Table of Contents
hil_task_create_other_reader_other_writer
Creates a task for reading from other inputs and writing to other outputs at the same time.
Description
The hil_task_create_other_reader_other_writer function creates a task for reading from the specified other input channels and writing to the specified other output channels at the same time. The task allows other operations to be performed while the other inputs are being read and the other outputs are being written "in the background". The data read from the other inputs is stored in an internal circular "task input buffer". The data written to the other outputs is read from an internal circular "task output buffer". The application may read the data from the task input buffer and write data to the task output buffer at any time using the hil_task_read_other_write_other function. Data may also be read separately from the task input buffer using the hil_task_read_other function, and data may also be written into the task output buffer using the hil_task_write_other function. The size of both the task input buffer and the task output buffer is determined by the samples_in_buffer parameter.
The hil_task_write_other function is typically called prior to starting the task in order to put the initial samples in the the task output buffer. After the task is started, hil_task_read_other_write_other is typically called to read the other input values from the task input buffer and to put more data into the task output buffer for the other outputs.
The task does not actually start reading from the other inputs and storing the data in the task input buffer or reading the data from the task output buffer and writing it to the other outputs until the hil_task_start function is called. In order for data to be available in the task buffer as soon as the task starts, store data in the buffer using hil_task_write_other prior to starting the task.
Each sampling instant, the task first reads from the other input channels selected and stores the data in the task input buffer. Then, in the same sampling instant, the task extracts one sample from the task output buffer and writes to the selected other output channels. This synchronization of input and output is particularly useful for system identification because the time at which a sample is read and a sample is written is known, so no postprocessing is required to determine the response delay in the system been identified.
Since the task writes to the other outputs at the sampling rate specified when the task is started, it will be reading data from the task output buffer at that rate. Thus, hil_task_read_other_write_other or hil_task_write_other must be called to add more data to the task output buffer before all the data in the buffer is depleted. Otherwise the task will have no data to write to the other outputs and will return with a QERR_BUFFER_OVERFLOW error the next time hil_task_read_other_write_other or hil_task_write_other is called.
The task must be deleted when it is no longer in use using the hil_task_delete function, in order to free the system and hardware resources used by the task. See Tasks for more information on tasks.
Prototype
t_error hil_task_create_other_reader_other_writer(t_card card, t_uint32 samples_in_buffer, const t_uint32 other_input_channels[], t_uint32 num_other_input_channels, const t_uint32 other_output_channels[], t_uint32 num_other_output_channels, t_task *task);
Parameters
t_card card
A handle to the board, as returned by hil_open.
t_uint32 samples_in_buffer
The number of samples in the task buffers. The hil_task_read_other_write_other function cannot read or write more samples than this in a single call. If the task input buffer overflows because hil_task_read_other_write_other has not been called in time to remove data from the task input buffer then the next call to hil_task_read_other_write_othe will return an HIL_BUFFER_OVERFLOW error. Likewise, if the task output buffer underflows because hil_task_read_other_write_other has not been called in time to add data to the task output buffer then the next call to hil_task_read_other_write_other will also return an HIL_BUFFER_OVERFLOW error. See Tasks for more information on task buffers.
const t_uint32 [] other_input_channels
An array containing the channel numbers of the other inputs to be read by the task.
Select a board type from the list for board-specific details: .
t_uint32 num_other_input_channels
The number of channels specified in the other_input_channels array.
const t_uint32 [] other_output_channels
An array containing the channel numbers of the other outputs to be written to by the task.
Select a board type from the list for board-specific details: .
t_uint32 num_other_output_channels
The number of channels specified in the other_output_channels array.
t_task * task
A handle to the task is returned in the t_task variable passed in this parameter. This argument cannot be NULL. Pass the address of a variable of type t_task.
Return value
The return value is 0 if the task is created successfully. Otherwise a
negative error code is returned. Error codes are
defined in quanser_errors.h
. A suitable error message
may be retrieved using
msg_get_error_message
.
Error codes
QERR_HIL_TASK_CREATE_OTHER_READER_OTHER_WRITER_NOT_SUPPORTED
This function is not supported by the board-specific HIL driver for this board type.
QERR_INVALID_CARD_HANDLE
An invalid card handle was passed as an argument. Once a card has been closed using hil_close the card handle is invalid.
QERR_TASK_ARGUMENT_IS_NULL
The task argument is NULL. A pointer to a t_task variable must be supplied because this variable must be passed to the other HIL task functions to refer to the task.
QERR_MISSING_OTHER_INPUTS
The other input channels argument is NULL when the number of other inputs specified is non-zero.
QERR_TOO_MANY_OTHER_INPUT_CHANNELS
Too many other input channels were specified.
QERR_INVALID_OTHER_INPUT_CHANNEL
One of the other input channels that was specified is not a valid channel number. Channel numbers range from 0 to one less than the number of channels.
QERR_OTHER_INPUT_CHANNELS_NOT_SUPPORTED
Other input channels are not supported by this board.
QERR_MISSING_OTHER_OUTPUTS
The other output channels argument is NULL when the number of other outputs specified is non-zero.
QERR_TOO_MANY_OTHER_OUTPUT_CHANNELS
Too many other output channels were specified.
QERR_INVALID_OTHER_OUTPUT_CHANNEL
One of the other output channels that was specified is not a valid channel number. Channel numbers range from 0 to one less than the number of channels.
QERR_OTHER_OUTPUT_CHANNELS_NOT_SUPPORTED
Other output channels are not supported by this board.
QERR_INVALID_BOARD_HANDLE
An invalid board handle was passed as an argument to the board-specific HIL driver. Once a card has been closed using hil_close the board handle is invalid.
QERR_INVALID_BUFFER_HANDLE
An invalid buffer handle was passed to a board-specific HIL driver function.
QERR_OPERATION_ARGUMENT_IS_NULL
The operation argument to a board-specific HIL driver is NULL. This situation should never occur unless the user is calling the board-specific driver directly or memory has been corrupted.
QERR_DRIVER_INCOMPATIBLE_WITH_BOARD_DLL
The board-specific HIL driver passed an invalid parameter to the operating system specific kernel-level driver for the board. The board-specific HIL driver is likely not compatible with the operating system specific kernel-level driver for the board. Make sure both are up-to-date and compatible versions.
QERR_INTERNAL_BUFFER_TOO_SMALL
The board-specific HIL driver used an internal buffer that was too small for the operating system specific kernel-level driver for the board. The board-specific HIL driver is likely not compatible with the operating system specific kernel-level driver for the board. Make sure both are up-to-date and compatible versions.
QERR_OUT_OF_REQUIRED_SYSTEM_RESOURCES
There are not enough system resources to perform the requested operation. Try rebooting, requesting fewer samples, or adding more memory to your machine.
QERR_OUT_OF_MEMORY
There is not enough memory to perform the operation.
Requirements
Include Files |
Libraries |
---|---|
hil.h |
hil.lib;quanser_runtime.lib;quanser_common.lib |
Examples
/* * Reads 5000 samples at 1 kHz from the first two other input channels while writing at the same time * to other output channels 2 and 3, using SYSTEM_CLOCK_1. Return values are ignored for simplicity. */ t_uint32 input_channels[] = { 0, 1 }; t_uint32 output_channels[] = { 2, 3 }; t_double frequency = 1000; t_uint32 samples = 5000; t_uint32 samples_in_buffer = frequency; t_uint32 samples_to_read_write = 1; static t_double input_buffer[2]; static t_double output_buffer[2]; t_task task; /* Fill output buffer */ ... hil_task_create_other_reader_other_writer(board, samples_in_buffer, input_channels, ARRAY_LENGTH(input_channels), output_channels, ARRAY_LENGTH(output_channels), &task); hil_task_write_other(task, samples_to_read_write, output_buffer); /* pre-fill the task output buffer prior to starting the task */ hil_task_start(task, SYSTEM_CLOCK_1, frequency, samples); for (int index = 0; index < samples; index += samples_to_read_write) { /* Fill output buffer */ ... hil_task_read_other_write_other(task, samples_to_write, input_buffer, output_buffer); /* waits for data to be read from hardware */ ... /* and for space in the task output buffer */ } hil_task_stop(task); hil_task_delete(task);
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