void ni_tio_init_counter(struct ni_gpct *counter)
{
struct ni_gpct_device *counter_dev = counter->counter_dev;
ni_tio_reset_count_and_disarm(counter);
/* initialize counter registers */
counter_dev->regs[NITIO_Gi_Autoincrement_Reg(counter->counter_index)] =
0x0;
write_register(counter,
counter_dev->
regs[NITIO_Gi_Autoincrement_Reg(counter->counter_index)],
NITIO_Gi_Autoincrement_Reg(counter->counter_index));
ni_tio_set_bits(counter, NITIO_Gi_Command_Reg(counter->counter_index),
~0, Gi_Synchronize_Gate_Bit);
ni_tio_set_bits(counter, NITIO_Gi_Mode_Reg(counter->counter_index), ~0,
0);
counter_dev->regs[NITIO_Gi_LoadA_Reg(counter->counter_index)] = 0x0;
write_register(counter,
counter_dev->
regs[NITIO_Gi_LoadA_Reg(counter->counter_index)],
NITIO_Gi_LoadA_Reg(counter->counter_index));
counter_dev->regs[NITIO_Gi_LoadB_Reg(counter->counter_index)] = 0x0;
write_register(counter,
counter_dev->
regs[NITIO_Gi_LoadB_Reg(counter->counter_index)],
NITIO_Gi_LoadB_Reg(counter->counter_index));
ni_tio_set_bits(counter,
NITIO_Gi_Input_Select_Reg(counter->counter_index), ~0,
0);
if (ni_tio_counting_mode_registers_present(counter_dev)) {
ni_tio_set_bits(counter,
NITIO_Gi_Counting_Mode_Reg(counter->
counter_index), ~0,
0);
}
if (ni_tio_second_gate_registers_present(counter_dev)) {
counter_dev->
regs[NITIO_Gi_Second_Gate_Reg(counter->counter_index)] =
0x0;
write_register(counter,
counter_dev->
regs[NITIO_Gi_Second_Gate_Reg
(counter->counter_index)],
NITIO_Gi_Second_Gate_Reg(counter->
counter_index));
}
ni_tio_set_bits(counter,
NITIO_Gi_DMA_Config_Reg(counter->counter_index), ~0,
0x0);
ni_tio_set_bits(counter,
NITIO_Gi_Interrupt_Enable_Reg(counter->counter_index),
~0, 0x0);
}
static unsigned ni_tio_next_load_register(struct ni_gpct *counter)
{
const unsigned bits = read_register(counter,
NITIO_Gxx_Status_Reg(counter->counter_index));
if (bits & Gi_Next_Load_Source_Bit(counter->counter_index)) {
return NITIO_Gi_LoadB_Reg(counter->counter_index);
} else {
return NITIO_Gi_LoadA_Reg(counter->counter_index);
}
}
int ni_tio_rinsn(struct ni_gpct *counter, struct comedi_insn *insn,
unsigned int *data)
{
struct ni_gpct_device *counter_dev = counter->counter_dev;
const unsigned channel = CR_CHAN(insn->chanspec);
unsigned first_read;
unsigned second_read;
unsigned correct_read;
if (insn->n < 1)
return 0;
switch (channel) {
case 0:
ni_tio_set_bits(counter,
NITIO_Gi_Command_Reg(counter->counter_index),
Gi_Save_Trace_Bit, 0);
ni_tio_set_bits(counter,
NITIO_Gi_Command_Reg(counter->counter_index),
Gi_Save_Trace_Bit, Gi_Save_Trace_Bit);
/* The count doesn't get latched until the next clock edge, so it is possible the count
may change (once) while we are reading. Since the read of the SW_Save_Reg isn't
atomic (apparently even when it's a 32 bit register according to 660x docs),
we need to read twice and make sure the reading hasn't changed. If it has,
a third read will be correct since the count value will definitely have latched by then. */
first_read =
read_register(counter,
NITIO_Gi_SW_Save_Reg(counter->counter_index));
second_read =
read_register(counter,
NITIO_Gi_SW_Save_Reg(counter->counter_index));
if (first_read != second_read)
correct_read =
read_register(counter,
NITIO_Gi_SW_Save_Reg(counter->
counter_index));
else
correct_read = first_read;
data[0] = correct_read;
return 0;
break;
case 1:
data[0] =
counter_dev->
regs[NITIO_Gi_LoadA_Reg(counter->counter_index)];
break;
case 2:
data[0] =
counter_dev->
regs[NITIO_Gi_LoadB_Reg(counter->counter_index)];
break;
}
return 0;
}
int ni_tio_winsn(struct ni_gpct *counter, struct comedi_insn *insn,
unsigned int *data)
{
struct ni_gpct_device *counter_dev = counter->counter_dev;
const unsigned channel = CR_CHAN(insn->chanspec);
unsigned load_reg;
if (insn->n < 1)
return 0;
switch (channel) {
case 0:
/* Unsafe if counter is armed. Should probably check status and return -EBUSY if armed. */
/* Don't disturb load source select, just use whichever load register is already selected. */
load_reg = ni_tio_next_load_register(counter);
write_register(counter, data[0], load_reg);
ni_tio_set_bits_transient(counter,
NITIO_Gi_Command_Reg(counter->
counter_index),
0, 0, Gi_Load_Bit);
/* restore state of load reg to whatever the user set last set it to */
write_register(counter, counter_dev->regs[load_reg], load_reg);
break;
case 1:
counter_dev->regs[NITIO_Gi_LoadA_Reg(counter->counter_index)] =
data[0];
write_register(counter, data[0],
NITIO_Gi_LoadA_Reg(counter->counter_index));
break;
case 2:
counter_dev->regs[NITIO_Gi_LoadB_Reg(counter->counter_index)] =
data[0];
write_register(counter, data[0],
NITIO_Gi_LoadB_Reg(counter->counter_index));
break;
default:
return -EINVAL;
break;
}
return 0;
}
int ni_tio_winsn(struct ni_gpct *counter, struct comedi_insn *insn,
unsigned int *data)
{
struct ni_gpct_device *counter_dev = counter->counter_dev;
const unsigned channel = CR_CHAN(insn->chanspec);
unsigned load_reg;
if (insn->n < 1)
return 0;
switch (channel) {
case 0:
load_reg = ni_tio_next_load_register(counter);
write_register(counter, data[0], load_reg);
ni_tio_set_bits_transient(counter,
NITIO_Gi_Command_Reg(counter->
counter_index),
0, 0, Gi_Load_Bit);
write_register(counter, counter_dev->regs[load_reg], load_reg);
break;
case 1:
counter_dev->regs[NITIO_Gi_LoadA_Reg(counter->counter_index)] =
data[0];
write_register(counter, data[0],
NITIO_Gi_LoadA_Reg(counter->counter_index));
break;
case 2:
counter_dev->regs[NITIO_Gi_LoadB_Reg(counter->counter_index)] =
data[0];
write_register(counter, data[0],
NITIO_Gi_LoadB_Reg(counter->counter_index));
break;
default:
return -EINVAL;
break;
}
return 0;
}
int ni_tio_rinsn(struct ni_gpct *counter, struct comedi_insn *insn,
unsigned int *data)
{
struct ni_gpct_device *counter_dev = counter->counter_dev;
const unsigned channel = CR_CHAN(insn->chanspec);
unsigned first_read;
unsigned second_read;
unsigned correct_read;
if (insn->n < 1)
return 0;
switch (channel) {
case 0:
ni_tio_set_bits(counter,
NITIO_Gi_Command_Reg(counter->counter_index),
Gi_Save_Trace_Bit, 0);
ni_tio_set_bits(counter,
NITIO_Gi_Command_Reg(counter->counter_index),
Gi_Save_Trace_Bit, Gi_Save_Trace_Bit);
first_read =
read_register(counter,
NITIO_Gi_SW_Save_Reg(counter->counter_index));
second_read =
read_register(counter,
NITIO_Gi_SW_Save_Reg(counter->counter_index));
if (first_read != second_read)
correct_read =
read_register(counter,
NITIO_Gi_SW_Save_Reg(counter->
counter_index));
else
correct_read = first_read;
data[0] = correct_read;
return 0;
break;
case 1:
data[0] =
counter_dev->
regs[NITIO_Gi_LoadA_Reg(counter->counter_index)];
break;
case 2:
data[0] =
counter_dev->
regs[NITIO_Gi_LoadB_Reg(counter->counter_index)];
break;
};
return 0;
}