struct comedi_subdevice *s,
struct comedi_cmd *cmd);
-/*-----------------------------------------------------------------------------
- Meilhaus inline functions
- ---------------------------------------------------------------------------*/
-
-static inline void me4000_outb(struct comedi_device *dev, unsigned char value,
- unsigned long port)
-{
- outb(value, port);
-}
-
-static inline void me4000_outl(struct comedi_device *dev, unsigned long value,
- unsigned long port)
-{
- outl(value, port);
-}
-
-static inline unsigned long me4000_inl(struct comedi_device *dev,
- unsigned long port)
-{
- unsigned long value;
- value = inl(port);
- return value;
-}
-
-static inline unsigned char me4000_inb(struct comedi_device *dev,
- unsigned long port)
-{
- unsigned char value;
- value = inb(port);
- return value;
-}
-
static const struct comedi_lrange me4000_ai_range = {
4,
{
unsigned long icr;
/* Make a hardware reset */
- icr = me4000_inl(dev, info->plx_regbase + PLX_ICR);
+ icr = inl(info->plx_regbase + PLX_ICR);
icr |= 0x40000000;
- me4000_outl(dev, icr, info->plx_regbase + PLX_ICR);
+ outl(icr, info->plx_regbase + PLX_ICR);
icr &= ~0x40000000;
- me4000_outl(dev, icr, info->plx_regbase + PLX_ICR);
+ outl(icr, info->plx_regbase + PLX_ICR);
/* 0x8000 to the DACs means an output voltage of 0V */
- me4000_outl(dev, 0x8000,
- info->me4000_regbase + ME4000_AO_00_SINGLE_REG);
- me4000_outl(dev, 0x8000,
- info->me4000_regbase + ME4000_AO_01_SINGLE_REG);
- me4000_outl(dev, 0x8000,
- info->me4000_regbase + ME4000_AO_02_SINGLE_REG);
- me4000_outl(dev, 0x8000,
- info->me4000_regbase + ME4000_AO_03_SINGLE_REG);
+ outl(0x8000, info->me4000_regbase + ME4000_AO_00_SINGLE_REG);
+ outl(0x8000, info->me4000_regbase + ME4000_AO_01_SINGLE_REG);
+ outl(0x8000, info->me4000_regbase + ME4000_AO_02_SINGLE_REG);
+ outl(0x8000, info->me4000_regbase + ME4000_AO_03_SINGLE_REG);
/* Set both stop bits in the analog input control register */
- me4000_outl(dev,
- ME4000_AI_CTRL_BIT_IMMEDIATE_STOP | ME4000_AI_CTRL_BIT_STOP,
- info->me4000_regbase + ME4000_AI_CTRL_REG);
+ outl(ME4000_AI_CTRL_BIT_IMMEDIATE_STOP | ME4000_AI_CTRL_BIT_STOP,
+ info->me4000_regbase + ME4000_AI_CTRL_REG);
/* Set both stop bits in the analog output control register */
- me4000_outl(dev,
- ME4000_AO_CTRL_BIT_IMMEDIATE_STOP | ME4000_AO_CTRL_BIT_STOP,
- info->me4000_regbase + ME4000_AO_00_CTRL_REG);
- me4000_outl(dev,
- ME4000_AO_CTRL_BIT_IMMEDIATE_STOP | ME4000_AO_CTRL_BIT_STOP,
- info->me4000_regbase + ME4000_AO_01_CTRL_REG);
- me4000_outl(dev,
- ME4000_AO_CTRL_BIT_IMMEDIATE_STOP | ME4000_AO_CTRL_BIT_STOP,
- info->me4000_regbase + ME4000_AO_02_CTRL_REG);
- me4000_outl(dev,
- ME4000_AO_CTRL_BIT_IMMEDIATE_STOP | ME4000_AO_CTRL_BIT_STOP,
- info->me4000_regbase + ME4000_AO_03_CTRL_REG);
+ outl(ME4000_AO_CTRL_BIT_IMMEDIATE_STOP | ME4000_AO_CTRL_BIT_STOP,
+ info->me4000_regbase + ME4000_AO_00_CTRL_REG);
+ outl(ME4000_AO_CTRL_BIT_IMMEDIATE_STOP | ME4000_AO_CTRL_BIT_STOP,
+ info->me4000_regbase + ME4000_AO_01_CTRL_REG);
+ outl(ME4000_AO_CTRL_BIT_IMMEDIATE_STOP | ME4000_AO_CTRL_BIT_STOP,
+ info->me4000_regbase + ME4000_AO_02_CTRL_REG);
+ outl(ME4000_AO_CTRL_BIT_IMMEDIATE_STOP | ME4000_AO_CTRL_BIT_STOP,
+ info->me4000_regbase + ME4000_AO_03_CTRL_REG);
/* Enable interrupts on the PLX */
- me4000_outl(dev, 0x43, info->plx_regbase + PLX_INTCSR);
+ outl(0x43, info->plx_regbase + PLX_INTCSR);
/* Set the adustment register for AO demux */
- me4000_outl(dev, ME4000_AO_DEMUX_ADJUST_VALUE,
+ outl(ME4000_AO_DEMUX_ADJUST_VALUE,
info->me4000_regbase + ME4000_AO_DEMUX_ADJUST_REG);
/*
* Set digital I/O direction for port 0
* to output on isolated versions
*/
- if (!(me4000_inl(dev, info->me4000_regbase + ME4000_DIO_DIR_REG) & 0x1)) {
- me4000_outl(dev, 0x1,
- info->me4000_regbase + ME4000_DIO_CTRL_REG);
- }
+ if (!(inl(info->me4000_regbase + ME4000_DIO_DIR_REG) & 0x1))
+ outl(0x1, info->me4000_regbase + ME4000_DIO_CTRL_REG);
return 0;
}
entry |= ME4000_AI_LIST_LAST_ENTRY;
/* Clear channel list, data fifo and both stop bits */
- tmp = me4000_inl(dev, info->ai_context.ctrl_reg);
+ tmp = inl(info->ai_context.ctrl_reg);
tmp &= ~(ME4000_AI_CTRL_BIT_CHANNEL_FIFO |
ME4000_AI_CTRL_BIT_DATA_FIFO |
ME4000_AI_CTRL_BIT_STOP | ME4000_AI_CTRL_BIT_IMMEDIATE_STOP);
- me4000_outl(dev, tmp, info->ai_context.ctrl_reg);
+ outl(tmp, info->ai_context.ctrl_reg);
/* Set the acquisition mode to single */
tmp &= ~(ME4000_AI_CTRL_BIT_MODE_0 | ME4000_AI_CTRL_BIT_MODE_1 |
ME4000_AI_CTRL_BIT_MODE_2);
- me4000_outl(dev, tmp, info->ai_context.ctrl_reg);
+ outl(tmp, info->ai_context.ctrl_reg);
/* Enable channel list and data fifo */
tmp |= ME4000_AI_CTRL_BIT_CHANNEL_FIFO | ME4000_AI_CTRL_BIT_DATA_FIFO;
- me4000_outl(dev, tmp, info->ai_context.ctrl_reg);
+ outl(tmp, info->ai_context.ctrl_reg);
/* Generate channel list entry */
- me4000_outl(dev, entry, info->ai_context.channel_list_reg);
+ outl(entry, info->ai_context.channel_list_reg);
/* Set the timer to maximum sample rate */
- me4000_outl(dev, ME4000_AI_MIN_TICKS, info->ai_context.chan_timer_reg);
- me4000_outl(dev, ME4000_AI_MIN_TICKS,
- info->ai_context.chan_pre_timer_reg);
+ outl(ME4000_AI_MIN_TICKS, info->ai_context.chan_timer_reg);
+ outl(ME4000_AI_MIN_TICKS, info->ai_context.chan_pre_timer_reg);
/* Start conversion by dummy read */
- me4000_inl(dev, info->ai_context.start_reg);
+ inl(info->ai_context.start_reg);
/* Wait until ready */
udelay(10);
- if (!
- (me4000_inl(dev, info->ai_context.status_reg) &
+ if (!(inl(info->ai_context.status_reg) &
ME4000_AI_STATUS_BIT_EF_DATA)) {
printk(KERN_ERR
"comedi%d: me4000: me4000_ai_insn_read(): "
}
/* Read value from data fifo */
- lval = me4000_inl(dev, info->ai_context.data_reg) & 0xFFFF;
+ lval = inl(info->ai_context.data_reg) & 0xFFFF;
data[0] = lval ^ 0x8000;
return 1;
unsigned long tmp;
/* Stop any running conversion */
- tmp = me4000_inl(dev, info->ai_context.ctrl_reg);
+ tmp = inl(info->ai_context.ctrl_reg);
tmp &= ~(ME4000_AI_CTRL_BIT_STOP | ME4000_AI_CTRL_BIT_IMMEDIATE_STOP);
- me4000_outl(dev, tmp, info->ai_context.ctrl_reg);
+ outl(tmp, info->ai_context.ctrl_reg);
/* Clear the control register */
- me4000_outl(dev, 0x0, info->ai_context.ctrl_reg);
+ outl(0x0, info->ai_context.ctrl_reg);
return 0;
}
unsigned int init_ticks,
unsigned int scan_ticks, unsigned int chan_ticks)
{
- me4000_outl(dev, init_ticks - 1,
- info->ai_context.scan_pre_timer_low_reg);
- me4000_outl(dev, 0x0, info->ai_context.scan_pre_timer_high_reg);
+ outl(init_ticks - 1, info->ai_context.scan_pre_timer_low_reg);
+ outl(0x0, info->ai_context.scan_pre_timer_high_reg);
if (scan_ticks) {
- me4000_outl(dev, scan_ticks - 1,
- info->ai_context.scan_timer_low_reg);
- me4000_outl(dev, 0x0, info->ai_context.scan_timer_high_reg);
+ outl(scan_ticks - 1, info->ai_context.scan_timer_low_reg);
+ outl(0x0, info->ai_context.scan_timer_high_reg);
}
- me4000_outl(dev, chan_ticks - 1, info->ai_context.chan_pre_timer_reg);
- me4000_outl(dev, chan_ticks - 1, info->ai_context.chan_timer_reg);
+ outl(chan_ticks - 1, info->ai_context.chan_pre_timer_reg);
+ outl(chan_ticks - 1, info->ai_context.chan_timer_reg);
}
static int ai_prepare(struct comedi_device *dev,
ai_write_timer(dev, init_ticks, scan_ticks, chan_ticks);
/* Reset control register */
- me4000_outl(dev, tmp, info->ai_context.ctrl_reg);
+ outl(tmp, info->ai_context.ctrl_reg);
/* Start sources */
if ((cmd->start_src == TRIG_EXT &&
/* Stop triggers */
if (cmd->stop_src == TRIG_COUNT) {
- me4000_outl(dev, cmd->chanlist_len * cmd->stop_arg,
+ outl(cmd->chanlist_len * cmd->stop_arg,
info->ai_context.sample_counter_reg);
tmp |= ME4000_AI_CTRL_BIT_HF_IRQ | ME4000_AI_CTRL_BIT_SC_IRQ;
} else if (cmd->stop_src == TRIG_NONE &&
cmd->scan_end_src == TRIG_COUNT) {
- me4000_outl(dev, cmd->scan_end_arg,
+ outl(cmd->scan_end_arg,
info->ai_context.sample_counter_reg);
tmp |= ME4000_AI_CTRL_BIT_HF_IRQ | ME4000_AI_CTRL_BIT_SC_IRQ;
} else {
}
/* Write the setup to the control register */
- me4000_outl(dev, tmp, info->ai_context.ctrl_reg);
+ outl(tmp, info->ai_context.ctrl_reg);
/* Write the channel list */
ai_write_chanlist(dev, s, cmd);
else
entry |= ME4000_AI_LIST_INPUT_SINGLE_ENDED;
- me4000_outl(dev, entry, info->ai_context.channel_list_reg);
+ outl(entry, info->ai_context.channel_list_reg);
}
return 0;
return err;
/* Start acquistion by dummy read */
- me4000_inl(dev, info->ai_context.start_reg);
+ inl(info->ai_context.start_reg);
return 0;
}
return IRQ_HANDLED;
}
- if (me4000_inl(dev,
- ai_context->irq_status_reg) &
+ if (inl(ai_context->irq_status_reg) &
ME4000_IRQ_STATUS_BIT_AI_HF) {
ISR_PDEBUG
("me4000_ai_isr(): Fifo half full interrupt occurred\n");
/* Read status register to find out what happened */
- tmp = me4000_inl(dev, ai_context->ctrl_reg);
+ tmp = inl(ai_context->ctrl_reg);
if (!(tmp & ME4000_AI_STATUS_BIT_FF_DATA) &&
!(tmp & ME4000_AI_STATUS_BIT_HF_DATA) &&
tmp |= ME4000_AI_CTRL_BIT_IMMEDIATE_STOP;
tmp &= ~(ME4000_AI_CTRL_BIT_HF_IRQ |
ME4000_AI_CTRL_BIT_SC_IRQ);
- me4000_outl(dev, tmp, ai_context->ctrl_reg);
+ outl(tmp, ai_context->ctrl_reg);
s->async->events |= COMEDI_CB_ERROR | COMEDI_CB_EOA;
tmp |= ME4000_AI_CTRL_BIT_IMMEDIATE_STOP;
tmp &= ~(ME4000_AI_CTRL_BIT_HF_IRQ |
ME4000_AI_CTRL_BIT_SC_IRQ);
- me4000_outl(dev, tmp, ai_context->ctrl_reg);
+ outl(tmp, ai_context->ctrl_reg);
s->async->events |= COMEDI_CB_ERROR | COMEDI_CB_EOA;
tmp |= ME4000_AI_CTRL_BIT_IMMEDIATE_STOP;
tmp &= ~(ME4000_AI_CTRL_BIT_HF_IRQ |
ME4000_AI_CTRL_BIT_SC_IRQ);
- me4000_outl(dev, tmp, ai_context->ctrl_reg);
+ outl(tmp, ai_context->ctrl_reg);
s->async->events |= COMEDI_CB_OVERFLOW;
/* Work is done, so reset the interrupt */
ISR_PDEBUG("me4000_ai_isr(): Reset fifo half full interrupt\n");
tmp |= ME4000_AI_CTRL_BIT_HF_IRQ_RESET;
- me4000_outl(dev, tmp, ai_context->ctrl_reg);
+ outl(tmp, ai_context->ctrl_reg);
tmp &= ~ME4000_AI_CTRL_BIT_HF_IRQ_RESET;
- me4000_outl(dev, tmp, ai_context->ctrl_reg);
+ outl(tmp, ai_context->ctrl_reg);
}
- if (me4000_inl(dev,
- ai_context->irq_status_reg) & ME4000_IRQ_STATUS_BIT_SC) {
+ if (inl(ai_context->irq_status_reg) & ME4000_IRQ_STATUS_BIT_SC) {
ISR_PDEBUG
("me4000_ai_isr(): Sample counter interrupt occurred\n");
* Acquisition is complete, so stop
* conversion and disable all interrupts
*/
- tmp = me4000_inl(dev, ai_context->ctrl_reg);
+ tmp = inl(ai_context->ctrl_reg);
tmp |= ME4000_AI_CTRL_BIT_IMMEDIATE_STOP;
tmp &= ~(ME4000_AI_CTRL_BIT_HF_IRQ | ME4000_AI_CTRL_BIT_SC_IRQ);
- me4000_outl(dev, tmp, ai_context->ctrl_reg);
+ outl(tmp, ai_context->ctrl_reg);
/* Poll data until fifo empty */
while (inl(ai_context->ctrl_reg) & ME4000_AI_STATUS_BIT_EF_DATA) {
ISR_PDEBUG
("me4000_ai_isr(): Reset interrupt from sample counter\n");
tmp |= ME4000_AI_CTRL_BIT_SC_IRQ_RESET;
- me4000_outl(dev, tmp, ai_context->ctrl_reg);
+ outl(tmp, ai_context->ctrl_reg);
tmp &= ~ME4000_AI_CTRL_BIT_SC_IRQ_RESET;
- me4000_outl(dev, tmp, ai_context->ctrl_reg);
+ outl(tmp, ai_context->ctrl_reg);
}
ISR_PDEBUG("me4000_ai_isr(): Events = 0x%X\n", s->async->events);
}
/* Stop any running conversion */
- tmp = me4000_inl(dev, info->ao_context[chan].ctrl_reg);
+ tmp = inl(info->ao_context[chan].ctrl_reg);
tmp |= ME4000_AO_CTRL_BIT_IMMEDIATE_STOP;
- me4000_outl(dev, tmp, info->ao_context[chan].ctrl_reg);
+ outl(tmp, info->ao_context[chan].ctrl_reg);
/* Clear control register and set to single mode */
- me4000_outl(dev, 0x0, info->ao_context[chan].ctrl_reg);
+ outl(0x0, info->ao_context[chan].ctrl_reg);
/* Write data value */
- me4000_outl(dev, data[0], info->ao_context[chan].single_reg);
+ outl(data[0], info->ao_context[chan].single_reg);
/* Store in the mirror */
info->ao_context[chan].mirror = data[0];
s->state |= data[0] & data[1];
/* Write out the new digital output lines */
- me4000_outl(dev, (s->state >> 0) & 0xFF,
+ outl((s->state >> 0) & 0xFF,
info->dio_context.port_0_reg);
- me4000_outl(dev, (s->state >> 8) & 0xFF,
+ outl((s->state >> 8) & 0xFF,
info->dio_context.port_1_reg);
- me4000_outl(dev, (s->state >> 16) & 0xFF,
+ outl((s->state >> 16) & 0xFF,
info->dio_context.port_2_reg);
- me4000_outl(dev, (s->state >> 24) & 0xFF,
+ outl((s->state >> 24) & 0xFF,
info->dio_context.port_3_reg);
}
/* On return, data[1] contains the value of
the digital input and output lines. */
- data[1] =
- ((me4000_inl(dev, info->dio_context.port_0_reg) & 0xFF) << 0) |
- ((me4000_inl(dev, info->dio_context.port_1_reg) & 0xFF) << 8) |
- ((me4000_inl(dev, info->dio_context.port_2_reg) & 0xFF) << 16) |
- ((me4000_inl(dev, info->dio_context.port_3_reg) & 0xFF) << 24);
+ data[1] = ((inl(info->dio_context.port_0_reg) & 0xFF) << 0) |
+ ((inl(info->dio_context.port_1_reg) & 0xFF) << 8) |
+ ((inl(info->dio_context.port_2_reg) & 0xFF) << 16) |
+ ((inl(info->dio_context.port_3_reg) & 0xFF) << 24);
return 2;
}
* On the ME-4000 it is only possible to switch port wise (8 bit)
*/
- tmp = me4000_inl(dev, info->dio_context.ctrl_reg);
+ tmp = inl(info->dio_context.ctrl_reg);
if (data[0] == INSN_CONFIG_DIO_OUTPUT) {
if (chan < 8) {
* If one the first port is a fixed output
* port and the second is a fixed input port.
*/
- if (!me4000_inl(dev, info->dio_context.dir_reg))
+ if (!inl(info->dio_context.dir_reg))
return -ENODEV;
s->io_bits |= 0xFF00;
* If one the first port is a fixed output
* port and the second is a fixed input port.
*/
- if (!me4000_inl(dev, info->dio_context.dir_reg))
+ if (!inl(info->dio_context.dir_reg))
return -ENODEV;
s->io_bits &= ~0xFF;
}
}
- me4000_outl(dev, tmp, info->dio_context.ctrl_reg);
+ outl(tmp, info->dio_context.ctrl_reg);
return 1;
}
{
switch (channel) {
case 0:
- me4000_outb(dev, 0x30, info->cnt_context.ctrl_reg);
- me4000_outb(dev, 0x00, info->cnt_context.counter_0_reg);
- me4000_outb(dev, 0x00, info->cnt_context.counter_0_reg);
+ outb(0x30, info->cnt_context.ctrl_reg);
+ outb(0x00, info->cnt_context.counter_0_reg);
+ outb(0x00, info->cnt_context.counter_0_reg);
break;
case 1:
- me4000_outb(dev, 0x70, info->cnt_context.ctrl_reg);
- me4000_outb(dev, 0x00, info->cnt_context.counter_1_reg);
- me4000_outb(dev, 0x00, info->cnt_context.counter_1_reg);
+ outb(0x70, info->cnt_context.ctrl_reg);
+ outb(0x00, info->cnt_context.counter_1_reg);
+ outb(0x00, info->cnt_context.counter_1_reg);
break;
case 2:
- me4000_outb(dev, 0xB0, info->cnt_context.ctrl_reg);
- me4000_outb(dev, 0x00, info->cnt_context.counter_2_reg);
- me4000_outb(dev, 0x00, info->cnt_context.counter_2_reg);
+ outb(0xB0, info->cnt_context.ctrl_reg);
+ outb(0x00, info->cnt_context.counter_2_reg);
+ outb(0x00, info->cnt_context.counter_2_reg);
break;
default:
printk(KERN_ERR
/* Write the control word */
tmp |= 0x30;
- me4000_outb(dev, tmp, info->cnt_context.ctrl_reg);
+ outb(tmp, info->cnt_context.ctrl_reg);
return 0;
}
switch (insn->chanspec) {
case 0:
- tmp = me4000_inb(dev, info->cnt_context.counter_0_reg);
+ tmp = inb(info->cnt_context.counter_0_reg);
data[0] = tmp;
- tmp = me4000_inb(dev, info->cnt_context.counter_0_reg);
+ tmp = inb(info->cnt_context.counter_0_reg);
data[0] |= tmp << 8;
break;
case 1:
- tmp = me4000_inb(dev, info->cnt_context.counter_1_reg);
+ tmp = inb(info->cnt_context.counter_1_reg);
data[0] = tmp;
- tmp = me4000_inb(dev, info->cnt_context.counter_1_reg);
+ tmp = inb(info->cnt_context.counter_1_reg);
data[0] |= tmp << 8;
break;
case 2:
- tmp = me4000_inb(dev, info->cnt_context.counter_2_reg);
+ tmp = inb(info->cnt_context.counter_2_reg);
data[0] = tmp;
- tmp = me4000_inb(dev, info->cnt_context.counter_2_reg);
+ tmp = inb(info->cnt_context.counter_2_reg);
data[0] |= tmp << 8;
break;
default:
switch (insn->chanspec) {
case 0:
tmp = data[0] & 0xFF;
- me4000_outb(dev, tmp, info->cnt_context.counter_0_reg);
+ outb(tmp, info->cnt_context.counter_0_reg);
tmp = (data[0] >> 8) & 0xFF;
- me4000_outb(dev, tmp, info->cnt_context.counter_0_reg);
+ outb(tmp, info->cnt_context.counter_0_reg);
break;
case 1:
tmp = data[0] & 0xFF;
- me4000_outb(dev, tmp, info->cnt_context.counter_1_reg);
+ outb(tmp, info->cnt_context.counter_1_reg);
tmp = (data[0] >> 8) & 0xFF;
- me4000_outb(dev, tmp, info->cnt_context.counter_1_reg);
+ outb(tmp, info->cnt_context.counter_1_reg);
break;
case 2:
tmp = data[0] & 0xFF;
- me4000_outb(dev, tmp, info->cnt_context.counter_2_reg);
+ outb(tmp, info->cnt_context.counter_2_reg);
tmp = (data[0] >> 8) & 0xFF;
- me4000_outb(dev, tmp, info->cnt_context.counter_2_reg);
+ outb(tmp, info->cnt_context.counter_2_reg);
break;
default:
printk(KERN_ERR
* Check for optoisolated ME-4000 version. If one the first
* port is a fixed output port and the second is a fixed input port.
*/
- if (!me4000_inl(dev, info->dio_context.dir_reg)) {
+ if (!inl(info->dio_context.dir_reg)) {
s->io_bits |= 0xFF;
- me4000_outl(dev, ME4000_DIO_CTRL_BIT_MODE_0,
- info->dio_context.dir_reg);
+ outl(ME4000_DIO_CTRL_BIT_MODE_0, info->dio_context.dir_reg);
}
/*=========================================================================
OSDN Git Service
