle | 1904 | UINT *data : Data Pointer to read status | 1905 +----------------------------------------------------------------------------+ 1906 | Output Parameters : -- | 1907 | data[0] : Calibration gain Value Of Input | 1908 | 1909 +----------------------------------------------------------------------------+ 1910 | Return Value : TRUE : No error occur | 1911 | : FALSE : Error occur. Return the error | 1912 | | 1913 +----------------------------------------------------------------------------+ 1914*/ 1915int i_APCI3200_ReadCalibrationGainValue(struct comedi_device * dev, UINT * data) 1916{ 1917 UINT ui_EOC = 0; 1918 INT ui_CommandRegister = 0; 1919 1920 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1921 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1922 12) >> 19) & 1) != 1) ; 1923 /*********************************/ 1924 /* Write the channel to configure */ 1925 /*********************************/ 1926 //Begin JK 20.10.2004: This seems not necessary ! 1927 //outl(0 | ui_Channel_num , devpriv->iobase+i_Offset + 0x4); 1928 //outl(0 | s_BoardInfos [dev->minor].ui_Channel_num , devpriv->iobase+s_BoardInfos [dev->minor].i_Offset + 0x4); 1929 //End JK 20.10.2004: This seems not necessary ! 1930 1931 /***************************/ 1932 /*Read the calibration gain */ 1933 /***************************/ 1934 /*******************************/ 1935 /* Set the convert timing unit */ 1936 /*******************************/ 1937 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1938 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1939 12) >> 19) & 1) != 1) ; 1940 //outl(i_ADDIDATAConversionTimeUnit , devpriv->iobase+i_Offset + 36); 1941 outl(s_BoardInfos[dev->minor].i_ADDIDATAConversionTimeUnit, 1942 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 36); 1943 /**************************/ 1944 /* Set the convert timing */ 1945 /**************************/ 1946 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1947 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1948 12) >> 19) & 1) != 1) ; 1949 //outl(i_ADDIDATAConversionTime , devpriv->iobase+i_Offset + 32); 1950 outl(s_BoardInfos[dev->minor].i_ADDIDATAConversionTime, 1951 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 32); 1952 /*******************************/ 1953 /*Configure the Gain Conversion */ 1954 /*******************************/ 1955 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1956 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1957 12) >> 19) & 1) != 1) ; 1958 //outl(0x00040000 , devpriv->iobase+i_Offset + 12); 1959 outl(0x00040000, 1960 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 12); 1961 1962 /*******************************/ 1963 /*Initialise ui_CommandRegister */ 1964 /*******************************/ 1965 1966 ui_CommandRegister = 0; 1967 1968 /*********************************/ 1969 /*Test if the interrupt is enable */ 1970 /*********************************/ 1971 1972 //if (i_InterruptFlag == ADDIDATA_ENABLE) 1973 if (s_BoardInfos[dev->minor].i_InterruptFlag == ADDIDATA_ENABLE) { 1974 1975 /**********************/ 1976 /*Enable the interrupt */ 1977 /**********************/ 1978 1979 ui_CommandRegister = ui_CommandRegister | 0x00100000; 1980 1981 } //if (i_InterruptFlag == ADDIDATA_ENABLE) 1982 1983 /**********************/ 1984 /*Start the conversion */ 1985 /**********************/ 1986 1987 ui_CommandRegister = ui_CommandRegister | 0x00080000; 1988 /***************************/ 1989 /*Write the command regiter */ 1990 /***************************/ 1991 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 1992 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 1993 12) >> 19) & 1) != 1) ; 1994 //outl(ui_CommandRegister , devpriv->iobase+i_Offset + 8); 1995 outl(ui_CommandRegister, 1996 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 8); 1997 1998 /*****************************/ 1999 /*Test if interrupt is enable */ 2000 /*****************************/ 2001 2002 //if (i_InterruptFlag == ADDIDATA_DISABLE) 2003 if (s_BoardInfos[dev->minor].i_InterruptFlag == ADDIDATA_DISABLE) { 2004 2005 do { 2006 2007 /*******************/ 2008 /*Read the EOC flag */ 2009 /*******************/ 2010 2011 //ui_EOC = inl(devpriv->iobase+i_Offset + 20) & 1; 2012 ui_EOC = inl(devpriv->iobase + 2013 s_BoardInfos[dev->minor].i_Offset + 20) & 1; 2014 2015 } while (ui_EOC != 1); 2016 2017 /************************************************/ 2018 /*Read the digital value of the calibration Gain */ 2019 /************************************************/ 2020 2021 //data[0] = inl(devpriv->iobase+i_Offset + 28); 2022 data[0] = 2023 inl(devpriv->iobase + 2024 s_BoardInfos[dev->minor].i_Offset + 28); 2025 2026 } //if (i_InterruptFlag == ADDIDATA_DISABLE) 2027 return 0; 2028} 2029 2030/* 2031 +----------------------------------------------------------------------------+ 2032 | Function Name : int i_APCI3200_ReadCJCValue | 2033 | (struct comedi_device *dev,struct comedi_subdevice *s, | 2034 | struct comedi_insn *insn,unsigned int *data) | 2035 +----------------------------------------------------------------------------+ 2036 | Task : Read CJC value of the selected channel | 2037 +----------------------------------------------------------------------------+ 2038 | Input Parameters : struct comedi_device *dev : Driver handle | 2039 | UINT *data : Data Pointer to read status | 2040 +----------------------------------------------------------------------------+ 2041 | Output Parameters : -- | 2042 | data[0] : CJC Value | 2043 | 2044 +----------------------------------------------------------------------------+ 2045 | Return Value : TRUE : No error occur | 2046 | : FALSE : Error occur. Return the error | 2047 | | 2048 +----------------------------------------------------------------------------+ 2049*/ 2050 2051int i_APCI3200_ReadCJCValue(struct comedi_device * dev, unsigned int * data) 2052{ 2053 UINT ui_EOC = 0; 2054 INT ui_CommandRegister = 0; 2055 2056 /******************************/ 2057 /*Set the converting time unit */ 2058 /******************************/ 2059 2060 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2061 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2062 12) >> 19) & 1) != 1) ; 2063 2064 //outl(i_ADDIDATAConversionTimeUnit , devpriv->iobase+i_Offset + 36); 2065 outl(s_BoardInfos[dev->minor].i_ADDIDATAConversionTimeUnit, 2066 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 36); 2067 /**************************/ 2068 /* Set the convert timing */ 2069 /**************************/ 2070 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2071 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2072 12) >> 19) & 1) != 1) ; 2073 2074 //outl(i_ADDIDATAConversionTime , devpriv->iobase+i_Offset + 32); 2075 outl(s_BoardInfos[dev->minor].i_ADDIDATAConversionTime, 2076 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 32); 2077 2078 /******************************/ 2079 /*Configure the CJC Conversion */ 2080 /******************************/ 2081 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2082 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2083 12) >> 19) & 1) != 1) ; 2084 2085 //outl( 0x00000400 , devpriv->iobase+i_Offset + 4); 2086 outl(0x00000400, 2087 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 4); 2088 /*******************************/ 2089 /*Initialise dw_CommandRegister */ 2090 /*******************************/ 2091 ui_CommandRegister = 0; 2092 /*********************************/ 2093 /*Test if the interrupt is enable */ 2094 /*********************************/ 2095 //if (i_InterruptFlag == ADDIDATA_ENABLE) 2096 if (s_BoardInfos[dev->minor].i_InterruptFlag == ADDIDATA_ENABLE) { 2097 /**********************/ 2098 /*Enable the interrupt */ 2099 /**********************/ 2100 ui_CommandRegister = ui_CommandRegister | 0x00100000; 2101 } 2102 2103 /**********************/ 2104 /*Start the conversion */ 2105 /**********************/ 2106 2107 ui_CommandRegister = ui_CommandRegister | 0x00080000; 2108 2109 /***************************/ 2110 /*Write the command regiter */ 2111 /***************************/ 2112 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2113 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2114 12) >> 19) & 1) != 1) ; 2115 //outl(ui_CommandRegister , devpriv->iobase+i_Offset + 8); 2116 outl(ui_CommandRegister, 2117 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 8); 2118 2119 /*****************************/ 2120 /*Test if interrupt is enable */ 2121 /*****************************/ 2122 2123 //if (i_InterruptFlag == ADDIDATA_DISABLE) 2124 if (s_BoardInfos[dev->minor].i_InterruptFlag == ADDIDATA_DISABLE) { 2125 do { 2126 2127 /*******************/ 2128 /*Read the EOC flag */ 2129 /*******************/ 2130 2131 //ui_EOC = inl(devpriv->iobase+i_Offset + 20) & 1; 2132 ui_EOC = inl(devpriv->iobase + 2133 s_BoardInfos[dev->minor].i_Offset + 20) & 1; 2134 2135 } while (ui_EOC != 1); 2136 2137 /***********************************/ 2138 /*Read the digital value of the CJC */ 2139 /***********************************/ 2140 2141 //data[0] = inl(devpriv->iobase+i_Offset + 28); 2142 data[0] = 2143 inl(devpriv->iobase + 2144 s_BoardInfos[dev->minor].i_Offset + 28); 2145 2146 } //if (i_InterruptFlag == ADDIDATA_DISABLE) 2147 return 0; 2148} 2149 2150/* 2151 +----------------------------------------------------------------------------+ 2152 | Function Name : int i_APCI3200_ReadCJCCalOffset | 2153 | (struct comedi_device *dev,struct comedi_subdevice *s, | 2154 | struct comedi_insn *insn,unsigned int *data) | 2155 +----------------------------------------------------------------------------+ 2156 | Task : Read CJC calibration offset value of the selected channel 2157 +----------------------------------------------------------------------------+ 2158 | Input Parameters : struct comedi_device *dev : Driver handle | 2159 | UINT *data : Data Pointer to read status | 2160 +----------------------------------------------------------------------------+ 2161 | Output Parameters : -- | 2162 | data[0] : CJC calibration offset Value 2163 | 2164 +----------------------------------------------------------------------------+ 2165 | Return Value : TRUE : No error occur | 2166 | : FALSE : Error occur. Return the error | 2167 | | 2168 +----------------------------------------------------------------------------+ 2169*/ 2170int i_APCI3200_ReadCJCCalOffset(struct comedi_device * dev, unsigned int * data) 2171{ 2172 UINT ui_EOC = 0; 2173 INT ui_CommandRegister = 0; 2174 /*******************************************/ 2175 /*Read calibration offset value for the CJC */ 2176 /*******************************************/ 2177 /*******************************/ 2178 /* Set the convert timing unit */ 2179 /*******************************/ 2180 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2181 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2182 12) >> 19) & 1) != 1) ; 2183 //outl(i_ADDIDATAConversionTimeUnit , devpriv->iobase+i_Offset + 36); 2184 outl(s_BoardInfos[dev->minor].i_ADDIDATAConversionTimeUnit, 2185 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 36); 2186 /**************************/ 2187 /* Set the convert timing */ 2188 /**************************/ 2189 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2190 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2191 12) >> 19) & 1) != 1) ; 2192 //outl(i_ADDIDATAConversionTime , devpriv->iobase+i_Offset + 32); 2193 outl(s_BoardInfos[dev->minor].i_ADDIDATAConversionTime, 2194 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 32); 2195 /******************************/ 2196 /*Configure the CJC Conversion */ 2197 /******************************/ 2198 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2199 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2200 12) >> 19) & 1) != 1) ; 2201 //outl(0x00000400 , devpriv->iobase+i_Offset + 4); 2202 outl(0x00000400, 2203 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 4); 2204 /*********************************/ 2205 /*Configure the Offset Conversion */ 2206 /*********************************/ 2207 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2208 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2209 12) >> 19) & 1) != 1) ; 2210 //outl(0x00020000, devpriv->iobase+i_Offset + 12); 2211 outl(0x00020000, 2212 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 12); 2213 /*******************************/ 2214 /*Initialise ui_CommandRegister */ 2215 /*******************************/ 2216 ui_CommandRegister = 0; 2217 /*********************************/ 2218 /*Test if the interrupt is enable */ 2219 /*********************************/ 2220 2221 //if (i_InterruptFlag == ADDIDATA_ENABLE) 2222 if (s_BoardInfos[dev->minor].i_InterruptFlag == ADDIDATA_ENABLE) { 2223 /**********************/ 2224 /*Enable the interrupt */ 2225 /**********************/ 2226 ui_CommandRegister = ui_CommandRegister | 0x00100000; 2227 2228 } 2229 2230 /**********************/ 2231 /*Start the conversion */ 2232 /**********************/ 2233 ui_CommandRegister = ui_CommandRegister | 0x00080000; 2234 /***************************/ 2235 /*Write the command regiter */ 2236 /***************************/ 2237 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2238 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2239 12) >> 19) & 1) != 1) ; 2240 //outl(ui_CommandRegister,devpriv->iobase+i_Offset + 8); 2241 outl(ui_CommandRegister, 2242 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 8); 2243 //if (i_InterruptFlag == ADDIDATA_DISABLE) 2244 if (s_BoardInfos[dev->minor].i_InterruptFlag == ADDIDATA_DISABLE) { 2245 do { 2246 /*******************/ 2247 /*Read the EOC flag */ 2248 /*******************/ 2249 //ui_EOC = inl(devpriv->iobase+i_Offset + 20) & 1; 2250 ui_EOC = inl(devpriv->iobase + 2251 s_BoardInfos[dev->minor].i_Offset + 20) & 1; 2252 } while (ui_EOC != 1); 2253 2254 /**************************************************/ 2255 /*Read the digital value of the calibration Offset */ 2256 /**************************************************/ 2257 //data[0] = inl(devpriv->iobase+i_Offset + 28); 2258 data[0] = 2259 inl(devpriv->iobase + 2260 s_BoardInfos[dev->minor].i_Offset + 28); 2261 } //if (i_InterruptFlag == ADDIDATA_DISABLE) 2262 return 0; 2263} 2264 2265/* 2266 +----------------------------------------------------------------------------+ 2267 | Function Name : int i_APCI3200_ReadCJCGainValue | 2268 | (struct comedi_device *dev,struct comedi_subdevice *s, | 2269 | struct comedi_insn *insn,unsigned int *data) | 2270 +----------------------------------------------------------------------------+ 2271 | Task : Read CJC calibration gain value 2272 +----------------------------------------------------------------------------+ 2273 | Input Parameters : struct comedi_device *dev : Driver handle | 2274 | UINT ui_NoOfChannels : No Of Channels To read | 2275 | UINT *data : Data Pointer to read status | 2276 +----------------------------------------------------------------------------+ 2277 | Output Parameters : -- | 2278 | data[0] : CJC calibration gain value 2279 | 2280 +----------------------------------------------------------------------------+ 2281 | Return Value : TRUE : No error occur | 2282 | : FALSE : Error occur. Return the error | 2283 | | 2284 +----------------------------------------------------------------------------+ 2285*/ 2286int i_APCI3200_ReadCJCCalGain(struct comedi_device * dev, unsigned int * data) 2287{ 2288 UINT ui_EOC = 0; 2289 INT ui_CommandRegister = 0; 2290 /*******************************/ 2291 /* Set the convert timing unit */ 2292 /*******************************/ 2293 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2294 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2295 12) >> 19) & 1) != 1) ; 2296 //outl(i_ADDIDATAConversionTimeUnit , devpriv->iobase+i_Offset + 36); 2297 outl(s_BoardInfos[dev->minor].i_ADDIDATAConversionTimeUnit, 2298 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 36); 2299 /**************************/ 2300 /* Set the convert timing */ 2301 /**************************/ 2302 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2303 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2304 12) >> 19) & 1) != 1) ; 2305 //outl(i_ADDIDATAConversionTime , devpriv->iobase+i_Offset + 32); 2306 outl(s_BoardInfos[dev->minor].i_ADDIDATAConversionTime, 2307 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 32); 2308 /******************************/ 2309 /*Configure the CJC Conversion */ 2310 /******************************/ 2311 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2312 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2313 12) >> 19) & 1) != 1) ; 2314 //outl(0x00000400,devpriv->iobase+i_Offset + 4); 2315 outl(0x00000400, 2316 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 4); 2317 /*******************************/ 2318 /*Configure the Gain Conversion */ 2319 /*******************************/ 2320 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2321 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2322 12) >> 19) & 1) != 1) ; 2323 //outl(0x00040000,devpriv->iobase+i_Offset + 12); 2324 outl(0x00040000, 2325 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 12); 2326 2327 /*******************************/ 2328 /*Initialise dw_CommandRegister */ 2329 /*******************************/ 2330 ui_CommandRegister = 0; 2331 /*********************************/ 2332 /*Test if the interrupt is enable */ 2333 /*********************************/ 2334 //if (i_InterruptFlag == ADDIDATA_ENABLE) 2335 if (s_BoardInfos[dev->minor].i_InterruptFlag == ADDIDATA_ENABLE) { 2336 /**********************/ 2337 /*Enable the interrupt */ 2338 /**********************/ 2339 ui_CommandRegister = ui_CommandRegister | 0x00100000; 2340 } 2341 /**********************/ 2342 /*Start the conversion */ 2343 /**********************/ 2344 ui_CommandRegister = ui_CommandRegister | 0x00080000; 2345 /***************************/ 2346 /*Write the command regiter */ 2347 /***************************/ 2348 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2349 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2350 12) >> 19) & 1) != 1) ; 2351 //outl(ui_CommandRegister ,devpriv->iobase+i_Offset + 8); 2352 outl(ui_CommandRegister, 2353 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 8); 2354 //if (i_InterruptFlag == ADDIDATA_DISABLE) 2355 if (s_BoardInfos[dev->minor].i_InterruptFlag == ADDIDATA_DISABLE) { 2356 do { 2357 /*******************/ 2358 /*Read the EOC flag */ 2359 /*******************/ 2360 //ui_EOC = inl(devpriv->iobase+i_Offset + 20) & 1; 2361 ui_EOC = inl(devpriv->iobase + 2362 s_BoardInfos[dev->minor].i_Offset + 20) & 1; 2363 } while (ui_EOC != 1); 2364 /************************************************/ 2365 /*Read the digital value of the calibration Gain */ 2366 /************************************************/ 2367 //data[0] = inl (devpriv->iobase+i_Offset + 28); 2368 data[0] = 2369 inl(devpriv->iobase + 2370 s_BoardInfos[dev->minor].i_Offset + 28); 2371 } //if (i_InterruptFlag == ADDIDATA_DISABLE) 2372 return 0; 2373} 2374 2375/* 2376 +----------------------------------------------------------------------------+ 2377 | Function Name : int i_APCI3200_InsnBits_AnalogInput_Test | 2378 | (struct comedi_device *dev,struct comedi_subdevice *s, | 2379 | struct comedi_insn *insn,unsigned int *data) | 2380 +----------------------------------------------------------------------------+ 2381 | Task : Tests the Selected Anlog Input Channel | 2382 +----------------------------------------------------------------------------+ 2383 | Input Parameters : struct comedi_device *dev : Driver handle | 2384 | struct comedi_subdevice *s : Subdevice Pointer | 2385 | struct comedi_insn *insn : Insn Structure Pointer | 2386 | unsigned int *data : Data Pointer contains | 2387 | configuration parameters as below | 2388 | 2389 | 2390 | data[0] : 0 TestAnalogInputShortCircuit 2391 | 1 TestAnalogInputConnection | 2392 2393 +----------------------------------------------------------------------------+ 2394 | Output Parameters : -- | 2395 | data[0] : Digital value obtained | 2396 | data[1] : calibration offset | 2397 | data[2] : calibration gain | 2398 | | 2399 | | 2400 +----------------------------------------------------------------------------+ 2401 | Return Value : TRUE : No error occur | 2402 | : FALSE : Error occur. Return the error | 2403 | | 2404 +----------------------------------------------------------------------------+ 2405*/ 2406 2407INT i_APCI3200_InsnBits_AnalogInput_Test(struct comedi_device * dev, 2408 struct comedi_subdevice * s, struct comedi_insn * insn, unsigned int * data) 2409{ 2410 UINT ui_Configuration = 0; 2411 INT i_Temp; //,i_TimeUnit; 2412 //if(i_Initialised==0) 2413 2414 if (s_BoardInfos[dev->minor].i_Initialised == 0) { 2415 i_APCI3200_Reset(dev); 2416 return -EINVAL; 2417 } //if(i_Initialised==0); 2418 if (data[0] != 0 && data[0] != 1) { 2419 printk("\nError in selection of functionality\n"); 2420 i_APCI3200_Reset(dev); 2421 return -EINVAL; 2422 } //if(data[0]!=0 && data[0]!=1) 2423 2424 if (data[0] == 1) //Perform Short Circuit TEST 2425 { 2426 /**************************/ 2427 /*Set the short-cicuit bit */ 2428 /**************************/ 2429 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2430 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor]. 2431 i_Offset + 12) >> 19) & 1) != 2432 1) ; 2433 //outl((0x00001000 |i_ChannelNo) , devpriv->iobase+i_Offset + 4); 2434 outl((0x00001000 | s_BoardInfos[dev->minor].i_ChannelNo), 2435 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2436 4); 2437 /*************************/ 2438 /*Set the time unit to ns */ 2439 /*************************/ 2440 /* i_TimeUnit= i_ADDIDATAConversionTimeUnit; 2441 i_ADDIDATAConversionTimeUnit= 1; */ 2442 //i_Temp= i_InterruptFlag ; 2443 i_Temp = s_BoardInfos[dev->minor].i_InterruptFlag; 2444 //i_InterruptFlag = ADDIDATA_DISABLE; 2445 s_BoardInfos[dev->minor].i_InterruptFlag = ADDIDATA_DISABLE; 2446 i_APCI3200_Read1AnalogInputChannel(dev, s, insn, data); 2447 //if(i_AutoCalibration == FALSE) 2448 if (s_BoardInfos[dev->minor].i_AutoCalibration == FALSE) { 2449 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2450 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor]. 2451 i_Offset + 2452 12) >> 19) & 1) != 1) ; 2453 2454 //outl((0x00001000 |i_ChannelNo) , devpriv->iobase+i_Offset + 4); 2455 outl((0x00001000 | s_BoardInfos[dev->minor]. 2456 i_ChannelNo), 2457 devpriv->iobase + 2458 s_BoardInfos[dev->minor].i_Offset + 4); 2459 data++; 2460 i_APCI3200_ReadCalibrationOffsetValue(dev, data); 2461 data++; 2462 i_APCI3200_ReadCalibrationGainValue(dev, data); 2463 } 2464 } else { 2465 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2466 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor]. 2467 i_Offset + 12) >> 19) & 1) != 2468 1) ; 2469 //outl((0x00000800|i_ChannelNo) , devpriv->iobase+i_Offset + 4); 2470 outl((0x00000800 | s_BoardInfos[dev->minor].i_ChannelNo), 2471 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2472 4); 2473 //ui_Configuration = inl(devpriv->iobase+i_Offset + 0); 2474 ui_Configuration = 2475 inl(devpriv->iobase + 2476 s_BoardInfos[dev->minor].i_Offset + 0); 2477 /*************************/ 2478 /*Set the time unit to ns */ 2479 /*************************/ 2480 /* i_TimeUnit= i_ADDIDATAConversionTimeUnit; 2481 i_ADDIDATAConversionTimeUnit= 1; */ 2482 //i_Temp= i_InterruptFlag ; 2483 i_Temp = s_BoardInfos[dev->minor].i_InterruptFlag; 2484 //i_InterruptFlag = ADDIDATA_DISABLE; 2485 s_BoardInfos[dev->minor].i_InterruptFlag = ADDIDATA_DISABLE; 2486 i_APCI3200_Read1AnalogInputChannel(dev, s, insn, data); 2487 //if(i_AutoCalibration == FALSE) 2488 if (s_BoardInfos[dev->minor].i_AutoCalibration == FALSE) { 2489 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2490 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor]. 2491 i_Offset + 2492 12) >> 19) & 1) != 1) ; 2493 //outl((0x00000800|i_ChannelNo) , devpriv->iobase+i_Offset + 4); 2494 outl((0x00000800 | s_BoardInfos[dev->minor]. 2495 i_ChannelNo), 2496 devpriv->iobase + 2497 s_BoardInfos[dev->minor].i_Offset + 4); 2498 data++; 2499 i_APCI3200_ReadCalibrationOffsetValue(dev, data); 2500 data++; 2501 i_APCI3200_ReadCalibrationGainValue(dev, data); 2502 } 2503 } 2504 //i_InterruptFlag=i_Temp ; 2505 s_BoardInfos[dev->minor].i_InterruptFlag = i_Temp; 2506 //printk("\ni_InterruptFlag=%d\n",i_InterruptFlag); 2507 return insn->n; 2508} 2509 2510/* 2511 +----------------------------------------------------------------------------+ 2512 | Function Name : int i_APCI3200_InsnWriteReleaseAnalogInput | 2513 | (struct comedi_device *dev,struct comedi_subdevice *s, | 2514 | struct comedi_insn *insn,unsigned int *data) | 2515 +----------------------------------------------------------------------------+ 2516 | Task : Resets the channels | 2517 +----------------------------------------------------------------------------+ 2518 | Input Parameters : struct comedi_device *dev : Driver handle | 2519 | struct comedi_subdevice *s : Subdevice Pointer | 2520 | struct comedi_insn *insn : Insn Structure Pointer | 2521 | unsigned int *data : Data Pointer 2522 +----------------------------------------------------------------------------+ 2523 | Output Parameters : -- | 2524 2525 +----------------------------------------------------------------------------+ 2526 | Return Value : TRUE : No error occur | 2527 | : FALSE : Error occur. Return the error | 2528 | | 2529 +----------------------------------------------------------------------------+ 2530*/ 2531 2532INT i_APCI3200_InsnWriteReleaseAnalogInput(struct comedi_device * dev, 2533 struct comedi_subdevice * s, struct comedi_insn * insn, unsigned int * data) 2534{ 2535 i_APCI3200_Reset(dev); 2536 return insn->n; 2537} 2538 2539/* 2540 +----------------------------------------------------------------------------+ 2541 | Function name :int i_APCI3200_CommandTestAnalogInput(struct comedi_device *dev| 2542 | ,struct comedi_subdevice *s,struct comedi_cmd *cmd) | 2543 | | 2544 +----------------------------------------------------------------------------+ 2545 | Task : Test validity for a command for cyclic anlog input | 2546 | acquisition | 2547 | | 2548 +----------------------------------------------------------------------------+ 2549 | Input Parameters : struct comedi_device *dev | 2550 | struct comedi_subdevice *s | 2551 | struct comedi_cmd *cmd | 2552 | | 2553 | 2554 | | 2555 | | 2556 | | 2557 +----------------------------------------------------------------------------+ 2558 | Return Value :0 | 2559 | | 2560 +----------------------------------------------------------------------------+ 2561*/ 2562 2563int i_APCI3200_CommandTestAnalogInput(struct comedi_device * dev, struct comedi_subdevice * s, 2564 struct comedi_cmd * cmd) 2565{ 2566 2567 int err = 0; 2568 int tmp; // divisor1,divisor2; 2569 UINT ui_ConvertTime = 0; 2570 UINT ui_ConvertTimeBase = 0; 2571 UINT ui_DelayTime = 0; 2572 UINT ui_DelayTimeBase = 0; 2573 INT i_Triggermode = 0; 2574 INT i_TriggerEdge = 0; 2575 INT i_NbrOfChannel = 0; 2576 INT i_Cpt = 0; 2577 double d_ConversionTimeForAllChannels = 0.0; 2578 double d_SCANTimeNewUnit = 0.0; 2579 // step 1: make sure trigger sources are trivially valid 2580 2581 tmp = cmd->start_src; 2582 cmd->start_src &= TRIG_NOW | TRIG_EXT; 2583 if (!cmd->start_src || tmp != cmd->start_src) 2584 err++; 2585 tmp = cmd->scan_begin_src; 2586 cmd->scan_begin_src &= TRIG_TIMER | TRIG_FOLLOW; 2587 if (!cmd->scan_begin_src || tmp != cmd->scan_begin_src) 2588 err++; 2589 tmp = cmd->convert_src; 2590 cmd->convert_src &= TRIG_TIMER; 2591 if (!cmd->convert_src || tmp != cmd->convert_src) 2592 err++; 2593 tmp = cmd->scan_end_src; 2594 cmd->scan_end_src &= TRIG_COUNT; 2595 if (!cmd->scan_end_src || tmp != cmd->scan_end_src) 2596 err++; 2597 tmp = cmd->stop_src; 2598 cmd->stop_src &= TRIG_COUNT | TRIG_NONE; 2599 if (!cmd->stop_src || tmp != cmd->stop_src) 2600 err++; 2601 //if(i_InterruptFlag==0) 2602 if (s_BoardInfos[dev->minor].i_InterruptFlag == 0) { 2603 err++; 2604 // printk("\nThe interrupt should be enabled\n"); 2605 } 2606 if (err) { 2607 i_APCI3200_Reset(dev); 2608 return 1; 2609 } 2610 2611 if (cmd->start_src != TRIG_NOW && cmd->start_src != TRIG_EXT) { 2612 err++; 2613 } 2614 if (cmd->start_src == TRIG_EXT) { 2615 i_TriggerEdge = cmd->start_arg & 0xFFFF; 2616 i_Triggermode = cmd->start_arg >> 16; 2617 if (i_TriggerEdge < 1 || i_TriggerEdge > 3) { 2618 err++; 2619 printk("\nThe trigger edge selection is in error\n"); 2620 } 2621 if (i_Triggermode != 2) { 2622 err++; 2623 printk("\nThe trigger mode selection is in error\n"); 2624 } 2625 } 2626 2627 if (cmd->scan_begin_src != TRIG_TIMER && 2628 cmd->scan_begin_src != TRIG_FOLLOW) 2629 err++; 2630 2631 if (cmd->convert_src != TRIG_TIMER) 2632 err++; 2633 2634 if (cmd->scan_end_src != TRIG_COUNT) { 2635 cmd->scan_end_src = TRIG_COUNT; 2636 err++; 2637 } 2638 2639 if (cmd->stop_src != TRIG_NONE && cmd->stop_src != TRIG_COUNT) 2640 err++; 2641 2642 if (err) { 2643 i_APCI3200_Reset(dev); 2644 return 2; 2645 } 2646 //i_FirstChannel=cmd->chanlist[0]; 2647 s_BoardInfos[dev->minor].i_FirstChannel = cmd->chanlist[0]; 2648 //i_LastChannel=cmd->chanlist[1]; 2649 s_BoardInfos[dev->minor].i_LastChannel = cmd->chanlist[1]; 2650 2651 if (cmd->convert_src == TRIG_TIMER) { 2652 ui_ConvertTime = cmd->convert_arg & 0xFFFF; 2653 ui_ConvertTimeBase = cmd->convert_arg >> 16; 2654 if (ui_ConvertTime != 20 && ui_ConvertTime != 40 2655 && ui_ConvertTime != 80 && ui_ConvertTime != 160) 2656 { 2657 printk("\nThe selection of conversion time reload value is in error\n"); 2658 err++; 2659 } // if (ui_ConvertTime!=20 && ui_ConvertTime!=40 && ui_ConvertTime!=80 && ui_ConvertTime!=160 ) 2660 if (ui_ConvertTimeBase != 2) { 2661 printk("\nThe selection of conversion time unit is in error\n"); 2662 err++; 2663 } //if(ui_ConvertTimeBase!=2) 2664 } else { 2665 ui_ConvertTime = 0; 2666 ui_ConvertTimeBase = 0; 2667 } 2668 if (cmd->scan_begin_src == TRIG_FOLLOW) { 2669 ui_DelayTime = 0; 2670 ui_DelayTimeBase = 0; 2671 } //if(cmd->scan_begin_src==TRIG_FOLLOW) 2672 else { 2673 ui_DelayTime = cmd->scan_begin_arg & 0xFFFF; 2674 ui_DelayTimeBase = cmd->scan_begin_arg >> 16; 2675 if (ui_DelayTimeBase != 2 && ui_DelayTimeBase != 3) { 2676 err++; 2677 printk("\nThe Delay time base selection is in error\n"); 2678 } 2679 if (ui_DelayTime < 1 && ui_DelayTime > 1023) { 2680 err++; 2681 printk("\nThe Delay time value is in error\n"); 2682 } 2683 if (err) { 2684 i_APCI3200_Reset(dev); 2685 return 3; 2686 } 2687 fpu_begin(); 2688 d_SCANTimeNewUnit = (double)ui_DelayTime; 2689 //i_NbrOfChannel= i_LastChannel-i_FirstChannel + 4; 2690 i_NbrOfChannel = 2691 s_BoardInfos[dev->minor].i_LastChannel - 2692 s_BoardInfos[dev->minor].i_FirstChannel + 4; 2693 /**********************************************************/ 2694 /*calculate the total conversion time for all the channels */ 2695 /**********************************************************/ 2696 d_ConversionTimeForAllChannels = 2697 (double)((double)ui_ConvertTime / 2698 (double)i_NbrOfChannel); 2699 2700 /*******************************/ 2701 /*Convert the frequence in time */ 2702 /*******************************/ 2703 d_ConversionTimeForAllChannels = 2704 (double)1.0 / d_ConversionTimeForAllChannels; 2705 ui_ConvertTimeBase = 3; 2706 /***********************************/ 2707 /*Test if the time unit is the same */ 2708 /***********************************/ 2709 2710 if (ui_DelayTimeBase <= ui_ConvertTimeBase) { 2711 2712 for (i_Cpt = 0; 2713 i_Cpt < (ui_ConvertTimeBase - ui_DelayTimeBase); 2714 i_Cpt++) { 2715 2716 d_ConversionTimeForAllChannels = 2717 d_ConversionTimeForAllChannels * 1000; 2718 d_ConversionTimeForAllChannels = 2719 d_ConversionTimeForAllChannels + 1; 2720 } 2721 } else { 2722 for (i_Cpt = 0; 2723 i_Cpt < (ui_DelayTimeBase - ui_ConvertTimeBase); 2724 i_Cpt++) { 2725 d_SCANTimeNewUnit = d_SCANTimeNewUnit * 1000; 2726 2727 } 2728 } 2729 2730 if (d_ConversionTimeForAllChannels >= d_SCANTimeNewUnit) { 2731 2732 printk("\nSCAN Delay value cannot be used\n"); 2733 /*********************************/ 2734 /*SCAN Delay value cannot be used */ 2735 /*********************************/ 2736 err++; 2737 } 2738 fpu_end(); 2739 } //else if(cmd->scan_begin_src==TRIG_FOLLOW) 2740 2741 if (err) { 2742 i_APCI3200_Reset(dev); 2743 return 4; 2744 } 2745 2746 return 0; 2747} 2748 2749/* 2750 +----------------------------------------------------------------------------+ 2751 | Function name :int i_APCI3200_StopCyclicAcquisition(struct comedi_device *dev,| 2752 | struct comedi_subdevice *s)| 2753 | | 2754 +----------------------------------------------------------------------------+ 2755 | Task : Stop the acquisition | 2756 | | 2757 +----------------------------------------------------------------------------+ 2758 | Input Parameters : struct comedi_device *dev | 2759 | struct comedi_subdevice *s | 2760 | | 2761 +----------------------------------------------------------------------------+ 2762 | Return Value :0 | 2763 | | 2764 +----------------------------------------------------------------------------+ 2765*/ 2766 2767int i_APCI3200_StopCyclicAcquisition(struct comedi_device * dev, struct comedi_subdevice * s) 2768{ 2769 UINT ui_Configuration = 0; 2770 //i_InterruptFlag=0; 2771 //i_Initialised=0; 2772 //i_Count=0; 2773 //i_Sum=0; 2774 s_BoardInfos[dev->minor].i_InterruptFlag = 0; 2775 s_BoardInfos[dev->minor].i_Initialised = 0; 2776 s_BoardInfos[dev->minor].i_Count = 0; 2777 s_BoardInfos[dev->minor].i_Sum = 0; 2778 2779 /*******************/ 2780 /*Read the register */ 2781 /*******************/ 2782 //ui_Configuration = inl(devpriv->iobase+i_Offset + 8); 2783 ui_Configuration = 2784 inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 8); 2785 /*****************************/ 2786 /*Reset the START and IRQ bit */ 2787 /*****************************/ 2788 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2789 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2790 12) >> 19) & 1) != 1) ; 2791 //outl((ui_Configuration & 0xFFE7FFFF),devpriv->iobase+i_Offset + 8); 2792 outl((ui_Configuration & 0xFFE7FFFF), 2793 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 8); 2794 return 0; 2795} 2796 2797/* 2798 +----------------------------------------------------------------------------+ 2799 | Function name : int i_APCI3200_CommandAnalogInput(struct comedi_device *dev, | 2800 | struct comedi_subdevice *s) | 2801 | | 2802 +----------------------------------------------------------------------------+ 2803 | Task : Does asynchronous acquisition | 2804 | Determines the mode 1 or 2. | 2805 | | 2806 +----------------------------------------------------------------------------+ 2807 | Input Parameters : struct comedi_device *dev | 2808 | struct comedi_subdevice *s | 2809 | | 2810 | | 2811 +----------------------------------------------------------------------------+ 2812 | Return Value : | 2813 | | 2814 +----------------------------------------------------------------------------+ 2815*/ 2816 2817int i_APCI3200_CommandAnalogInput(struct comedi_device * dev, struct comedi_subdevice * s) 2818{ 2819 struct comedi_cmd *cmd = &s->async->cmd; 2820 UINT ui_Configuration = 0; 2821 //INT i_CurrentSource = 0; 2822 UINT ui_Trigger = 0; 2823 UINT ui_TriggerEdge = 0; 2824 UINT ui_Triggermode = 0; 2825 UINT ui_ScanMode = 0; 2826 UINT ui_ConvertTime = 0; 2827 UINT ui_ConvertTimeBase = 0; 2828 UINT ui_DelayTime = 0; 2829 UINT ui_DelayTimeBase = 0; 2830 UINT ui_DelayMode = 0; 2831 //i_FirstChannel=cmd->chanlist[0]; 2832 //i_LastChannel=cmd->chanlist[1]; 2833 s_BoardInfos[dev->minor].i_FirstChannel = cmd->chanlist[0]; 2834 s_BoardInfos[dev->minor].i_LastChannel = cmd->chanlist[1]; 2835 if (cmd->start_src == TRIG_EXT) { 2836 ui_Trigger = 1; 2837 ui_TriggerEdge = cmd->start_arg & 0xFFFF; 2838 ui_Triggermode = cmd->start_arg >> 16; 2839 } //if(cmd->start_src==TRIG_EXT) 2840 else { 2841 ui_Trigger = 0; 2842 } //elseif(cmd->start_src==TRIG_EXT) 2843 2844 if (cmd->stop_src == TRIG_COUNT) { 2845 ui_ScanMode = 0; 2846 } // if (cmd->stop_src==TRIG_COUNT) 2847 else { 2848 ui_ScanMode = 2; 2849 } //else if (cmd->stop_src==TRIG_COUNT) 2850 2851 if (cmd->scan_begin_src == TRIG_FOLLOW) { 2852 ui_DelayTime = 0; 2853 ui_DelayTimeBase = 0; 2854 ui_DelayMode = 0; 2855 } //if(cmd->scan_begin_src==TRIG_FOLLOW) 2856 else { 2857 ui_DelayTime = cmd->scan_begin_arg & 0xFFFF; 2858 ui_DelayTimeBase = cmd->scan_begin_arg >> 16; 2859 ui_DelayMode = 1; 2860 } //else if(cmd->scan_begin_src==TRIG_FOLLOW) 2861 // printk("\nui_DelayTime=%u\n",ui_DelayTime); 2862 // printk("\nui_DelayTimeBase=%u\n",ui_DelayTimeBase); 2863 if (cmd->convert_src == TRIG_TIMER) { 2864 ui_ConvertTime = cmd->convert_arg & 0xFFFF; 2865 ui_ConvertTimeBase = cmd->convert_arg >> 16; 2866 } else { 2867 ui_ConvertTime = 0; 2868 ui_ConvertTimeBase = 0; 2869 } 2870 2871 // if(i_ADDIDATAType ==1 || ((i_ADDIDATAType==2))) 2872 // { 2873 /**************************************************/ 2874 /*Read the old configuration of the current source */ 2875 /**************************************************/ 2876 //ui_Configuration = inl(devpriv->iobase+i_Offset + 12); 2877 ui_Configuration = 2878 inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 12); 2879 /***********************************************/ 2880 /*Write the configuration of the current source */ 2881 /***********************************************/ 2882 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2883 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2884 12) >> 19) & 1) != 1) ; 2885 //outl((ui_Configuration & 0xFFC00000 ), devpriv->iobase+i_Offset +12); 2886 outl((ui_Configuration & 0xFFC00000), 2887 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 12); 2888 // } 2889 ui_Configuration = 0; 2890 // printk("\nfirstchannel=%u\n",i_FirstChannel); 2891 // printk("\nlastchannel=%u\n",i_LastChannel); 2892 // printk("\nui_Trigger=%u\n",ui_Trigger); 2893 // printk("\nui_TriggerEdge=%u\n",ui_TriggerEdge); 2894 // printk("\nui_Triggermode=%u\n",ui_Triggermode); 2895 // printk("\nui_DelayMode=%u\n",ui_DelayMode); 2896 // printk("\nui_ScanMode=%u\n",ui_ScanMode); 2897 2898 //ui_Configuration = i_FirstChannel |(i_LastChannel << 8)| 0x00100000 | 2899 ui_Configuration = 2900 s_BoardInfos[dev->minor].i_FirstChannel | (s_BoardInfos[dev-> 2901 minor]. 2902 i_LastChannel << 8) | 0x00100000 | (ui_Trigger << 24) | 2903 (ui_TriggerEdge << 25) | (ui_Triggermode << 27) | (ui_DelayMode 2904 << 18) | (ui_ScanMode << 16); 2905 2906 /*************************/ 2907 /*Write the Configuration */ 2908 /*************************/ 2909 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2910 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2911 12) >> 19) & 1) != 1) ; 2912 //outl( ui_Configuration, devpriv->iobase+i_Offset + 0x8); 2913 outl(ui_Configuration, 2914 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 0x8); 2915 /***********************/ 2916 /*Write the Delay Value */ 2917 /***********************/ 2918 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2919 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2920 12) >> 19) & 1) != 1) ; 2921 //outl(ui_DelayTime,devpriv->iobase+i_Offset + 40); 2922 outl(ui_DelayTime, 2923 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 40); 2924 /***************************/ 2925 /*Write the Delay time base */ 2926 /***************************/ 2927 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2928 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2929 12) >> 19) & 1) != 1) ; 2930 //outl(ui_DelayTimeBase,devpriv->iobase+i_Offset + 44); 2931 outl(ui_DelayTimeBase, 2932 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 44); 2933 /*********************************/ 2934 /*Write the conversion time value */ 2935 /*********************************/ 2936 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2937 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2938 12) >> 19) & 1) != 1) ; 2939 //outl(ui_ConvertTime,devpriv->iobase+i_Offset + 32); 2940 outl(ui_ConvertTime, 2941 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 32); 2942 2943 /********************************/ 2944 /*Write the conversion time base */ 2945 /********************************/ 2946 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2947 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2948 12) >> 19) & 1) != 1) ; 2949 //outl(ui_ConvertTimeBase,devpriv->iobase+i_Offset + 36); 2950 outl(ui_ConvertTimeBase, 2951 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 36); 2952 /*******************/ 2953 /*Read the register */ 2954 /*******************/ 2955 //ui_Configuration = inl(devpriv->iobase+i_Offset + 4); 2956 ui_Configuration = 2957 inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 4); 2958 /******************/ 2959 /*Set the SCAN bit */ 2960 /******************/ 2961 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2962 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2963 12) >> 19) & 1) != 1) ; 2964 2965 //outl(((ui_Configuration & 0x1E0FF) | 0x00002000),devpriv->iobase+i_Offset + 4); 2966 outl(((ui_Configuration & 0x1E0FF) | 0x00002000), 2967 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 4); 2968 /*******************/ 2969 /*Read the register */ 2970 /*******************/ 2971 ui_Configuration = 0; 2972 //ui_Configuration = inl(devpriv->iobase+i_Offset + 8); 2973 ui_Configuration = 2974 inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 8); 2975 2976 /*******************/ 2977 /*Set the START bit */ 2978 /*******************/ 2979 //while (((inl(devpriv->iobase+i_Offset+12)>>19) & 1) != 1); 2980 while (((inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 2981 12) >> 19) & 1) != 1) ; 2982 //outl((ui_Configuration | 0x00080000),devpriv->iobase+i_Offset + 8); 2983 outl((ui_Configuration | 0x00080000), 2984 devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 8); 2985 return 0; 2986} 2987 2988/* 2989 +----------------------------------------------------------------------------+ 2990 | Function Name : int i_APCI3200_Reset(struct comedi_device *dev) | 2991 | | 2992 +----------------------------------------------------------------------------+ 2993 | Task :Resets the registers of the card | 2994 +----------------------------------------------------------------------------+ 2995 | Input Parameters : | 2996 +----------------------------------------------------------------------------+ 2997 | Output Parameters : -- | 2998 +----------------------------------------------------------------------------+ 2999 | Return Value : | 3000 | | 3001 +----------------------------------------------------------------------------+ 3002*/ 3003 3004int i_APCI3200_Reset(struct comedi_device * dev) 3005{ 3006 INT i_Temp; 3007 DWORD dw_Dummy; 3008 //i_InterruptFlag=0; 3009 //i_Initialised==0; 3010 //i_Count=0; 3011 //i_Sum=0; 3012 3013 s_BoardInfos[dev->minor].i_InterruptFlag = 0; 3014 s_BoardInfos[dev->minor].i_Initialised = 0; 3015 s_BoardInfos[dev->minor].i_Count = 0; 3016 s_BoardInfos[dev->minor].i_Sum = 0; 3017 s_BoardInfos[dev->minor].b_StructInitialized = 0; 3018 3019 outl(0x83838383, devpriv->i_IobaseAmcc + 0x60); 3020 3021 // Enable the interrupt for the controler 3022 dw_Dummy = inl(devpriv->i_IobaseAmcc + 0x38); 3023 outl(dw_Dummy | 0x2000, devpriv->i_IobaseAmcc + 0x38); 3024 outl(0, devpriv->i_IobaseAddon); //Resets the output 3025 /***************/ 3026 /*Empty the buffer */ 3027 /**************/ 3028 for (i_Temp = 0; i_Temp <= 95; i_Temp++) { 3029 //ui_InterruptChannelValue[i_Temp]=0; 3030 s_BoardInfos[dev->minor].ui_InterruptChannelValue[i_Temp] = 0; 3031 } //for(i_Temp=0;i_Temp<=95;i_Temp++) 3032 /*****************************/ 3033 /*Reset the START and IRQ bit */ 3034 /*****************************/ 3035 for (i_Temp = 0; i_Temp <= 192;) { 3036 while (((inl(devpriv->iobase + i_Temp + 12) >> 19) & 1) != 1) ; 3037 outl(0, devpriv->iobase + i_Temp + 8); 3038 i_Temp = i_Temp + 64; 3039 } //for(i_Temp=0;i_Temp<=192;i_Temp+64) 3040 return 0; 3041} 3042 3043/* 3044 +----------------------------------------------------------------------------+ 3045 | Function Name : static void v_APCI3200_Interrupt | 3046 | (int irq , void *d) | 3047 +----------------------------------------------------------------------------+ 3048 | Task : Interrupt processing Routine | 3049 +----------------------------------------------------------------------------+ 3050 | Input Parameters : int irq : irq number | 3051 | void *d : void pointer | 3052 +----------------------------------------------------------------------------+ 3053 | Output Parameters : -- | 3054 +----------------------------------------------------------------------------+ 3055 | Return Value : TRUE : No error occur | 3056 | : FALSE : Error occur. Return the error | 3057 | | 3058 +----------------------------------------------------------------------------+ 3059*/ 3060void v_APCI3200_Interrupt(int irq, void *d) 3061{ 3062 struct comedi_device *dev = d; 3063 UINT ui_StatusRegister = 0; 3064 UINT ui_ChannelNumber = 0; 3065 INT i_CalibrationFlag = 0; 3066 INT i_CJCFlag = 0; 3067 UINT ui_DummyValue = 0; 3068 UINT ui_DigitalTemperature = 0; 3069 UINT ui_DigitalInput = 0; 3070 int i_ConvertCJCCalibration; 3071 3072 //BEGIN JK TEST 3073 int i_ReturnValue = 0; 3074 //END JK TEST 3075 3076 //printk ("\n i_ScanType = %i i_ADDIDATAType = %i", s_BoardInfos [dev->minor].i_ScanType, s_BoardInfos [dev->minor].i_ADDIDATAType); 3077 3078 //switch(i_ScanType) 3079 switch (s_BoardInfos[dev->minor].i_ScanType) { 3080 case 0: 3081 case 1: 3082 //switch(i_ADDIDATAType) 3083 switch (s_BoardInfos[dev->minor].i_ADDIDATAType) { 3084 case 0: 3085 case 1: 3086 3087 /************************************/ 3088 /*Read the interrupt status register */ 3089 /************************************/ 3090 //ui_StatusRegister = inl(devpriv->iobase+i_Offset + 16); 3091 ui_StatusRegister = 3092 inl(devpriv->iobase + 3093 s_BoardInfos[dev->minor].i_Offset + 16); 3094 if ((ui_StatusRegister & 0x2) == 0x2) { 3095 //i_CalibrationFlag = ((inl(devpriv->iobase+i_Offset + 12) & 0x00060000) >> 17); 3096 i_CalibrationFlag = 3097 ((inl(devpriv->iobase + 3098 s_BoardInfos[dev-> 3099 minor]. 3100 i_Offset + 3101 12) & 0x00060000) >> 3102 17); 3103 /*************************/ 3104 /*Read the channel number */ 3105 /*************************/ 3106 //ui_ChannelNumber = inl(devpriv->iobase+i_Offset + 24); 3107 3108 /*************************************/ 3109 /*Read the digital analog input value */ 3110 /*************************************/ 3111 //ui_DigitalInput = inl(devpriv->iobase+i_Offset + 28); 3112 ui_DigitalInput = 3113 inl(devpriv->iobase + 3114 s_BoardInfos[dev->minor].i_Offset + 28); 3115 3116 /***********************************************/ 3117 /* Test if the value read is the channel value */ 3118 /***********************************************/ 3119 if (i_CalibrationFlag == 0) { 3120 //ui_InterruptChannelValue[i_Count + 0] = ui_DigitalInput; 3121 s_BoardInfos[dev->minor]. 3122 ui_InterruptChannelValue 3123 [s_BoardInfos[dev->minor]. 3124 i_Count + 0] = ui_DigitalInput; 3125 3126 //Begin JK 22.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 3127 /* 3128 printk("\n 1 - i_APCI3200_GetChannelCalibrationValue (dev, s_BoardInfos %i", ui_ChannelNumber); 3129 i_APCI3200_GetChannelCalibrationValue (dev, s_BoardInfos [dev->minor].ui_Channel_num, 3130 &s_BoardInfos [dev->minor].ui_InterruptChannelValue[s_BoardInfos [dev->minor].i_Count + 6], 3131 &s_BoardInfos [dev->minor].ui_InterruptChannelValue[s_BoardInfos [dev->minor].i_Count + 7], 3132 &s_BoardInfos [dev->minor].ui_InterruptChannelValue[s_BoardInfos [dev->minor].i_Count + 8]); 3133 */ 3134 //End JK 22.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 3135 3136 /******************************************************/ 3137 /*Start the conversion of the calibration offset value */ 3138 /******************************************************/ 3139 i_APCI3200_ReadCalibrationOffsetValue 3140 (dev, &ui_DummyValue); 3141 } //if (i_CalibrationFlag == 0) 3142 /**********************************************************/ 3143 /* Test if the value read is the calibration offset value */ 3144 /**********************************************************/ 3145 3146 if (i_CalibrationFlag == 1) { 3147 3148 /******************/ 3149 /* Save the value */ 3150 /******************/ 3151 3152 //ui_InterruptChannelValue[i_Count + 1] = ui_DigitalInput; 3153 s_BoardInfos[dev->minor]. 3154 ui_InterruptChannelValue 3155 [s_BoardInfos[dev->minor]. 3156 i_Count + 1] = ui_DigitalInput; 3157 3158 /******************************************************/ 3159 /* Start the conversion of the calibration gain value */ 3160 /******************************************************/ 3161 i_APCI3200_ReadCalibrationGainValue(dev, 3162 &ui_DummyValue); 3163 } //if (i_CalibrationFlag == 1) 3164 /******************************************************/ 3165 /*Test if the value read is the calibration gain value */ 3166 /******************************************************/ 3167 3168 if (i_CalibrationFlag == 2) { 3169 3170 /****************/ 3171 /*Save the value */ 3172 /****************/ 3173 //ui_InterruptChannelValue[i_Count + 2] = ui_DigitalInput; 3174 s_BoardInfos[dev->minor]. 3175 ui_InterruptChannelValue 3176 [s_BoardInfos[dev->minor]. 3177 i_Count + 2] = ui_DigitalInput; 3178 //if(i_ScanType==1) 3179 if (s_BoardInfos[dev->minor]. 3180 i_ScanType == 1) { 3181 3182 //i_InterruptFlag=0; 3183 s_BoardInfos[dev->minor]. 3184 i_InterruptFlag = 0; 3185 //i_Count=i_Count + 6; 3186 //Begin JK 22.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 3187 //s_BoardInfos [dev->minor].i_Count=s_BoardInfos [dev->minor].i_Count + 6; 3188 s_BoardInfos[dev->minor]. 3189 i_Count = 3190 s_BoardInfos[dev-> 3191 minor].i_Count + 9; 3192 //End JK 22.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 3193 } //if(i_ScanType==1) 3194 else { 3195 //i_Count=0; 3196 s_BoardInfos[dev->minor]. 3197 i_Count = 0; 3198 } //elseif(i_ScanType==1) 3199 //if(i_ScanType!=1) 3200 if (s_BoardInfos[dev->minor]. 3201 i_ScanType != 1) { 3202 i_ReturnValue = send_sig(SIGIO, devpriv->tsk_Current, 0); // send signal to the sample 3203 } //if(i_ScanType!=1) 3204 else { 3205 //if(i_ChannelCount==i_Sum) 3206 if (s_BoardInfos[dev->minor]. 3207 i_ChannelCount == 3208 s_BoardInfos[dev-> 3209 minor].i_Sum) { 3210 send_sig(SIGIO, devpriv->tsk_Current, 0); // send signal to the sample 3211 } 3212 } //if(i_ScanType!=1) 3213 } //if (i_CalibrationFlag == 2) 3214 } // if ((ui_StatusRegister & 0x2) == 0x2) 3215 3216 break; 3217 3218 case 2: 3219 /************************************/ 3220 /*Read the interrupt status register */ 3221 /************************************/ 3222 3223 //ui_StatusRegister = inl(devpriv->iobase+i_Offset + 16); 3224 ui_StatusRegister = 3225 inl(devpriv->iobase + 3226 s_BoardInfos[dev->minor].i_Offset + 16); 3227 /*************************/ 3228 /*Test if interrupt occur */ 3229 /*************************/ 3230 3231 if ((ui_StatusRegister & 0x2) == 0x2) { 3232 3233 //i_CJCFlag = ((inl(devpriv->iobase+i_Offset + 4) & 0x00000400) >> 10); 3234 i_CJCFlag = 3235 ((inl(devpriv->iobase + 3236 s_BoardInfos[dev-> 3237 minor]. 3238 i_Offset + 3239 4) & 0x00000400) >> 10); 3240 3241 //i_CalibrationFlag = ((inl(devpriv->iobase+i_Offset + 12) & 0x00060000) >> 17); 3242 i_CalibrationFlag = 3243 ((inl(devpriv->iobase + 3244 s_BoardInfos[dev-> 3245 minor]. 3246 i_Offset + 3247 12) & 0x00060000) >> 3248 17); 3249 3250 /*************************/ 3251 /*Read the channel number */ 3252 /*************************/ 3253 3254 //ui_ChannelNumber = inl(devpriv->iobase+i_Offset + 24); 3255 ui_ChannelNumber = 3256 inl(devpriv->iobase + 3257 s_BoardInfos[dev->minor].i_Offset + 24); 3258 //Begin JK 22.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 3259 s_BoardInfos[dev->minor].ui_Channel_num = 3260 ui_ChannelNumber; 3261 //End JK 22.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 3262 3263 /************************************/ 3264 /*Read the digital temperature value */ 3265 /************************************/ 3266 //ui_DigitalTemperature = inl(devpriv->iobase+i_Offset + 28); 3267 ui_DigitalTemperature = 3268 inl(devpriv->iobase + 3269 s_BoardInfos[dev->minor].i_Offset + 28); 3270 3271 /*********************************************/ 3272 /*Test if the value read is the channel value */ 3273 /*********************************************/ 3274 3275 if ((i_CalibrationFlag == 0) 3276 && (i_CJCFlag == 0)) { 3277 //ui_InterruptChannelValue[i_Count + 0]=ui_DigitalTemperature; 3278 s_BoardInfos[dev->minor]. 3279 ui_InterruptChannelValue 3280 [s_BoardInfos[dev->minor]. 3281 i_Count + 0] = 3282 ui_DigitalTemperature; 3283 3284 /*********************************/ 3285 /*Start the conversion of the CJC */ 3286 /*********************************/ 3287 i_APCI3200_ReadCJCValue(dev, 3288 &ui_DummyValue); 3289 3290 } //if ((i_CalibrationFlag == 0) && (i_CJCFlag == 0)) 3291 3292 /*****************************************/ 3293 /*Test if the value read is the CJC value */ 3294 /*****************************************/ 3295 3296 if ((i_CJCFlag == 1) 3297 && (i_CalibrationFlag == 0)) { 3298 //ui_InterruptChannelValue[i_Count + 3]=ui_DigitalTemperature; 3299 s_BoardInfos[dev->minor]. 3300 ui_InterruptChannelValue 3301 [s_BoardInfos[dev->minor]. 3302 i_Count + 3] = 3303 ui_DigitalTemperature; 3304 3305 /******************************************************/ 3306 /*Start the conversion of the calibration offset value */ 3307 /******************************************************/ 3308 i_APCI3200_ReadCalibrationOffsetValue 3309 (dev, &ui_DummyValue); 3310 } // if ((i_CJCFlag == 1) && (i_CalibrationFlag == 0)) 3311 3312 /********************************************************/ 3313 /*Test if the value read is the calibration offset value */ 3314 /********************************************************/ 3315 3316 if ((i_CalibrationFlag == 1) 3317 && (i_CJCFlag == 0)) { 3318 //ui_InterruptChannelValue[i_Count + 1]=ui_DigitalTemperature; 3319 s_BoardInfos[dev->minor]. 3320 ui_InterruptChannelValue 3321 [s_BoardInfos[dev->minor]. 3322 i_Count + 1] = 3323 ui_DigitalTemperature; 3324 3325 /****************************************************/ 3326 /*Start the conversion of the calibration gain value */ 3327 /****************************************************/ 3328 i_APCI3200_ReadCalibrationGainValue(dev, 3329 &ui_DummyValue); 3330 3331 } //if ((i_CalibrationFlag == 1) && (i_CJCFlag == 0)) 3332 3333 /******************************************************/ 3334 /*Test if the value read is the calibration gain value */ 3335 /******************************************************/ 3336 3337 if ((i_CalibrationFlag == 2) 3338 && (i_CJCFlag == 0)) { 3339 //ui_InterruptChannelValue[i_Count + 2]=ui_DigitalTemperature; 3340 s_BoardInfos[dev->minor]. 3341 ui_InterruptChannelValue 3342 [s_BoardInfos[dev->minor]. 3343 i_Count + 2] = 3344 ui_DigitalTemperature; 3345 3346 /**********************************************************/ 3347 /*Test if the Calibration channel must be read for the CJC */ 3348 /**********************************************************/ 3349 3350 /*Test if the polarity is the same */ 3351 /**********************************/ 3352 //if(i_CJCPolarity!=i_ADDIDATAPolarity) 3353 if (s_BoardInfos[dev->minor]. 3354 i_CJCPolarity != 3355 s_BoardInfos[dev->minor]. 3356 i_ADDIDATAPolarity) { 3357 i_ConvertCJCCalibration = 1; 3358 } //if(i_CJCPolarity!=i_ADDIDATAPolarity) 3359 else { 3360 //if(i_CJCGain==i_ADDIDATAGain) 3361 if (s_BoardInfos[dev->minor]. 3362 i_CJCGain == 3363 s_BoardInfos[dev-> 3364 minor]. 3365 i_ADDIDATAGain) { 3366 i_ConvertCJCCalibration 3367 = 0; 3368 } //if(i_CJCGain==i_ADDIDATAGain) 3369 else { 3370 i_ConvertCJCCalibration 3371 = 1; 3372 } //elseif(i_CJCGain==i_ADDIDATAGain) 3373 } //elseif(i_CJCPolarity!=i_ADDIDATAPolarity) 3374 if (i_ConvertCJCCalibration == 1) { 3375 /****************************************************************/ 3376 /*Start the conversion of the calibration gain value for the CJC */ 3377 /****************************************************************/ 3378 i_APCI3200_ReadCJCCalOffset(dev, 3379 &ui_DummyValue); 3380 3381 } //if(i_ConvertCJCCalibration==1) 3382 else { 3383 //ui_InterruptChannelValue[i_Count + 4]=0; 3384 //ui_InterruptChannelValue[i_Count + 5]=0; 3385 s_BoardInfos[dev->minor]. 3386 ui_InterruptChannelValue 3387 [s_BoardInfos[dev-> 3388 minor].i_Count + 3389 4] = 0; 3390 s_BoardInfos[dev->minor]. 3391 ui_InterruptChannelValue 3392 [s_BoardInfos[dev-> 3393 minor].i_Count + 3394 5] = 0; 3395 } //elseif(i_ConvertCJCCalibration==1) 3396 } //else if ((i_CalibrationFlag == 2) && (i_CJCFlag == 0)) 3397 3398 /********************************************************************/ 3399 /*Test if the value read is the calibration offset value for the CJC */ 3400 /********************************************************************/ 3401 3402 if ((i_CalibrationFlag == 1) 3403 && (i_CJCFlag == 1)) { 3404 //ui_InterruptChannelValue[i_Count + 4]=ui_DigitalTemperature; 3405 s_BoardInfos[dev->minor]. 3406 ui_InterruptChannelValue 3407 [s_BoardInfos[dev->minor]. 3408 i_Count + 4] = 3409 ui_DigitalTemperature; 3410 3411 /****************************************************************/ 3412 /*Start the conversion of the calibration gain value for the CJC */ 3413 /****************************************************************/ 3414 i_APCI3200_ReadCJCCalGain(dev, 3415 &ui_DummyValue); 3416 3417 } //if ((i_CalibrationFlag == 1) && (i_CJCFlag == 1)) 3418 3419 /******************************************************************/ 3420 /*Test if the value read is the calibration gain value for the CJC */ 3421 /******************************************************************/ 3422 3423 if ((i_CalibrationFlag == 2) 3424 && (i_CJCFlag == 1)) { 3425 //ui_InterruptChannelValue[i_Count + 5]=ui_DigitalTemperature; 3426 s_BoardInfos[dev->minor]. 3427 ui_InterruptChannelValue 3428 [s_BoardInfos[dev->minor]. 3429 i_Count + 5] = 3430 ui_DigitalTemperature; 3431 3432 //if(i_ScanType==1) 3433 if (s_BoardInfos[dev->minor]. 3434 i_ScanType == 1) { 3435 3436 //i_InterruptFlag=0; 3437 s_BoardInfos[dev->minor]. 3438 i_InterruptFlag = 0; 3439 //i_Count=i_Count + 6; 3440 //Begin JK 22.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 3441 //s_BoardInfos [dev->minor].i_Count=s_BoardInfos [dev->minor].i_Count + 6; 3442 s_BoardInfos[dev->minor]. 3443 i_Count = 3444 s_BoardInfos[dev-> 3445 minor].i_Count + 9; 3446 //End JK 22.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 3447 } //if(i_ScanType==1) 3448 else { 3449 //i_Count=0; 3450 s_BoardInfos[dev->minor]. 3451 i_Count = 0; 3452 } //elseif(i_ScanType==1) 3453 3454 //if(i_ScanType!=1) 3455 if (s_BoardInfos[dev->minor]. 3456 i_ScanType != 1) { 3457 send_sig(SIGIO, devpriv->tsk_Current, 0); // send signal to the sample 3458 } //if(i_ScanType!=1) 3459 else { 3460 //if(i_ChannelCount==i_Sum) 3461 if (s_BoardInfos[dev->minor]. 3462 i_ChannelCount == 3463 s_BoardInfos[dev-> 3464 minor].i_Sum) { 3465 send_sig(SIGIO, devpriv->tsk_Current, 0); // send signal to the sample 3466 3467 } //if(i_ChannelCount==i_Sum) 3468 } //else if(i_ScanType!=1) 3469 } //if ((i_CalibrationFlag == 2) && (i_CJCFlag == 1)) 3470 3471 } //else if ((ui_StatusRegister & 0x2) == 0x2) 3472 break; 3473 } //switch(i_ADDIDATAType) 3474 break; 3475 case 2: 3476 case 3: 3477 i_APCI3200_InterruptHandleEos(dev); 3478 break; 3479 } //switch(i_ScanType) 3480 return; 3481} 3482 3483/* 3484 +----------------------------------------------------------------------------+ 3485 | Function name :int i_APCI3200_InterruptHandleEos(struct comedi_device *dev) | 3486 | | 3487 | | 3488 +----------------------------------------------------------------------------+ 3489 | Task : . | 3490 | This function copies the acquired data(from FIFO) | 3491 | to Comedi buffer. | 3492 | | 3493 +----------------------------------------------------------------------------+ 3494 | Input Parameters : struct comedi_device *dev | 3495 | | 3496 | | 3497 +----------------------------------------------------------------------------+ 3498 | Return Value : 0 | 3499 | | 3500 +----------------------------------------------------------------------------+ 3501*/ 3502int i_APCI3200_InterruptHandleEos(struct comedi_device * dev) 3503{ 3504 UINT ui_StatusRegister = 0; 3505 struct comedi_subdevice *s = dev->subdevices + 0; 3506 3507 //BEGIN JK 18.10.2004: APCI-3200 Driver update 0.7.57 -> 0.7.68 3508 //comedi_async *async = s->async; 3509 //UINT *data; 3510 //data=async->data+async->buf_int_ptr;//new samples added from here onwards 3511 int n = 0, i = 0; 3512 //END JK 18.10.2004: APCI-3200 Driver update 0.7.57 -> 0.7.68 3513 3514 /************************************/ 3515 /*Read the interrupt status register */ 3516 /************************************/ 3517 //ui_StatusRegister = inl(devpriv->iobase+i_Offset + 16); 3518 ui_StatusRegister = 3519 inl(devpriv->iobase + s_BoardInfos[dev->minor].i_Offset + 16); 3520 3521 /*************************/ 3522 /*Test if interrupt occur */ 3523 /*************************/ 3524 3525 if ((ui_StatusRegister & 0x2) == 0x2) { 3526 /*************************/ 3527 /*Read the channel number */ 3528 /*************************/ 3529 //ui_ChannelNumber = inl(devpriv->iobase+i_Offset + 24); 3530 //BEGIN JK 18.10.2004: APCI-3200 Driver update 0.7.57 -> 0.7.68 3531 //This value is not used 3532 //ui_ChannelNumber = inl(devpriv->iobase+s_BoardInfos [dev->minor].i_Offset + 24); 3533 s->async->events = 0; 3534 //END JK 18.10.2004: APCI-3200 Driver update 0.7.57 -> 0.7.68 3535 3536 /*************************************/ 3537 /*Read the digital Analog Input value */ 3538 /*************************************/ 3539 3540 //data[i_Count] = inl(devpriv->iobase+i_Offset + 28); 3541 //Begin JK 18.10.2004: APCI-3200 Driver update 0.7.57 -> 0.7.68 3542 //data[s_BoardInfos [dev->minor].i_Count] = inl(devpriv->iobase+s_BoardInfos [dev->minor].i_Offset + 28); 3543 s_BoardInfos[dev->minor].ui_ScanValueArray[s_BoardInfos[dev-> 3544 minor].i_Count] = 3545 inl(devpriv->iobase + 3546 s_BoardInfos[dev->minor].i_Offset + 28); 3547 //End JK 18.10.2004: APCI-3200 Driver update 0.7.57 -> 0.7.68 3548 3549 //if((i_Count == (i_LastChannel-i_FirstChannel+3))) 3550 if ((s_BoardInfos[dev->minor].i_Count == 3551 (s_BoardInfos[dev->minor].i_LastChannel - 3552 s_BoardInfos[dev->minor]. 3553 i_FirstChannel + 3))) { 3554 3555 //Begin JK 22.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 3556 s_BoardInfos[dev->minor].i_Count++; 3557 3558 for (i = s_BoardInfos[dev->minor].i_FirstChannel; 3559 i <= s_BoardInfos[dev->minor].i_LastChannel; 3560 i++) { 3561 i_APCI3200_GetChannelCalibrationValue(dev, i, 3562 &s_BoardInfos[dev->minor]. 3563 ui_ScanValueArray[s_BoardInfos[dev-> 3564 minor].i_Count + ((i - 3565 s_BoardInfos 3566 [dev->minor]. 3567 i_FirstChannel) 3568 * 3)], 3569 &s_BoardInfos[dev->minor]. 3570 ui_ScanValueArray[s_BoardInfos[dev-> 3571 minor].i_Count + ((i - 3572 s_BoardInfos 3573 [dev->minor]. 3574 i_FirstChannel) 3575 * 3) + 1], 3576 &s_BoardInfos[dev->minor]. 3577 ui_ScanValueArray[s_BoardInfos[dev-> 3578 minor].i_Count + ((i - 3579 s_BoardInfos 3580 [dev->minor]. 3581 i_FirstChannel) 3582 * 3) + 2]); 3583 } 3584 3585 //End JK 22.10.2004: APCI-3200 / APCI-3300 Reading of EEPROM values 3586 3587 //i_Count=-1; 3588 3589 s_BoardInfos[dev->minor].i_Count = -1; 3590 3591 //async->buf_int_count+=(i_LastChannel-i_FirstChannel+4)*sizeof(UINT); 3592 //Begin JK 18.10.2004: APCI-3200 Driver update 0.7.57 -> 0.7.68 3593 //async->buf_int_count+=(s_BoardInfos [dev->minor].i_LastChannel-s_BoardInfos [dev->minor].i_FirstChannel+4)*sizeof(UINT); 3594 //End JK 18.10.2004: APCI-3200 Driver update 0.7.57 -> 0.7.68 3595 //async->buf_int_ptr+=(i_LastChannel-i_FirstChannel+4)*sizeof(UINT); 3596 //Begin JK 18.10.2004: APCI-3200 Driver update 0.7.57 -> 0.7.68 3597 //async->buf_int_ptr+=(s_BoardInfos [dev->minor].i_LastChannel-s_BoardInfos [dev->minor].i_FirstChannel+4)*sizeof(UINT); 3598 //comedi_eos(dev,s); 3599 3600 // Set the event type (Comedi Buffer End Of Scan) 3601 s->async->events |= COMEDI_CB_EOS; 3602 3603 // Test if enougth memory is available and allocate it for 7 values 3604 //n = comedi_buf_write_alloc(s->async, 7*sizeof(unsigned int)); 3605 n = comedi_buf_write_alloc(s->async, 3606 (7 + 12) * sizeof(unsigned int)); 3607 3608 // If not enougth memory available, event is set to Comedi Buffer Errror 3609 if (n > ((7 + 12) * sizeof(unsigned int))) { 3610 printk("\ncomedi_buf_write_alloc n = %i", n); 3611 s->async->events |= COMEDI_CB_ERROR; 3612 } 3613 // Write all 7 scan values in the comedi buffer 3614 comedi_buf_memcpy_to(s->async, 0, 3615 (unsigned int *) s_BoardInfos[dev->minor]. 3616 ui_ScanValueArray, (7 + 12) * sizeof(unsigned int)); 3617 3618 // Update comedi buffer pinters indexes 3619 comedi_buf_write_free(s->async, 3620 (7 + 12) * sizeof(unsigned int)); 3621 3622 // Send events 3623 comedi_event(dev, s); 3624 //End JK 18.10.2004: APCI-3200 Driver update 0.7.57 -> 0.7.68 3625 3626 //BEGIN JK 18.10.2004: APCI-3200 Driver update 0.7.57 -> 0.7.68 3627 // 3628 //if (s->async->buf_int_ptr>=s->async->data_len) // for buffer rool over 3629 // { 3630 // /* buffer rollover */ 3631 // s->async->buf_int_ptr=0; 3632 // comedi_eobuf(dev,s); 3633 // } 3634 //End JK 18.10.2004: APCI-3200 Driver update 0.7.57 -> 0.7.68 3635 } 3636 //i_Count++; 3637 s_BoardInfos[dev->minor].i_Count++; 3638 } 3639 //i_InterruptFlag=0; 3640 s_BoardInfos[dev->minor].i_InterruptFlag = 0; 3641 return 0; 3642} 3643