2 comedi/drivers/ni_labpc.c
3 Driver for National Instruments Lab-PC series boards and compatibles
4 Copyright (C) 2001, 2002, 2003 Frank Mori Hess <fmhess@users.sourceforge.net>
6 This program is free software; you can redistribute it and/or modify
7 it under the terms of the GNU General Public License as published by
8 the Free Software Foundation; either version 2 of the License, or
9 (at your option) any later version.
11 This program is distributed in the hope that it will be useful,
12 but WITHOUT ANY WARRANTY; without even the implied warranty of
13 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14 GNU General Public License for more details.
16 You should have received a copy of the GNU General Public License
17 along with this program; if not, write to the Free Software
18 Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
20 ************************************************************************
24 Description: National Instruments Lab-PC (& compatibles)
25 Author: Frank Mori Hess <fmhess@users.sourceforge.net>
26 Devices: [National Instruments] Lab-PC-1200 (labpc-1200),
27 Lab-PC-1200AI (labpc-1200ai), Lab-PC+ (lab-pc+), PCI-1200 (ni_labpc)
30 Tested with lab-pc-1200. For the older Lab-PC+, not all input ranges
31 and analog references will work, the available ranges/arefs will
32 depend on how you have configured the jumpers on your board
33 (see your owner's manual).
35 Kernel-level ISA plug-and-play support for the lab-pc-1200
37 yet been added to the driver, mainly due to the fact that
38 I don't know the device id numbers. If you have one
40 please file a bug report at http://comedi.org/
41 so I can get the necessary information from you.
43 The 1200 series boards have onboard calibration dacs for correcting
44 analog input/output offsets and gains. The proper settings for these
45 caldacs are stored on the board's eeprom. To read the caldac values
46 from the eeprom and store them into a file that can be then be used by
47 comedilib, use the comedi_calibrate program.
49 Configuration options - ISA boards:
50 [0] - I/O port base address
51 [1] - IRQ (optional, required for timed or externally triggered conversions)
52 [2] - DMA channel (optional)
54 Configuration options - PCI boards:
58 The Lab-pc+ has quirky chanlist requirements
59 when scanning multiple channels. Multiple channel scan
60 sequence must start at highest channel, then decrement down to
61 channel 0. The rest of the cards can scan down like lab-pc+ or scan
62 up from channel zero. Chanlists consisting of all one channel
63 are also legal, and allow you to pace conversions in bursts.
70 341309a (labpc-1200 register manual)
76 #include <linux/interrupt.h>
77 #include <linux/slab.h>
79 #include "../comedidev.h"
81 #include <linux/delay.h>
87 #include "comedi_fc.h"
90 #define DRV_NAME "ni_labpc"
92 /* size of io region used by board */
94 /* 2 MHz master clock */
95 #define LABPC_TIMER_BASE 500
97 /* Registers for the lab-pc+ */
99 /* write-only registers */
100 #define COMMAND1_REG 0x0
101 #define ADC_GAIN_MASK (0x7 << 4)
102 #define ADC_CHAN_BITS(x) ((x) & 0x7)
103 /* enables multi channel scans */
104 #define ADC_SCAN_EN_BIT 0x80
105 #define COMMAND2_REG 0x1
106 /* enable pretriggering (used in conjunction with SWTRIG) */
107 #define PRETRIG_BIT 0x1
108 /* enable paced conversions on external trigger */
109 #define HWTRIG_BIT 0x2
110 /* enable paced conversions */
111 #define SWTRIG_BIT 0x4
112 /* use two cascaded counters for pacing */
113 #define CASCADE_BIT 0x8
114 #define DAC_PACED_BIT(channel) (0x40 << ((channel) & 0x1))
115 #define COMMAND3_REG 0x2
116 /* enable dma transfers */
117 #define DMA_EN_BIT 0x1
118 /* enable interrupts for 8255 */
119 #define DIO_INTR_EN_BIT 0x2
120 /* enable dma terminal count interrupt */
121 #define DMATC_INTR_EN_BIT 0x4
122 /* enable timer interrupt */
123 #define TIMER_INTR_EN_BIT 0x8
124 /* enable error interrupt */
125 #define ERR_INTR_EN_BIT 0x10
126 /* enable fifo not empty interrupt */
127 #define ADC_FNE_INTR_EN_BIT 0x20
128 #define ADC_CONVERT_REG 0x3
129 #define DAC_LSB_REG(channel) (0x4 + 2 * ((channel) & 0x1))
130 #define DAC_MSB_REG(channel) (0x5 + 2 * ((channel) & 0x1))
131 #define ADC_CLEAR_REG 0x8
132 #define DMATC_CLEAR_REG 0xa
133 #define TIMER_CLEAR_REG 0xc
134 /* 1200 boards only */
135 #define COMMAND6_REG 0xe
136 /* select ground or common-mode reference */
137 #define ADC_COMMON_BIT 0x1
139 #define ADC_UNIP_BIT 0x2
141 #define DAC_UNIP_BIT(channel) (0x4 << ((channel) & 0x1))
142 /* enable fifo half full interrupt */
143 #define ADC_FHF_INTR_EN_BIT 0x20
144 /* enable interrupt on end of hardware count */
145 #define A1_INTR_EN_BIT 0x40
146 /* scan up from channel zero instead of down to zero */
147 #define ADC_SCAN_UP_BIT 0x80
148 #define COMMAND4_REG 0xf
149 /* enables 'interval' scanning */
150 #define INTERVAL_SCAN_EN_BIT 0x1
151 /* enables external signal on counter b1 output to trigger scan */
152 #define EXT_SCAN_EN_BIT 0x2
153 /* chooses direction (output or input) for EXTCONV* line */
154 #define EXT_CONVERT_OUT_BIT 0x4
155 /* chooses differential inputs for adc (in conjunction with board jumper) */
156 #define ADC_DIFF_BIT 0x8
157 #define EXT_CONVERT_DISABLE_BIT 0x10
158 /* 1200 boards only, calibration stuff */
159 #define COMMAND5_REG 0x1c
160 /* enable eeprom for write */
161 #define EEPROM_WRITE_UNPROTECT_BIT 0x4
162 /* enable dithering */
163 #define DITHER_EN_BIT 0x8
164 /* load calibration dac */
165 #define CALDAC_LOAD_BIT 0x10
166 /* serial clock - rising edge writes, falling edge reads */
167 #define SCLOCK_BIT 0x20
168 /* serial data bit for writing to eeprom or calibration dacs */
169 #define SDATA_BIT 0x40
170 /* enable eeprom for read/write */
171 #define EEPROM_EN_BIT 0x80
172 #define INTERVAL_COUNT_REG 0x1e
173 #define INTERVAL_LOAD_REG 0x1f
174 #define INTERVAL_LOAD_BITS 0x1
176 /* read-only registers */
177 #define STATUS1_REG 0x0
178 /* data is available in fifo */
179 #define DATA_AVAIL_BIT 0x1
180 /* overrun has occurred */
181 #define OVERRUN_BIT 0x2
183 #define OVERFLOW_BIT 0x4
184 /* timer interrupt has occurred */
185 #define TIMER_BIT 0x8
186 /* dma terminal count has occurred */
187 #define DMATC_BIT 0x10
188 /* external trigger has occurred */
189 #define EXT_TRIG_BIT 0x40
190 /* 1200 boards only */
191 #define STATUS2_REG 0x1d
192 /* programmable eeprom serial output */
193 #define EEPROM_OUT_BIT 0x1
194 /* counter A1 terminal count */
195 #define A1_TC_BIT 0x2
196 /* fifo not half full */
198 #define ADC_FIFO_REG 0xa
200 #define DIO_BASE_REG 0x10
201 #define COUNTER_A_BASE_REG 0x14
202 #define COUNTER_A_CONTROL_REG (COUNTER_A_BASE_REG + 0x3)
203 /* check modes put conversion pacer output in harmless state (a0 mode 2) */
204 #define INIT_A0_BITS 0x14
205 /* put hardware conversion counter output in harmless state (a1 mode 0) */
206 #define INIT_A1_BITS 0x70
207 #define COUNTER_B_BASE_REG 0x18
211 MODE_SINGLE_CHAN_INTERVAL
,
216 static int labpc_cancel(struct comedi_device
*dev
, struct comedi_subdevice
*s
);
217 static irqreturn_t
labpc_interrupt(int irq
, void *d
);
218 static int labpc_drain_fifo(struct comedi_device
*dev
);
219 #ifdef CONFIG_ISA_DMA_API
220 static void labpc_drain_dma(struct comedi_device
*dev
);
221 static void handle_isa_dma(struct comedi_device
*dev
);
223 static void labpc_drain_dregs(struct comedi_device
*dev
);
224 static int labpc_ai_cmdtest(struct comedi_device
*dev
,
225 struct comedi_subdevice
*s
, struct comedi_cmd
*cmd
);
226 static int labpc_ai_cmd(struct comedi_device
*dev
, struct comedi_subdevice
*s
);
227 static int labpc_ai_rinsn(struct comedi_device
*dev
, struct comedi_subdevice
*s
,
228 struct comedi_insn
*insn
, unsigned int *data
);
229 static int labpc_ao_winsn(struct comedi_device
*dev
, struct comedi_subdevice
*s
,
230 struct comedi_insn
*insn
, unsigned int *data
);
231 static int labpc_ao_rinsn(struct comedi_device
*dev
, struct comedi_subdevice
*s
,
232 struct comedi_insn
*insn
, unsigned int *data
);
233 static int labpc_calib_read_insn(struct comedi_device
*dev
,
234 struct comedi_subdevice
*s
,
235 struct comedi_insn
*insn
, unsigned int *data
);
236 static int labpc_calib_write_insn(struct comedi_device
*dev
,
237 struct comedi_subdevice
*s
,
238 struct comedi_insn
*insn
, unsigned int *data
);
239 static int labpc_eeprom_read_insn(struct comedi_device
*dev
,
240 struct comedi_subdevice
*s
,
241 struct comedi_insn
*insn
, unsigned int *data
);
242 static int labpc_eeprom_write_insn(struct comedi_device
*dev
,
243 struct comedi_subdevice
*s
,
244 struct comedi_insn
*insn
,
246 static void labpc_adc_timing(struct comedi_device
*dev
, struct comedi_cmd
*cmd
,
247 enum scan_mode scan_mode
);
248 #ifdef CONFIG_ISA_DMA_API
249 static unsigned int labpc_suggest_transfer_size(const struct comedi_cmd
*cmd
);
251 static int labpc_dio_mem_callback(int dir
, int port
, int data
,
253 static void labpc_serial_out(struct comedi_device
*dev
, unsigned int value
,
254 unsigned int num_bits
);
255 static unsigned int labpc_serial_in(struct comedi_device
*dev
);
256 static unsigned int labpc_eeprom_read(struct comedi_device
*dev
,
257 unsigned int address
);
258 static unsigned int labpc_eeprom_read_status(struct comedi_device
*dev
);
259 static int labpc_eeprom_write(struct comedi_device
*dev
,
260 unsigned int address
,
262 static void write_caldac(struct comedi_device
*dev
, unsigned int channel
,
265 /* analog input ranges */
266 #define NUM_LABPC_PLUS_AI_RANGES 16
267 /* indicates unipolar ranges */
268 static const int labpc_plus_is_unipolar
[NUM_LABPC_PLUS_AI_RANGES
] = {
287 /* map range index to gain bits */
288 static const int labpc_plus_ai_gain_bits
[NUM_LABPC_PLUS_AI_RANGES
] = {
307 static const struct comedi_lrange range_labpc_plus_ai
= {
308 NUM_LABPC_PLUS_AI_RANGES
,
329 #define NUM_LABPC_1200_AI_RANGES 14
330 /* indicates unipolar ranges */
331 const int labpc_1200_is_unipolar
[NUM_LABPC_1200_AI_RANGES
] = {
347 EXPORT_SYMBOL_GPL(labpc_1200_is_unipolar
);
349 /* map range index to gain bits */
350 const int labpc_1200_ai_gain_bits
[NUM_LABPC_1200_AI_RANGES
] = {
366 EXPORT_SYMBOL_GPL(labpc_1200_ai_gain_bits
);
368 const struct comedi_lrange range_labpc_1200_ai
= {
369 NUM_LABPC_1200_AI_RANGES
,
387 EXPORT_SYMBOL_GPL(range_labpc_1200_ai
);
389 /* analog output ranges */
390 #define AO_RANGE_IS_UNIPOLAR 0x1
391 static const struct comedi_lrange range_labpc_ao
= {
399 /* functions that do inb/outb and readb/writeb so we can use
400 * function pointers to decide which to use */
401 static inline unsigned int labpc_inb(unsigned long address
)
406 static inline void labpc_outb(unsigned int byte
, unsigned long address
)
411 static inline unsigned int labpc_readb(unsigned long address
)
413 return readb((void __iomem
*)address
);
416 static inline void labpc_writeb(unsigned int byte
, unsigned long address
)
418 writeb(byte
, (void __iomem
*)address
);
421 static const struct labpc_board_struct labpc_boards
[] = {
423 .name
= "lab-pc-1200",
425 .bustype
= isa_bustype
,
426 .register_layout
= labpc_1200_layout
,
428 .ai_range_table
= &range_labpc_1200_ai
,
429 .ai_range_code
= labpc_1200_ai_gain_bits
,
430 .ai_range_is_unipolar
= labpc_1200_is_unipolar
,
432 .memory_mapped_io
= 0,
435 .name
= "lab-pc-1200ai",
437 .bustype
= isa_bustype
,
438 .register_layout
= labpc_1200_layout
,
440 .ai_range_table
= &range_labpc_1200_ai
,
441 .ai_range_code
= labpc_1200_ai_gain_bits
,
442 .ai_range_is_unipolar
= labpc_1200_is_unipolar
,
444 .memory_mapped_io
= 0,
449 .bustype
= isa_bustype
,
450 .register_layout
= labpc_plus_layout
,
452 .ai_range_table
= &range_labpc_plus_ai
,
453 .ai_range_code
= labpc_plus_ai_gain_bits
,
454 .ai_range_is_unipolar
= labpc_plus_is_unipolar
,
456 .memory_mapped_io
= 0,
458 #ifdef CONFIG_COMEDI_PCI_DRIVERS
463 .bustype
= pci_bustype
,
464 .register_layout
= labpc_1200_layout
,
466 .ai_range_table
= &range_labpc_1200_ai
,
467 .ai_range_code
= labpc_1200_ai_gain_bits
,
468 .ai_range_is_unipolar
= labpc_1200_is_unipolar
,
470 .memory_mapped_io
= 1,
472 /* dummy entry so pci board works when comedi_config is passed driver name */
475 .bustype
= pci_bustype
,
481 * Useful for shorthand access to the particular board structure
483 #define thisboard ((struct labpc_board_struct *)dev->board_ptr)
485 /* size in bytes of dma buffer */
486 static const int dma_buffer_size
= 0xff00;
487 /* 2 bytes per sample */
488 static const int sample_size
= 2;
490 static inline int labpc_counter_load(struct comedi_device
*dev
,
491 unsigned long base_address
,
492 unsigned int counter_number
,
493 unsigned int count
, unsigned int mode
)
495 if (thisboard
->memory_mapped_io
)
496 return i8254_mm_load((void __iomem
*)base_address
, 0,
497 counter_number
, count
, mode
);
499 return i8254_load(base_address
, 0, counter_number
, count
, mode
);
502 int labpc_common_attach(struct comedi_device
*dev
, unsigned long iobase
,
503 unsigned int irq
, unsigned int dma_chan
)
505 struct labpc_private
*devpriv
= dev
->private;
506 struct comedi_subdevice
*s
;
508 unsigned long isr_flags
;
509 #ifdef CONFIG_ISA_DMA_API
510 unsigned long dma_flags
;
515 dev_info(dev
->class_dev
, "ni_labpc: %s\n", thisboard
->name
);
517 dev_err(dev
->class_dev
, "io base address is zero!\n");
520 /* request io regions for isa boards */
521 if (thisboard
->bustype
== isa_bustype
) {
522 /* check if io addresses are available */
523 if (!request_region(iobase
, LABPC_SIZE
, DRV_NAME
)) {
524 dev_err(dev
->class_dev
, "I/O port conflict\n");
528 dev
->iobase
= iobase
;
530 if (thisboard
->memory_mapped_io
) {
531 devpriv
->read_byte
= labpc_readb
;
532 devpriv
->write_byte
= labpc_writeb
;
534 devpriv
->read_byte
= labpc_inb
;
535 devpriv
->write_byte
= labpc_outb
;
537 /* initialize board's command registers */
538 devpriv
->write_byte(devpriv
->command1_bits
, dev
->iobase
+ COMMAND1_REG
);
539 devpriv
->write_byte(devpriv
->command2_bits
, dev
->iobase
+ COMMAND2_REG
);
540 devpriv
->write_byte(devpriv
->command3_bits
, dev
->iobase
+ COMMAND3_REG
);
541 devpriv
->write_byte(devpriv
->command4_bits
, dev
->iobase
+ COMMAND4_REG
);
542 if (thisboard
->register_layout
== labpc_1200_layout
) {
543 devpriv
->write_byte(devpriv
->command5_bits
,
544 dev
->iobase
+ COMMAND5_REG
);
545 devpriv
->write_byte(devpriv
->command6_bits
,
546 dev
->iobase
+ COMMAND6_REG
);
552 if (thisboard
->bustype
== pci_bustype
553 || thisboard
->bustype
== pcmcia_bustype
)
554 isr_flags
|= IRQF_SHARED
;
555 if (request_irq(irq
, labpc_interrupt
, isr_flags
,
557 dev_err(dev
->class_dev
, "unable to allocate irq %u\n",
564 #ifdef CONFIG_ISA_DMA_API
565 /* grab dma channel */
567 dev_err(dev
->class_dev
, "invalid dma channel %u\n", dma_chan
);
569 } else if (dma_chan
) {
570 /* allocate dma buffer */
571 devpriv
->dma_buffer
=
572 kmalloc(dma_buffer_size
, GFP_KERNEL
| GFP_DMA
);
573 if (devpriv
->dma_buffer
== NULL
) {
574 dev_err(dev
->class_dev
,
575 "failed to allocate dma buffer\n");
578 if (request_dma(dma_chan
, DRV_NAME
)) {
579 dev_err(dev
->class_dev
,
580 "failed to allocate dma channel %u\n",
584 devpriv
->dma_chan
= dma_chan
;
585 dma_flags
= claim_dma_lock();
586 disable_dma(devpriv
->dma_chan
);
587 set_dma_mode(devpriv
->dma_chan
, DMA_MODE_READ
);
588 release_dma_lock(dma_flags
);
592 dev
->board_name
= thisboard
->name
;
594 ret
= comedi_alloc_subdevices(dev
, 5);
598 /* analog input subdevice */
599 s
= &dev
->subdevices
[0];
600 dev
->read_subdev
= s
;
601 s
->type
= COMEDI_SUBD_AI
;
603 SDF_READABLE
| SDF_GROUND
| SDF_COMMON
| SDF_DIFF
| SDF_CMD_READ
;
606 s
->maxdata
= (1 << 12) - 1; /* 12 bit resolution */
607 s
->range_table
= thisboard
->ai_range_table
;
608 s
->do_cmd
= labpc_ai_cmd
;
609 s
->do_cmdtest
= labpc_ai_cmdtest
;
610 s
->insn_read
= labpc_ai_rinsn
;
611 s
->cancel
= labpc_cancel
;
614 s
= &dev
->subdevices
[1];
615 if (thisboard
->has_ao
) {
617 * Could provide command support, except it only has a
618 * one sample hardware buffer for analog output and no
621 s
->type
= COMEDI_SUBD_AO
;
622 s
->subdev_flags
= SDF_READABLE
| SDF_WRITABLE
| SDF_GROUND
;
623 s
->n_chan
= NUM_AO_CHAN
;
624 s
->maxdata
= (1 << 12) - 1; /* 12 bit resolution */
625 s
->range_table
= &range_labpc_ao
;
626 s
->insn_read
= labpc_ao_rinsn
;
627 s
->insn_write
= labpc_ao_winsn
;
628 /* initialize analog outputs to a known value */
629 for (i
= 0; i
< s
->n_chan
; i
++) {
630 devpriv
->ao_value
[i
] = s
->maxdata
/ 2;
631 lsb
= devpriv
->ao_value
[i
] & 0xff;
632 msb
= (devpriv
->ao_value
[i
] >> 8) & 0xff;
633 devpriv
->write_byte(lsb
, dev
->iobase
+ DAC_LSB_REG(i
));
634 devpriv
->write_byte(msb
, dev
->iobase
+ DAC_MSB_REG(i
));
637 s
->type
= COMEDI_SUBD_UNUSED
;
641 s
= &dev
->subdevices
[2];
642 /* if board uses io memory we have to give a custom callback
643 * function to the 8255 driver */
644 if (thisboard
->memory_mapped_io
)
645 subdev_8255_init(dev
, s
, labpc_dio_mem_callback
,
646 (unsigned long)(dev
->iobase
+ DIO_BASE_REG
));
648 subdev_8255_init(dev
, s
, NULL
, dev
->iobase
+ DIO_BASE_REG
);
650 /* calibration subdevices for boards that have one */
651 s
= &dev
->subdevices
[3];
652 if (thisboard
->register_layout
== labpc_1200_layout
) {
653 s
->type
= COMEDI_SUBD_CALIB
;
654 s
->subdev_flags
= SDF_READABLE
| SDF_WRITABLE
| SDF_INTERNAL
;
657 s
->insn_read
= labpc_calib_read_insn
;
658 s
->insn_write
= labpc_calib_write_insn
;
660 for (i
= 0; i
< s
->n_chan
; i
++)
661 write_caldac(dev
, i
, s
->maxdata
/ 2);
663 s
->type
= COMEDI_SUBD_UNUSED
;
666 s
= &dev
->subdevices
[4];
667 if (thisboard
->register_layout
== labpc_1200_layout
) {
668 s
->type
= COMEDI_SUBD_MEMORY
;
669 s
->subdev_flags
= SDF_READABLE
| SDF_WRITABLE
| SDF_INTERNAL
;
670 s
->n_chan
= EEPROM_SIZE
;
672 s
->insn_read
= labpc_eeprom_read_insn
;
673 s
->insn_write
= labpc_eeprom_write_insn
;
675 for (i
= 0; i
< EEPROM_SIZE
; i
++)
676 devpriv
->eeprom_data
[i
] = labpc_eeprom_read(dev
, i
);
678 s
->type
= COMEDI_SUBD_UNUSED
;
682 EXPORT_SYMBOL_GPL(labpc_common_attach
);
684 static const struct labpc_board_struct
*
685 labpc_pci_find_boardinfo(struct pci_dev
*pcidev
)
687 unsigned int device_id
= pcidev
->device
;
690 for (n
= 0; n
< ARRAY_SIZE(labpc_boards
); n
++) {
691 const struct labpc_board_struct
*board
= &labpc_boards
[n
];
692 if (board
->bustype
== pci_bustype
&&
693 board
->device_id
== device_id
)
699 static int __devinit
labpc_attach_pci(struct comedi_device
*dev
,
700 struct pci_dev
*pcidev
)
702 struct labpc_private
*devpriv
;
703 unsigned long iobase
;
707 if (!IS_ENABLED(CONFIG_COMEDI_PCI_DRIVERS
))
710 devpriv
= kzalloc(sizeof(*devpriv
), GFP_KERNEL
);
713 dev
->private = devpriv
;
715 dev
->board_ptr
= labpc_pci_find_boardinfo(pcidev
);
718 devpriv
->mite
= mite_alloc(pcidev
);
721 ret
= mite_setup(devpriv
->mite
);
724 iobase
= (unsigned long)devpriv
->mite
->daq_io_addr
;
725 irq
= mite_irq(devpriv
->mite
);
726 return labpc_common_attach(dev
, iobase
, irq
, 0);
729 static int labpc_attach(struct comedi_device
*dev
, struct comedi_devconfig
*it
)
731 struct labpc_private
*devpriv
;
732 unsigned long iobase
= 0;
733 unsigned int irq
= 0;
734 unsigned int dma_chan
= 0;
736 devpriv
= kzalloc(sizeof(*devpriv
), GFP_KERNEL
);
739 dev
->private = devpriv
;
741 /* get base address, irq etc. based on bustype */
742 switch (thisboard
->bustype
) {
744 #ifdef CONFIG_ISA_DMA_API
745 iobase
= it
->options
[0];
746 irq
= it
->options
[1];
747 dma_chan
= it
->options
[2];
749 dev_err(dev
->class_dev
,
750 "ni_labpc driver has not been built with ISA DMA support.\n");
755 #ifdef CONFIG_COMEDI_PCI_DRIVERS
756 dev_err(dev
->class_dev
,
757 "manual configuration of PCI board '%s' is not supported\n",
761 dev_err(dev
->class_dev
,
762 "ni_labpc driver has not been built with PCI support.\n");
767 dev_err(dev
->class_dev
,
768 "ni_labpc: bug! couldn't determine board type\n");
773 return labpc_common_attach(dev
, iobase
, irq
, dma_chan
);
776 void labpc_common_detach(struct comedi_device
*dev
)
778 struct labpc_private
*devpriv
= dev
->private;
779 struct comedi_subdevice
*s
;
781 if (dev
->subdevices
) {
782 s
= &dev
->subdevices
[2];
783 subdev_8255_cleanup(dev
, s
);
785 #ifdef CONFIG_ISA_DMA_API
786 /* only free stuff if it has been allocated by _attach */
787 kfree(devpriv
->dma_buffer
);
788 if (devpriv
->dma_chan
)
789 free_dma(devpriv
->dma_chan
);
792 free_irq(dev
->irq
, dev
);
793 if (thisboard
->bustype
== isa_bustype
&& dev
->iobase
)
794 release_region(dev
->iobase
, LABPC_SIZE
);
795 #ifdef CONFIG_COMEDI_PCI_DRIVERS
797 mite_unsetup(devpriv
->mite
);
798 mite_free(devpriv
->mite
);
802 EXPORT_SYMBOL_GPL(labpc_common_detach
);
804 static void labpc_clear_adc_fifo(const struct comedi_device
*dev
)
806 struct labpc_private
*devpriv
= dev
->private;
808 devpriv
->write_byte(0x1, dev
->iobase
+ ADC_CLEAR_REG
);
809 devpriv
->read_byte(dev
->iobase
+ ADC_FIFO_REG
);
810 devpriv
->read_byte(dev
->iobase
+ ADC_FIFO_REG
);
813 static int labpc_cancel(struct comedi_device
*dev
, struct comedi_subdevice
*s
)
815 struct labpc_private
*devpriv
= dev
->private;
818 spin_lock_irqsave(&dev
->spinlock
, flags
);
819 devpriv
->command2_bits
&= ~SWTRIG_BIT
& ~HWTRIG_BIT
& ~PRETRIG_BIT
;
820 devpriv
->write_byte(devpriv
->command2_bits
, dev
->iobase
+ COMMAND2_REG
);
821 spin_unlock_irqrestore(&dev
->spinlock
, flags
);
823 devpriv
->command3_bits
= 0;
824 devpriv
->write_byte(devpriv
->command3_bits
, dev
->iobase
+ COMMAND3_REG
);
829 static enum scan_mode
labpc_ai_scan_mode(const struct comedi_cmd
*cmd
)
831 if (cmd
->chanlist_len
== 1)
832 return MODE_SINGLE_CHAN
;
834 /* chanlist may be NULL during cmdtest. */
835 if (cmd
->chanlist
== NULL
)
836 return MODE_MULT_CHAN_UP
;
838 if (CR_CHAN(cmd
->chanlist
[0]) == CR_CHAN(cmd
->chanlist
[1]))
839 return MODE_SINGLE_CHAN_INTERVAL
;
841 if (CR_CHAN(cmd
->chanlist
[0]) < CR_CHAN(cmd
->chanlist
[1]))
842 return MODE_MULT_CHAN_UP
;
844 if (CR_CHAN(cmd
->chanlist
[0]) > CR_CHAN(cmd
->chanlist
[1]))
845 return MODE_MULT_CHAN_DOWN
;
847 pr_err("ni_labpc: bug! cannot determine AI scan mode\n");
851 static int labpc_ai_chanlist_invalid(const struct comedi_device
*dev
,
852 const struct comedi_cmd
*cmd
,
855 int channel
, range
, aref
, i
;
857 if (cmd
->chanlist
== NULL
)
860 if (mode
== MODE_SINGLE_CHAN
)
863 if (mode
== MODE_SINGLE_CHAN_INTERVAL
) {
864 if (cmd
->chanlist_len
> 0xff) {
866 "ni_labpc: chanlist too long for single channel interval mode\n");
871 channel
= CR_CHAN(cmd
->chanlist
[0]);
872 range
= CR_RANGE(cmd
->chanlist
[0]);
873 aref
= CR_AREF(cmd
->chanlist
[0]);
875 for (i
= 0; i
< cmd
->chanlist_len
; i
++) {
878 case MODE_SINGLE_CHAN_INTERVAL
:
879 if (CR_CHAN(cmd
->chanlist
[i
]) != channel
) {
881 "channel scanning order specified in chanlist is not supported by hardware.\n");
885 case MODE_MULT_CHAN_UP
:
886 if (CR_CHAN(cmd
->chanlist
[i
]) != i
) {
888 "channel scanning order specified in chanlist is not supported by hardware.\n");
892 case MODE_MULT_CHAN_DOWN
:
893 if (CR_CHAN(cmd
->chanlist
[i
]) !=
894 cmd
->chanlist_len
- i
- 1) {
896 "channel scanning order specified in chanlist is not supported by hardware.\n");
901 dev_err(dev
->class_dev
,
902 "ni_labpc: bug! in chanlist check\n");
907 if (CR_RANGE(cmd
->chanlist
[i
]) != range
) {
909 "entries in chanlist must all have the same range\n");
913 if (CR_AREF(cmd
->chanlist
[i
]) != aref
) {
915 "entries in chanlist must all have the same reference\n");
923 static int labpc_use_continuous_mode(const struct comedi_cmd
*cmd
,
926 if (mode
== MODE_SINGLE_CHAN
)
929 if (cmd
->scan_begin_src
== TRIG_FOLLOW
)
935 static unsigned int labpc_ai_convert_period(const struct comedi_cmd
*cmd
,
938 if (cmd
->convert_src
!= TRIG_TIMER
)
941 if (mode
== MODE_SINGLE_CHAN
&& cmd
->scan_begin_src
== TRIG_TIMER
)
942 return cmd
->scan_begin_arg
;
944 return cmd
->convert_arg
;
947 static void labpc_set_ai_convert_period(struct comedi_cmd
*cmd
,
948 enum scan_mode mode
, unsigned int ns
)
950 if (cmd
->convert_src
!= TRIG_TIMER
)
953 if (mode
== MODE_SINGLE_CHAN
&&
954 cmd
->scan_begin_src
== TRIG_TIMER
) {
955 cmd
->scan_begin_arg
= ns
;
956 if (cmd
->convert_arg
> cmd
->scan_begin_arg
)
957 cmd
->convert_arg
= cmd
->scan_begin_arg
;
959 cmd
->convert_arg
= ns
;
962 static unsigned int labpc_ai_scan_period(const struct comedi_cmd
*cmd
,
965 if (cmd
->scan_begin_src
!= TRIG_TIMER
)
968 if (mode
== MODE_SINGLE_CHAN
&& cmd
->convert_src
== TRIG_TIMER
)
971 return cmd
->scan_begin_arg
;
974 static void labpc_set_ai_scan_period(struct comedi_cmd
*cmd
,
975 enum scan_mode mode
, unsigned int ns
)
977 if (cmd
->scan_begin_src
!= TRIG_TIMER
)
980 if (mode
== MODE_SINGLE_CHAN
&& cmd
->convert_src
== TRIG_TIMER
)
983 cmd
->scan_begin_arg
= ns
;
986 static int labpc_ai_cmdtest(struct comedi_device
*dev
,
987 struct comedi_subdevice
*s
, struct comedi_cmd
*cmd
)
991 unsigned int stop_mask
;
994 /* Step 1 : check if triggers are trivially valid */
996 err
|= cfc_check_trigger_src(&cmd
->start_src
, TRIG_NOW
| TRIG_EXT
);
997 err
|= cfc_check_trigger_src(&cmd
->scan_begin_src
,
998 TRIG_TIMER
| TRIG_FOLLOW
| TRIG_EXT
);
999 err
|= cfc_check_trigger_src(&cmd
->convert_src
, TRIG_TIMER
| TRIG_EXT
);
1000 err
|= cfc_check_trigger_src(&cmd
->scan_end_src
, TRIG_COUNT
);
1002 stop_mask
= TRIG_COUNT
| TRIG_NONE
;
1003 if (thisboard
->register_layout
== labpc_1200_layout
)
1004 stop_mask
|= TRIG_EXT
;
1005 err
|= cfc_check_trigger_src(&cmd
->stop_src
, stop_mask
);
1010 /* Step 2a : make sure trigger sources are unique */
1012 err
|= cfc_check_trigger_is_unique(cmd
->start_src
);
1013 err
|= cfc_check_trigger_is_unique(cmd
->scan_begin_src
);
1014 err
|= cfc_check_trigger_is_unique(cmd
->convert_src
);
1015 err
|= cfc_check_trigger_is_unique(cmd
->stop_src
);
1017 /* Step 2b : and mutually compatible */
1019 /* can't have external stop and start triggers at once */
1020 if (cmd
->start_src
== TRIG_EXT
&& cmd
->stop_src
== TRIG_EXT
)
1026 /* step 3: make sure arguments are trivially compatible */
1028 if (cmd
->start_arg
== TRIG_NOW
&& cmd
->start_arg
!= 0) {
1033 if (!cmd
->chanlist_len
)
1036 if (cmd
->scan_end_arg
!= cmd
->chanlist_len
) {
1037 cmd
->scan_end_arg
= cmd
->chanlist_len
;
1041 if (cmd
->convert_src
== TRIG_TIMER
) {
1042 if (cmd
->convert_arg
< thisboard
->ai_speed
) {
1043 cmd
->convert_arg
= thisboard
->ai_speed
;
1047 /* make sure scan timing is not too fast */
1048 if (cmd
->scan_begin_src
== TRIG_TIMER
) {
1049 if (cmd
->convert_src
== TRIG_TIMER
&&
1050 cmd
->scan_begin_arg
<
1051 cmd
->convert_arg
* cmd
->chanlist_len
) {
1052 cmd
->scan_begin_arg
=
1053 cmd
->convert_arg
* cmd
->chanlist_len
;
1056 if (cmd
->scan_begin_arg
<
1057 thisboard
->ai_speed
* cmd
->chanlist_len
) {
1058 cmd
->scan_begin_arg
=
1059 thisboard
->ai_speed
* cmd
->chanlist_len
;
1064 switch (cmd
->stop_src
) {
1066 if (!cmd
->stop_arg
) {
1072 if (cmd
->stop_arg
!= 0) {
1078 * TRIG_EXT doesn't care since it doesn't
1079 * trigger off a numbered channel
1088 /* step 4: fix up any arguments */
1090 tmp
= cmd
->convert_arg
;
1091 tmp2
= cmd
->scan_begin_arg
;
1092 mode
= labpc_ai_scan_mode(cmd
);
1093 labpc_adc_timing(dev
, cmd
, mode
);
1094 if (tmp
!= cmd
->convert_arg
|| tmp2
!= cmd
->scan_begin_arg
)
1100 if (labpc_ai_chanlist_invalid(dev
, cmd
, mode
))
1106 static int labpc_ai_cmd(struct comedi_device
*dev
, struct comedi_subdevice
*s
)
1108 struct labpc_private
*devpriv
= dev
->private;
1109 int channel
, range
, aref
;
1110 #ifdef CONFIG_ISA_DMA_API
1111 unsigned long irq_flags
;
1114 struct comedi_async
*async
= s
->async
;
1115 struct comedi_cmd
*cmd
= &async
->cmd
;
1116 enum transfer_type xfer
;
1117 enum scan_mode mode
;
1118 unsigned long flags
;
1121 comedi_error(dev
, "no irq assigned, cannot perform command");
1125 range
= CR_RANGE(cmd
->chanlist
[0]);
1126 aref
= CR_AREF(cmd
->chanlist
[0]);
1128 /* make sure board is disabled before setting up acquisition */
1129 spin_lock_irqsave(&dev
->spinlock
, flags
);
1130 devpriv
->command2_bits
&= ~SWTRIG_BIT
& ~HWTRIG_BIT
& ~PRETRIG_BIT
;
1131 devpriv
->write_byte(devpriv
->command2_bits
, dev
->iobase
+ COMMAND2_REG
);
1132 spin_unlock_irqrestore(&dev
->spinlock
, flags
);
1134 devpriv
->command3_bits
= 0;
1135 devpriv
->write_byte(devpriv
->command3_bits
, dev
->iobase
+ COMMAND3_REG
);
1137 /* initialize software conversion count */
1138 if (cmd
->stop_src
== TRIG_COUNT
)
1139 devpriv
->count
= cmd
->stop_arg
* cmd
->chanlist_len
;
1141 /* setup hardware conversion counter */
1142 if (cmd
->stop_src
== TRIG_EXT
) {
1144 * load counter a1 with count of 3
1145 * (pc+ manual says this is minimum allowed) using mode 0
1147 ret
= labpc_counter_load(dev
, dev
->iobase
+ COUNTER_A_BASE_REG
,
1150 comedi_error(dev
, "error loading counter a1");
1154 * otherwise, just put a1 in mode 0
1155 * with no count to set its output low
1157 devpriv
->write_byte(INIT_A1_BITS
,
1158 dev
->iobase
+ COUNTER_A_CONTROL_REG
);
1160 #ifdef CONFIG_ISA_DMA_API
1161 /* figure out what method we will use to transfer data */
1162 if (devpriv
->dma_chan
&& /* need a dma channel allocated */
1164 * dma unsafe at RT priority,
1165 * and too much setup time for TRIG_WAKE_EOS for
1167 (cmd
->flags
& (TRIG_WAKE_EOS
| TRIG_RT
)) == 0 &&
1168 /* only available on the isa boards */
1169 thisboard
->bustype
== isa_bustype
) {
1170 xfer
= isa_dma_transfer
;
1171 /* pc-plus has no fifo-half full interrupt */
1174 if (thisboard
->register_layout
== labpc_1200_layout
&&
1175 /* wake-end-of-scan should interrupt on fifo not empty */
1176 (cmd
->flags
& TRIG_WAKE_EOS
) == 0 &&
1177 /* make sure we are taking more than just a few points */
1178 (cmd
->stop_src
!= TRIG_COUNT
|| devpriv
->count
> 256)) {
1179 xfer
= fifo_half_full_transfer
;
1181 xfer
= fifo_not_empty_transfer
;
1182 devpriv
->current_transfer
= xfer
;
1183 mode
= labpc_ai_scan_mode(cmd
);
1185 /* setup command6 register for 1200 boards */
1186 if (thisboard
->register_layout
== labpc_1200_layout
) {
1187 /* reference inputs to ground or common? */
1188 if (aref
!= AREF_GROUND
)
1189 devpriv
->command6_bits
|= ADC_COMMON_BIT
;
1191 devpriv
->command6_bits
&= ~ADC_COMMON_BIT
;
1192 /* bipolar or unipolar range? */
1193 if (thisboard
->ai_range_is_unipolar
[range
])
1194 devpriv
->command6_bits
|= ADC_UNIP_BIT
;
1196 devpriv
->command6_bits
&= ~ADC_UNIP_BIT
;
1197 /* interrupt on fifo half full? */
1198 if (xfer
== fifo_half_full_transfer
)
1199 devpriv
->command6_bits
|= ADC_FHF_INTR_EN_BIT
;
1201 devpriv
->command6_bits
&= ~ADC_FHF_INTR_EN_BIT
;
1202 /* enable interrupt on counter a1 terminal count? */
1203 if (cmd
->stop_src
== TRIG_EXT
)
1204 devpriv
->command6_bits
|= A1_INTR_EN_BIT
;
1206 devpriv
->command6_bits
&= ~A1_INTR_EN_BIT
;
1207 /* are we scanning up or down through channels? */
1208 if (mode
== MODE_MULT_CHAN_UP
)
1209 devpriv
->command6_bits
|= ADC_SCAN_UP_BIT
;
1211 devpriv
->command6_bits
&= ~ADC_SCAN_UP_BIT
;
1212 /* write to register */
1213 devpriv
->write_byte(devpriv
->command6_bits
,
1214 dev
->iobase
+ COMMAND6_REG
);
1217 /* setup channel list, etc (command1 register) */
1218 devpriv
->command1_bits
= 0;
1219 if (mode
== MODE_MULT_CHAN_UP
)
1220 channel
= CR_CHAN(cmd
->chanlist
[cmd
->chanlist_len
- 1]);
1222 channel
= CR_CHAN(cmd
->chanlist
[0]);
1223 /* munge channel bits for differential / scan disabled mode */
1224 if (mode
!= MODE_SINGLE_CHAN
&& aref
== AREF_DIFF
)
1226 devpriv
->command1_bits
|= ADC_CHAN_BITS(channel
);
1227 devpriv
->command1_bits
|= thisboard
->ai_range_code
[range
];
1228 devpriv
->write_byte(devpriv
->command1_bits
, dev
->iobase
+ COMMAND1_REG
);
1229 /* manual says to set scan enable bit on second pass */
1230 if (mode
== MODE_MULT_CHAN_UP
|| mode
== MODE_MULT_CHAN_DOWN
) {
1231 devpriv
->command1_bits
|= ADC_SCAN_EN_BIT
;
1232 /* need a brief delay before enabling scan, or scan
1233 * list will get screwed when you switch
1234 * between scan up to scan down mode - dunno why */
1236 devpriv
->write_byte(devpriv
->command1_bits
,
1237 dev
->iobase
+ COMMAND1_REG
);
1239 /* setup any external triggering/pacing (command4 register) */
1240 devpriv
->command4_bits
= 0;
1241 if (cmd
->convert_src
!= TRIG_EXT
)
1242 devpriv
->command4_bits
|= EXT_CONVERT_DISABLE_BIT
;
1243 /* XXX should discard first scan when using interval scanning
1244 * since manual says it is not synced with scan clock */
1245 if (labpc_use_continuous_mode(cmd
, mode
) == 0) {
1246 devpriv
->command4_bits
|= INTERVAL_SCAN_EN_BIT
;
1247 if (cmd
->scan_begin_src
== TRIG_EXT
)
1248 devpriv
->command4_bits
|= EXT_SCAN_EN_BIT
;
1250 /* single-ended/differential */
1251 if (aref
== AREF_DIFF
)
1252 devpriv
->command4_bits
|= ADC_DIFF_BIT
;
1253 devpriv
->write_byte(devpriv
->command4_bits
, dev
->iobase
+ COMMAND4_REG
);
1255 devpriv
->write_byte(cmd
->chanlist_len
,
1256 dev
->iobase
+ INTERVAL_COUNT_REG
);
1258 devpriv
->write_byte(INTERVAL_LOAD_BITS
,
1259 dev
->iobase
+ INTERVAL_LOAD_REG
);
1261 if (cmd
->convert_src
== TRIG_TIMER
|| cmd
->scan_begin_src
== TRIG_TIMER
) {
1263 labpc_adc_timing(dev
, cmd
, mode
);
1264 /* load counter b0 in mode 3 */
1265 ret
= labpc_counter_load(dev
, dev
->iobase
+ COUNTER_B_BASE_REG
,
1266 0, devpriv
->divisor_b0
, 3);
1268 comedi_error(dev
, "error loading counter b0");
1272 /* set up conversion pacing */
1273 if (labpc_ai_convert_period(cmd
, mode
)) {
1274 /* load counter a0 in mode 2 */
1275 ret
= labpc_counter_load(dev
, dev
->iobase
+ COUNTER_A_BASE_REG
,
1276 0, devpriv
->divisor_a0
, 2);
1278 comedi_error(dev
, "error loading counter a0");
1282 devpriv
->write_byte(INIT_A0_BITS
,
1283 dev
->iobase
+ COUNTER_A_CONTROL_REG
);
1285 /* set up scan pacing */
1286 if (labpc_ai_scan_period(cmd
, mode
)) {
1287 /* load counter b1 in mode 2 */
1288 ret
= labpc_counter_load(dev
, dev
->iobase
+ COUNTER_B_BASE_REG
,
1289 1, devpriv
->divisor_b1
, 2);
1291 comedi_error(dev
, "error loading counter b1");
1296 labpc_clear_adc_fifo(dev
);
1298 #ifdef CONFIG_ISA_DMA_API
1299 /* set up dma transfer */
1300 if (xfer
== isa_dma_transfer
) {
1301 irq_flags
= claim_dma_lock();
1302 disable_dma(devpriv
->dma_chan
);
1303 /* clear flip-flop to make sure 2-byte registers for
1304 * count and address get set correctly */
1305 clear_dma_ff(devpriv
->dma_chan
);
1306 set_dma_addr(devpriv
->dma_chan
,
1307 virt_to_bus(devpriv
->dma_buffer
));
1308 /* set appropriate size of transfer */
1309 devpriv
->dma_transfer_size
= labpc_suggest_transfer_size(cmd
);
1310 if (cmd
->stop_src
== TRIG_COUNT
&&
1311 devpriv
->count
* sample_size
< devpriv
->dma_transfer_size
) {
1312 devpriv
->dma_transfer_size
=
1313 devpriv
->count
* sample_size
;
1315 set_dma_count(devpriv
->dma_chan
, devpriv
->dma_transfer_size
);
1316 enable_dma(devpriv
->dma_chan
);
1317 release_dma_lock(irq_flags
);
1318 /* enable board's dma */
1319 devpriv
->command3_bits
|= DMA_EN_BIT
| DMATC_INTR_EN_BIT
;
1321 devpriv
->command3_bits
&= ~DMA_EN_BIT
& ~DMATC_INTR_EN_BIT
;
1324 /* enable error interrupts */
1325 devpriv
->command3_bits
|= ERR_INTR_EN_BIT
;
1326 /* enable fifo not empty interrupt? */
1327 if (xfer
== fifo_not_empty_transfer
)
1328 devpriv
->command3_bits
|= ADC_FNE_INTR_EN_BIT
;
1330 devpriv
->command3_bits
&= ~ADC_FNE_INTR_EN_BIT
;
1331 devpriv
->write_byte(devpriv
->command3_bits
, dev
->iobase
+ COMMAND3_REG
);
1333 /* startup acquisition */
1336 /* use 2 cascaded counters for pacing */
1337 spin_lock_irqsave(&dev
->spinlock
, flags
);
1338 devpriv
->command2_bits
|= CASCADE_BIT
;
1339 switch (cmd
->start_src
) {
1341 devpriv
->command2_bits
|= HWTRIG_BIT
;
1342 devpriv
->command2_bits
&= ~PRETRIG_BIT
& ~SWTRIG_BIT
;
1345 devpriv
->command2_bits
|= SWTRIG_BIT
;
1346 devpriv
->command2_bits
&= ~PRETRIG_BIT
& ~HWTRIG_BIT
;
1349 comedi_error(dev
, "bug with start_src");
1350 spin_unlock_irqrestore(&dev
->spinlock
, flags
);
1354 switch (cmd
->stop_src
) {
1356 devpriv
->command2_bits
|= HWTRIG_BIT
| PRETRIG_BIT
;
1362 comedi_error(dev
, "bug with stop_src");
1363 spin_unlock_irqrestore(&dev
->spinlock
, flags
);
1366 devpriv
->write_byte(devpriv
->command2_bits
, dev
->iobase
+ COMMAND2_REG
);
1367 spin_unlock_irqrestore(&dev
->spinlock
, flags
);
1372 /* interrupt service routine */
1373 static irqreturn_t
labpc_interrupt(int irq
, void *d
)
1375 struct comedi_device
*dev
= d
;
1376 struct labpc_private
*devpriv
= dev
->private;
1377 struct comedi_subdevice
*s
= dev
->read_subdev
;
1378 struct comedi_async
*async
;
1379 struct comedi_cmd
*cmd
;
1381 if (dev
->attached
== 0) {
1382 comedi_error(dev
, "premature interrupt");
1390 /* read board status */
1391 devpriv
->status1_bits
= devpriv
->read_byte(dev
->iobase
+ STATUS1_REG
);
1392 if (thisboard
->register_layout
== labpc_1200_layout
)
1393 devpriv
->status2_bits
=
1394 devpriv
->read_byte(dev
->iobase
+ STATUS2_REG
);
1396 if ((devpriv
->status1_bits
& (DMATC_BIT
| TIMER_BIT
| OVERFLOW_BIT
|
1397 OVERRUN_BIT
| DATA_AVAIL_BIT
)) == 0
1398 && (devpriv
->status2_bits
& A1_TC_BIT
) == 0
1399 && (devpriv
->status2_bits
& FNHF_BIT
)) {
1403 if (devpriv
->status1_bits
& OVERRUN_BIT
) {
1404 /* clear error interrupt */
1405 devpriv
->write_byte(0x1, dev
->iobase
+ ADC_CLEAR_REG
);
1406 async
->events
|= COMEDI_CB_ERROR
| COMEDI_CB_EOA
;
1407 comedi_event(dev
, s
);
1408 comedi_error(dev
, "overrun");
1412 #ifdef CONFIG_ISA_DMA_API
1413 if (devpriv
->current_transfer
== isa_dma_transfer
) {
1415 * if a dma terminal count of external stop trigger
1418 if (devpriv
->status1_bits
& DMATC_BIT
||
1419 (thisboard
->register_layout
== labpc_1200_layout
1420 && devpriv
->status2_bits
& A1_TC_BIT
)) {
1421 handle_isa_dma(dev
);
1425 labpc_drain_fifo(dev
);
1427 if (devpriv
->status1_bits
& TIMER_BIT
) {
1428 comedi_error(dev
, "handled timer interrupt?");
1430 devpriv
->write_byte(0x1, dev
->iobase
+ TIMER_CLEAR_REG
);
1433 if (devpriv
->status1_bits
& OVERFLOW_BIT
) {
1434 /* clear error interrupt */
1435 devpriv
->write_byte(0x1, dev
->iobase
+ ADC_CLEAR_REG
);
1436 async
->events
|= COMEDI_CB_ERROR
| COMEDI_CB_EOA
;
1437 comedi_event(dev
, s
);
1438 comedi_error(dev
, "overflow");
1441 /* handle external stop trigger */
1442 if (cmd
->stop_src
== TRIG_EXT
) {
1443 if (devpriv
->status2_bits
& A1_TC_BIT
) {
1444 labpc_drain_dregs(dev
);
1445 labpc_cancel(dev
, s
);
1446 async
->events
|= COMEDI_CB_EOA
;
1450 /* TRIG_COUNT end of acquisition */
1451 if (cmd
->stop_src
== TRIG_COUNT
) {
1452 if (devpriv
->count
== 0) {
1453 labpc_cancel(dev
, s
);
1454 async
->events
|= COMEDI_CB_EOA
;
1458 comedi_event(dev
, s
);
1462 /* read all available samples from ai fifo */
1463 static int labpc_drain_fifo(struct comedi_device
*dev
)
1465 struct labpc_private
*devpriv
= dev
->private;
1466 unsigned int lsb
, msb
;
1468 struct comedi_async
*async
= dev
->read_subdev
->async
;
1469 const int timeout
= 10000;
1472 devpriv
->status1_bits
= devpriv
->read_byte(dev
->iobase
+ STATUS1_REG
);
1474 for (i
= 0; (devpriv
->status1_bits
& DATA_AVAIL_BIT
) && i
< timeout
;
1476 /* quit if we have all the data we want */
1477 if (async
->cmd
.stop_src
== TRIG_COUNT
) {
1478 if (devpriv
->count
== 0)
1482 lsb
= devpriv
->read_byte(dev
->iobase
+ ADC_FIFO_REG
);
1483 msb
= devpriv
->read_byte(dev
->iobase
+ ADC_FIFO_REG
);
1484 data
= (msb
<< 8) | lsb
;
1485 cfc_write_to_buffer(dev
->read_subdev
, data
);
1486 devpriv
->status1_bits
=
1487 devpriv
->read_byte(dev
->iobase
+ STATUS1_REG
);
1490 comedi_error(dev
, "ai timeout, fifo never empties");
1491 async
->events
|= COMEDI_CB_ERROR
| COMEDI_CB_EOA
;
1498 #ifdef CONFIG_ISA_DMA_API
1499 static void labpc_drain_dma(struct comedi_device
*dev
)
1501 struct labpc_private
*devpriv
= dev
->private;
1502 struct comedi_subdevice
*s
= dev
->read_subdev
;
1503 struct comedi_async
*async
= s
->async
;
1505 unsigned long flags
;
1506 unsigned int max_points
, num_points
, residue
, leftover
;
1509 status
= devpriv
->status1_bits
;
1511 flags
= claim_dma_lock();
1512 disable_dma(devpriv
->dma_chan
);
1513 /* clear flip-flop to make sure 2-byte registers for
1514 * count and address get set correctly */
1515 clear_dma_ff(devpriv
->dma_chan
);
1517 /* figure out how many points to read */
1518 max_points
= devpriv
->dma_transfer_size
/ sample_size
;
1519 /* residue is the number of points left to be done on the dma
1520 * transfer. It should always be zero at this point unless
1521 * the stop_src is set to external triggering.
1523 residue
= get_dma_residue(devpriv
->dma_chan
) / sample_size
;
1524 num_points
= max_points
- residue
;
1525 if (devpriv
->count
< num_points
&& async
->cmd
.stop_src
== TRIG_COUNT
)
1526 num_points
= devpriv
->count
;
1528 /* figure out how many points will be stored next time */
1530 if (async
->cmd
.stop_src
!= TRIG_COUNT
) {
1531 leftover
= devpriv
->dma_transfer_size
/ sample_size
;
1532 } else if (devpriv
->count
> num_points
) {
1533 leftover
= devpriv
->count
- num_points
;
1534 if (leftover
> max_points
)
1535 leftover
= max_points
;
1538 /* write data to comedi buffer */
1539 for (i
= 0; i
< num_points
; i
++)
1540 cfc_write_to_buffer(s
, devpriv
->dma_buffer
[i
]);
1542 if (async
->cmd
.stop_src
== TRIG_COUNT
)
1543 devpriv
->count
-= num_points
;
1545 /* set address and count for next transfer */
1546 set_dma_addr(devpriv
->dma_chan
, virt_to_bus(devpriv
->dma_buffer
));
1547 set_dma_count(devpriv
->dma_chan
, leftover
* sample_size
);
1548 release_dma_lock(flags
);
1550 async
->events
|= COMEDI_CB_BLOCK
;
1553 static void handle_isa_dma(struct comedi_device
*dev
)
1555 struct labpc_private
*devpriv
= dev
->private;
1557 labpc_drain_dma(dev
);
1559 enable_dma(devpriv
->dma_chan
);
1561 /* clear dma tc interrupt */
1562 devpriv
->write_byte(0x1, dev
->iobase
+ DMATC_CLEAR_REG
);
1566 /* makes sure all data acquired by board is transferred to comedi (used
1567 * when acquisition is terminated by stop_src == TRIG_EXT). */
1568 static void labpc_drain_dregs(struct comedi_device
*dev
)
1570 #ifdef CONFIG_ISA_DMA_API
1571 struct labpc_private
*devpriv
= dev
->private;
1573 if (devpriv
->current_transfer
== isa_dma_transfer
)
1574 labpc_drain_dma(dev
);
1577 labpc_drain_fifo(dev
);
1580 static int labpc_ai_rinsn(struct comedi_device
*dev
, struct comedi_subdevice
*s
,
1581 struct comedi_insn
*insn
, unsigned int *data
)
1583 struct labpc_private
*devpriv
= dev
->private;
1588 unsigned long flags
;
1590 /* disable timed conversions */
1591 spin_lock_irqsave(&dev
->spinlock
, flags
);
1592 devpriv
->command2_bits
&= ~SWTRIG_BIT
& ~HWTRIG_BIT
& ~PRETRIG_BIT
;
1593 devpriv
->write_byte(devpriv
->command2_bits
, dev
->iobase
+ COMMAND2_REG
);
1594 spin_unlock_irqrestore(&dev
->spinlock
, flags
);
1596 /* disable interrupt generation and dma */
1597 devpriv
->command3_bits
= 0;
1598 devpriv
->write_byte(devpriv
->command3_bits
, dev
->iobase
+ COMMAND3_REG
);
1600 /* set gain and channel */
1601 devpriv
->command1_bits
= 0;
1602 chan
= CR_CHAN(insn
->chanspec
);
1603 range
= CR_RANGE(insn
->chanspec
);
1604 devpriv
->command1_bits
|= thisboard
->ai_range_code
[range
];
1605 /* munge channel bits for differential/scan disabled mode */
1606 if (CR_AREF(insn
->chanspec
) == AREF_DIFF
)
1608 devpriv
->command1_bits
|= ADC_CHAN_BITS(chan
);
1609 devpriv
->write_byte(devpriv
->command1_bits
, dev
->iobase
+ COMMAND1_REG
);
1611 /* setup command6 register for 1200 boards */
1612 if (thisboard
->register_layout
== labpc_1200_layout
) {
1613 /* reference inputs to ground or common? */
1614 if (CR_AREF(insn
->chanspec
) != AREF_GROUND
)
1615 devpriv
->command6_bits
|= ADC_COMMON_BIT
;
1617 devpriv
->command6_bits
&= ~ADC_COMMON_BIT
;
1618 /* bipolar or unipolar range? */
1619 if (thisboard
->ai_range_is_unipolar
[range
])
1620 devpriv
->command6_bits
|= ADC_UNIP_BIT
;
1622 devpriv
->command6_bits
&= ~ADC_UNIP_BIT
;
1623 /* don't interrupt on fifo half full */
1624 devpriv
->command6_bits
&= ~ADC_FHF_INTR_EN_BIT
;
1625 /* don't enable interrupt on counter a1 terminal count? */
1626 devpriv
->command6_bits
&= ~A1_INTR_EN_BIT
;
1627 /* write to register */
1628 devpriv
->write_byte(devpriv
->command6_bits
,
1629 dev
->iobase
+ COMMAND6_REG
);
1631 /* setup command4 register */
1632 devpriv
->command4_bits
= 0;
1633 devpriv
->command4_bits
|= EXT_CONVERT_DISABLE_BIT
;
1634 /* single-ended/differential */
1635 if (CR_AREF(insn
->chanspec
) == AREF_DIFF
)
1636 devpriv
->command4_bits
|= ADC_DIFF_BIT
;
1637 devpriv
->write_byte(devpriv
->command4_bits
, dev
->iobase
+ COMMAND4_REG
);
1640 * initialize pacer counter output to make sure it doesn't
1641 * cause any problems
1643 devpriv
->write_byte(INIT_A0_BITS
, dev
->iobase
+ COUNTER_A_CONTROL_REG
);
1645 labpc_clear_adc_fifo(dev
);
1647 for (n
= 0; n
< insn
->n
; n
++) {
1648 /* trigger conversion */
1649 devpriv
->write_byte(0x1, dev
->iobase
+ ADC_CONVERT_REG
);
1651 for (i
= 0; i
< timeout
; i
++) {
1652 if (devpriv
->read_byte(dev
->iobase
+
1653 STATUS1_REG
) & DATA_AVAIL_BIT
)
1658 comedi_error(dev
, "timeout");
1661 lsb
= devpriv
->read_byte(dev
->iobase
+ ADC_FIFO_REG
);
1662 msb
= devpriv
->read_byte(dev
->iobase
+ ADC_FIFO_REG
);
1663 data
[n
] = (msb
<< 8) | lsb
;
1669 /* analog output insn */
1670 static int labpc_ao_winsn(struct comedi_device
*dev
, struct comedi_subdevice
*s
,
1671 struct comedi_insn
*insn
, unsigned int *data
)
1673 struct labpc_private
*devpriv
= dev
->private;
1675 unsigned long flags
;
1678 channel
= CR_CHAN(insn
->chanspec
);
1680 /* turn off pacing of analog output channel */
1681 /* note: hardware bug in daqcard-1200 means pacing cannot
1682 * be independently enabled/disabled for its the two channels */
1683 spin_lock_irqsave(&dev
->spinlock
, flags
);
1684 devpriv
->command2_bits
&= ~DAC_PACED_BIT(channel
);
1685 devpriv
->write_byte(devpriv
->command2_bits
, dev
->iobase
+ COMMAND2_REG
);
1686 spin_unlock_irqrestore(&dev
->spinlock
, flags
);
1689 if (thisboard
->register_layout
== labpc_1200_layout
) {
1690 range
= CR_RANGE(insn
->chanspec
);
1691 if (range
& AO_RANGE_IS_UNIPOLAR
)
1692 devpriv
->command6_bits
|= DAC_UNIP_BIT(channel
);
1694 devpriv
->command6_bits
&= ~DAC_UNIP_BIT(channel
);
1695 /* write to register */
1696 devpriv
->write_byte(devpriv
->command6_bits
,
1697 dev
->iobase
+ COMMAND6_REG
);
1700 lsb
= data
[0] & 0xff;
1701 msb
= (data
[0] >> 8) & 0xff;
1702 devpriv
->write_byte(lsb
, dev
->iobase
+ DAC_LSB_REG(channel
));
1703 devpriv
->write_byte(msb
, dev
->iobase
+ DAC_MSB_REG(channel
));
1705 /* remember value for readback */
1706 devpriv
->ao_value
[channel
] = data
[0];
1711 /* analog output readback insn */
1712 static int labpc_ao_rinsn(struct comedi_device
*dev
, struct comedi_subdevice
*s
,
1713 struct comedi_insn
*insn
, unsigned int *data
)
1715 struct labpc_private
*devpriv
= dev
->private;
1717 data
[0] = devpriv
->ao_value
[CR_CHAN(insn
->chanspec
)];
1722 static int labpc_calib_read_insn(struct comedi_device
*dev
,
1723 struct comedi_subdevice
*s
,
1724 struct comedi_insn
*insn
, unsigned int *data
)
1726 struct labpc_private
*devpriv
= dev
->private;
1728 data
[0] = devpriv
->caldac
[CR_CHAN(insn
->chanspec
)];
1733 static int labpc_calib_write_insn(struct comedi_device
*dev
,
1734 struct comedi_subdevice
*s
,
1735 struct comedi_insn
*insn
, unsigned int *data
)
1737 int channel
= CR_CHAN(insn
->chanspec
);
1739 write_caldac(dev
, channel
, data
[0]);
1743 static int labpc_eeprom_read_insn(struct comedi_device
*dev
,
1744 struct comedi_subdevice
*s
,
1745 struct comedi_insn
*insn
, unsigned int *data
)
1747 struct labpc_private
*devpriv
= dev
->private;
1749 data
[0] = devpriv
->eeprom_data
[CR_CHAN(insn
->chanspec
)];
1754 static int labpc_eeprom_write_insn(struct comedi_device
*dev
,
1755 struct comedi_subdevice
*s
,
1756 struct comedi_insn
*insn
, unsigned int *data
)
1758 int channel
= CR_CHAN(insn
->chanspec
);
1761 /* only allow writes to user area of eeprom */
1762 if (channel
< 16 || channel
> 127) {
1763 dev_dbg(dev
->class_dev
,
1764 "eeprom writes are only allowed to channels 16 through 127 (the pointer and user areas)\n");
1768 ret
= labpc_eeprom_write(dev
, channel
, data
[0]);
1775 #ifdef CONFIG_ISA_DMA_API
1776 /* utility function that suggests a dma transfer size in bytes */
1777 static unsigned int labpc_suggest_transfer_size(const struct comedi_cmd
*cmd
)
1782 if (cmd
->convert_src
== TRIG_TIMER
)
1783 freq
= 1000000000 / cmd
->convert_arg
;
1784 /* return some default value */
1788 /* make buffer fill in no more than 1/3 second */
1789 size
= (freq
/ 3) * sample_size
;
1791 /* set a minimum and maximum size allowed */
1792 if (size
> dma_buffer_size
)
1793 size
= dma_buffer_size
- dma_buffer_size
% sample_size
;
1794 else if (size
< sample_size
)
1801 /* figures out what counter values to use based on command */
1802 static void labpc_adc_timing(struct comedi_device
*dev
, struct comedi_cmd
*cmd
,
1803 enum scan_mode mode
)
1805 struct labpc_private
*devpriv
= dev
->private;
1806 /* max value for 16 bit counter in mode 2 */
1807 const int max_counter_value
= 0x10000;
1808 /* min value for 16 bit counter in mode 2 */
1809 const int min_counter_value
= 2;
1810 unsigned int base_period
;
1811 unsigned int scan_period
;
1812 unsigned int convert_period
;
1815 * if both convert and scan triggers are TRIG_TIMER, then they
1816 * both rely on counter b0
1818 convert_period
= labpc_ai_convert_period(cmd
, mode
);
1819 scan_period
= labpc_ai_scan_period(cmd
, mode
);
1820 if (convert_period
&& scan_period
) {
1822 * pick the lowest b0 divisor value we can (for maximum input
1823 * clock speed on convert and scan counters)
1825 devpriv
->divisor_b0
= (scan_period
- 1) /
1826 (LABPC_TIMER_BASE
* max_counter_value
) + 1;
1827 if (devpriv
->divisor_b0
< min_counter_value
)
1828 devpriv
->divisor_b0
= min_counter_value
;
1829 if (devpriv
->divisor_b0
> max_counter_value
)
1830 devpriv
->divisor_b0
= max_counter_value
;
1832 base_period
= LABPC_TIMER_BASE
* devpriv
->divisor_b0
;
1834 /* set a0 for conversion frequency and b1 for scan frequency */
1835 switch (cmd
->flags
& TRIG_ROUND_MASK
) {
1837 case TRIG_ROUND_NEAREST
:
1838 devpriv
->divisor_a0
=
1839 (convert_period
+ (base_period
/ 2)) / base_period
;
1840 devpriv
->divisor_b1
=
1841 (scan_period
+ (base_period
/ 2)) / base_period
;
1844 devpriv
->divisor_a0
=
1845 (convert_period
+ (base_period
- 1)) / base_period
;
1846 devpriv
->divisor_b1
=
1847 (scan_period
+ (base_period
- 1)) / base_period
;
1849 case TRIG_ROUND_DOWN
:
1850 devpriv
->divisor_a0
= convert_period
/ base_period
;
1851 devpriv
->divisor_b1
= scan_period
/ base_period
;
1854 /* make sure a0 and b1 values are acceptable */
1855 if (devpriv
->divisor_a0
< min_counter_value
)
1856 devpriv
->divisor_a0
= min_counter_value
;
1857 if (devpriv
->divisor_a0
> max_counter_value
)
1858 devpriv
->divisor_a0
= max_counter_value
;
1859 if (devpriv
->divisor_b1
< min_counter_value
)
1860 devpriv
->divisor_b1
= min_counter_value
;
1861 if (devpriv
->divisor_b1
> max_counter_value
)
1862 devpriv
->divisor_b1
= max_counter_value
;
1863 /* write corrected timings to command */
1864 labpc_set_ai_convert_period(cmd
, mode
,
1865 base_period
* devpriv
->divisor_a0
);
1866 labpc_set_ai_scan_period(cmd
, mode
,
1867 base_period
* devpriv
->divisor_b1
);
1869 * if only one TRIG_TIMER is used, we can employ the generic
1870 * cascaded timing functions
1872 } else if (scan_period
) {
1874 * calculate cascaded counter values
1875 * that give desired scan timing
1877 i8253_cascade_ns_to_timer_2div(LABPC_TIMER_BASE
,
1878 &(devpriv
->divisor_b1
),
1879 &(devpriv
->divisor_b0
),
1881 cmd
->flags
& TRIG_ROUND_MASK
);
1882 labpc_set_ai_scan_period(cmd
, mode
, scan_period
);
1883 } else if (convert_period
) {
1885 * calculate cascaded counter values
1886 * that give desired conversion timing
1888 i8253_cascade_ns_to_timer_2div(LABPC_TIMER_BASE
,
1889 &(devpriv
->divisor_a0
),
1890 &(devpriv
->divisor_b0
),
1892 cmd
->flags
& TRIG_ROUND_MASK
);
1893 labpc_set_ai_convert_period(cmd
, mode
, convert_period
);
1897 static int labpc_dio_mem_callback(int dir
, int port
, int data
,
1898 unsigned long iobase
)
1901 writeb(data
, (void __iomem
*)(iobase
+ port
));
1904 return readb((void __iomem
*)(iobase
+ port
));
1908 /* lowlevel write to eeprom/dac */
1909 static void labpc_serial_out(struct comedi_device
*dev
, unsigned int value
,
1910 unsigned int value_width
)
1912 struct labpc_private
*devpriv
= dev
->private;
1915 for (i
= 1; i
<= value_width
; i
++) {
1916 /* clear serial clock */
1917 devpriv
->command5_bits
&= ~SCLOCK_BIT
;
1918 /* send bits most significant bit first */
1919 if (value
& (1 << (value_width
- i
)))
1920 devpriv
->command5_bits
|= SDATA_BIT
;
1922 devpriv
->command5_bits
&= ~SDATA_BIT
;
1924 devpriv
->write_byte(devpriv
->command5_bits
,
1925 dev
->iobase
+ COMMAND5_REG
);
1926 /* set clock to load bit */
1927 devpriv
->command5_bits
|= SCLOCK_BIT
;
1929 devpriv
->write_byte(devpriv
->command5_bits
,
1930 dev
->iobase
+ COMMAND5_REG
);
1934 /* lowlevel read from eeprom */
1935 static unsigned int labpc_serial_in(struct comedi_device
*dev
)
1937 struct labpc_private
*devpriv
= dev
->private;
1938 unsigned int value
= 0;
1940 const int value_width
= 8; /* number of bits wide values are */
1942 for (i
= 1; i
<= value_width
; i
++) {
1943 /* set serial clock */
1944 devpriv
->command5_bits
|= SCLOCK_BIT
;
1946 devpriv
->write_byte(devpriv
->command5_bits
,
1947 dev
->iobase
+ COMMAND5_REG
);
1948 /* clear clock bit */
1949 devpriv
->command5_bits
&= ~SCLOCK_BIT
;
1951 devpriv
->write_byte(devpriv
->command5_bits
,
1952 dev
->iobase
+ COMMAND5_REG
);
1953 /* read bits most significant bit first */
1955 devpriv
->status2_bits
=
1956 devpriv
->read_byte(dev
->iobase
+ STATUS2_REG
);
1957 if (devpriv
->status2_bits
& EEPROM_OUT_BIT
)
1958 value
|= 1 << (value_width
- i
);
1964 static unsigned int labpc_eeprom_read(struct comedi_device
*dev
,
1965 unsigned int address
)
1967 struct labpc_private
*devpriv
= dev
->private;
1969 /* bits to tell eeprom to expect a read */
1970 const int read_instruction
= 0x3;
1971 /* 8 bit write lengths to eeprom */
1972 const int write_length
= 8;
1974 /* enable read/write to eeprom */
1975 devpriv
->command5_bits
&= ~EEPROM_EN_BIT
;
1977 devpriv
->write_byte(devpriv
->command5_bits
, dev
->iobase
+ COMMAND5_REG
);
1978 devpriv
->command5_bits
|= EEPROM_EN_BIT
| EEPROM_WRITE_UNPROTECT_BIT
;
1980 devpriv
->write_byte(devpriv
->command5_bits
, dev
->iobase
+ COMMAND5_REG
);
1982 /* send read instruction */
1983 labpc_serial_out(dev
, read_instruction
, write_length
);
1984 /* send 8 bit address to read from */
1985 labpc_serial_out(dev
, address
, write_length
);
1987 value
= labpc_serial_in(dev
);
1989 /* disable read/write to eeprom */
1990 devpriv
->command5_bits
&= ~EEPROM_EN_BIT
& ~EEPROM_WRITE_UNPROTECT_BIT
;
1992 devpriv
->write_byte(devpriv
->command5_bits
, dev
->iobase
+ COMMAND5_REG
);
1997 static int labpc_eeprom_write(struct comedi_device
*dev
,
1998 unsigned int address
, unsigned int value
)
2000 struct labpc_private
*devpriv
= dev
->private;
2001 const int write_enable_instruction
= 0x6;
2002 const int write_instruction
= 0x2;
2003 const int write_length
= 8; /* 8 bit write lengths to eeprom */
2004 const int write_in_progress_bit
= 0x1;
2005 const int timeout
= 10000;
2008 /* make sure there isn't already a write in progress */
2009 for (i
= 0; i
< timeout
; i
++) {
2010 if ((labpc_eeprom_read_status(dev
) & write_in_progress_bit
) ==
2015 comedi_error(dev
, "eeprom write timed out");
2018 /* update software copy of eeprom */
2019 devpriv
->eeprom_data
[address
] = value
;
2021 /* enable read/write to eeprom */
2022 devpriv
->command5_bits
&= ~EEPROM_EN_BIT
;
2024 devpriv
->write_byte(devpriv
->command5_bits
, dev
->iobase
+ COMMAND5_REG
);
2025 devpriv
->command5_bits
|= EEPROM_EN_BIT
| EEPROM_WRITE_UNPROTECT_BIT
;
2027 devpriv
->write_byte(devpriv
->command5_bits
, dev
->iobase
+ COMMAND5_REG
);
2029 /* send write_enable instruction */
2030 labpc_serial_out(dev
, write_enable_instruction
, write_length
);
2031 devpriv
->command5_bits
&= ~EEPROM_EN_BIT
;
2033 devpriv
->write_byte(devpriv
->command5_bits
, dev
->iobase
+ COMMAND5_REG
);
2035 /* send write instruction */
2036 devpriv
->command5_bits
|= EEPROM_EN_BIT
;
2038 devpriv
->write_byte(devpriv
->command5_bits
, dev
->iobase
+ COMMAND5_REG
);
2039 labpc_serial_out(dev
, write_instruction
, write_length
);
2040 /* send 8 bit address to write to */
2041 labpc_serial_out(dev
, address
, write_length
);
2043 labpc_serial_out(dev
, value
, write_length
);
2044 devpriv
->command5_bits
&= ~EEPROM_EN_BIT
;
2046 devpriv
->write_byte(devpriv
->command5_bits
, dev
->iobase
+ COMMAND5_REG
);
2048 /* disable read/write to eeprom */
2049 devpriv
->command5_bits
&= ~EEPROM_EN_BIT
& ~EEPROM_WRITE_UNPROTECT_BIT
;
2051 devpriv
->write_byte(devpriv
->command5_bits
, dev
->iobase
+ COMMAND5_REG
);
2056 static unsigned int labpc_eeprom_read_status(struct comedi_device
*dev
)
2058 struct labpc_private
*devpriv
= dev
->private;
2060 const int read_status_instruction
= 0x5;
2061 const int write_length
= 8; /* 8 bit write lengths to eeprom */
2063 /* enable read/write to eeprom */
2064 devpriv
->command5_bits
&= ~EEPROM_EN_BIT
;
2066 devpriv
->write_byte(devpriv
->command5_bits
, dev
->iobase
+ COMMAND5_REG
);
2067 devpriv
->command5_bits
|= EEPROM_EN_BIT
| EEPROM_WRITE_UNPROTECT_BIT
;
2069 devpriv
->write_byte(devpriv
->command5_bits
, dev
->iobase
+ COMMAND5_REG
);
2071 /* send read status instruction */
2072 labpc_serial_out(dev
, read_status_instruction
, write_length
);
2074 value
= labpc_serial_in(dev
);
2076 /* disable read/write to eeprom */
2077 devpriv
->command5_bits
&= ~EEPROM_EN_BIT
& ~EEPROM_WRITE_UNPROTECT_BIT
;
2079 devpriv
->write_byte(devpriv
->command5_bits
, dev
->iobase
+ COMMAND5_REG
);
2084 /* writes to 8 bit calibration dacs */
2085 static void write_caldac(struct comedi_device
*dev
, unsigned int channel
,
2088 struct labpc_private
*devpriv
= dev
->private;
2090 if (value
== devpriv
->caldac
[channel
])
2092 devpriv
->caldac
[channel
] = value
;
2094 /* clear caldac load bit and make sure we don't write to eeprom */
2095 devpriv
->command5_bits
&=
2096 ~CALDAC_LOAD_BIT
& ~EEPROM_EN_BIT
& ~EEPROM_WRITE_UNPROTECT_BIT
;
2098 devpriv
->write_byte(devpriv
->command5_bits
, dev
->iobase
+ COMMAND5_REG
);
2100 /* write 4 bit channel */
2101 labpc_serial_out(dev
, channel
, 4);
2102 /* write 8 bit caldac value */
2103 labpc_serial_out(dev
, value
, 8);
2105 /* set and clear caldac bit to load caldac value */
2106 devpriv
->command5_bits
|= CALDAC_LOAD_BIT
;
2108 devpriv
->write_byte(devpriv
->command5_bits
, dev
->iobase
+ COMMAND5_REG
);
2109 devpriv
->command5_bits
&= ~CALDAC_LOAD_BIT
;
2111 devpriv
->write_byte(devpriv
->command5_bits
, dev
->iobase
+ COMMAND5_REG
);
2114 static struct comedi_driver labpc_driver
= {
2115 .driver_name
= DRV_NAME
,
2116 .module
= THIS_MODULE
,
2117 .attach
= labpc_attach
,
2118 .attach_pci
= labpc_attach_pci
,
2119 .detach
= labpc_common_detach
,
2120 .num_names
= ARRAY_SIZE(labpc_boards
),
2121 .board_name
= &labpc_boards
[0].name
,
2122 .offset
= sizeof(struct labpc_board_struct
),
2125 #ifdef CONFIG_COMEDI_PCI_DRIVERS
2126 static DEFINE_PCI_DEVICE_TABLE(labpc_pci_table
) = {
2127 {PCI_DEVICE(PCI_VENDOR_ID_NI
, 0x161)},
2130 MODULE_DEVICE_TABLE(pci
, labpc_pci_table
);
2132 static int __devinit
labpc_pci_probe(struct pci_dev
*dev
,
2133 const struct pci_device_id
*ent
)
2135 return comedi_pci_auto_config(dev
, &labpc_driver
);
2138 static void __devexit
labpc_pci_remove(struct pci_dev
*dev
)
2140 comedi_pci_auto_unconfig(dev
);
2143 static struct pci_driver labpc_pci_driver
= {
2145 .id_table
= labpc_pci_table
,
2146 .probe
= labpc_pci_probe
,
2147 .remove
= __devexit_p(labpc_pci_remove
)
2149 module_comedi_pci_driver(labpc_driver
, labpc_pci_driver
);
2151 module_comedi_driver(labpc_driver
);
2155 MODULE_AUTHOR("Comedi http://www.comedi.org");
2156 MODULE_DESCRIPTION("Comedi low-level driver");
2157 MODULE_LICENSE("GPL");