s626.c revision 25985edcedea6396277003854657b5f3cb31a628
1/* 2 comedi/drivers/s626.c 3 Sensoray s626 Comedi driver 4 5 COMEDI - Linux Control and Measurement Device Interface 6 Copyright (C) 2000 David A. Schleef <ds@schleef.org> 7 8 Based on Sensoray Model 626 Linux driver Version 0.2 9 Copyright (C) 2002-2004 Sensoray Co., Inc. 10 11 This program is free software; you can redistribute it and/or modify 12 it under the terms of the GNU General Public License as published by 13 the Free Software Foundation; either version 2 of the License, or 14 (at your option) any later version. 15 16 This program is distributed in the hope that it will be useful, 17 but WITHOUT ANY WARRANTY; without even the implied warranty of 18 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the 19 GNU General Public License for more details. 20 21 You should have received a copy of the GNU General Public License 22 along with this program; if not, write to the Free Software 23 Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. 24 25*/ 26 27/* 28Driver: s626 29Description: Sensoray 626 driver 30Devices: [Sensoray] 626 (s626) 31Authors: Gianluca Palli <gpalli@deis.unibo.it>, 32Updated: Fri, 15 Feb 2008 10:28:42 +0000 33Status: experimental 34 35Configuration options: 36 [0] - PCI bus of device (optional) 37 [1] - PCI slot of device (optional) 38 If bus/slot is not specified, the first supported 39 PCI device found will be used. 40 41INSN_CONFIG instructions: 42 analog input: 43 none 44 45 analog output: 46 none 47 48 digital channel: 49 s626 has 3 dio subdevices (2,3 and 4) each with 16 i/o channels 50 supported configuration options: 51 INSN_CONFIG_DIO_QUERY 52 COMEDI_INPUT 53 COMEDI_OUTPUT 54 55 encoder: 56 Every channel must be configured before reading. 57 58 Example code 59 60 insn.insn=INSN_CONFIG; //configuration instruction 61 insn.n=1; //number of operation (must be 1) 62 insn.data=&initialvalue; //initial value loaded into encoder 63 //during configuration 64 insn.subdev=5; //encoder subdevice 65 insn.chanspec=CR_PACK(encoder_channel,0,AREF_OTHER); //encoder_channel 66 //to configure 67 68 comedi_do_insn(cf,&insn); //executing configuration 69*/ 70 71#include <linux/interrupt.h> 72#include <linux/kernel.h> 73#include <linux/types.h> 74 75#include "../comedidev.h" 76 77#include "comedi_pci.h" 78 79#include "comedi_fc.h" 80#include "s626.h" 81 82MODULE_AUTHOR("Gianluca Palli <gpalli@deis.unibo.it>"); 83MODULE_DESCRIPTION("Sensoray 626 Comedi driver module"); 84MODULE_LICENSE("GPL"); 85 86struct s626_board { 87 const char *name; 88 int ai_chans; 89 int ai_bits; 90 int ao_chans; 91 int ao_bits; 92 int dio_chans; 93 int dio_banks; 94 int enc_chans; 95}; 96 97static const struct s626_board s626_boards[] = { 98 { 99 .name = "s626", 100 .ai_chans = S626_ADC_CHANNELS, 101 .ai_bits = 14, 102 .ao_chans = S626_DAC_CHANNELS, 103 .ao_bits = 13, 104 .dio_chans = S626_DIO_CHANNELS, 105 .dio_banks = S626_DIO_BANKS, 106 .enc_chans = S626_ENCODER_CHANNELS, 107 } 108}; 109 110#define thisboard ((const struct s626_board *)dev->board_ptr) 111#define PCI_VENDOR_ID_S626 0x1131 112#define PCI_DEVICE_ID_S626 0x7146 113 114/* 115 * For devices with vendor:device id == 0x1131:0x7146 you must specify 116 * also subvendor:subdevice ids, because otherwise it will conflict with 117 * Philips SAA7146 media/dvb based cards. 118 */ 119static DEFINE_PCI_DEVICE_TABLE(s626_pci_table) = { 120 {PCI_VENDOR_ID_S626, PCI_DEVICE_ID_S626, 0x6000, 0x0272, 0, 0, 0}, 121 {0} 122}; 123 124MODULE_DEVICE_TABLE(pci, s626_pci_table); 125 126static int s626_attach(struct comedi_device *dev, struct comedi_devconfig *it); 127static int s626_detach(struct comedi_device *dev); 128 129static struct comedi_driver driver_s626 = { 130 .driver_name = "s626", 131 .module = THIS_MODULE, 132 .attach = s626_attach, 133 .detach = s626_detach, 134}; 135 136struct s626_private { 137 struct pci_dev *pdev; 138 void *base_addr; 139 int got_regions; 140 short allocatedBuf; 141 uint8_t ai_cmd_running; /* ai_cmd is running */ 142 uint8_t ai_continous; /* continous acquisition */ 143 int ai_sample_count; /* number of samples to acquire */ 144 unsigned int ai_sample_timer; 145 /* time between samples in units of the timer */ 146 int ai_convert_count; /* conversion counter */ 147 unsigned int ai_convert_timer; 148 /* time between conversion in units of the timer */ 149 uint16_t CounterIntEnabs; 150 /* Counter interrupt enable mask for MISC2 register. */ 151 uint8_t AdcItems; /* Number of items in ADC poll list. */ 152 struct bufferDMA RPSBuf; /* DMA buffer used to hold ADC (RPS1) program. */ 153 struct bufferDMA ANABuf; 154 /* DMA buffer used to receive ADC data and hold DAC data. */ 155 uint32_t *pDacWBuf; 156 /* Pointer to logical adrs of DMA buffer used to hold DAC data. */ 157 uint16_t Dacpol; /* Image of DAC polarity register. */ 158 uint8_t TrimSetpoint[12]; /* Images of TrimDAC setpoints */ 159 uint16_t ChargeEnabled; /* Image of MISC2 Battery */ 160 /* Charge Enabled (0 or WRMISC2_CHARGE_ENABLE). */ 161 uint16_t WDInterval; /* Image of MISC2 watchdog interval control bits. */ 162 uint32_t I2CAdrs; 163 /* I2C device address for onboard EEPROM (board rev dependent). */ 164 /* short I2Cards; */ 165 unsigned int ao_readback[S626_DAC_CHANNELS]; 166}; 167 168struct dio_private { 169 uint16_t RDDIn; 170 uint16_t WRDOut; 171 uint16_t RDEdgSel; 172 uint16_t WREdgSel; 173 uint16_t RDCapSel; 174 uint16_t WRCapSel; 175 uint16_t RDCapFlg; 176 uint16_t RDIntSel; 177 uint16_t WRIntSel; 178}; 179 180static struct dio_private dio_private_A = { 181 .RDDIn = LP_RDDINA, 182 .WRDOut = LP_WRDOUTA, 183 .RDEdgSel = LP_RDEDGSELA, 184 .WREdgSel = LP_WREDGSELA, 185 .RDCapSel = LP_RDCAPSELA, 186 .WRCapSel = LP_WRCAPSELA, 187 .RDCapFlg = LP_RDCAPFLGA, 188 .RDIntSel = LP_RDINTSELA, 189 .WRIntSel = LP_WRINTSELA, 190}; 191 192static struct dio_private dio_private_B = { 193 .RDDIn = LP_RDDINB, 194 .WRDOut = LP_WRDOUTB, 195 .RDEdgSel = LP_RDEDGSELB, 196 .WREdgSel = LP_WREDGSELB, 197 .RDCapSel = LP_RDCAPSELB, 198 .WRCapSel = LP_WRCAPSELB, 199 .RDCapFlg = LP_RDCAPFLGB, 200 .RDIntSel = LP_RDINTSELB, 201 .WRIntSel = LP_WRINTSELB, 202}; 203 204static struct dio_private dio_private_C = { 205 .RDDIn = LP_RDDINC, 206 .WRDOut = LP_WRDOUTC, 207 .RDEdgSel = LP_RDEDGSELC, 208 .WREdgSel = LP_WREDGSELC, 209 .RDCapSel = LP_RDCAPSELC, 210 .WRCapSel = LP_WRCAPSELC, 211 .RDCapFlg = LP_RDCAPFLGC, 212 .RDIntSel = LP_RDINTSELC, 213 .WRIntSel = LP_WRINTSELC, 214}; 215 216/* to group dio devices (48 bits mask and data are not allowed ???) 217static struct dio_private *dio_private_word[]={ 218 &dio_private_A, 219 &dio_private_B, 220 &dio_private_C, 221}; 222*/ 223 224#define devpriv ((struct s626_private *)dev->private) 225#define diopriv ((struct dio_private *)s->private) 226 227static int __devinit driver_s626_pci_probe(struct pci_dev *dev, 228 const struct pci_device_id *ent) 229{ 230 return comedi_pci_auto_config(dev, driver_s626.driver_name); 231} 232 233static void __devexit driver_s626_pci_remove(struct pci_dev *dev) 234{ 235 comedi_pci_auto_unconfig(dev); 236} 237 238static struct pci_driver driver_s626_pci_driver = { 239 .id_table = s626_pci_table, 240 .probe = &driver_s626_pci_probe, 241 .remove = __devexit_p(&driver_s626_pci_remove) 242}; 243 244static int __init driver_s626_init_module(void) 245{ 246 int retval; 247 248 retval = comedi_driver_register(&driver_s626); 249 if (retval < 0) 250 return retval; 251 252 driver_s626_pci_driver.name = (char *)driver_s626.driver_name; 253 return pci_register_driver(&driver_s626_pci_driver); 254} 255 256static void __exit driver_s626_cleanup_module(void) 257{ 258 pci_unregister_driver(&driver_s626_pci_driver); 259 comedi_driver_unregister(&driver_s626); 260} 261 262module_init(driver_s626_init_module); 263module_exit(driver_s626_cleanup_module); 264 265/* ioctl routines */ 266static int s626_ai_insn_config(struct comedi_device *dev, 267 struct comedi_subdevice *s, 268 struct comedi_insn *insn, unsigned int *data); 269/* static int s626_ai_rinsn(struct comedi_device *dev,struct comedi_subdevice *s,struct comedi_insn *insn,unsigned int *data); */ 270static int s626_ai_insn_read(struct comedi_device *dev, 271 struct comedi_subdevice *s, 272 struct comedi_insn *insn, unsigned int *data); 273static int s626_ai_cmd(struct comedi_device *dev, struct comedi_subdevice *s); 274static int s626_ai_cmdtest(struct comedi_device *dev, 275 struct comedi_subdevice *s, struct comedi_cmd *cmd); 276static int s626_ai_cancel(struct comedi_device *dev, 277 struct comedi_subdevice *s); 278static int s626_ao_winsn(struct comedi_device *dev, struct comedi_subdevice *s, 279 struct comedi_insn *insn, unsigned int *data); 280static int s626_ao_rinsn(struct comedi_device *dev, struct comedi_subdevice *s, 281 struct comedi_insn *insn, unsigned int *data); 282static int s626_dio_insn_bits(struct comedi_device *dev, 283 struct comedi_subdevice *s, 284 struct comedi_insn *insn, unsigned int *data); 285static int s626_dio_insn_config(struct comedi_device *dev, 286 struct comedi_subdevice *s, 287 struct comedi_insn *insn, unsigned int *data); 288static int s626_dio_set_irq(struct comedi_device *dev, unsigned int chan); 289static int s626_dio_reset_irq(struct comedi_device *dev, unsigned int gruop, 290 unsigned int mask); 291static int s626_dio_clear_irq(struct comedi_device *dev); 292static int s626_enc_insn_config(struct comedi_device *dev, 293 struct comedi_subdevice *s, 294 struct comedi_insn *insn, unsigned int *data); 295static int s626_enc_insn_read(struct comedi_device *dev, 296 struct comedi_subdevice *s, 297 struct comedi_insn *insn, unsigned int *data); 298static int s626_enc_insn_write(struct comedi_device *dev, 299 struct comedi_subdevice *s, 300 struct comedi_insn *insn, unsigned int *data); 301static int s626_ns_to_timer(int *nanosec, int round_mode); 302static int s626_ai_load_polllist(uint8_t *ppl, struct comedi_cmd *cmd); 303static int s626_ai_inttrig(struct comedi_device *dev, 304 struct comedi_subdevice *s, unsigned int trignum); 305static irqreturn_t s626_irq_handler(int irq, void *d); 306static unsigned int s626_ai_reg_to_uint(int data); 307/* static unsigned int s626_uint_to_reg(struct comedi_subdevice *s, int data); */ 308 309/* end ioctl routines */ 310 311/* internal routines */ 312static void s626_dio_init(struct comedi_device *dev); 313static void ResetADC(struct comedi_device *dev, uint8_t * ppl); 314static void LoadTrimDACs(struct comedi_device *dev); 315static void WriteTrimDAC(struct comedi_device *dev, uint8_t LogicalChan, 316 uint8_t DacData); 317static uint8_t I2Cread(struct comedi_device *dev, uint8_t addr); 318static uint32_t I2Chandshake(struct comedi_device *dev, uint32_t val); 319static void SetDAC(struct comedi_device *dev, uint16_t chan, short dacdata); 320static void SendDAC(struct comedi_device *dev, uint32_t val); 321static void WriteMISC2(struct comedi_device *dev, uint16_t NewImage); 322static void DEBItransfer(struct comedi_device *dev); 323static uint16_t DEBIread(struct comedi_device *dev, uint16_t addr); 324static void DEBIwrite(struct comedi_device *dev, uint16_t addr, uint16_t wdata); 325static void DEBIreplace(struct comedi_device *dev, uint16_t addr, uint16_t mask, 326 uint16_t wdata); 327static void CloseDMAB(struct comedi_device *dev, struct bufferDMA *pdma, 328 size_t bsize); 329 330/* COUNTER OBJECT ------------------------------------------------ */ 331struct enc_private { 332 /* Pointers to functions that differ for A and B counters: */ 333 uint16_t(*GetEnable) (struct comedi_device *dev, struct enc_private *); /* Return clock enable. */ 334 uint16_t(*GetIntSrc) (struct comedi_device *dev, struct enc_private *); /* Return interrupt source. */ 335 uint16_t(*GetLoadTrig) (struct comedi_device *dev, struct enc_private *); /* Return preload trigger source. */ 336 uint16_t(*GetMode) (struct comedi_device *dev, struct enc_private *); /* Return standardized operating mode. */ 337 void (*PulseIndex) (struct comedi_device *dev, struct enc_private *); /* Generate soft index strobe. */ 338 void (*SetEnable) (struct comedi_device *dev, struct enc_private *, uint16_t enab); /* Program clock enable. */ 339 void (*SetIntSrc) (struct comedi_device *dev, struct enc_private *, uint16_t IntSource); /* Program interrupt source. */ 340 void (*SetLoadTrig) (struct comedi_device *dev, struct enc_private *, uint16_t Trig); /* Program preload trigger source. */ 341 void (*SetMode) (struct comedi_device *dev, struct enc_private *, uint16_t Setup, uint16_t DisableIntSrc); /* Program standardized operating mode. */ 342 void (*ResetCapFlags) (struct comedi_device *dev, struct enc_private *); /* Reset event capture flags. */ 343 344 uint16_t MyCRA; /* Address of CRA register. */ 345 uint16_t MyCRB; /* Address of CRB register. */ 346 uint16_t MyLatchLsw; /* Address of Latch least-significant-word */ 347 /* register. */ 348 uint16_t MyEventBits[4]; /* Bit translations for IntSrc -->RDMISC2. */ 349}; 350 351#define encpriv ((struct enc_private *)(dev->subdevices+5)->private) 352 353/* counters routines */ 354static void s626_timer_load(struct comedi_device *dev, struct enc_private *k, 355 int tick); 356static uint32_t ReadLatch(struct comedi_device *dev, struct enc_private *k); 357static void ResetCapFlags_A(struct comedi_device *dev, struct enc_private *k); 358static void ResetCapFlags_B(struct comedi_device *dev, struct enc_private *k); 359static uint16_t GetMode_A(struct comedi_device *dev, struct enc_private *k); 360static uint16_t GetMode_B(struct comedi_device *dev, struct enc_private *k); 361static void SetMode_A(struct comedi_device *dev, struct enc_private *k, 362 uint16_t Setup, uint16_t DisableIntSrc); 363static void SetMode_B(struct comedi_device *dev, struct enc_private *k, 364 uint16_t Setup, uint16_t DisableIntSrc); 365static void SetEnable_A(struct comedi_device *dev, struct enc_private *k, 366 uint16_t enab); 367static void SetEnable_B(struct comedi_device *dev, struct enc_private *k, 368 uint16_t enab); 369static uint16_t GetEnable_A(struct comedi_device *dev, struct enc_private *k); 370static uint16_t GetEnable_B(struct comedi_device *dev, struct enc_private *k); 371static void SetLatchSource(struct comedi_device *dev, struct enc_private *k, 372 uint16_t value); 373/* static uint16_t GetLatchSource(struct comedi_device *dev, struct enc_private *k ); */ 374static void SetLoadTrig_A(struct comedi_device *dev, struct enc_private *k, 375 uint16_t Trig); 376static void SetLoadTrig_B(struct comedi_device *dev, struct enc_private *k, 377 uint16_t Trig); 378static uint16_t GetLoadTrig_A(struct comedi_device *dev, struct enc_private *k); 379static uint16_t GetLoadTrig_B(struct comedi_device *dev, struct enc_private *k); 380static void SetIntSrc_B(struct comedi_device *dev, struct enc_private *k, 381 uint16_t IntSource); 382static void SetIntSrc_A(struct comedi_device *dev, struct enc_private *k, 383 uint16_t IntSource); 384static uint16_t GetIntSrc_A(struct comedi_device *dev, struct enc_private *k); 385static uint16_t GetIntSrc_B(struct comedi_device *dev, struct enc_private *k); 386/* static void SetClkMult(struct comedi_device *dev, struct enc_private *k, uint16_t value ) ; */ 387/* static uint16_t GetClkMult(struct comedi_device *dev, struct enc_private *k ) ; */ 388/* static void SetIndexPol(struct comedi_device *dev, struct enc_private *k, uint16_t value ); */ 389/* static uint16_t GetClkPol(struct comedi_device *dev, struct enc_private *k ) ; */ 390/* static void SetIndexSrc( struct comedi_device *dev,struct enc_private *k, uint16_t value ); */ 391/* static uint16_t GetClkSrc( struct comedi_device *dev,struct enc_private *k ); */ 392/* static void SetIndexSrc( struct comedi_device *dev,struct enc_private *k, uint16_t value ); */ 393/* static uint16_t GetIndexSrc( struct comedi_device *dev,struct enc_private *k ); */ 394static void PulseIndex_A(struct comedi_device *dev, struct enc_private *k); 395static void PulseIndex_B(struct comedi_device *dev, struct enc_private *k); 396static void Preload(struct comedi_device *dev, struct enc_private *k, 397 uint32_t value); 398static void CountersInit(struct comedi_device *dev); 399/* end internal routines */ 400 401/* Counter objects constructor. */ 402 403/* Counter overflow/index event flag masks for RDMISC2. */ 404#define INDXMASK(C) (1 << (((C) > 2) ? ((C) * 2 - 1) : ((C) * 2 + 4))) 405#define OVERMASK(C) (1 << (((C) > 2) ? ((C) * 2 + 5) : ((C) * 2 + 10))) 406#define EVBITS(C) { 0, OVERMASK(C), INDXMASK(C), OVERMASK(C) | INDXMASK(C) } 407 408/* Translation table to map IntSrc into equivalent RDMISC2 event flag bits. */ 409/* static const uint16_t EventBits[][4] = { EVBITS(0), EVBITS(1), EVBITS(2), EVBITS(3), EVBITS(4), EVBITS(5) }; */ 410 411/* struct enc_private; */ 412static struct enc_private enc_private_data[] = { 413 { 414 .GetEnable = GetEnable_A, 415 .GetIntSrc = GetIntSrc_A, 416 .GetLoadTrig = GetLoadTrig_A, 417 .GetMode = GetMode_A, 418 .PulseIndex = PulseIndex_A, 419 .SetEnable = SetEnable_A, 420 .SetIntSrc = SetIntSrc_A, 421 .SetLoadTrig = SetLoadTrig_A, 422 .SetMode = SetMode_A, 423 .ResetCapFlags = ResetCapFlags_A, 424 .MyCRA = LP_CR0A, 425 .MyCRB = LP_CR0B, 426 .MyLatchLsw = LP_CNTR0ALSW, 427 .MyEventBits = EVBITS(0), 428 }, 429 { 430 .GetEnable = GetEnable_A, 431 .GetIntSrc = GetIntSrc_A, 432 .GetLoadTrig = GetLoadTrig_A, 433 .GetMode = GetMode_A, 434 .PulseIndex = PulseIndex_A, 435 .SetEnable = SetEnable_A, 436 .SetIntSrc = SetIntSrc_A, 437 .SetLoadTrig = SetLoadTrig_A, 438 .SetMode = SetMode_A, 439 .ResetCapFlags = ResetCapFlags_A, 440 .MyCRA = LP_CR1A, 441 .MyCRB = LP_CR1B, 442 .MyLatchLsw = LP_CNTR1ALSW, 443 .MyEventBits = EVBITS(1), 444 }, 445 { 446 .GetEnable = GetEnable_A, 447 .GetIntSrc = GetIntSrc_A, 448 .GetLoadTrig = GetLoadTrig_A, 449 .GetMode = GetMode_A, 450 .PulseIndex = PulseIndex_A, 451 .SetEnable = SetEnable_A, 452 .SetIntSrc = SetIntSrc_A, 453 .SetLoadTrig = SetLoadTrig_A, 454 .SetMode = SetMode_A, 455 .ResetCapFlags = ResetCapFlags_A, 456 .MyCRA = LP_CR2A, 457 .MyCRB = LP_CR2B, 458 .MyLatchLsw = LP_CNTR2ALSW, 459 .MyEventBits = EVBITS(2), 460 }, 461 { 462 .GetEnable = GetEnable_B, 463 .GetIntSrc = GetIntSrc_B, 464 .GetLoadTrig = GetLoadTrig_B, 465 .GetMode = GetMode_B, 466 .PulseIndex = PulseIndex_B, 467 .SetEnable = SetEnable_B, 468 .SetIntSrc = SetIntSrc_B, 469 .SetLoadTrig = SetLoadTrig_B, 470 .SetMode = SetMode_B, 471 .ResetCapFlags = ResetCapFlags_B, 472 .MyCRA = LP_CR0A, 473 .MyCRB = LP_CR0B, 474 .MyLatchLsw = LP_CNTR0BLSW, 475 .MyEventBits = EVBITS(3), 476 }, 477 { 478 .GetEnable = GetEnable_B, 479 .GetIntSrc = GetIntSrc_B, 480 .GetLoadTrig = GetLoadTrig_B, 481 .GetMode = GetMode_B, 482 .PulseIndex = PulseIndex_B, 483 .SetEnable = SetEnable_B, 484 .SetIntSrc = SetIntSrc_B, 485 .SetLoadTrig = SetLoadTrig_B, 486 .SetMode = SetMode_B, 487 .ResetCapFlags = ResetCapFlags_B, 488 .MyCRA = LP_CR1A, 489 .MyCRB = LP_CR1B, 490 .MyLatchLsw = LP_CNTR1BLSW, 491 .MyEventBits = EVBITS(4), 492 }, 493 { 494 .GetEnable = GetEnable_B, 495 .GetIntSrc = GetIntSrc_B, 496 .GetLoadTrig = GetLoadTrig_B, 497 .GetMode = GetMode_B, 498 .PulseIndex = PulseIndex_B, 499 .SetEnable = SetEnable_B, 500 .SetIntSrc = SetIntSrc_B, 501 .SetLoadTrig = SetLoadTrig_B, 502 .SetMode = SetMode_B, 503 .ResetCapFlags = ResetCapFlags_B, 504 .MyCRA = LP_CR2A, 505 .MyCRB = LP_CR2B, 506 .MyLatchLsw = LP_CNTR2BLSW, 507 .MyEventBits = EVBITS(5), 508 }, 509}; 510 511/* enab/disable a function or test status bit(s) that are accessed */ 512/* through Main Control Registers 1 or 2. */ 513#define MC_ENABLE(REGADRS, CTRLWORD) writel(((uint32_t)(CTRLWORD) << 16) | (uint32_t)(CTRLWORD), devpriv->base_addr+(REGADRS)) 514 515#define MC_DISABLE(REGADRS, CTRLWORD) writel((uint32_t)(CTRLWORD) << 16 , devpriv->base_addr+(REGADRS)) 516 517#define MC_TEST(REGADRS, CTRLWORD) ((readl(devpriv->base_addr+(REGADRS)) & CTRLWORD) != 0) 518 519/* #define WR7146(REGARDS,CTRLWORD) 520 writel(CTRLWORD,(uint32_t)(devpriv->base_addr+(REGARDS))) */ 521#define WR7146(REGARDS, CTRLWORD) writel(CTRLWORD, devpriv->base_addr+(REGARDS)) 522 523/* #define RR7146(REGARDS) 524 readl((uint32_t)(devpriv->base_addr+(REGARDS))) */ 525#define RR7146(REGARDS) readl(devpriv->base_addr+(REGARDS)) 526 527#define BUGFIX_STREG(REGADRS) (REGADRS - 4) 528 529/* Write a time slot control record to TSL2. */ 530#define VECTPORT(VECTNUM) (P_TSL2 + ((VECTNUM) << 2)) 531#define SETVECT(VECTNUM, VECTVAL) WR7146(VECTPORT(VECTNUM), (VECTVAL)) 532 533/* Code macros used for constructing I2C command bytes. */ 534#define I2C_B2(ATTR, VAL) (((ATTR) << 6) | ((VAL) << 24)) 535#define I2C_B1(ATTR, VAL) (((ATTR) << 4) | ((VAL) << 16)) 536#define I2C_B0(ATTR, VAL) (((ATTR) << 2) | ((VAL) << 8)) 537 538static const struct comedi_lrange s626_range_table = { 2, { 539 RANGE(-5, 5), 540 RANGE(-10, 10), 541 } 542}; 543 544static int s626_attach(struct comedi_device *dev, struct comedi_devconfig *it) 545{ 546/* uint8_t PollList; */ 547/* uint16_t AdcData; */ 548/* uint16_t StartVal; */ 549/* uint16_t index; */ 550/* unsigned int data[16]; */ 551 int result; 552 int i; 553 int ret; 554 resource_size_t resourceStart; 555 dma_addr_t appdma; 556 struct comedi_subdevice *s; 557 const struct pci_device_id *ids; 558 struct pci_dev *pdev = NULL; 559 560 if (alloc_private(dev, sizeof(struct s626_private)) < 0) 561 return -ENOMEM; 562 563 for (i = 0; i < (ARRAY_SIZE(s626_pci_table) - 1) && !pdev; i++) { 564 ids = &s626_pci_table[i]; 565 do { 566 pdev = pci_get_subsys(ids->vendor, ids->device, 567 ids->subvendor, ids->subdevice, 568 pdev); 569 570 if ((it->options[0] || it->options[1]) && pdev) { 571 /* matches requested bus/slot */ 572 if (pdev->bus->number == it->options[0] && 573 PCI_SLOT(pdev->devfn) == it->options[1]) 574 break; 575 } else 576 break; 577 } while (1); 578 } 579 devpriv->pdev = pdev; 580 581 if (pdev == NULL) { 582 printk(KERN_ERR "s626_attach: Board not present!!!\n"); 583 return -ENODEV; 584 } 585 586 result = comedi_pci_enable(pdev, "s626"); 587 if (result < 0) { 588 printk(KERN_ERR "s626_attach: comedi_pci_enable fails\n"); 589 return -ENODEV; 590 } 591 devpriv->got_regions = 1; 592 593 resourceStart = pci_resource_start(devpriv->pdev, 0); 594 595 devpriv->base_addr = ioremap(resourceStart, SIZEOF_ADDRESS_SPACE); 596 if (devpriv->base_addr == NULL) { 597 printk(KERN_ERR "s626_attach: IOREMAP failed\n"); 598 return -ENODEV; 599 } 600 601 if (devpriv->base_addr) { 602 /* disable master interrupt */ 603 writel(0, devpriv->base_addr + P_IER); 604 605 /* soft reset */ 606 writel(MC1_SOFT_RESET, devpriv->base_addr + P_MC1); 607 608 /* DMA FIXME DMA// */ 609 DEBUG("s626_attach: DMA ALLOCATION\n"); 610 611 /* adc buffer allocation */ 612 devpriv->allocatedBuf = 0; 613 614 devpriv->ANABuf.LogicalBase = 615 pci_alloc_consistent(devpriv->pdev, DMABUF_SIZE, &appdma); 616 617 if (devpriv->ANABuf.LogicalBase == NULL) { 618 printk(KERN_ERR "s626_attach: DMA Memory mapping error\n"); 619 return -ENOMEM; 620 } 621 622 devpriv->ANABuf.PhysicalBase = appdma; 623 624 DEBUG 625 ("s626_attach: AllocDMAB ADC Logical=%p, bsize=%d, Physical=0x%x\n", 626 devpriv->ANABuf.LogicalBase, DMABUF_SIZE, 627 (uint32_t) devpriv->ANABuf.PhysicalBase); 628 629 devpriv->allocatedBuf++; 630 631 devpriv->RPSBuf.LogicalBase = 632 pci_alloc_consistent(devpriv->pdev, DMABUF_SIZE, &appdma); 633 634 if (devpriv->RPSBuf.LogicalBase == NULL) { 635 printk(KERN_ERR "s626_attach: DMA Memory mapping error\n"); 636 return -ENOMEM; 637 } 638 639 devpriv->RPSBuf.PhysicalBase = appdma; 640 641 DEBUG 642 ("s626_attach: AllocDMAB RPS Logical=%p, bsize=%d, Physical=0x%x\n", 643 devpriv->RPSBuf.LogicalBase, DMABUF_SIZE, 644 (uint32_t) devpriv->RPSBuf.PhysicalBase); 645 646 devpriv->allocatedBuf++; 647 648 } 649 650 dev->board_ptr = s626_boards; 651 dev->board_name = thisboard->name; 652 653 if (alloc_subdevices(dev, 6) < 0) 654 return -ENOMEM; 655 656 dev->iobase = (unsigned long)devpriv->base_addr; 657 dev->irq = devpriv->pdev->irq; 658 659 /* set up interrupt handler */ 660 if (dev->irq == 0) { 661 printk(KERN_ERR " unknown irq (bad)\n"); 662 } else { 663 ret = request_irq(dev->irq, s626_irq_handler, IRQF_SHARED, 664 "s626", dev); 665 666 if (ret < 0) { 667 printk(KERN_ERR " irq not available\n"); 668 dev->irq = 0; 669 } 670 } 671 672 DEBUG("s626_attach: -- it opts %d,%d --\n", 673 it->options[0], it->options[1]); 674 675 s = dev->subdevices + 0; 676 /* analog input subdevice */ 677 dev->read_subdev = s; 678 /* we support single-ended (ground) and differential */ 679 s->type = COMEDI_SUBD_AI; 680 s->subdev_flags = SDF_READABLE | SDF_DIFF | SDF_CMD_READ; 681 s->n_chan = thisboard->ai_chans; 682 s->maxdata = (0xffff >> 2); 683 s->range_table = &s626_range_table; 684 s->len_chanlist = thisboard->ai_chans; /* This is the maximum chanlist 685 length that the board can 686 handle */ 687 s->insn_config = s626_ai_insn_config; 688 s->insn_read = s626_ai_insn_read; 689 s->do_cmd = s626_ai_cmd; 690 s->do_cmdtest = s626_ai_cmdtest; 691 s->cancel = s626_ai_cancel; 692 693 s = dev->subdevices + 1; 694 /* analog output subdevice */ 695 s->type = COMEDI_SUBD_AO; 696 s->subdev_flags = SDF_WRITABLE | SDF_READABLE; 697 s->n_chan = thisboard->ao_chans; 698 s->maxdata = (0x3fff); 699 s->range_table = &range_bipolar10; 700 s->insn_write = s626_ao_winsn; 701 s->insn_read = s626_ao_rinsn; 702 703 s = dev->subdevices + 2; 704 /* digital I/O subdevice */ 705 s->type = COMEDI_SUBD_DIO; 706 s->subdev_flags = SDF_WRITABLE | SDF_READABLE; 707 s->n_chan = S626_DIO_CHANNELS; 708 s->maxdata = 1; 709 s->io_bits = 0xffff; 710 s->private = &dio_private_A; 711 s->range_table = &range_digital; 712 s->insn_config = s626_dio_insn_config; 713 s->insn_bits = s626_dio_insn_bits; 714 715 s = dev->subdevices + 3; 716 /* digital I/O subdevice */ 717 s->type = COMEDI_SUBD_DIO; 718 s->subdev_flags = SDF_WRITABLE | SDF_READABLE; 719 s->n_chan = 16; 720 s->maxdata = 1; 721 s->io_bits = 0xffff; 722 s->private = &dio_private_B; 723 s->range_table = &range_digital; 724 s->insn_config = s626_dio_insn_config; 725 s->insn_bits = s626_dio_insn_bits; 726 727 s = dev->subdevices + 4; 728 /* digital I/O subdevice */ 729 s->type = COMEDI_SUBD_DIO; 730 s->subdev_flags = SDF_WRITABLE | SDF_READABLE; 731 s->n_chan = 16; 732 s->maxdata = 1; 733 s->io_bits = 0xffff; 734 s->private = &dio_private_C; 735 s->range_table = &range_digital; 736 s->insn_config = s626_dio_insn_config; 737 s->insn_bits = s626_dio_insn_bits; 738 739 s = dev->subdevices + 5; 740 /* encoder (counter) subdevice */ 741 s->type = COMEDI_SUBD_COUNTER; 742 s->subdev_flags = SDF_WRITABLE | SDF_READABLE | SDF_LSAMPL; 743 s->n_chan = thisboard->enc_chans; 744 s->private = enc_private_data; 745 s->insn_config = s626_enc_insn_config; 746 s->insn_read = s626_enc_insn_read; 747 s->insn_write = s626_enc_insn_write; 748 s->maxdata = 0xffffff; 749 s->range_table = &range_unknown; 750 751 /* stop ai_command */ 752 devpriv->ai_cmd_running = 0; 753 754 if (devpriv->base_addr && (devpriv->allocatedBuf == 2)) { 755 dma_addr_t pPhysBuf; 756 uint16_t chan; 757 758 /* enab DEBI and audio pins, enable I2C interface. */ 759 MC_ENABLE(P_MC1, MC1_DEBI | MC1_AUDIO | MC1_I2C); 760 /* Configure DEBI operating mode. */ 761 WR7146(P_DEBICFG, DEBI_CFG_SLAVE16 /* Local bus is 16 */ 762 /* bits wide. */ 763 | (DEBI_TOUT << DEBI_CFG_TOUT_BIT) 764 765 /* Declare DEBI */ 766 /* transfer timeout */ 767 /* interval. */ 768 |DEBI_SWAP /* Set up byte lane */ 769 /* steering. */ 770 | DEBI_CFG_INTEL); /* Intel-compatible */ 771 /* local bus (DEBI */ 772 /* never times out). */ 773 DEBUG("s626_attach: %d debi init -- %d\n", 774 DEBI_CFG_SLAVE16 | (DEBI_TOUT << DEBI_CFG_TOUT_BIT) | 775 DEBI_SWAP | DEBI_CFG_INTEL, 776 DEBI_CFG_INTEL | DEBI_CFG_TOQ | DEBI_CFG_INCQ | 777 DEBI_CFG_16Q); 778 779 /* DEBI INIT S626 WR7146( P_DEBICFG, DEBI_CFG_INTEL | DEBI_CFG_TOQ */ 780 /* | DEBI_CFG_INCQ| DEBI_CFG_16Q); //end */ 781 782 /* Paging is disabled. */ 783 WR7146(P_DEBIPAGE, DEBI_PAGE_DISABLE); /* Disable MMU paging. */ 784 785 /* Init GPIO so that ADC Start* is negated. */ 786 WR7146(P_GPIO, GPIO_BASE | GPIO1_HI); 787 788 /* IsBoardRevA is a boolean that indicates whether the board is RevA. 789 * 790 * VERSION 2.01 CHANGE: REV A & B BOARDS NOW SUPPORTED BY DYNAMIC 791 * EEPROM ADDRESS SELECTION. Initialize the I2C interface, which 792 * is used to access the onboard serial EEPROM. The EEPROM's I2C 793 * DeviceAddress is hardwired to a value that is dependent on the 794 * 626 board revision. On all board revisions, the EEPROM stores 795 * TrimDAC calibration constants for analog I/O. On RevB and 796 * higher boards, the DeviceAddress is hardwired to 0 to enable 797 * the EEPROM to also store the PCI SubVendorID and SubDeviceID; 798 * this is the address at which the SAA7146 expects a 799 * configuration EEPROM to reside. On RevA boards, the EEPROM 800 * device address, which is hardwired to 4, prevents the SAA7146 801 * from retrieving PCI sub-IDs, so the SAA7146 uses its built-in 802 * default values, instead. 803 */ 804 805 /* devpriv->I2Cards= IsBoardRevA ? 0xA8 : 0xA0; // Set I2C EEPROM */ 806 /* DeviceType (0xA0) */ 807 /* and DeviceAddress<<1. */ 808 809 devpriv->I2CAdrs = 0xA0; /* I2C device address for onboard */ 810 /* eeprom(revb) */ 811 812 /* Issue an I2C ABORT command to halt any I2C operation in */ 813 /* progress and reset BUSY flag. */ 814 WR7146(P_I2CSTAT, I2C_CLKSEL | I2C_ABORT); 815 /* Write I2C control: abort any I2C activity. */ 816 MC_ENABLE(P_MC2, MC2_UPLD_IIC); 817 /* Invoke command upload */ 818 while ((RR7146(P_MC2) & MC2_UPLD_IIC) == 0) 819 ; 820 /* and wait for upload to complete. */ 821 822 /* Per SAA7146 data sheet, write to STATUS reg twice to 823 * reset all I2C error flags. */ 824 for (i = 0; i < 2; i++) { 825 WR7146(P_I2CSTAT, I2C_CLKSEL); 826 /* Write I2C control: reset error flags. */ 827 MC_ENABLE(P_MC2, MC2_UPLD_IIC); /* Invoke command upload */ 828 while (!MC_TEST(P_MC2, MC2_UPLD_IIC)) 829 ; 830 /* and wait for upload to complete. */ 831 } 832 833 /* Init audio interface functional attributes: set DAC/ADC 834 * serial clock rates, invert DAC serial clock so that 835 * DAC data setup times are satisfied, enable DAC serial 836 * clock out. 837 */ 838 839 WR7146(P_ACON2, ACON2_INIT); 840 841 /* Set up TSL1 slot list, which is used to control the 842 * accumulation of ADC data: RSD1 = shift data in on SD1. 843 * SIB_A1 = store data uint8_t at next available location in 844 * FB BUFFER1 register. */ 845 WR7146(P_TSL1, RSD1 | SIB_A1); 846 /* Fetch ADC high data uint8_t. */ 847 WR7146(P_TSL1 + 4, RSD1 | SIB_A1 | EOS); 848 /* Fetch ADC low data uint8_t; end of TSL1. */ 849 850 /* enab TSL1 slot list so that it executes all the time. */ 851 WR7146(P_ACON1, ACON1_ADCSTART); 852 853 /* Initialize RPS registers used for ADC. */ 854 855 /* Physical start of RPS program. */ 856 WR7146(P_RPSADDR1, (uint32_t) devpriv->RPSBuf.PhysicalBase); 857 858 WR7146(P_RPSPAGE1, 0); 859 /* RPS program performs no explicit mem writes. */ 860 WR7146(P_RPS1_TOUT, 0); /* Disable RPS timeouts. */ 861 862 /* SAA7146 BUG WORKAROUND. Initialize SAA7146 ADC interface 863 * to a known state by invoking ADCs until FB BUFFER 1 864 * register shows that it is correctly receiving ADC data. 865 * This is necessary because the SAA7146 ADC interface does 866 * not start up in a defined state after a PCI reset. 867 */ 868 869/* PollList = EOPL; // Create a simple polling */ 870/* // list for analog input */ 871/* // channel 0. */ 872/* ResetADC( dev, &PollList ); */ 873 874/* s626_ai_rinsn(dev,dev->subdevices,NULL,data); //( &AdcData ); // */ 875/* //Get initial ADC */ 876/* //value. */ 877 878/* StartVal = data[0]; */ 879 880/* // VERSION 2.01 CHANGE: TIMEOUT ADDED TO PREVENT HANGED EXECUTION. */ 881/* // Invoke ADCs until the new ADC value differs from the initial */ 882/* // value or a timeout occurs. The timeout protects against the */ 883/* // possibility that the driver is restarting and the ADC data is a */ 884/* // fixed value resulting from the applied ADC analog input being */ 885/* // unusually quiet or at the rail. */ 886 887/* for ( index = 0; index < 500; index++ ) */ 888/* { */ 889/* s626_ai_rinsn(dev,dev->subdevices,NULL,data); */ 890/* AdcData = data[0]; //ReadADC( &AdcData ); */ 891/* if ( AdcData != StartVal ) */ 892/* break; */ 893/* } */ 894 895 /* end initADC */ 896 897 /* init the DAC interface */ 898 899 /* Init Audio2's output DMAC attributes: burst length = 1 900 * DWORD, threshold = 1 DWORD. 901 */ 902 WR7146(P_PCI_BT_A, 0); 903 904 /* Init Audio2's output DMA physical addresses. The protection 905 * address is set to 1 DWORD past the base address so that a 906 * single DWORD will be transferred each time a DMA transfer is 907 * enabled. */ 908 909 pPhysBuf = 910 devpriv->ANABuf.PhysicalBase + 911 (DAC_WDMABUF_OS * sizeof(uint32_t)); 912 913 WR7146(P_BASEA2_OUT, (uint32_t) pPhysBuf); /* Buffer base adrs. */ 914 WR7146(P_PROTA2_OUT, (uint32_t) (pPhysBuf + sizeof(uint32_t))); /* Protection address. */ 915 916 /* Cache Audio2's output DMA buffer logical address. This is 917 * where DAC data is buffered for A2 output DMA transfers. */ 918 devpriv->pDacWBuf = 919 (uint32_t *) devpriv->ANABuf.LogicalBase + DAC_WDMABUF_OS; 920 921 /* Audio2's output channels does not use paging. The protection 922 * violation handling bit is set so that the DMAC will 923 * automatically halt and its PCI address pointer will be reset 924 * when the protection address is reached. */ 925 926 WR7146(P_PAGEA2_OUT, 8); 927 928 /* Initialize time slot list 2 (TSL2), which is used to control 929 * the clock generation for and serialization of data to be sent 930 * to the DAC devices. Slot 0 is a NOP that is used to trap TSL 931 * execution; this permits other slots to be safely modified 932 * without first turning off the TSL sequencer (which is 933 * apparently impossible to do). Also, SD3 (which is driven by a 934 * pull-up resistor) is shifted in and stored to the MSB of 935 * FB_BUFFER2 to be used as evidence that the slot sequence has 936 * not yet finished executing. 937 */ 938 939 SETVECT(0, XSD2 | RSD3 | SIB_A2 | EOS); 940 /* Slot 0: Trap TSL execution, shift 0xFF into FB_BUFFER2. */ 941 942 /* Initialize slot 1, which is constant. Slot 1 causes a 943 * DWORD to be transferred from audio channel 2's output FIFO 944 * to the FIFO's output buffer so that it can be serialized 945 * and sent to the DAC during subsequent slots. All remaining 946 * slots are dynamically populated as required by the target 947 * DAC device. 948 */ 949 SETVECT(1, LF_A2); 950 /* Slot 1: Fetch DWORD from Audio2's output FIFO. */ 951 952 /* Start DAC's audio interface (TSL2) running. */ 953 WR7146(P_ACON1, ACON1_DACSTART); 954 955 /* end init DAC interface */ 956 957 /* Init Trim DACs to calibrated values. Do it twice because the 958 * SAA7146 audio channel does not always reset properly and 959 * sometimes causes the first few TrimDAC writes to malfunction. 960 */ 961 962 LoadTrimDACs(dev); 963 LoadTrimDACs(dev); /* Insurance. */ 964 965 /* Manually init all gate array hardware in case this is a soft 966 * reset (we have no way of determining whether this is a warm 967 * or cold start). This is necessary because the gate array will 968 * reset only in response to a PCI hard reset; there is no soft 969 * reset function. */ 970 971 /* Init all DAC outputs to 0V and init all DAC setpoint and 972 * polarity images. 973 */ 974 for (chan = 0; chan < S626_DAC_CHANNELS; chan++) 975 SetDAC(dev, chan, 0); 976 977 /* Init image of WRMISC2 Battery Charger Enabled control bit. 978 * This image is used when the state of the charger control bit, 979 * which has no direct hardware readback mechanism, is queried. 980 */ 981 devpriv->ChargeEnabled = 0; 982 983 /* Init image of watchdog timer interval in WRMISC2. This image 984 * maintains the value of the control bits of MISC2 are 985 * continuously reset to zero as long as the WD timer is disabled. 986 */ 987 devpriv->WDInterval = 0; 988 989 /* Init Counter Interrupt enab mask for RDMISC2. This mask is 990 * applied against MISC2 when testing to determine which timer 991 * events are requesting interrupt service. 992 */ 993 devpriv->CounterIntEnabs = 0; 994 995 /* Init counters. */ 996 CountersInit(dev); 997 998 /* Without modifying the state of the Battery Backup enab, disable 999 * the watchdog timer, set DIO channels 0-5 to operate in the 1000 * standard DIO (vs. counter overflow) mode, disable the battery 1001 * charger, and reset the watchdog interval selector to zero. 1002 */ 1003 WriteMISC2(dev, (uint16_t) (DEBIread(dev, 1004 LP_RDMISC2) & 1005 MISC2_BATT_ENABLE)); 1006 1007 /* Initialize the digital I/O subsystem. */ 1008 s626_dio_init(dev); 1009 1010 /* enable interrupt test */ 1011 /* writel(IRQ_GPIO3 | IRQ_RPS1,devpriv->base_addr+P_IER); */ 1012 } 1013 1014 DEBUG("s626_attach: comedi%d s626 attached %04x\n", dev->minor, 1015 (uint32_t) devpriv->base_addr); 1016 1017 return 1; 1018} 1019 1020static unsigned int s626_ai_reg_to_uint(int data) 1021{ 1022 unsigned int tempdata; 1023 1024 tempdata = (data >> 18); 1025 if (tempdata & 0x2000) 1026 tempdata &= 0x1fff; 1027 else 1028 tempdata += (1 << 13); 1029 1030 return tempdata; 1031} 1032 1033/* static unsigned int s626_uint_to_reg(struct comedi_subdevice *s, int data){ */ 1034/* return 0; */ 1035/* } */ 1036 1037static irqreturn_t s626_irq_handler(int irq, void *d) 1038{ 1039 struct comedi_device *dev = d; 1040 struct comedi_subdevice *s; 1041 struct comedi_cmd *cmd; 1042 struct enc_private *k; 1043 unsigned long flags; 1044 int32_t *readaddr; 1045 uint32_t irqtype, irqstatus; 1046 int i = 0; 1047 short tempdata; 1048 uint8_t group; 1049 uint16_t irqbit; 1050 1051 DEBUG("s626_irq_handler: interrupt request received!!!\n"); 1052 1053 if (dev->attached == 0) 1054 return IRQ_NONE; 1055 /* lock to avoid race with comedi_poll */ 1056 spin_lock_irqsave(&dev->spinlock, flags); 1057 1058 /* save interrupt enable register state */ 1059 irqstatus = readl(devpriv->base_addr + P_IER); 1060 1061 /* read interrupt type */ 1062 irqtype = readl(devpriv->base_addr + P_ISR); 1063 1064 /* disable master interrupt */ 1065 writel(0, devpriv->base_addr + P_IER); 1066 1067 /* clear interrupt */ 1068 writel(irqtype, devpriv->base_addr + P_ISR); 1069 1070 /* do somethings */ 1071 DEBUG("s626_irq_handler: interrupt type %d\n", irqtype); 1072 1073 switch (irqtype) { 1074 case IRQ_RPS1: /* end_of_scan occurs */ 1075 1076 DEBUG("s626_irq_handler: RPS1 irq detected\n"); 1077 1078 /* manage ai subdevice */ 1079 s = dev->subdevices; 1080 cmd = &(s->async->cmd); 1081 1082 /* Init ptr to DMA buffer that holds new ADC data. We skip the 1083 * first uint16_t in the buffer because it contains junk data from 1084 * the final ADC of the previous poll list scan. 1085 */ 1086 readaddr = (int32_t *) devpriv->ANABuf.LogicalBase + 1; 1087 1088 /* get the data and hand it over to comedi */ 1089 for (i = 0; i < (s->async->cmd.chanlist_len); i++) { 1090 /* Convert ADC data to 16-bit integer values and copy to application */ 1091 /* buffer. */ 1092 tempdata = s626_ai_reg_to_uint((int)*readaddr); 1093 readaddr++; 1094 1095 /* put data into read buffer */ 1096 /* comedi_buf_put(s->async, tempdata); */ 1097 if (cfc_write_to_buffer(s, tempdata) == 0) 1098 printk 1099 ("s626_irq_handler: cfc_write_to_buffer error!\n"); 1100 1101 DEBUG("s626_irq_handler: ai channel %d acquired: %d\n", 1102 i, tempdata); 1103 } 1104 1105 /* end of scan occurs */ 1106 s->async->events |= COMEDI_CB_EOS; 1107 1108 if (!(devpriv->ai_continous)) 1109 devpriv->ai_sample_count--; 1110 if (devpriv->ai_sample_count <= 0) { 1111 devpriv->ai_cmd_running = 0; 1112 1113 /* Stop RPS program. */ 1114 MC_DISABLE(P_MC1, MC1_ERPS1); 1115 1116 /* send end of acquisition */ 1117 s->async->events |= COMEDI_CB_EOA; 1118 1119 /* disable master interrupt */ 1120 irqstatus = 0; 1121 } 1122 1123 if (devpriv->ai_cmd_running && cmd->scan_begin_src == TRIG_EXT) { 1124 DEBUG 1125 ("s626_irq_handler: enable interrupt on dio channel %d\n", 1126 cmd->scan_begin_arg); 1127 1128 s626_dio_set_irq(dev, cmd->scan_begin_arg); 1129 1130 DEBUG("s626_irq_handler: External trigger is set!!!\n"); 1131 } 1132 /* tell comedi that data is there */ 1133 DEBUG("s626_irq_handler: events %d\n", s->async->events); 1134 comedi_event(dev, s); 1135 break; 1136 case IRQ_GPIO3: /* check dio and conter interrupt */ 1137 1138 DEBUG("s626_irq_handler: GPIO3 irq detected\n"); 1139 1140 /* manage ai subdevice */ 1141 s = dev->subdevices; 1142 cmd = &(s->async->cmd); 1143 1144 /* s626_dio_clear_irq(dev); */ 1145 1146 for (group = 0; group < S626_DIO_BANKS; group++) { 1147 irqbit = 0; 1148 /* read interrupt type */ 1149 irqbit = DEBIread(dev, 1150 ((struct dio_private *)(dev-> 1151 subdevices + 1152 2 + 1153 group)-> 1154 private)->RDCapFlg); 1155 1156 /* check if interrupt is generated from dio channels */ 1157 if (irqbit) { 1158 s626_dio_reset_irq(dev, group, irqbit); 1159 DEBUG 1160 ("s626_irq_handler: check interrupt on dio group %d %d\n", 1161 group, i); 1162 if (devpriv->ai_cmd_running) { 1163 /* check if interrupt is an ai acquisition start trigger */ 1164 if ((irqbit >> (cmd->start_arg - 1165 (16 * group))) 1166 == 1 && cmd->start_src == TRIG_EXT) { 1167 DEBUG 1168 ("s626_irq_handler: Edge capture interrupt received from channel %d\n", 1169 cmd->start_arg); 1170 1171 /* Start executing the RPS program. */ 1172 MC_ENABLE(P_MC1, MC1_ERPS1); 1173 1174 DEBUG 1175 ("s626_irq_handler: acquisition start triggered!!!\n"); 1176 1177 if (cmd->scan_begin_src == 1178 TRIG_EXT) { 1179 DEBUG 1180 ("s626_ai_cmd: enable interrupt on dio channel %d\n", 1181 cmd-> 1182 scan_begin_arg); 1183 1184 s626_dio_set_irq(dev, 1185 cmd->scan_begin_arg); 1186 1187 DEBUG 1188 ("s626_irq_handler: External scan trigger is set!!!\n"); 1189 } 1190 } 1191 if ((irqbit >> (cmd->scan_begin_arg - 1192 (16 * group))) 1193 == 1 1194 && cmd->scan_begin_src == 1195 TRIG_EXT) { 1196 DEBUG 1197 ("s626_irq_handler: Edge capture interrupt received from channel %d\n", 1198 cmd->scan_begin_arg); 1199 1200 /* Trigger ADC scan loop start by setting RPS Signal 0. */ 1201 MC_ENABLE(P_MC2, MC2_ADC_RPS); 1202 1203 DEBUG 1204 ("s626_irq_handler: scan triggered!!! %d\n", 1205 devpriv->ai_sample_count); 1206 if (cmd->convert_src == 1207 TRIG_EXT) { 1208 1209 DEBUG 1210 ("s626_ai_cmd: enable interrupt on dio channel %d group %d\n", 1211 cmd->convert_arg - 1212 (16 * group), 1213 group); 1214 1215 devpriv->ai_convert_count 1216 = cmd->chanlist_len; 1217 1218 s626_dio_set_irq(dev, 1219 cmd->convert_arg); 1220 1221 DEBUG 1222 ("s626_irq_handler: External convert trigger is set!!!\n"); 1223 } 1224 1225 if (cmd->convert_src == 1226 TRIG_TIMER) { 1227 k = &encpriv[5]; 1228 devpriv->ai_convert_count 1229 = cmd->chanlist_len; 1230 k->SetEnable(dev, k, 1231 CLKENAB_ALWAYS); 1232 } 1233 } 1234 if ((irqbit >> (cmd->convert_arg - 1235 (16 * group))) 1236 == 1 1237 && cmd->convert_src == TRIG_EXT) { 1238 DEBUG 1239 ("s626_irq_handler: Edge capture interrupt received from channel %d\n", 1240 cmd->convert_arg); 1241 1242 /* Trigger ADC scan loop start by setting RPS Signal 0. */ 1243 MC_ENABLE(P_MC2, MC2_ADC_RPS); 1244 1245 DEBUG 1246 ("s626_irq_handler: adc convert triggered!!!\n"); 1247 1248 devpriv->ai_convert_count--; 1249 1250 if (devpriv->ai_convert_count > 1251 0) { 1252 1253 DEBUG 1254 ("s626_ai_cmd: enable interrupt on dio channel %d group %d\n", 1255 cmd->convert_arg - 1256 (16 * group), 1257 group); 1258 1259 s626_dio_set_irq(dev, 1260 cmd->convert_arg); 1261 1262 DEBUG 1263 ("s626_irq_handler: External trigger is set!!!\n"); 1264 } 1265 } 1266 } 1267 break; 1268 } 1269 } 1270 1271 /* read interrupt type */ 1272 irqbit = DEBIread(dev, LP_RDMISC2); 1273 1274 /* check interrupt on counters */ 1275 DEBUG("s626_irq_handler: check counters interrupt %d\n", 1276 irqbit); 1277 1278 if (irqbit & IRQ_COINT1A) { 1279 DEBUG 1280 ("s626_irq_handler: interrupt on counter 1A overflow\n"); 1281 k = &encpriv[0]; 1282 1283 /* clear interrupt capture flag */ 1284 k->ResetCapFlags(dev, k); 1285 } 1286 if (irqbit & IRQ_COINT2A) { 1287 DEBUG 1288 ("s626_irq_handler: interrupt on counter 2A overflow\n"); 1289 k = &encpriv[1]; 1290 1291 /* clear interrupt capture flag */ 1292 k->ResetCapFlags(dev, k); 1293 } 1294 if (irqbit & IRQ_COINT3A) { 1295 DEBUG 1296 ("s626_irq_handler: interrupt on counter 3A overflow\n"); 1297 k = &encpriv[2]; 1298 1299 /* clear interrupt capture flag */ 1300 k->ResetCapFlags(dev, k); 1301 } 1302 if (irqbit & IRQ_COINT1B) { 1303 DEBUG 1304 ("s626_irq_handler: interrupt on counter 1B overflow\n"); 1305 k = &encpriv[3]; 1306 1307 /* clear interrupt capture flag */ 1308 k->ResetCapFlags(dev, k); 1309 } 1310 if (irqbit & IRQ_COINT2B) { 1311 DEBUG 1312 ("s626_irq_handler: interrupt on counter 2B overflow\n"); 1313 k = &encpriv[4]; 1314 1315 /* clear interrupt capture flag */ 1316 k->ResetCapFlags(dev, k); 1317 1318 if (devpriv->ai_convert_count > 0) { 1319 devpriv->ai_convert_count--; 1320 if (devpriv->ai_convert_count == 0) 1321 k->SetEnable(dev, k, CLKENAB_INDEX); 1322 1323 if (cmd->convert_src == TRIG_TIMER) { 1324 DEBUG 1325 ("s626_irq_handler: conver timer trigger!!! %d\n", 1326 devpriv->ai_convert_count); 1327 1328 /* Trigger ADC scan loop start by setting RPS Signal 0. */ 1329 MC_ENABLE(P_MC2, MC2_ADC_RPS); 1330 } 1331 } 1332 } 1333 if (irqbit & IRQ_COINT3B) { 1334 DEBUG 1335 ("s626_irq_handler: interrupt on counter 3B overflow\n"); 1336 k = &encpriv[5]; 1337 1338 /* clear interrupt capture flag */ 1339 k->ResetCapFlags(dev, k); 1340 1341 if (cmd->scan_begin_src == TRIG_TIMER) { 1342 DEBUG 1343 ("s626_irq_handler: scan timer trigger!!!\n"); 1344 1345 /* Trigger ADC scan loop start by setting RPS Signal 0. */ 1346 MC_ENABLE(P_MC2, MC2_ADC_RPS); 1347 } 1348 1349 if (cmd->convert_src == TRIG_TIMER) { 1350 DEBUG 1351 ("s626_irq_handler: convert timer trigger is set\n"); 1352 k = &encpriv[4]; 1353 devpriv->ai_convert_count = cmd->chanlist_len; 1354 k->SetEnable(dev, k, CLKENAB_ALWAYS); 1355 } 1356 } 1357 } 1358 1359 /* enable interrupt */ 1360 writel(irqstatus, devpriv->base_addr + P_IER); 1361 1362 DEBUG("s626_irq_handler: exit interrupt service routine.\n"); 1363 1364 spin_unlock_irqrestore(&dev->spinlock, flags); 1365 return IRQ_HANDLED; 1366} 1367 1368static int s626_detach(struct comedi_device *dev) 1369{ 1370 if (devpriv) { 1371 /* stop ai_command */ 1372 devpriv->ai_cmd_running = 0; 1373 1374 if (devpriv->base_addr) { 1375 /* interrupt mask */ 1376 WR7146(P_IER, 0); /* Disable master interrupt. */ 1377 WR7146(P_ISR, IRQ_GPIO3 | IRQ_RPS1); /* Clear board's IRQ status flag. */ 1378 1379 /* Disable the watchdog timer and battery charger. */ 1380 WriteMISC2(dev, 0); 1381 1382 /* Close all interfaces on 7146 device. */ 1383 WR7146(P_MC1, MC1_SHUTDOWN); 1384 WR7146(P_ACON1, ACON1_BASE); 1385 1386 CloseDMAB(dev, &devpriv->RPSBuf, DMABUF_SIZE); 1387 CloseDMAB(dev, &devpriv->ANABuf, DMABUF_SIZE); 1388 } 1389 1390 if (dev->irq) 1391 free_irq(dev->irq, dev); 1392 1393 if (devpriv->base_addr) 1394 iounmap(devpriv->base_addr); 1395 1396 if (devpriv->pdev) { 1397 if (devpriv->got_regions) 1398 comedi_pci_disable(devpriv->pdev); 1399 pci_dev_put(devpriv->pdev); 1400 } 1401 } 1402 1403 DEBUG("s626_detach: S626 detached!\n"); 1404 1405 return 0; 1406} 1407 1408/* 1409 * this functions build the RPS program for hardware driven acquistion 1410 */ 1411void ResetADC(struct comedi_device *dev, uint8_t * ppl) 1412{ 1413 register uint32_t *pRPS; 1414 uint32_t JmpAdrs; 1415 uint16_t i; 1416 uint16_t n; 1417 uint32_t LocalPPL; 1418 struct comedi_cmd *cmd = &(dev->subdevices->async->cmd); 1419 1420 /* Stop RPS program in case it is currently running. */ 1421 MC_DISABLE(P_MC1, MC1_ERPS1); 1422 1423 /* Set starting logical address to write RPS commands. */ 1424 pRPS = (uint32_t *) devpriv->RPSBuf.LogicalBase; 1425 1426 /* Initialize RPS instruction pointer. */ 1427 WR7146(P_RPSADDR1, (uint32_t) devpriv->RPSBuf.PhysicalBase); 1428 1429 /* Construct RPS program in RPSBuf DMA buffer */ 1430 1431 if (cmd != NULL && cmd->scan_begin_src != TRIG_FOLLOW) { 1432 DEBUG("ResetADC: scan_begin pause inserted\n"); 1433 /* Wait for Start trigger. */ 1434 *pRPS++ = RPS_PAUSE | RPS_SIGADC; 1435 *pRPS++ = RPS_CLRSIGNAL | RPS_SIGADC; 1436 } 1437 1438 /* SAA7146 BUG WORKAROUND Do a dummy DEBI Write. This is necessary 1439 * because the first RPS DEBI Write following a non-RPS DEBI write 1440 * seems to always fail. If we don't do this dummy write, the ADC 1441 * gain might not be set to the value required for the first slot in 1442 * the poll list; the ADC gain would instead remain unchanged from 1443 * the previously programmed value. 1444 */ 1445 *pRPS++ = RPS_LDREG | (P_DEBICMD >> 2); 1446 /* Write DEBI Write command and address to shadow RAM. */ 1447 1448 *pRPS++ = DEBI_CMD_WRWORD | LP_GSEL; 1449 *pRPS++ = RPS_LDREG | (P_DEBIAD >> 2); 1450 /* Write DEBI immediate data to shadow RAM: */ 1451 1452 *pRPS++ = GSEL_BIPOLAR5V; 1453 /* arbitrary immediate data value. */ 1454 1455 *pRPS++ = RPS_CLRSIGNAL | RPS_DEBI; 1456 /* Reset "shadow RAM uploaded" flag. */ 1457 *pRPS++ = RPS_UPLOAD | RPS_DEBI; /* Invoke shadow RAM upload. */ 1458 *pRPS++ = RPS_PAUSE | RPS_DEBI; /* Wait for shadow upload to finish. */ 1459 1460 /* Digitize all slots in the poll list. This is implemented as a 1461 * for loop to limit the slot count to 16 in case the application 1462 * forgot to set the EOPL flag in the final slot. 1463 */ 1464 for (devpriv->AdcItems = 0; devpriv->AdcItems < 16; devpriv->AdcItems++) { 1465 /* Convert application's poll list item to private board class 1466 * format. Each app poll list item is an uint8_t with form 1467 * (EOPL,x,x,RANGE,CHAN<3:0>), where RANGE code indicates 0 = 1468 * +-10V, 1 = +-5V, and EOPL = End of Poll List marker. 1469 */ 1470 LocalPPL = 1471 (*ppl << 8) | (*ppl & 0x10 ? GSEL_BIPOLAR5V : 1472 GSEL_BIPOLAR10V); 1473 1474 /* Switch ADC analog gain. */ 1475 *pRPS++ = RPS_LDREG | (P_DEBICMD >> 2); /* Write DEBI command */ 1476 /* and address to */ 1477 /* shadow RAM. */ 1478 *pRPS++ = DEBI_CMD_WRWORD | LP_GSEL; 1479 *pRPS++ = RPS_LDREG | (P_DEBIAD >> 2); /* Write DEBI */ 1480 /* immediate data to */ 1481 /* shadow RAM. */ 1482 *pRPS++ = LocalPPL; 1483 *pRPS++ = RPS_CLRSIGNAL | RPS_DEBI; /* Reset "shadow RAM uploaded" */ 1484 /* flag. */ 1485 *pRPS++ = RPS_UPLOAD | RPS_DEBI; /* Invoke shadow RAM upload. */ 1486 *pRPS++ = RPS_PAUSE | RPS_DEBI; /* Wait for shadow upload to */ 1487 /* finish. */ 1488 1489 /* Select ADC analog input channel. */ 1490 *pRPS++ = RPS_LDREG | (P_DEBICMD >> 2); 1491 /* Write DEBI command and address to shadow RAM. */ 1492 *pRPS++ = DEBI_CMD_WRWORD | LP_ISEL; 1493 *pRPS++ = RPS_LDREG | (P_DEBIAD >> 2); 1494 /* Write DEBI immediate data to shadow RAM. */ 1495 *pRPS++ = LocalPPL; 1496 *pRPS++ = RPS_CLRSIGNAL | RPS_DEBI; 1497 /* Reset "shadow RAM uploaded" flag. */ 1498 1499 *pRPS++ = RPS_UPLOAD | RPS_DEBI; 1500 /* Invoke shadow RAM upload. */ 1501 1502 *pRPS++ = RPS_PAUSE | RPS_DEBI; 1503 /* Wait for shadow upload to finish. */ 1504 1505 /* Delay at least 10 microseconds for analog input settling. 1506 * Instead of padding with NOPs, we use RPS_JUMP instructions 1507 * here; this allows us to produce a longer delay than is 1508 * possible with NOPs because each RPS_JUMP flushes the RPS' 1509 * instruction prefetch pipeline. 1510 */ 1511 JmpAdrs = 1512 (uint32_t) devpriv->RPSBuf.PhysicalBase + 1513 (uint32_t) ((unsigned long)pRPS - 1514 (unsigned long)devpriv->RPSBuf.LogicalBase); 1515 for (i = 0; i < (10 * RPSCLK_PER_US / 2); i++) { 1516 JmpAdrs += 8; /* Repeat to implement time delay: */ 1517 *pRPS++ = RPS_JUMP; /* Jump to next RPS instruction. */ 1518 *pRPS++ = JmpAdrs; 1519 } 1520 1521 if (cmd != NULL && cmd->convert_src != TRIG_NOW) { 1522 DEBUG("ResetADC: convert pause inserted\n"); 1523 /* Wait for Start trigger. */ 1524 *pRPS++ = RPS_PAUSE | RPS_SIGADC; 1525 *pRPS++ = RPS_CLRSIGNAL | RPS_SIGADC; 1526 } 1527 /* Start ADC by pulsing GPIO1. */ 1528 *pRPS++ = RPS_LDREG | (P_GPIO >> 2); /* Begin ADC Start pulse. */ 1529 *pRPS++ = GPIO_BASE | GPIO1_LO; 1530 *pRPS++ = RPS_NOP; 1531 /* VERSION 2.03 CHANGE: STRETCH OUT ADC START PULSE. */ 1532 *pRPS++ = RPS_LDREG | (P_GPIO >> 2); /* End ADC Start pulse. */ 1533 *pRPS++ = GPIO_BASE | GPIO1_HI; 1534 1535 /* Wait for ADC to complete (GPIO2 is asserted high when ADC not 1536 * busy) and for data from previous conversion to shift into FB 1537 * BUFFER 1 register. 1538 */ 1539 *pRPS++ = RPS_PAUSE | RPS_GPIO2; /* Wait for ADC done. */ 1540 1541 /* Transfer ADC data from FB BUFFER 1 register to DMA buffer. */ 1542 *pRPS++ = RPS_STREG | (BUGFIX_STREG(P_FB_BUFFER1) >> 2); 1543 *pRPS++ = 1544 (uint32_t) devpriv->ANABuf.PhysicalBase + 1545 (devpriv->AdcItems << 2); 1546 1547 /* If this slot's EndOfPollList flag is set, all channels have */ 1548 /* now been processed. */ 1549 if (*ppl++ & EOPL) { 1550 devpriv->AdcItems++; /* Adjust poll list item count. */ 1551 break; /* Exit poll list processing loop. */ 1552 } 1553 } 1554 DEBUG("ResetADC: ADC items %d\n", devpriv->AdcItems); 1555 1556 /* VERSION 2.01 CHANGE: DELAY CHANGED FROM 250NS to 2US. Allow the 1557 * ADC to stabilize for 2 microseconds before starting the final 1558 * (dummy) conversion. This delay is necessary to allow sufficient 1559 * time between last conversion finished and the start of the dummy 1560 * conversion. Without this delay, the last conversion's data value 1561 * is sometimes set to the previous conversion's data value. 1562 */ 1563 for (n = 0; n < (2 * RPSCLK_PER_US); n++) 1564 *pRPS++ = RPS_NOP; 1565 1566 /* Start a dummy conversion to cause the data from the last 1567 * conversion of interest to be shifted in. 1568 */ 1569 *pRPS++ = RPS_LDREG | (P_GPIO >> 2); /* Begin ADC Start pulse. */ 1570 *pRPS++ = GPIO_BASE | GPIO1_LO; 1571 *pRPS++ = RPS_NOP; 1572 /* VERSION 2.03 CHANGE: STRETCH OUT ADC START PULSE. */ 1573 *pRPS++ = RPS_LDREG | (P_GPIO >> 2); /* End ADC Start pulse. */ 1574 *pRPS++ = GPIO_BASE | GPIO1_HI; 1575 1576 /* Wait for the data from the last conversion of interest to arrive 1577 * in FB BUFFER 1 register. 1578 */ 1579 *pRPS++ = RPS_PAUSE | RPS_GPIO2; /* Wait for ADC done. */ 1580 1581 /* Transfer final ADC data from FB BUFFER 1 register to DMA buffer. */ 1582 *pRPS++ = RPS_STREG | (BUGFIX_STREG(P_FB_BUFFER1) >> 2); /* */ 1583 *pRPS++ = 1584 (uint32_t) devpriv->ANABuf.PhysicalBase + (devpriv->AdcItems << 2); 1585 1586 /* Indicate ADC scan loop is finished. */ 1587 /* *pRPS++= RPS_CLRSIGNAL | RPS_SIGADC ; // Signal ReadADC() that scan is done. */ 1588 1589 /* invoke interrupt */ 1590 if (devpriv->ai_cmd_running == 1) { 1591 DEBUG("ResetADC: insert irq in ADC RPS task\n"); 1592 *pRPS++ = RPS_IRQ; 1593 } 1594 /* Restart RPS program at its beginning. */ 1595 *pRPS++ = RPS_JUMP; /* Branch to start of RPS program. */ 1596 *pRPS++ = (uint32_t) devpriv->RPSBuf.PhysicalBase; 1597 1598 /* End of RPS program build */ 1599} 1600 1601/* TO COMPLETE, IF NECESSARY */ 1602static int s626_ai_insn_config(struct comedi_device *dev, 1603 struct comedi_subdevice *s, 1604 struct comedi_insn *insn, unsigned int *data) 1605{ 1606 1607 return -EINVAL; 1608} 1609 1610/* static int s626_ai_rinsn(struct comedi_device *dev,struct comedi_subdevice *s,struct comedi_insn *insn,unsigned int *data) */ 1611/* { */ 1612/* register uint8_t i; */ 1613/* register int32_t *readaddr; */ 1614 1615/* DEBUG("as626_ai_rinsn: ai_rinsn enter\n"); */ 1616 1617/* Trigger ADC scan loop start by setting RPS Signal 0. */ 1618/* MC_ENABLE( P_MC2, MC2_ADC_RPS ); */ 1619 1620/* Wait until ADC scan loop is finished (RPS Signal 0 reset). */ 1621/* while ( MC_TEST( P_MC2, MC2_ADC_RPS ) ); */ 1622 1623/* Init ptr to DMA buffer that holds new ADC data. We skip the 1624 * first uint16_t in the buffer because it contains junk data from 1625 * the final ADC of the previous poll list scan. 1626 */ 1627/* readaddr = (uint32_t *)devpriv->ANABuf.LogicalBase + 1; */ 1628 1629/* Convert ADC data to 16-bit integer values and copy to application buffer. */ 1630/* for ( i = 0; i < devpriv->AdcItems; i++ ) { */ 1631/* *data = s626_ai_reg_to_uint( *readaddr++ ); */ 1632/* DEBUG("s626_ai_rinsn: data %d\n",*data); */ 1633/* data++; */ 1634/* } */ 1635 1636/* DEBUG("s626_ai_rinsn: ai_rinsn escape\n"); */ 1637/* return i; */ 1638/* } */ 1639 1640static int s626_ai_insn_read(struct comedi_device *dev, 1641 struct comedi_subdevice *s, 1642 struct comedi_insn *insn, unsigned int *data) 1643{ 1644 uint16_t chan = CR_CHAN(insn->chanspec); 1645 uint16_t range = CR_RANGE(insn->chanspec); 1646 uint16_t AdcSpec = 0; 1647 uint32_t GpioImage; 1648 int n; 1649 1650 /* interrupt call test */ 1651/* writel(IRQ_GPIO3,devpriv->base_addr+P_PSR); */ 1652 /* Writing a logical 1 into any of the RPS_PSR bits causes the 1653 * corresponding interrupt to be generated if enabled 1654 */ 1655 1656 DEBUG("s626_ai_insn_read: entering\n"); 1657 1658 /* Convert application's ADC specification into form 1659 * appropriate for register programming. 1660 */ 1661 if (range == 0) 1662 AdcSpec = (chan << 8) | (GSEL_BIPOLAR5V); 1663 else 1664 AdcSpec = (chan << 8) | (GSEL_BIPOLAR10V); 1665 1666 /* Switch ADC analog gain. */ 1667 DEBIwrite(dev, LP_GSEL, AdcSpec); /* Set gain. */ 1668 1669 /* Select ADC analog input channel. */ 1670 DEBIwrite(dev, LP_ISEL, AdcSpec); /* Select channel. */ 1671 1672 for (n = 0; n < insn->n; n++) { 1673 1674 /* Delay 10 microseconds for analog input settling. */ 1675 udelay(10); 1676 1677 /* Start ADC by pulsing GPIO1 low. */ 1678 GpioImage = RR7146(P_GPIO); 1679 /* Assert ADC Start command */ 1680 WR7146(P_GPIO, GpioImage & ~GPIO1_HI); 1681 /* and stretch it out. */ 1682 WR7146(P_GPIO, GpioImage & ~GPIO1_HI); 1683 WR7146(P_GPIO, GpioImage & ~GPIO1_HI); 1684 /* Negate ADC Start command. */ 1685 WR7146(P_GPIO, GpioImage | GPIO1_HI); 1686 1687 /* Wait for ADC to complete (GPIO2 is asserted high when */ 1688 /* ADC not busy) and for data from previous conversion to */ 1689 /* shift into FB BUFFER 1 register. */ 1690 1691 /* Wait for ADC done. */ 1692 while (!(RR7146(P_PSR) & PSR_GPIO2)) 1693 ; 1694 1695 /* Fetch ADC data. */ 1696 if (n != 0) 1697 data[n - 1] = s626_ai_reg_to_uint(RR7146(P_FB_BUFFER1)); 1698 1699 /* Allow the ADC to stabilize for 4 microseconds before 1700 * starting the next (final) conversion. This delay is 1701 * necessary to allow sufficient time between last 1702 * conversion finished and the start of the next 1703 * conversion. Without this delay, the last conversion's 1704 * data value is sometimes set to the previous 1705 * conversion's data value. 1706 */ 1707 udelay(4); 1708 } 1709 1710 /* Start a dummy conversion to cause the data from the 1711 * previous conversion to be shifted in. */ 1712 GpioImage = RR7146(P_GPIO); 1713 1714 /* Assert ADC Start command */ 1715 WR7146(P_GPIO, GpioImage & ~GPIO1_HI); 1716 /* and stretch it out. */ 1717 WR7146(P_GPIO, GpioImage & ~GPIO1_HI); 1718 WR7146(P_GPIO, GpioImage & ~GPIO1_HI); 1719 /* Negate ADC Start command. */ 1720 WR7146(P_GPIO, GpioImage | GPIO1_HI); 1721 1722 /* Wait for the data to arrive in FB BUFFER 1 register. */ 1723 1724 /* Wait for ADC done. */ 1725 while (!(RR7146(P_PSR) & PSR_GPIO2)) 1726 ; 1727 1728 /* Fetch ADC data from audio interface's input shift register. */ 1729 1730 /* Fetch ADC data. */ 1731 if (n != 0) 1732 data[n - 1] = s626_ai_reg_to_uint(RR7146(P_FB_BUFFER1)); 1733 1734 DEBUG("s626_ai_insn_read: samples %d, data %d\n", n, data[n - 1]); 1735 1736 return n; 1737} 1738 1739static int s626_ai_load_polllist(uint8_t *ppl, struct comedi_cmd *cmd) 1740{ 1741 1742 int n; 1743 1744 for (n = 0; n < cmd->chanlist_len; n++) { 1745 if (CR_RANGE((cmd->chanlist)[n]) == 0) 1746 ppl[n] = (CR_CHAN((cmd->chanlist)[n])) | (RANGE_5V); 1747 else 1748 ppl[n] = (CR_CHAN((cmd->chanlist)[n])) | (RANGE_10V); 1749 } 1750 if (n != 0) 1751 ppl[n - 1] |= EOPL; 1752 1753 return n; 1754} 1755 1756static int s626_ai_inttrig(struct comedi_device *dev, 1757 struct comedi_subdevice *s, unsigned int trignum) 1758{ 1759 if (trignum != 0) 1760 return -EINVAL; 1761 1762 DEBUG("s626_ai_inttrig: trigger adc start..."); 1763 1764 /* Start executing the RPS program. */ 1765 MC_ENABLE(P_MC1, MC1_ERPS1); 1766 1767 s->async->inttrig = NULL; 1768 1769 DEBUG(" done\n"); 1770 1771 return 1; 1772} 1773 1774/* TO COMPLETE */ 1775static int s626_ai_cmd(struct comedi_device *dev, struct comedi_subdevice *s) 1776{ 1777 1778 uint8_t ppl[16]; 1779 struct comedi_cmd *cmd = &s->async->cmd; 1780 struct enc_private *k; 1781 int tick; 1782 1783 DEBUG("s626_ai_cmd: entering command function\n"); 1784 1785 if (devpriv->ai_cmd_running) { 1786 printk(KERN_ERR "s626_ai_cmd: Another ai_cmd is running %d\n", 1787 dev->minor); 1788 return -EBUSY; 1789 } 1790 /* disable interrupt */ 1791 writel(0, devpriv->base_addr + P_IER); 1792 1793 /* clear interrupt request */ 1794 writel(IRQ_RPS1 | IRQ_GPIO3, devpriv->base_addr + P_ISR); 1795 1796 /* clear any pending interrupt */ 1797 s626_dio_clear_irq(dev); 1798 /* s626_enc_clear_irq(dev); */ 1799 1800 /* reset ai_cmd_running flag */ 1801 devpriv->ai_cmd_running = 0; 1802 1803 /* test if cmd is valid */ 1804 if (cmd == NULL) { 1805 DEBUG("s626_ai_cmd: NULL command\n"); 1806 return -EINVAL; 1807 } else { 1808 DEBUG("s626_ai_cmd: command received!!!\n"); 1809 } 1810 1811 if (dev->irq == 0) { 1812 comedi_error(dev, 1813 "s626_ai_cmd: cannot run command without an irq"); 1814 return -EIO; 1815 } 1816 1817 s626_ai_load_polllist(ppl, cmd); 1818 devpriv->ai_cmd_running = 1; 1819 devpriv->ai_convert_count = 0; 1820 1821 switch (cmd->scan_begin_src) { 1822 case TRIG_FOLLOW: 1823 break; 1824 case TRIG_TIMER: 1825 /* set a conter to generate adc trigger at scan_begin_arg interval */ 1826 k = &encpriv[5]; 1827 tick = s626_ns_to_timer((int *)&cmd->scan_begin_arg, 1828 cmd->flags & TRIG_ROUND_MASK); 1829 1830 /* load timer value and enable interrupt */ 1831 s626_timer_load(dev, k, tick); 1832 k->SetEnable(dev, k, CLKENAB_ALWAYS); 1833 1834 DEBUG("s626_ai_cmd: scan trigger timer is set with value %d\n", 1835 tick); 1836 1837 break; 1838 case TRIG_EXT: 1839 /* set the digital line and interrupt for scan trigger */ 1840 if (cmd->start_src != TRIG_EXT) 1841 s626_dio_set_irq(dev, cmd->scan_begin_arg); 1842 1843 DEBUG("s626_ai_cmd: External scan trigger is set!!!\n"); 1844 1845 break; 1846 } 1847 1848 switch (cmd->convert_src) { 1849 case TRIG_NOW: 1850 break; 1851 case TRIG_TIMER: 1852 /* set a conter to generate adc trigger at convert_arg interval */ 1853 k = &encpriv[4]; 1854 tick = s626_ns_to_timer((int *)&cmd->convert_arg, 1855 cmd->flags & TRIG_ROUND_MASK); 1856 1857 /* load timer value and enable interrupt */ 1858 s626_timer_load(dev, k, tick); 1859 k->SetEnable(dev, k, CLKENAB_INDEX); 1860 1861 DEBUG 1862 ("s626_ai_cmd: convert trigger timer is set with value %d\n", 1863 tick); 1864 break; 1865 case TRIG_EXT: 1866 /* set the digital line and interrupt for convert trigger */ 1867 if (cmd->scan_begin_src != TRIG_EXT 1868 && cmd->start_src == TRIG_EXT) 1869 s626_dio_set_irq(dev, cmd->convert_arg); 1870 1871 DEBUG("s626_ai_cmd: External convert trigger is set!!!\n"); 1872 1873 break; 1874 } 1875 1876 switch (cmd->stop_src) { 1877 case TRIG_COUNT: 1878 /* data arrives as one packet */ 1879 devpriv->ai_sample_count = cmd->stop_arg; 1880 devpriv->ai_continous = 0; 1881 break; 1882 case TRIG_NONE: 1883 /* continous acquisition */ 1884 devpriv->ai_continous = 1; 1885 devpriv->ai_sample_count = 0; 1886 break; 1887 } 1888 1889 ResetADC(dev, ppl); 1890 1891 switch (cmd->start_src) { 1892 case TRIG_NOW: 1893 /* Trigger ADC scan loop start by setting RPS Signal 0. */ 1894 /* MC_ENABLE( P_MC2, MC2_ADC_RPS ); */ 1895 1896 /* Start executing the RPS program. */ 1897 MC_ENABLE(P_MC1, MC1_ERPS1); 1898 1899 DEBUG("s626_ai_cmd: ADC triggered\n"); 1900 s->async->inttrig = NULL; 1901 break; 1902 case TRIG_EXT: 1903 /* configure DIO channel for acquisition trigger */ 1904 s626_dio_set_irq(dev, cmd->start_arg); 1905 1906 DEBUG("s626_ai_cmd: External start trigger is set!!!\n"); 1907 1908 s->async->inttrig = NULL; 1909 break; 1910 case TRIG_INT: 1911 s->async->inttrig = s626_ai_inttrig; 1912 break; 1913 } 1914 1915 /* enable interrupt */ 1916 writel(IRQ_GPIO3 | IRQ_RPS1, devpriv->base_addr + P_IER); 1917 1918 DEBUG("s626_ai_cmd: command function terminated\n"); 1919 1920 return 0; 1921} 1922 1923static int s626_ai_cmdtest(struct comedi_device *dev, 1924 struct comedi_subdevice *s, struct comedi_cmd *cmd) 1925{ 1926 int err = 0; 1927 int tmp; 1928 1929 /* cmdtest tests a particular command to see if it is valid. Using 1930 * the cmdtest ioctl, a user can create a valid cmd and then have it 1931 * executes by the cmd ioctl. 1932 * 1933 * cmdtest returns 1,2,3,4 or 0, depending on which tests the 1934 * command passes. */ 1935 1936 /* step 1: make sure trigger sources are trivially valid */ 1937 1938 tmp = cmd->start_src; 1939 cmd->start_src &= TRIG_NOW | TRIG_INT | TRIG_EXT; 1940 if (!cmd->start_src || tmp != cmd->start_src) 1941 err++; 1942 1943 tmp = cmd->scan_begin_src; 1944 cmd->scan_begin_src &= TRIG_TIMER | TRIG_EXT | TRIG_FOLLOW; 1945 if (!cmd->scan_begin_src || tmp != cmd->scan_begin_src) 1946 err++; 1947 1948 tmp = cmd->convert_src; 1949 cmd->convert_src &= TRIG_TIMER | TRIG_EXT | TRIG_NOW; 1950 if (!cmd->convert_src || tmp != cmd->convert_src) 1951 err++; 1952 1953 tmp = cmd->scan_end_src; 1954 cmd->scan_end_src &= TRIG_COUNT; 1955 if (!cmd->scan_end_src || tmp != cmd->scan_end_src) 1956 err++; 1957 1958 tmp = cmd->stop_src; 1959 cmd->stop_src &= TRIG_COUNT | TRIG_NONE; 1960 if (!cmd->stop_src || tmp != cmd->stop_src) 1961 err++; 1962 1963 if (err) 1964 return 1; 1965 1966 /* step 2: make sure trigger sources are unique and mutually 1967 compatible */ 1968 1969 /* note that mutual compatibility is not an issue here */ 1970 if (cmd->scan_begin_src != TRIG_TIMER && 1971 cmd->scan_begin_src != TRIG_EXT 1972 && cmd->scan_begin_src != TRIG_FOLLOW) 1973 err++; 1974 if (cmd->convert_src != TRIG_TIMER && 1975 cmd->convert_src != TRIG_EXT && cmd->convert_src != TRIG_NOW) 1976 err++; 1977 if (cmd->stop_src != TRIG_COUNT && cmd->stop_src != TRIG_NONE) 1978 err++; 1979 1980 if (err) 1981 return 2; 1982 1983 /* step 3: make sure arguments are trivially compatible */ 1984 1985 if (cmd->start_src != TRIG_EXT && cmd->start_arg != 0) { 1986 cmd->start_arg = 0; 1987 err++; 1988 } 1989 1990 if (cmd->start_src == TRIG_EXT && cmd->start_arg > 39) { 1991 cmd->start_arg = 39; 1992 err++; 1993 } 1994 1995 if (cmd->scan_begin_src == TRIG_EXT && cmd->scan_begin_arg > 39) { 1996 cmd->scan_begin_arg = 39; 1997 err++; 1998 } 1999 2000 if (cmd->convert_src == TRIG_EXT && cmd->convert_arg > 39) { 2001 cmd->convert_arg = 39; 2002 err++; 2003 } 2004#define MAX_SPEED 200000 /* in nanoseconds */ 2005#define MIN_SPEED 2000000000 /* in nanoseconds */ 2006 2007 if (cmd->scan_begin_src == TRIG_TIMER) { 2008 if (cmd->scan_begin_arg < MAX_SPEED) { 2009 cmd->scan_begin_arg = MAX_SPEED; 2010 err++; 2011 } 2012 if (cmd->scan_begin_arg > MIN_SPEED) { 2013 cmd->scan_begin_arg = MIN_SPEED; 2014 err++; 2015 } 2016 } else { 2017 /* external trigger */ 2018 /* should be level/edge, hi/lo specification here */ 2019 /* should specify multiple external triggers */ 2020/* if(cmd->scan_begin_arg>9){ */ 2021/* cmd->scan_begin_arg=9; */ 2022/* err++; */ 2023/* } */ 2024 } 2025 if (cmd->convert_src == TRIG_TIMER) { 2026 if (cmd->convert_arg < MAX_SPEED) { 2027 cmd->convert_arg = MAX_SPEED; 2028 err++; 2029 } 2030 if (cmd->convert_arg > MIN_SPEED) { 2031 cmd->convert_arg = MIN_SPEED; 2032 err++; 2033 } 2034 } else { 2035 /* external trigger */ 2036 /* see above */ 2037/* if(cmd->convert_arg>9){ */ 2038/* cmd->convert_arg=9; */ 2039/* err++; */ 2040/* } */ 2041 } 2042 2043 if (cmd->scan_end_arg != cmd->chanlist_len) { 2044 cmd->scan_end_arg = cmd->chanlist_len; 2045 err++; 2046 } 2047 if (cmd->stop_src == TRIG_COUNT) { 2048 if (cmd->stop_arg > 0x00ffffff) { 2049 cmd->stop_arg = 0x00ffffff; 2050 err++; 2051 } 2052 } else { 2053 /* TRIG_NONE */ 2054 if (cmd->stop_arg != 0) { 2055 cmd->stop_arg = 0; 2056 err++; 2057 } 2058 } 2059 2060 if (err) 2061 return 3; 2062 2063 /* step 4: fix up any arguments */ 2064 2065 if (cmd->scan_begin_src == TRIG_TIMER) { 2066 tmp = cmd->scan_begin_arg; 2067 s626_ns_to_timer((int *)&cmd->scan_begin_arg, 2068 cmd->flags & TRIG_ROUND_MASK); 2069 if (tmp != cmd->scan_begin_arg) 2070 err++; 2071 } 2072 if (cmd->convert_src == TRIG_TIMER) { 2073 tmp = cmd->convert_arg; 2074 s626_ns_to_timer((int *)&cmd->convert_arg, 2075 cmd->flags & TRIG_ROUND_MASK); 2076 if (tmp != cmd->convert_arg) 2077 err++; 2078 if (cmd->scan_begin_src == TRIG_TIMER && 2079 cmd->scan_begin_arg < 2080 cmd->convert_arg * cmd->scan_end_arg) { 2081 cmd->scan_begin_arg = 2082 cmd->convert_arg * cmd->scan_end_arg; 2083 err++; 2084 } 2085 } 2086 2087 if (err) 2088 return 4; 2089 2090 return 0; 2091} 2092 2093static int s626_ai_cancel(struct comedi_device *dev, struct comedi_subdevice *s) 2094{ 2095 /* Stop RPS program in case it is currently running. */ 2096 MC_DISABLE(P_MC1, MC1_ERPS1); 2097 2098 /* disable master interrupt */ 2099 writel(0, devpriv->base_addr + P_IER); 2100 2101 devpriv->ai_cmd_running = 0; 2102 2103 return 0; 2104} 2105 2106/* This function doesn't require a particular form, this is just what 2107 * happens to be used in some of the drivers. It should convert ns 2108 * nanoseconds to a counter value suitable for programming the device. 2109 * Also, it should adjust ns so that it cooresponds to the actual time 2110 * that the device will use. */ 2111static int s626_ns_to_timer(int *nanosec, int round_mode) 2112{ 2113 int divider, base; 2114 2115 base = 500; /* 2MHz internal clock */ 2116 2117 switch (round_mode) { 2118 case TRIG_ROUND_NEAREST: 2119 default: 2120 divider = (*nanosec + base / 2) / base; 2121 break; 2122 case TRIG_ROUND_DOWN: 2123 divider = (*nanosec) / base; 2124 break; 2125 case TRIG_ROUND_UP: 2126 divider = (*nanosec + base - 1) / base; 2127 break; 2128 } 2129 2130 *nanosec = base * divider; 2131 return divider - 1; 2132} 2133 2134static int s626_ao_winsn(struct comedi_device *dev, struct comedi_subdevice *s, 2135 struct comedi_insn *insn, unsigned int *data) 2136{ 2137 2138 int i; 2139 uint16_t chan = CR_CHAN(insn->chanspec); 2140 int16_t dacdata; 2141 2142 for (i = 0; i < insn->n; i++) { 2143 dacdata = (int16_t) data[i]; 2144 devpriv->ao_readback[CR_CHAN(insn->chanspec)] = data[i]; 2145 dacdata -= (0x1fff); 2146 2147 SetDAC(dev, chan, dacdata); 2148 } 2149 2150 return i; 2151} 2152 2153static int s626_ao_rinsn(struct comedi_device *dev, struct comedi_subdevice *s, 2154 struct comedi_insn *insn, unsigned int *data) 2155{ 2156 int i; 2157 2158 for (i = 0; i < insn->n; i++) 2159 data[i] = devpriv->ao_readback[CR_CHAN(insn->chanspec)]; 2160 2161 return i; 2162} 2163 2164/* *************** DIGITAL I/O FUNCTIONS *************** 2165 * All DIO functions address a group of DIO channels by means of 2166 * "group" argument. group may be 0, 1 or 2, which correspond to DIO 2167 * ports A, B and C, respectively. 2168 */ 2169 2170static void s626_dio_init(struct comedi_device *dev) 2171{ 2172 uint16_t group; 2173 struct comedi_subdevice *s; 2174 2175 /* Prepare to treat writes to WRCapSel as capture disables. */ 2176 DEBIwrite(dev, LP_MISC1, MISC1_NOEDCAP); 2177 2178 /* For each group of sixteen channels ... */ 2179 for (group = 0; group < S626_DIO_BANKS; group++) { 2180 s = dev->subdevices + 2 + group; 2181 DEBIwrite(dev, diopriv->WRIntSel, 0); /* Disable all interrupts. */ 2182 DEBIwrite(dev, diopriv->WRCapSel, 0xFFFF); /* Disable all event */ 2183 /* captures. */ 2184 DEBIwrite(dev, diopriv->WREdgSel, 0); /* Init all DIOs to */ 2185 /* default edge */ 2186 /* polarity. */ 2187 DEBIwrite(dev, diopriv->WRDOut, 0); /* Program all outputs */ 2188 /* to inactive state. */ 2189 } 2190 DEBUG("s626_dio_init: DIO initialized\n"); 2191} 2192 2193/* DIO devices are slightly special. Although it is possible to 2194 * implement the insn_read/insn_write interface, it is much more 2195 * useful to applications if you implement the insn_bits interface. 2196 * This allows packed reading/writing of the DIO channels. The comedi 2197 * core can convert between insn_bits and insn_read/write */ 2198 2199static int s626_dio_insn_bits(struct comedi_device *dev, 2200 struct comedi_subdevice *s, 2201 struct comedi_insn *insn, unsigned int *data) 2202{ 2203 2204 /* Length of data must be 2 (mask and new data, see below) */ 2205 if (insn->n == 0) 2206 return 0; 2207 2208 if (insn->n != 2) { 2209 printk 2210 ("comedi%d: s626: s626_dio_insn_bits(): Invalid instruction length\n", 2211 dev->minor); 2212 return -EINVAL; 2213 } 2214 2215 /* 2216 * The insn data consists of a mask in data[0] and the new data in 2217 * data[1]. The mask defines which bits we are concerning about. 2218 * The new data must be anded with the mask. Each channel 2219 * corresponds to a bit. 2220 */ 2221 if (data[0]) { 2222 /* Check if requested ports are configured for output */ 2223 if ((s->io_bits & data[0]) != data[0]) 2224 return -EIO; 2225 2226 s->state &= ~data[0]; 2227 s->state |= data[0] & data[1]; 2228 2229 /* Write out the new digital output lines */ 2230 2231 DEBIwrite(dev, diopriv->WRDOut, s->state); 2232 } 2233 data[1] = DEBIread(dev, diopriv->RDDIn); 2234 2235 return 2; 2236} 2237 2238static int s626_dio_insn_config(struct comedi_device *dev, 2239 struct comedi_subdevice *s, 2240 struct comedi_insn *insn, unsigned int *data) 2241{ 2242 2243 switch (data[0]) { 2244 case INSN_CONFIG_DIO_QUERY: 2245 data[1] = 2246 (s-> 2247 io_bits & (1 << CR_CHAN(insn->chanspec))) ? COMEDI_OUTPUT : 2248 COMEDI_INPUT; 2249 return insn->n; 2250 break; 2251 case COMEDI_INPUT: 2252 s->io_bits &= ~(1 << CR_CHAN(insn->chanspec)); 2253 break; 2254 case COMEDI_OUTPUT: 2255 s->io_bits |= 1 << CR_CHAN(insn->chanspec); 2256 break; 2257 default: 2258 return -EINVAL; 2259 break; 2260 } 2261 DEBIwrite(dev, diopriv->WRDOut, s->io_bits); 2262 2263 return 1; 2264} 2265 2266static int s626_dio_set_irq(struct comedi_device *dev, unsigned int chan) 2267{ 2268 unsigned int group; 2269 unsigned int bitmask; 2270 unsigned int status; 2271 2272 /* select dio bank */ 2273 group = chan / 16; 2274 bitmask = 1 << (chan - (16 * group)); 2275 DEBUG("s626_dio_set_irq: enable interrupt on dio channel %d group %d\n", 2276 chan - (16 * group), group); 2277 2278 /* set channel to capture positive edge */ 2279 status = DEBIread(dev, 2280 ((struct dio_private *)(dev->subdevices + 2 + 2281 group)->private)->RDEdgSel); 2282 DEBIwrite(dev, 2283 ((struct dio_private *)(dev->subdevices + 2 + 2284 group)->private)->WREdgSel, 2285 bitmask | status); 2286 2287 /* enable interrupt on selected channel */ 2288 status = DEBIread(dev, 2289 ((struct dio_private *)(dev->subdevices + 2 + 2290 group)->private)->RDIntSel); 2291 DEBIwrite(dev, 2292 ((struct dio_private *)(dev->subdevices + 2 + 2293 group)->private)->WRIntSel, 2294 bitmask | status); 2295 2296 /* enable edge capture write command */ 2297 DEBIwrite(dev, LP_MISC1, MISC1_EDCAP); 2298 2299 /* enable edge capture on selected channel */ 2300 status = DEBIread(dev, 2301 ((struct dio_private *)(dev->subdevices + 2 + 2302 group)->private)->RDCapSel); 2303 DEBIwrite(dev, 2304 ((struct dio_private *)(dev->subdevices + 2 + 2305 group)->private)->WRCapSel, 2306 bitmask | status); 2307 2308 return 0; 2309} 2310 2311static int s626_dio_reset_irq(struct comedi_device *dev, unsigned int group, 2312 unsigned int mask) 2313{ 2314 DEBUG 2315 ("s626_dio_reset_irq: disable interrupt on dio channel %d group %d\n", 2316 mask, group); 2317 2318 /* disable edge capture write command */ 2319 DEBIwrite(dev, LP_MISC1, MISC1_NOEDCAP); 2320 2321 /* enable edge capture on selected channel */ 2322 DEBIwrite(dev, 2323 ((struct dio_private *)(dev->subdevices + 2 + 2324 group)->private)->WRCapSel, mask); 2325 2326 return 0; 2327} 2328 2329static int s626_dio_clear_irq(struct comedi_device *dev) 2330{ 2331 unsigned int group; 2332 2333 /* disable edge capture write command */ 2334 DEBIwrite(dev, LP_MISC1, MISC1_NOEDCAP); 2335 2336 for (group = 0; group < S626_DIO_BANKS; group++) { 2337 /* clear pending events and interrupt */ 2338 DEBIwrite(dev, 2339 ((struct dio_private *)(dev->subdevices + 2 + 2340 group)->private)->WRCapSel, 2341 0xffff); 2342 } 2343 2344 return 0; 2345} 2346 2347/* Now this function initializes the value of the counter (data[0]) 2348 and set the subdevice. To complete with trigger and interrupt 2349 configuration */ 2350static int s626_enc_insn_config(struct comedi_device *dev, 2351 struct comedi_subdevice *s, 2352 struct comedi_insn *insn, unsigned int *data) 2353{ 2354 uint16_t Setup = (LOADSRC_INDX << BF_LOADSRC) | /* Preload upon */ 2355 /* index. */ 2356 (INDXSRC_SOFT << BF_INDXSRC) | /* Disable hardware index. */ 2357 (CLKSRC_COUNTER << BF_CLKSRC) | /* Operating mode is Counter. */ 2358 (CLKPOL_POS << BF_CLKPOL) | /* Active high clock. */ 2359 /* ( CNTDIR_UP << BF_CLKPOL ) | // Count direction is Down. */ 2360 (CLKMULT_1X << BF_CLKMULT) | /* Clock multiplier is 1x. */ 2361 (CLKENAB_INDEX << BF_CLKENAB); 2362 /* uint16_t DisableIntSrc=TRUE; */ 2363 /* uint32_t Preloadvalue; //Counter initial value */ 2364 uint16_t valueSrclatch = LATCHSRC_AB_READ; 2365 uint16_t enab = CLKENAB_ALWAYS; 2366 struct enc_private *k = &encpriv[CR_CHAN(insn->chanspec)]; 2367 2368 DEBUG("s626_enc_insn_config: encoder config\n"); 2369 2370 /* (data==NULL) ? (Preloadvalue=0) : (Preloadvalue=data[0]); */ 2371 2372 k->SetMode(dev, k, Setup, TRUE); 2373 Preload(dev, k, *(insn->data)); 2374 k->PulseIndex(dev, k); 2375 SetLatchSource(dev, k, valueSrclatch); 2376 k->SetEnable(dev, k, (uint16_t) (enab != 0)); 2377 2378 return insn->n; 2379} 2380 2381static int s626_enc_insn_read(struct comedi_device *dev, 2382 struct comedi_subdevice *s, 2383 struct comedi_insn *insn, unsigned int *data) 2384{ 2385 2386 int n; 2387 struct enc_private *k = &encpriv[CR_CHAN(insn->chanspec)]; 2388 2389 DEBUG("s626_enc_insn_read: encoder read channel %d\n", 2390 CR_CHAN(insn->chanspec)); 2391 2392 for (n = 0; n < insn->n; n++) 2393 data[n] = ReadLatch(dev, k); 2394 2395 DEBUG("s626_enc_insn_read: encoder sample %d\n", data[n]); 2396 2397 return n; 2398} 2399 2400static int s626_enc_insn_write(struct comedi_device *dev, 2401 struct comedi_subdevice *s, 2402 struct comedi_insn *insn, unsigned int *data) 2403{ 2404 2405 struct enc_private *k = &encpriv[CR_CHAN(insn->chanspec)]; 2406 2407 DEBUG("s626_enc_insn_write: encoder write channel %d\n", 2408 CR_CHAN(insn->chanspec)); 2409 2410 /* Set the preload register */ 2411 Preload(dev, k, data[0]); 2412 2413 /* Software index pulse forces the preload register to load */ 2414 /* into the counter */ 2415 k->SetLoadTrig(dev, k, 0); 2416 k->PulseIndex(dev, k); 2417 k->SetLoadTrig(dev, k, 2); 2418 2419 DEBUG("s626_enc_insn_write: End encoder write\n"); 2420 2421 return 1; 2422} 2423 2424static void s626_timer_load(struct comedi_device *dev, struct enc_private *k, 2425 int tick) 2426{ 2427 uint16_t Setup = (LOADSRC_INDX << BF_LOADSRC) | /* Preload upon */ 2428 /* index. */ 2429 (INDXSRC_SOFT << BF_INDXSRC) | /* Disable hardware index. */ 2430 (CLKSRC_TIMER << BF_CLKSRC) | /* Operating mode is Timer. */ 2431 (CLKPOL_POS << BF_CLKPOL) | /* Active high clock. */ 2432 (CNTDIR_DOWN << BF_CLKPOL) | /* Count direction is Down. */ 2433 (CLKMULT_1X << BF_CLKMULT) | /* Clock multiplier is 1x. */ 2434 (CLKENAB_INDEX << BF_CLKENAB); 2435 uint16_t valueSrclatch = LATCHSRC_A_INDXA; 2436 /* uint16_t enab=CLKENAB_ALWAYS; */ 2437 2438 k->SetMode(dev, k, Setup, FALSE); 2439 2440 /* Set the preload register */ 2441 Preload(dev, k, tick); 2442 2443 /* Software index pulse forces the preload register to load */ 2444 /* into the counter */ 2445 k->SetLoadTrig(dev, k, 0); 2446 k->PulseIndex(dev, k); 2447 2448 /* set reload on counter overflow */ 2449 k->SetLoadTrig(dev, k, 1); 2450 2451 /* set interrupt on overflow */ 2452 k->SetIntSrc(dev, k, INTSRC_OVER); 2453 2454 SetLatchSource(dev, k, valueSrclatch); 2455 /* k->SetEnable(dev,k,(uint16_t)(enab != 0)); */ 2456} 2457 2458/* *********** DAC FUNCTIONS *********** */ 2459 2460/* Slot 0 base settings. */ 2461#define VECT0 (XSD2 | RSD3 | SIB_A2) 2462/* Slot 0 always shifts in 0xFF and store it to FB_BUFFER2. */ 2463 2464/* TrimDac LogicalChan-to-PhysicalChan mapping table. */ 2465static uint8_t trimchan[] = { 10, 9, 8, 3, 2, 7, 6, 1, 0, 5, 4 }; 2466 2467/* TrimDac LogicalChan-to-EepromAdrs mapping table. */ 2468static uint8_t trimadrs[] = { 0x40, 0x41, 0x42, 0x50, 0x51, 0x52, 0x53, 0x60, 0x61, 0x62, 0x63 }; 2469 2470static void LoadTrimDACs(struct comedi_device *dev) 2471{ 2472 register uint8_t i; 2473 2474 /* Copy TrimDac setpoint values from EEPROM to TrimDacs. */ 2475 for (i = 0; i < ARRAY_SIZE(trimchan); i++) 2476 WriteTrimDAC(dev, i, I2Cread(dev, trimadrs[i])); 2477} 2478 2479static void WriteTrimDAC(struct comedi_device *dev, uint8_t LogicalChan, 2480 uint8_t DacData) 2481{ 2482 uint32_t chan; 2483 2484 /* Save the new setpoint in case the application needs to read it back later. */ 2485 devpriv->TrimSetpoint[LogicalChan] = (uint8_t) DacData; 2486 2487 /* Map logical channel number to physical channel number. */ 2488 chan = (uint32_t) trimchan[LogicalChan]; 2489 2490 /* Set up TSL2 records for TrimDac write operation. All slots shift 2491 * 0xFF in from pulled-up SD3 so that the end of the slot sequence 2492 * can be detected. 2493 */ 2494 2495 SETVECT(2, XSD2 | XFIFO_1 | WS3); 2496 /* Slot 2: Send high uint8_t to target TrimDac. */ 2497 SETVECT(3, XSD2 | XFIFO_0 | WS3); 2498 /* Slot 3: Send low uint8_t to target TrimDac. */ 2499 SETVECT(4, XSD2 | XFIFO_3 | WS1); 2500 /* Slot 4: Send NOP high uint8_t to DAC0 to keep clock running. */ 2501 SETVECT(5, XSD2 | XFIFO_2 | WS1 | EOS); 2502 /* Slot 5: Send NOP low uint8_t to DAC0. */ 2503 2504 /* Construct and transmit target DAC's serial packet: 2505 * ( 0000 AAAA ), ( DDDD DDDD ),( 0x00 ),( 0x00 ) where A<3:0> is the 2506 * DAC channel's address, and D<7:0> is the DAC setpoint. Append a 2507 * WORD value (that writes a channel 0 NOP command to a non-existent 2508 * main DAC channel) that serves to keep the clock running after the 2509 * packet has been sent to the target DAC. 2510 */ 2511 2512 /* Address the DAC channel within the trimdac device. */ 2513 SendDAC(dev, ((uint32_t) chan << 8) 2514 | (uint32_t) DacData); /* Include DAC setpoint data. */ 2515} 2516 2517/* ************** EEPROM ACCESS FUNCTIONS ************** */ 2518/* Read uint8_t from EEPROM. */ 2519 2520static uint8_t I2Cread(struct comedi_device *dev, uint8_t addr) 2521{ 2522 uint8_t rtnval; 2523 2524 /* Send EEPROM target address. */ 2525 if (I2Chandshake(dev, I2C_B2(I2C_ATTRSTART, I2CW) 2526 /* Byte2 = I2C command: write to I2C EEPROM device. */ 2527 | I2C_B1(I2C_ATTRSTOP, addr) 2528 /* Byte1 = EEPROM internal target address. */ 2529 | I2C_B0(I2C_ATTRNOP, 0))) { /* Byte0 = Not sent. */ 2530 /* Abort function and declare error if handshake failed. */ 2531 DEBUG("I2Cread: error handshake I2Cread a\n"); 2532 return 0; 2533 } 2534 /* Execute EEPROM read. */ 2535 if (I2Chandshake(dev, I2C_B2(I2C_ATTRSTART, I2CR) 2536 2537 /* Byte2 = I2C */ 2538 /* command: read */ 2539 /* from I2C EEPROM */ 2540 /* device. */ 2541 |I2C_B1(I2C_ATTRSTOP, 0) 2542 2543 /* Byte1 receives */ 2544 /* uint8_t from */ 2545 /* EEPROM. */ 2546 |I2C_B0(I2C_ATTRNOP, 0))) { /* Byte0 = Not sent. */ 2547 2548 /* Abort function and declare error if handshake failed. */ 2549 DEBUG("I2Cread: error handshake I2Cread b\n"); 2550 return 0; 2551 } 2552 /* Return copy of EEPROM value. */ 2553 rtnval = (uint8_t) (RR7146(P_I2CCTRL) >> 16); 2554 return rtnval; 2555} 2556 2557static uint32_t I2Chandshake(struct comedi_device *dev, uint32_t val) 2558{ 2559 /* Write I2C command to I2C Transfer Control shadow register. */ 2560 WR7146(P_I2CCTRL, val); 2561 2562 /* Upload I2C shadow registers into working registers and wait for */ 2563 /* upload confirmation. */ 2564 2565 MC_ENABLE(P_MC2, MC2_UPLD_IIC); 2566 while (!MC_TEST(P_MC2, MC2_UPLD_IIC)) 2567 ; 2568 2569 /* Wait until I2C bus transfer is finished or an error occurs. */ 2570 while ((RR7146(P_I2CCTRL) & (I2C_BUSY | I2C_ERR)) == I2C_BUSY) 2571 ; 2572 2573 /* Return non-zero if I2C error occurred. */ 2574 return RR7146(P_I2CCTRL) & I2C_ERR; 2575 2576} 2577 2578/* Private helper function: Write setpoint to an application DAC channel. */ 2579 2580static void SetDAC(struct comedi_device *dev, uint16_t chan, short dacdata) 2581{ 2582 register uint16_t signmask; 2583 register uint32_t WSImage; 2584 2585 /* Adjust DAC data polarity and set up Polarity Control Register */ 2586 /* image. */ 2587 signmask = 1 << chan; 2588 if (dacdata < 0) { 2589 dacdata = -dacdata; 2590 devpriv->Dacpol |= signmask; 2591 } else 2592 devpriv->Dacpol &= ~signmask; 2593 2594 /* Limit DAC setpoint value to valid range. */ 2595 if ((uint16_t) dacdata > 0x1FFF) 2596 dacdata = 0x1FFF; 2597 2598 /* Set up TSL2 records (aka "vectors") for DAC update. Vectors V2 2599 * and V3 transmit the setpoint to the target DAC. V4 and V5 send 2600 * data to a non-existent TrimDac channel just to keep the clock 2601 * running after sending data to the target DAC. This is necessary 2602 * to eliminate the clock glitch that would otherwise occur at the 2603 * end of the target DAC's serial data stream. When the sequence 2604 * restarts at V0 (after executing V5), the gate array automatically 2605 * disables gating for the DAC clock and all DAC chip selects. 2606 */ 2607 2608 WSImage = (chan & 2) ? WS1 : WS2; 2609 /* Choose DAC chip select to be asserted. */ 2610 SETVECT(2, XSD2 | XFIFO_1 | WSImage); 2611 /* Slot 2: Transmit high data byte to target DAC. */ 2612 SETVECT(3, XSD2 | XFIFO_0 | WSImage); 2613 /* Slot 3: Transmit low data byte to target DAC. */ 2614 SETVECT(4, XSD2 | XFIFO_3 | WS3); 2615 /* Slot 4: Transmit to non-existent TrimDac channel to keep clock */ 2616 SETVECT(5, XSD2 | XFIFO_2 | WS3 | EOS); 2617 /* Slot 5: running after writing target DAC's low data byte. */ 2618 2619 /* Construct and transmit target DAC's serial packet: 2620 * ( A10D DDDD ),( DDDD DDDD ),( 0x0F ),( 0x00 ) where A is chan<0>, 2621 * and D<12:0> is the DAC setpoint. Append a WORD value (that writes 2622 * to a non-existent TrimDac channel) that serves to keep the clock 2623 * running after the packet has been sent to the target DAC. 2624 */ 2625 SendDAC(dev, 0x0F000000 2626 /* Continue clock after target DAC data (write to non-existent trimdac). */ 2627 | 0x00004000 2628 /* Address the two main dual-DAC devices (TSL's chip select enables 2629 * target device). */ 2630 | ((uint32_t) (chan & 1) << 15) 2631 /* Address the DAC channel within the device. */ 2632 | (uint32_t) dacdata); /* Include DAC setpoint data. */ 2633 2634} 2635 2636/* Private helper function: Transmit serial data to DAC via Audio 2637 * channel 2. Assumes: (1) TSL2 slot records initialized, and (2) 2638 * Dacpol contains valid target image. 2639 */ 2640 2641static void SendDAC(struct comedi_device *dev, uint32_t val) 2642{ 2643 2644 /* START THE SERIAL CLOCK RUNNING ------------- */ 2645 2646 /* Assert DAC polarity control and enable gating of DAC serial clock 2647 * and audio bit stream signals. At this point in time we must be 2648 * assured of being in time slot 0. If we are not in slot 0, the 2649 * serial clock and audio stream signals will be disabled; this is 2650 * because the following DEBIwrite statement (which enables signals 2651 * to be passed through the gate array) would execute before the 2652 * trailing edge of WS1/WS3 (which turns off the signals), thus 2653 * causing the signals to be inactive during the DAC write. 2654 */ 2655 DEBIwrite(dev, LP_DACPOL, devpriv->Dacpol); 2656 2657 /* TRANSFER OUTPUT DWORD VALUE INTO A2'S OUTPUT FIFO ---------------- */ 2658 2659 /* Copy DAC setpoint value to DAC's output DMA buffer. */ 2660 2661 /* WR7146( (uint32_t)devpriv->pDacWBuf, val ); */ 2662 *devpriv->pDacWBuf = val; 2663 2664 /* enab the output DMA transfer. This will cause the DMAC to copy 2665 * the DAC's data value to A2's output FIFO. The DMA transfer will 2666 * then immediately terminate because the protection address is 2667 * reached upon transfer of the first DWORD value. 2668 */ 2669 MC_ENABLE(P_MC1, MC1_A2OUT); 2670 2671 /* While the DMA transfer is executing ... */ 2672 2673 /* Reset Audio2 output FIFO's underflow flag (along with any other 2674 * FIFO underflow/overflow flags). When set, this flag will 2675 * indicate that we have emerged from slot 0. 2676 */ 2677 WR7146(P_ISR, ISR_AFOU); 2678 2679 /* Wait for the DMA transfer to finish so that there will be data 2680 * available in the FIFO when time slot 1 tries to transfer a DWORD 2681 * from the FIFO to the output buffer register. We test for DMA 2682 * Done by polling the DMAC enable flag; this flag is automatically 2683 * cleared when the transfer has finished. 2684 */ 2685 while ((RR7146(P_MC1) & MC1_A2OUT) != 0) 2686 ; 2687 2688 /* START THE OUTPUT STREAM TO THE TARGET DAC -------------------- */ 2689 2690 /* FIFO data is now available, so we enable execution of time slots 2691 * 1 and higher by clearing the EOS flag in slot 0. Note that SD3 2692 * will be shifted in and stored in FB_BUFFER2 for end-of-slot-list 2693 * detection. 2694 */ 2695 SETVECT(0, XSD2 | RSD3 | SIB_A2); 2696 2697 /* Wait for slot 1 to execute to ensure that the Packet will be 2698 * transmitted. This is detected by polling the Audio2 output FIFO 2699 * underflow flag, which will be set when slot 1 execution has 2700 * finished transferring the DAC's data DWORD from the output FIFO 2701 * to the output buffer register. 2702 */ 2703 while ((RR7146(P_SSR) & SSR_AF2_OUT) == 0) 2704 ; 2705 2706 /* Set up to trap execution at slot 0 when the TSL sequencer cycles 2707 * back to slot 0 after executing the EOS in slot 5. Also, 2708 * simultaneously shift out and in the 0x00 that is ALWAYS the value 2709 * stored in the last byte to be shifted out of the FIFO's DWORD 2710 * buffer register. 2711 */ 2712 SETVECT(0, XSD2 | XFIFO_2 | RSD2 | SIB_A2 | EOS); 2713 2714 /* WAIT FOR THE TRANSACTION TO FINISH ----------------------- */ 2715 2716 /* Wait for the TSL to finish executing all time slots before 2717 * exiting this function. We must do this so that the next DAC 2718 * write doesn't start, thereby enabling clock/chip select signals: 2719 * 2720 * 1. Before the TSL sequence cycles back to slot 0, which disables 2721 * the clock/cs signal gating and traps slot // list execution. 2722 * we have not yet finished slot 5 then the clock/cs signals are 2723 * still gated and we have not finished transmitting the stream. 2724 * 2725 * 2. While slots 2-5 are executing due to a late slot 0 trap. In 2726 * this case, the slot sequence is currently repeating, but with 2727 * clock/cs signals disabled. We must wait for slot 0 to trap 2728 * execution before setting up the next DAC setpoint DMA transfer 2729 * and enabling the clock/cs signals. To detect the end of slot 5, 2730 * we test for the FB_BUFFER2 MSB contents to be equal to 0xFF. If 2731 * the TSL has not yet finished executing slot 5 ... 2732 */ 2733 if ((RR7146(P_FB_BUFFER2) & 0xFF000000) != 0) { 2734 /* The trap was set on time and we are still executing somewhere 2735 * in slots 2-5, so we now wait for slot 0 to execute and trap 2736 * TSL execution. This is detected when FB_BUFFER2 MSB changes 2737 * from 0xFF to 0x00, which slot 0 causes to happen by shifting 2738 * out/in on SD2 the 0x00 that is always referenced by slot 5. 2739 */ 2740 while ((RR7146(P_FB_BUFFER2) & 0xFF000000) != 0) 2741 ; 2742 } 2743 /* Either (1) we were too late setting the slot 0 trap; the TSL 2744 * sequencer restarted slot 0 before we could set the EOS trap flag, 2745 * or (2) we were not late and execution is now trapped at slot 0. 2746 * In either case, we must now change slot 0 so that it will store 2747 * value 0xFF (instead of 0x00) to FB_BUFFER2 next time it executes. 2748 * In order to do this, we reprogram slot 0 so that it will shift in 2749 * SD3, which is driven only by a pull-up resistor. 2750 */ 2751 SETVECT(0, RSD3 | SIB_A2 | EOS); 2752 2753 /* Wait for slot 0 to execute, at which time the TSL is setup for 2754 * the next DAC write. This is detected when FB_BUFFER2 MSB changes 2755 * from 0x00 to 0xFF. 2756 */ 2757 while ((RR7146(P_FB_BUFFER2) & 0xFF000000) == 0) 2758 ; 2759} 2760 2761static void WriteMISC2(struct comedi_device *dev, uint16_t NewImage) 2762{ 2763 DEBIwrite(dev, LP_MISC1, MISC1_WENABLE); /* enab writes to */ 2764 /* MISC2 register. */ 2765 DEBIwrite(dev, LP_WRMISC2, NewImage); /* Write new image to MISC2. */ 2766 DEBIwrite(dev, LP_MISC1, MISC1_WDISABLE); /* Disable writes to MISC2. */ 2767} 2768 2769/* Initialize the DEBI interface for all transfers. */ 2770 2771static uint16_t DEBIread(struct comedi_device *dev, uint16_t addr) 2772{ 2773 uint16_t retval; 2774 2775 /* Set up DEBI control register value in shadow RAM. */ 2776 WR7146(P_DEBICMD, DEBI_CMD_RDWORD | addr); 2777 2778 /* Execute the DEBI transfer. */ 2779 DEBItransfer(dev); 2780 2781 /* Fetch target register value. */ 2782 retval = (uint16_t) RR7146(P_DEBIAD); 2783 2784 /* Return register value. */ 2785 return retval; 2786} 2787 2788/* Execute a DEBI transfer. This must be called from within a */ 2789/* critical section. */ 2790static void DEBItransfer(struct comedi_device *dev) 2791{ 2792 /* Initiate upload of shadow RAM to DEBI control register. */ 2793 MC_ENABLE(P_MC2, MC2_UPLD_DEBI); 2794 2795 /* Wait for completion of upload from shadow RAM to DEBI control */ 2796 /* register. */ 2797 while (!MC_TEST(P_MC2, MC2_UPLD_DEBI)) 2798 ; 2799 2800 /* Wait until DEBI transfer is done. */ 2801 while (RR7146(P_PSR) & PSR_DEBI_S) 2802 ; 2803} 2804 2805/* Write a value to a gate array register. */ 2806static void DEBIwrite(struct comedi_device *dev, uint16_t addr, uint16_t wdata) 2807{ 2808 2809 /* Set up DEBI control register value in shadow RAM. */ 2810 WR7146(P_DEBICMD, DEBI_CMD_WRWORD | addr); 2811 WR7146(P_DEBIAD, wdata); 2812 2813 /* Execute the DEBI transfer. */ 2814 DEBItransfer(dev); 2815} 2816 2817/* Replace the specified bits in a gate array register. Imports: mask 2818 * specifies bits that are to be preserved, wdata is new value to be 2819 * or'd with the masked original. 2820 */ 2821static void DEBIreplace(struct comedi_device *dev, uint16_t addr, uint16_t mask, 2822 uint16_t wdata) 2823{ 2824 2825 /* Copy target gate array register into P_DEBIAD register. */ 2826 WR7146(P_DEBICMD, DEBI_CMD_RDWORD | addr); 2827 /* Set up DEBI control reg value in shadow RAM. */ 2828 DEBItransfer(dev); /* Execute the DEBI Read transfer. */ 2829 2830 /* Write back the modified image. */ 2831 WR7146(P_DEBICMD, DEBI_CMD_WRWORD | addr); 2832 /* Set up DEBI control reg value in shadow RAM. */ 2833 2834 WR7146(P_DEBIAD, wdata | ((uint16_t) RR7146(P_DEBIAD) & mask)); 2835 /* Modify the register image. */ 2836 DEBItransfer(dev); /* Execute the DEBI Write transfer. */ 2837} 2838 2839static void CloseDMAB(struct comedi_device *dev, struct bufferDMA *pdma, 2840 size_t bsize) 2841{ 2842 void *vbptr; 2843 dma_addr_t vpptr; 2844 2845 DEBUG("CloseDMAB: Entering S626DRV_CloseDMAB():\n"); 2846 if (pdma == NULL) 2847 return; 2848 /* find the matching allocation from the board struct */ 2849 2850 vbptr = pdma->LogicalBase; 2851 vpptr = pdma->PhysicalBase; 2852 if (vbptr) { 2853 pci_free_consistent(devpriv->pdev, bsize, vbptr, vpptr); 2854 pdma->LogicalBase = 0; 2855 pdma->PhysicalBase = 0; 2856 2857 DEBUG("CloseDMAB(): Logical=%p, bsize=%d, Physical=0x%x\n", 2858 vbptr, bsize, (uint32_t) vpptr); 2859 } 2860} 2861 2862/* ****** COUNTER FUNCTIONS ******* */ 2863/* All counter functions address a specific counter by means of the 2864 * "Counter" argument, which is a logical counter number. The Counter 2865 * argument may have any of the following legal values: 0=0A, 1=1A, 2866 * 2=2A, 3=0B, 4=1B, 5=2B. 2867 */ 2868 2869/* Forward declarations for functions that are common to both A and B counters: */ 2870 2871/* ****** PRIVATE COUNTER FUNCTIONS ****** */ 2872 2873/* Read a counter's output latch. */ 2874 2875static uint32_t ReadLatch(struct comedi_device *dev, struct enc_private *k) 2876{ 2877 register uint32_t value; 2878 /* DEBUG FIXME DEBUG("ReadLatch: Read Latch enter\n"); */ 2879 2880 /* Latch counts and fetch LSW of latched counts value. */ 2881 value = (uint32_t) DEBIread(dev, k->MyLatchLsw); 2882 2883 /* Fetch MSW of latched counts and combine with LSW. */ 2884 value |= ((uint32_t) DEBIread(dev, k->MyLatchLsw + 2) << 16); 2885 2886 /* DEBUG FIXME DEBUG("ReadLatch: Read Latch exit\n"); */ 2887 2888 /* Return latched counts. */ 2889 return value; 2890} 2891 2892/* Reset a counter's index and overflow event capture flags. */ 2893 2894static void ResetCapFlags_A(struct comedi_device *dev, struct enc_private *k) 2895{ 2896 DEBIreplace(dev, k->MyCRB, (uint16_t) (~CRBMSK_INTCTRL), 2897 CRBMSK_INTRESETCMD | CRBMSK_INTRESET_A); 2898} 2899 2900static void ResetCapFlags_B(struct comedi_device *dev, struct enc_private *k) 2901{ 2902 DEBIreplace(dev, k->MyCRB, (uint16_t) (~CRBMSK_INTCTRL), 2903 CRBMSK_INTRESETCMD | CRBMSK_INTRESET_B); 2904} 2905 2906/* Return counter setup in a format (COUNTER_SETUP) that is consistent */ 2907/* for both A and B counters. */ 2908 2909static uint16_t GetMode_A(struct comedi_device *dev, struct enc_private *k) 2910{ 2911 register uint16_t cra; 2912 register uint16_t crb; 2913 register uint16_t setup; 2914 2915 /* Fetch CRA and CRB register images. */ 2916 cra = DEBIread(dev, k->MyCRA); 2917 crb = DEBIread(dev, k->MyCRB); 2918 2919 /* Populate the standardized counter setup bit fields. Note: */ 2920 /* IndexSrc is restricted to ENC_X or IndxPol. */ 2921 setup = ((cra & STDMSK_LOADSRC) /* LoadSrc = LoadSrcA. */ 2922 |((crb << (STDBIT_LATCHSRC - CRBBIT_LATCHSRC)) & STDMSK_LATCHSRC) /* LatchSrc = LatchSrcA. */ 2923 |((cra << (STDBIT_INTSRC - CRABIT_INTSRC_A)) & STDMSK_INTSRC) /* IntSrc = IntSrcA. */ 2924 |((cra << (STDBIT_INDXSRC - (CRABIT_INDXSRC_A + 1))) & STDMSK_INDXSRC) /* IndxSrc = IndxSrcA<1>. */ 2925 |((cra >> (CRABIT_INDXPOL_A - STDBIT_INDXPOL)) & STDMSK_INDXPOL) /* IndxPol = IndxPolA. */ 2926 |((crb >> (CRBBIT_CLKENAB_A - STDBIT_CLKENAB)) & STDMSK_CLKENAB)); /* ClkEnab = ClkEnabA. */ 2927 2928 /* Adjust mode-dependent parameters. */ 2929 if (cra & (2 << CRABIT_CLKSRC_A)) /* If Timer mode (ClkSrcA<1> == 1): */ 2930 setup |= ((CLKSRC_TIMER << STDBIT_CLKSRC) /* Indicate Timer mode. */ 2931 |((cra << (STDBIT_CLKPOL - CRABIT_CLKSRC_A)) & STDMSK_CLKPOL) /* Set ClkPol to indicate count direction (ClkSrcA<0>). */ 2932 |(MULT_X1 << STDBIT_CLKMULT)); /* ClkMult must be 1x in Timer mode. */ 2933 2934 else /* If Counter mode (ClkSrcA<1> == 0): */ 2935 setup |= ((CLKSRC_COUNTER << STDBIT_CLKSRC) /* Indicate Counter mode. */ 2936 |((cra >> (CRABIT_CLKPOL_A - STDBIT_CLKPOL)) & STDMSK_CLKPOL) /* Pass through ClkPol. */ 2937 |(((cra & CRAMSK_CLKMULT_A) == (MULT_X0 << CRABIT_CLKMULT_A)) ? /* Force ClkMult to 1x if not legal, else pass through. */ 2938 (MULT_X1 << STDBIT_CLKMULT) : 2939 ((cra >> (CRABIT_CLKMULT_A - 2940 STDBIT_CLKMULT)) & STDMSK_CLKMULT))); 2941 2942 /* Return adjusted counter setup. */ 2943 return setup; 2944} 2945 2946static uint16_t GetMode_B(struct comedi_device *dev, struct enc_private *k) 2947{ 2948 register uint16_t cra; 2949 register uint16_t crb; 2950 register uint16_t setup; 2951 2952 /* Fetch CRA and CRB register images. */ 2953 cra = DEBIread(dev, k->MyCRA); 2954 crb = DEBIread(dev, k->MyCRB); 2955 2956 /* Populate the standardized counter setup bit fields. Note: */ 2957 /* IndexSrc is restricted to ENC_X or IndxPol. */ 2958 setup = (((crb << (STDBIT_INTSRC - CRBBIT_INTSRC_B)) & STDMSK_INTSRC) /* IntSrc = IntSrcB. */ 2959 |((crb << (STDBIT_LATCHSRC - CRBBIT_LATCHSRC)) & STDMSK_LATCHSRC) /* LatchSrc = LatchSrcB. */ 2960 |((crb << (STDBIT_LOADSRC - CRBBIT_LOADSRC_B)) & STDMSK_LOADSRC) /* LoadSrc = LoadSrcB. */ 2961 |((crb << (STDBIT_INDXPOL - CRBBIT_INDXPOL_B)) & STDMSK_INDXPOL) /* IndxPol = IndxPolB. */ 2962 |((crb >> (CRBBIT_CLKENAB_B - STDBIT_CLKENAB)) & STDMSK_CLKENAB) /* ClkEnab = ClkEnabB. */ 2963 |((cra >> ((CRABIT_INDXSRC_B + 1) - STDBIT_INDXSRC)) & STDMSK_INDXSRC)); /* IndxSrc = IndxSrcB<1>. */ 2964 2965 /* Adjust mode-dependent parameters. */ 2966 if ((crb & CRBMSK_CLKMULT_B) == (MULT_X0 << CRBBIT_CLKMULT_B)) /* If Extender mode (ClkMultB == MULT_X0): */ 2967 setup |= ((CLKSRC_EXTENDER << STDBIT_CLKSRC) /* Indicate Extender mode. */ 2968 |(MULT_X1 << STDBIT_CLKMULT) /* Indicate multiplier is 1x. */ 2969 |((cra >> (CRABIT_CLKSRC_B - STDBIT_CLKPOL)) & STDMSK_CLKPOL)); /* Set ClkPol equal to Timer count direction (ClkSrcB<0>). */ 2970 2971 else if (cra & (2 << CRABIT_CLKSRC_B)) /* If Timer mode (ClkSrcB<1> == 1): */ 2972 setup |= ((CLKSRC_TIMER << STDBIT_CLKSRC) /* Indicate Timer mode. */ 2973 |(MULT_X1 << STDBIT_CLKMULT) /* Indicate multiplier is 1x. */ 2974 |((cra >> (CRABIT_CLKSRC_B - STDBIT_CLKPOL)) & STDMSK_CLKPOL)); /* Set ClkPol equal to Timer count direction (ClkSrcB<0>). */ 2975 2976 else /* If Counter mode (ClkSrcB<1> == 0): */ 2977 setup |= ((CLKSRC_COUNTER << STDBIT_CLKSRC) /* Indicate Timer mode. */ 2978 |((crb >> (CRBBIT_CLKMULT_B - STDBIT_CLKMULT)) & STDMSK_CLKMULT) /* Clock multiplier is passed through. */ 2979 |((crb << (STDBIT_CLKPOL - CRBBIT_CLKPOL_B)) & STDMSK_CLKPOL)); /* Clock polarity is passed through. */ 2980 2981 /* Return adjusted counter setup. */ 2982 return setup; 2983} 2984 2985/* 2986 * Set the operating mode for the specified counter. The setup 2987 * parameter is treated as a COUNTER_SETUP data type. The following 2988 * parameters are programmable (all other parms are ignored): ClkMult, 2989 * ClkPol, ClkEnab, IndexSrc, IndexPol, LoadSrc. 2990 */ 2991 2992static void SetMode_A(struct comedi_device *dev, struct enc_private *k, 2993 uint16_t Setup, uint16_t DisableIntSrc) 2994{ 2995 register uint16_t cra; 2996 register uint16_t crb; 2997 register uint16_t setup = Setup; /* Cache the Standard Setup. */ 2998 2999 /* Initialize CRA and CRB images. */ 3000 cra = ((setup & CRAMSK_LOADSRC_A) /* Preload trigger is passed through. */ 3001 |((setup & STDMSK_INDXSRC) >> (STDBIT_INDXSRC - (CRABIT_INDXSRC_A + 1)))); /* IndexSrc is restricted to ENC_X or IndxPol. */ 3002 3003 crb = (CRBMSK_INTRESETCMD | CRBMSK_INTRESET_A /* Reset any pending CounterA event captures. */ 3004 | ((setup & STDMSK_CLKENAB) << (CRBBIT_CLKENAB_A - STDBIT_CLKENAB))); /* Clock enable is passed through. */ 3005 3006 /* Force IntSrc to Disabled if DisableIntSrc is asserted. */ 3007 if (!DisableIntSrc) 3008 cra |= ((setup & STDMSK_INTSRC) >> (STDBIT_INTSRC - 3009 CRABIT_INTSRC_A)); 3010 3011 /* Populate all mode-dependent attributes of CRA & CRB images. */ 3012 switch ((setup & STDMSK_CLKSRC) >> STDBIT_CLKSRC) { 3013 case CLKSRC_EXTENDER: /* Extender Mode: Force to Timer mode */ 3014 /* (Extender valid only for B counters). */ 3015 3016 case CLKSRC_TIMER: /* Timer Mode: */ 3017 cra |= ((2 << CRABIT_CLKSRC_A) /* ClkSrcA<1> selects system clock */ 3018 |((setup & STDMSK_CLKPOL) >> (STDBIT_CLKPOL - CRABIT_CLKSRC_A)) /* with count direction (ClkSrcA<0>) obtained from ClkPol. */ 3019 |(1 << CRABIT_CLKPOL_A) /* ClkPolA behaves as always-on clock enable. */ 3020 |(MULT_X1 << CRABIT_CLKMULT_A)); /* ClkMult must be 1x. */ 3021 break; 3022 3023 default: /* Counter Mode: */ 3024 cra |= (CLKSRC_COUNTER /* Select ENC_C and ENC_D as clock/direction inputs. */ 3025 | ((setup & STDMSK_CLKPOL) << (CRABIT_CLKPOL_A - STDBIT_CLKPOL)) /* Clock polarity is passed through. */ 3026 |(((setup & STDMSK_CLKMULT) == (MULT_X0 << STDBIT_CLKMULT)) ? /* Force multiplier to x1 if not legal, otherwise pass through. */ 3027 (MULT_X1 << CRABIT_CLKMULT_A) : 3028 ((setup & STDMSK_CLKMULT) << (CRABIT_CLKMULT_A - 3029 STDBIT_CLKMULT)))); 3030 } 3031 3032 /* Force positive index polarity if IndxSrc is software-driven only, */ 3033 /* otherwise pass it through. */ 3034 if (~setup & STDMSK_INDXSRC) 3035 cra |= ((setup & STDMSK_INDXPOL) << (CRABIT_INDXPOL_A - 3036 STDBIT_INDXPOL)); 3037 3038 /* If IntSrc has been forced to Disabled, update the MISC2 interrupt */ 3039 /* enable mask to indicate the counter interrupt is disabled. */ 3040 if (DisableIntSrc) 3041 devpriv->CounterIntEnabs &= ~k->MyEventBits[3]; 3042 3043 /* While retaining CounterB and LatchSrc configurations, program the */ 3044 /* new counter operating mode. */ 3045 DEBIreplace(dev, k->MyCRA, CRAMSK_INDXSRC_B | CRAMSK_CLKSRC_B, cra); 3046 DEBIreplace(dev, k->MyCRB, 3047 (uint16_t) (~(CRBMSK_INTCTRL | CRBMSK_CLKENAB_A)), crb); 3048} 3049 3050static void SetMode_B(struct comedi_device *dev, struct enc_private *k, 3051 uint16_t Setup, uint16_t DisableIntSrc) 3052{ 3053 register uint16_t cra; 3054 register uint16_t crb; 3055 register uint16_t setup = Setup; /* Cache the Standard Setup. */ 3056 3057 /* Initialize CRA and CRB images. */ 3058 cra = ((setup & STDMSK_INDXSRC) << ((CRABIT_INDXSRC_B + 1) - STDBIT_INDXSRC)); /* IndexSrc field is restricted to ENC_X or IndxPol. */ 3059 3060 crb = (CRBMSK_INTRESETCMD | CRBMSK_INTRESET_B /* Reset event captures and disable interrupts. */ 3061 | ((setup & STDMSK_CLKENAB) << (CRBBIT_CLKENAB_B - STDBIT_CLKENAB)) /* Clock enable is passed through. */ 3062 |((setup & STDMSK_LOADSRC) >> (STDBIT_LOADSRC - CRBBIT_LOADSRC_B))); /* Preload trigger source is passed through. */ 3063 3064 /* Force IntSrc to Disabled if DisableIntSrc is asserted. */ 3065 if (!DisableIntSrc) 3066 crb |= ((setup & STDMSK_INTSRC) >> (STDBIT_INTSRC - 3067 CRBBIT_INTSRC_B)); 3068 3069 /* Populate all mode-dependent attributes of CRA & CRB images. */ 3070 switch ((setup & STDMSK_CLKSRC) >> STDBIT_CLKSRC) { 3071 case CLKSRC_TIMER: /* Timer Mode: */ 3072 cra |= ((2 << CRABIT_CLKSRC_B) /* ClkSrcB<1> selects system clock */ 3073 |((setup & STDMSK_CLKPOL) << (CRABIT_CLKSRC_B - STDBIT_CLKPOL))); /* with direction (ClkSrcB<0>) obtained from ClkPol. */ 3074 crb |= ((1 << CRBBIT_CLKPOL_B) /* ClkPolB behaves as always-on clock enable. */ 3075 |(MULT_X1 << CRBBIT_CLKMULT_B)); /* ClkMultB must be 1x. */ 3076 break; 3077 3078 case CLKSRC_EXTENDER: /* Extender Mode: */ 3079 cra |= ((2 << CRABIT_CLKSRC_B) /* ClkSrcB source is OverflowA (same as "timer") */ 3080 |((setup & STDMSK_CLKPOL) << (CRABIT_CLKSRC_B - STDBIT_CLKPOL))); /* with direction obtained from ClkPol. */ 3081 crb |= ((1 << CRBBIT_CLKPOL_B) /* ClkPolB controls IndexB -- always set to active. */ 3082 |(MULT_X0 << CRBBIT_CLKMULT_B)); /* ClkMultB selects OverflowA as the clock source. */ 3083 break; 3084 3085 default: /* Counter Mode: */ 3086 cra |= (CLKSRC_COUNTER << CRABIT_CLKSRC_B); /* Select ENC_C and ENC_D as clock/direction inputs. */ 3087 crb |= (((setup & STDMSK_CLKPOL) >> (STDBIT_CLKPOL - CRBBIT_CLKPOL_B)) /* ClkPol is passed through. */ 3088 |(((setup & STDMSK_CLKMULT) == (MULT_X0 << STDBIT_CLKMULT)) ? /* Force ClkMult to x1 if not legal, otherwise pass through. */ 3089 (MULT_X1 << CRBBIT_CLKMULT_B) : 3090 ((setup & STDMSK_CLKMULT) << (CRBBIT_CLKMULT_B - 3091 STDBIT_CLKMULT)))); 3092 } 3093 3094 /* Force positive index polarity if IndxSrc is software-driven only, */ 3095 /* otherwise pass it through. */ 3096 if (~setup & STDMSK_INDXSRC) 3097 crb |= ((setup & STDMSK_INDXPOL) >> (STDBIT_INDXPOL - 3098 CRBBIT_INDXPOL_B)); 3099 3100 /* If IntSrc has been forced to Disabled, update the MISC2 interrupt */ 3101 /* enable mask to indicate the counter interrupt is disabled. */ 3102 if (DisableIntSrc) 3103 devpriv->CounterIntEnabs &= ~k->MyEventBits[3]; 3104 3105 /* While retaining CounterA and LatchSrc configurations, program the */ 3106 /* new counter operating mode. */ 3107 DEBIreplace(dev, k->MyCRA, 3108 (uint16_t) (~(CRAMSK_INDXSRC_B | CRAMSK_CLKSRC_B)), cra); 3109 DEBIreplace(dev, k->MyCRB, CRBMSK_CLKENAB_A | CRBMSK_LATCHSRC, crb); 3110} 3111 3112/* Return/set a counter's enable. enab: 0=always enabled, 1=enabled by index. */ 3113 3114static void SetEnable_A(struct comedi_device *dev, struct enc_private *k, 3115 uint16_t enab) 3116{ 3117 DEBUG("SetEnable_A: SetEnable_A enter 3541\n"); 3118 DEBIreplace(dev, k->MyCRB, 3119 (uint16_t) (~(CRBMSK_INTCTRL | CRBMSK_CLKENAB_A)), 3120 (uint16_t) (enab << CRBBIT_CLKENAB_A)); 3121} 3122 3123static void SetEnable_B(struct comedi_device *dev, struct enc_private *k, 3124 uint16_t enab) 3125{ 3126 DEBIreplace(dev, k->MyCRB, 3127 (uint16_t) (~(CRBMSK_INTCTRL | CRBMSK_CLKENAB_B)), 3128 (uint16_t) (enab << CRBBIT_CLKENAB_B)); 3129} 3130 3131static uint16_t GetEnable_A(struct comedi_device *dev, struct enc_private *k) 3132{ 3133 return (DEBIread(dev, k->MyCRB) >> CRBBIT_CLKENAB_A) & 1; 3134} 3135 3136static uint16_t GetEnable_B(struct comedi_device *dev, struct enc_private *k) 3137{ 3138 return (DEBIread(dev, k->MyCRB) >> CRBBIT_CLKENAB_B) & 1; 3139} 3140 3141/* Return/set a counter pair's latch trigger source. 0: On read 3142 * access, 1: A index latches A, 2: B index latches B, 3: A overflow 3143 * latches B. 3144 */ 3145 3146static void SetLatchSource(struct comedi_device *dev, struct enc_private *k, 3147 uint16_t value) 3148{ 3149 DEBUG("SetLatchSource: SetLatchSource enter 3550\n"); 3150 DEBIreplace(dev, k->MyCRB, 3151 (uint16_t) (~(CRBMSK_INTCTRL | CRBMSK_LATCHSRC)), 3152 (uint16_t) (value << CRBBIT_LATCHSRC)); 3153 3154 DEBUG("SetLatchSource: SetLatchSource exit\n"); 3155} 3156 3157/* 3158 * static uint16_t GetLatchSource(struct comedi_device *dev, struct enc_private *k ) 3159 * { 3160 * return ( DEBIread( dev, k->MyCRB) >> CRBBIT_LATCHSRC ) & 3; 3161 * } 3162 */ 3163 3164/* 3165 * Return/set the event that will trigger transfer of the preload 3166 * register into the counter. 0=ThisCntr_Index, 1=ThisCntr_Overflow, 3167 * 2=OverflowA (B counters only), 3=disabled. 3168 */ 3169 3170static void SetLoadTrig_A(struct comedi_device *dev, struct enc_private *k, 3171 uint16_t Trig) 3172{ 3173 DEBIreplace(dev, k->MyCRA, (uint16_t) (~CRAMSK_LOADSRC_A), 3174 (uint16_t) (Trig << CRABIT_LOADSRC_A)); 3175} 3176 3177static void SetLoadTrig_B(struct comedi_device *dev, struct enc_private *k, 3178 uint16_t Trig) 3179{ 3180 DEBIreplace(dev, k->MyCRB, 3181 (uint16_t) (~(CRBMSK_LOADSRC_B | CRBMSK_INTCTRL)), 3182 (uint16_t) (Trig << CRBBIT_LOADSRC_B)); 3183} 3184 3185static uint16_t GetLoadTrig_A(struct comedi_device *dev, struct enc_private *k) 3186{ 3187 return (DEBIread(dev, k->MyCRA) >> CRABIT_LOADSRC_A) & 3; 3188} 3189 3190static uint16_t GetLoadTrig_B(struct comedi_device *dev, struct enc_private *k) 3191{ 3192 return (DEBIread(dev, k->MyCRB) >> CRBBIT_LOADSRC_B) & 3; 3193} 3194 3195/* Return/set counter interrupt source and clear any captured 3196 * index/overflow events. IntSource: 0=Disabled, 1=OverflowOnly, 3197 * 2=IndexOnly, 3=IndexAndOverflow. 3198 */ 3199 3200static void SetIntSrc_A(struct comedi_device *dev, struct enc_private *k, 3201 uint16_t IntSource) 3202{ 3203 /* Reset any pending counter overflow or index captures. */ 3204 DEBIreplace(dev, k->MyCRB, (uint16_t) (~CRBMSK_INTCTRL), 3205 CRBMSK_INTRESETCMD | CRBMSK_INTRESET_A); 3206 3207 /* Program counter interrupt source. */ 3208 DEBIreplace(dev, k->MyCRA, ~CRAMSK_INTSRC_A, 3209 (uint16_t) (IntSource << CRABIT_INTSRC_A)); 3210 3211 /* Update MISC2 interrupt enable mask. */ 3212 devpriv->CounterIntEnabs = 3213 (devpriv->CounterIntEnabs & ~k-> 3214 MyEventBits[3]) | k->MyEventBits[IntSource]; 3215} 3216 3217static void SetIntSrc_B(struct comedi_device *dev, struct enc_private *k, 3218 uint16_t IntSource) 3219{ 3220 uint16_t crb; 3221 3222 /* Cache writeable CRB register image. */ 3223 crb = DEBIread(dev, k->MyCRB) & ~CRBMSK_INTCTRL; 3224 3225 /* Reset any pending counter overflow or index captures. */ 3226 DEBIwrite(dev, k->MyCRB, 3227 (uint16_t) (crb | CRBMSK_INTRESETCMD | CRBMSK_INTRESET_B)); 3228 3229 /* Program counter interrupt source. */ 3230 DEBIwrite(dev, k->MyCRB, 3231 (uint16_t) ((crb & ~CRBMSK_INTSRC_B) | (IntSource << 3232 CRBBIT_INTSRC_B))); 3233 3234 /* Update MISC2 interrupt enable mask. */ 3235 devpriv->CounterIntEnabs = 3236 (devpriv->CounterIntEnabs & ~k-> 3237 MyEventBits[3]) | k->MyEventBits[IntSource]; 3238} 3239 3240static uint16_t GetIntSrc_A(struct comedi_device *dev, struct enc_private *k) 3241{ 3242 return (DEBIread(dev, k->MyCRA) >> CRABIT_INTSRC_A) & 3; 3243} 3244 3245static uint16_t GetIntSrc_B(struct comedi_device *dev, struct enc_private *k) 3246{ 3247 return (DEBIread(dev, k->MyCRB) >> CRBBIT_INTSRC_B) & 3; 3248} 3249 3250/* Return/set the clock multiplier. */ 3251 3252/* static void SetClkMult(struct comedi_device *dev, struct enc_private *k, uint16_t value ) */ 3253/* { */ 3254/* k->SetMode(dev, k, (uint16_t)( ( k->GetMode(dev, k ) & ~STDMSK_CLKMULT ) | ( value << STDBIT_CLKMULT ) ), FALSE ); */ 3255/* } */ 3256 3257/* static uint16_t GetClkMult(struct comedi_device *dev, struct enc_private *k ) */ 3258/* { */ 3259/* return ( k->GetMode(dev, k ) >> STDBIT_CLKMULT ) & 3; */ 3260/* } */ 3261 3262/* Return/set the clock polarity. */ 3263 3264/* static void SetClkPol( struct comedi_device *dev,struct enc_private *k, uint16_t value ) */ 3265/* { */ 3266/* k->SetMode(dev, k, (uint16_t)( ( k->GetMode(dev, k ) & ~STDMSK_CLKPOL ) | ( value << STDBIT_CLKPOL ) ), FALSE ); */ 3267/* } */ 3268 3269/* static uint16_t GetClkPol(struct comedi_device *dev, struct enc_private *k ) */ 3270/* { */ 3271/* return ( k->GetMode(dev, k ) >> STDBIT_CLKPOL ) & 1; */ 3272/* } */ 3273 3274/* Return/set the clock source. */ 3275 3276/* static void SetClkSrc( struct comedi_device *dev,struct enc_private *k, uint16_t value ) */ 3277/* { */ 3278/* k->SetMode(dev, k, (uint16_t)( ( k->GetMode(dev, k ) & ~STDMSK_CLKSRC ) | ( value << STDBIT_CLKSRC ) ), FALSE ); */ 3279/* } */ 3280 3281/* static uint16_t GetClkSrc( struct comedi_device *dev,struct enc_private *k ) */ 3282/* { */ 3283/* return ( k->GetMode(dev, k ) >> STDBIT_CLKSRC ) & 3; */ 3284/* } */ 3285 3286/* Return/set the index polarity. */ 3287 3288/* static void SetIndexPol(struct comedi_device *dev, struct enc_private *k, uint16_t value ) */ 3289/* { */ 3290/* k->SetMode(dev, k, (uint16_t)( ( k->GetMode(dev, k ) & ~STDMSK_INDXPOL ) | ( (value != 0) << STDBIT_INDXPOL ) ), FALSE ); */ 3291/* } */ 3292 3293/* static uint16_t GetIndexPol(struct comedi_device *dev, struct enc_private *k ) */ 3294/* { */ 3295/* return ( k->GetMode(dev, k ) >> STDBIT_INDXPOL ) & 1; */ 3296/* } */ 3297 3298/* Return/set the index source. */ 3299 3300/* static void SetIndexSrc(struct comedi_device *dev, struct enc_private *k, uint16_t value ) */ 3301/* { */ 3302/* DEBUG("SetIndexSrc: set index src enter 3700\n"); */ 3303/* k->SetMode(dev, k, (uint16_t)( ( k->GetMode(dev, k ) & ~STDMSK_INDXSRC ) | ( (value != 0) << STDBIT_INDXSRC ) ), FALSE ); */ 3304/* } */ 3305 3306/* static uint16_t GetIndexSrc(struct comedi_device *dev, struct enc_private *k ) */ 3307/* { */ 3308/* return ( k->GetMode(dev, k ) >> STDBIT_INDXSRC ) & 1; */ 3309/* } */ 3310 3311/* Generate an index pulse. */ 3312 3313static void PulseIndex_A(struct comedi_device *dev, struct enc_private *k) 3314{ 3315 register uint16_t cra; 3316 3317 DEBUG("PulseIndex_A: pulse index enter\n"); 3318 3319 cra = DEBIread(dev, k->MyCRA); /* Pulse index. */ 3320 DEBIwrite(dev, k->MyCRA, (uint16_t) (cra ^ CRAMSK_INDXPOL_A)); 3321 DEBUG("PulseIndex_A: pulse index step1\n"); 3322 DEBIwrite(dev, k->MyCRA, cra); 3323} 3324 3325static void PulseIndex_B(struct comedi_device *dev, struct enc_private *k) 3326{ 3327 register uint16_t crb; 3328 3329 crb = DEBIread(dev, k->MyCRB) & ~CRBMSK_INTCTRL; /* Pulse index. */ 3330 DEBIwrite(dev, k->MyCRB, (uint16_t) (crb ^ CRBMSK_INDXPOL_B)); 3331 DEBIwrite(dev, k->MyCRB, crb); 3332} 3333 3334/* Write value into counter preload register. */ 3335 3336static void Preload(struct comedi_device *dev, struct enc_private *k, 3337 uint32_t value) 3338{ 3339 DEBUG("Preload: preload enter\n"); 3340 DEBIwrite(dev, (uint16_t) (k->MyLatchLsw), (uint16_t) value); /* Write value to preload register. */ 3341 DEBUG("Preload: preload step 1\n"); 3342 DEBIwrite(dev, (uint16_t) (k->MyLatchLsw + 2), 3343 (uint16_t) (value >> 16)); 3344} 3345 3346static void CountersInit(struct comedi_device *dev) 3347{ 3348 int chan; 3349 struct enc_private *k; 3350 uint16_t Setup = (LOADSRC_INDX << BF_LOADSRC) | /* Preload upon */ 3351 /* index. */ 3352 (INDXSRC_SOFT << BF_INDXSRC) | /* Disable hardware index. */ 3353 (CLKSRC_COUNTER << BF_CLKSRC) | /* Operating mode is counter. */ 3354 (CLKPOL_POS << BF_CLKPOL) | /* Active high clock. */ 3355 (CNTDIR_UP << BF_CLKPOL) | /* Count direction is up. */ 3356 (CLKMULT_1X << BF_CLKMULT) | /* Clock multiplier is 1x. */ 3357 (CLKENAB_INDEX << BF_CLKENAB); /* Enabled by index */ 3358 3359 /* Disable all counter interrupts and clear any captured counter events. */ 3360 for (chan = 0; chan < S626_ENCODER_CHANNELS; chan++) { 3361 k = &encpriv[chan]; 3362 k->SetMode(dev, k, Setup, TRUE); 3363 k->SetIntSrc(dev, k, 0); 3364 k->ResetCapFlags(dev, k); 3365 k->SetEnable(dev, k, CLKENAB_ALWAYS); 3366 } 3367 DEBUG("CountersInit: counters initialized\n"); 3368 3369} 3370