linux/drivers/comedi/comedidev.h

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/* SPDX-License-Identifier: GPL-2.0+ */
/*
* comedidev.h
* header file for kernel-only structures, variables, and constants
*
* COMEDI - Linux Control and Measurement Device Interface
* Copyright (C) 1997-2000 David A. Schleef <ds@schleef.org>
*/
#ifndef _COMEDIDEV_H
#define _COMEDIDEV_H
#include <linux/dma-mapping.h>
#include <linux/mutex.h>
#include <linux/spinlock_types.h>
#include <linux/rwsem.h>
#include <linux/kref.h>
#include "comedi.h"
#define COMEDI_VERSION(a, b, c) (((a) << 16) + ((b) << 8) + (c))
#define COMEDI_VERSION_CODE COMEDI_VERSION(COMEDI_MAJORVERSION, \
COMEDI_MINORVERSION, COMEDI_MICROVERSION)
#define COMEDI_RELEASE VERSION
#define COMEDI_NUM_BOARD_MINORS 0x30
/**
* struct comedi_subdevice - Working data for a COMEDI subdevice
* @device: COMEDI device to which this subdevice belongs. (Initialized by
* comedi_alloc_subdevices().)
* @index: Index of this subdevice within device's array of subdevices.
* (Initialized by comedi_alloc_subdevices().)
* @type: Type of subdevice from &enum comedi_subdevice_type. (Initialized by
* the low-level driver.)
* @n_chan: Number of channels the subdevice supports. (Initialized by the
* low-level driver.)
* @subdev_flags: Various "SDF" flags indicating aspects of the subdevice to
* the COMEDI core and user application. (Initialized by the low-level
* driver.)
* @len_chanlist: Maximum length of a channel list if the subdevice supports
* asynchronous acquisition commands. (Optionally initialized by the
* low-level driver, or changed from 0 to 1 during post-configuration.)
* @private: Private data pointer which is either set by the low-level driver
* itself, or by a call to comedi_alloc_spriv() which allocates storage.
* In the latter case, the storage is automatically freed after the
* low-level driver's "detach" handler is called for the device.
* (Initialized by the low-level driver.)
* @async: Pointer to &struct comedi_async id the subdevice supports
* asynchronous acquisition commands. (Allocated and initialized during
* post-configuration if needed.)
* @lock: Pointer to a file object that performed a %COMEDI_LOCK ioctl on the
* subdevice. (Initially NULL.)
* @busy: Pointer to a file object that is performing an asynchronous
* acquisition command on the subdevice. (Initially NULL.)
* @runflags: Internal flags for use by COMEDI core, mostly indicating whether
* an asynchronous acquisition command is running.
* @spin_lock: Generic spin-lock for use by the COMEDI core and the low-level
* driver. (Initialized by comedi_alloc_subdevices().)
* @io_bits: Bit-mask indicating the channel directions for a DIO subdevice
* with no more than 32 channels. A '1' at a bit position indicates the
* corresponding channel is configured as an output. (Initialized by the
* low-level driver for a DIO subdevice. Forced to all-outputs during
* post-configuration for a digital output subdevice.)
* @maxdata: If non-zero, this is the maximum raw data value of each channel.
* If zero, the maximum data value is channel-specific. (Initialized by
* the low-level driver.)
* @maxdata_list: If the maximum data value is channel-specific, this points
* to an array of maximum data values indexed by channel index.
* (Initialized by the low-level driver.)
* @range_table: If non-NULL, this points to a COMEDI range table for the
* subdevice. If NULL, the range table is channel-specific. (Initialized
* by the low-level driver, will be set to an "invalid" range table during
* post-configuration if @range_table and @range_table_list are both
* NULL.)
* @range_table_list: If the COMEDI range table is channel-specific, this
* points to an array of pointers to COMEDI range tables indexed by
* channel number. (Initialized by the low-level driver.)
* @chanlist: Not used.
* @insn_read: Optional pointer to a handler for the %INSN_READ instruction.
* (Initialized by the low-level driver, or set to a default handler
* during post-configuration.)
* @insn_write: Optional pointer to a handler for the %INSN_WRITE instruction.
* (Initialized by the low-level driver, or set to a default handler
* during post-configuration.)
* @insn_bits: Optional pointer to a handler for the %INSN_BITS instruction
* for a digital input, digital output or digital input/output subdevice.
* (Initialized by the low-level driver, or set to a default handler
* during post-configuration.)
* @insn_config: Optional pointer to a handler for the %INSN_CONFIG
* instruction. (Initialized by the low-level driver, or set to a default
* handler during post-configuration.)
* @do_cmd: If the subdevice supports asynchronous acquisition commands, this
* points to a handler to set it up in hardware. (Initialized by the
* low-level driver.)
* @do_cmdtest: If the subdevice supports asynchronous acquisition commands,
* this points to a handler used to check and possibly tweak a prospective
* acquisition command without setting it up in hardware. (Initialized by
* the low-level driver.)
* @poll: If the subdevice supports asynchronous acquisition commands, this
* is an optional pointer to a handler for the %COMEDI_POLL ioctl which
* instructs the low-level driver to synchronize buffers. (Initialized by
* the low-level driver if needed.)
* @cancel: If the subdevice supports asynchronous acquisition commands, this
* points to a handler used to terminate a running command. (Initialized
* by the low-level driver.)
* @buf_change: If the subdevice supports asynchronous acquisition commands,
* this is an optional pointer to a handler that is called when the data
* buffer for handling asynchronous commands is allocated or reallocated.
* (Initialized by the low-level driver if needed.)
* @munge: If the subdevice supports asynchronous acquisition commands and
* uses DMA to transfer data from the hardware to the acquisition buffer,
* this points to a function used to "munge" the data values from the
* hardware into the format expected by COMEDI. (Initialized by the
* low-level driver if needed.)
* @async_dma_dir: If the subdevice supports asynchronous acquisition commands
* and uses DMA to transfer data from the hardware to the acquisition
* buffer, this sets the DMA direction for the buffer. (initialized to
* %DMA_NONE by comedi_alloc_subdevices() and changed by the low-level
* driver if necessary.)
* @state: Handy bit-mask indicating the output states for a DIO or digital
* output subdevice with no more than 32 channels. (Initialized by the
* low-level driver.)
* @class_dev: If the subdevice supports asynchronous acquisition commands,
* this points to a sysfs comediX_subdY device where X is the minor device
* number of the COMEDI device and Y is the subdevice number. The minor
* device number for the sysfs device is allocated dynamically in the
* range 48 to 255. This is used to allow the COMEDI device to be opened
* with a different default read or write subdevice. (Allocated during
* post-configuration if needed.)
* @minor: If @class_dev is set, this is its dynamically allocated minor
* device number. (Set during post-configuration if necessary.)
* @readback: Optional pointer to memory allocated by
* comedi_alloc_subdev_readback() used to hold the values written to
* analog output channels so they can be read back. The storage is
* automatically freed after the low-level driver's "detach" handler is
* called for the device. (Initialized by the low-level driver.)
*
* This is the main control structure for a COMEDI subdevice. If the subdevice
* supports asynchronous acquisition commands, additional information is stored
* in the &struct comedi_async pointed to by @async.
*
* Most of the subdevice is initialized by the low-level driver's "attach" or
* "auto_attach" handlers but parts of it are initialized by
* comedi_alloc_subdevices(), and other parts are initialized during
* post-configuration on return from that handler.
*
* A low-level driver that sets @insn_bits for a digital input, digital output,
* or DIO subdevice may leave @insn_read and @insn_write uninitialized, in
* which case they will be set to a default handler during post-configuration
* that uses @insn_bits to emulate the %INSN_READ and %INSN_WRITE instructions.
*/
struct comedi_subdevice {
struct comedi_device *device;
int index;
int type;
int n_chan;
int subdev_flags;
int len_chanlist; /* maximum length of channel/gain list */
void *private;
struct comedi_async *async;
void *lock;
void *busy;
unsigned int runflags;
spinlock_t spin_lock; /* generic spin-lock for COMEDI and drivers */
unsigned int io_bits;
unsigned int maxdata; /* if maxdata==0, use list */
const unsigned int *maxdata_list; /* list is channel specific */
const struct comedi_lrange *range_table;
const struct comedi_lrange *const *range_table_list;
unsigned int *chanlist; /* driver-owned chanlist (not used) */
int (*insn_read)(struct comedi_device *dev, struct comedi_subdevice *s,
struct comedi_insn *insn, unsigned int *data);
int (*insn_write)(struct comedi_device *dev, struct comedi_subdevice *s,
struct comedi_insn *insn, unsigned int *data);
int (*insn_bits)(struct comedi_device *dev, struct comedi_subdevice *s,
struct comedi_insn *insn, unsigned int *data);
int (*insn_config)(struct comedi_device *dev,
struct comedi_subdevice *s,
struct comedi_insn *insn,
unsigned int *data);
int (*do_cmd)(struct comedi_device *dev, struct comedi_subdevice *s);
int (*do_cmdtest)(struct comedi_device *dev,
struct comedi_subdevice *s,
struct comedi_cmd *cmd);
int (*poll)(struct comedi_device *dev, struct comedi_subdevice *s);
int (*cancel)(struct comedi_device *dev, struct comedi_subdevice *s);
/* called when the buffer changes */
int (*buf_change)(struct comedi_device *dev,
struct comedi_subdevice *s);
void (*munge)(struct comedi_device *dev, struct comedi_subdevice *s,
void *data, unsigned int num_bytes,
unsigned int start_chan_index);
enum dma_data_direction async_dma_dir;
unsigned int state;
struct device *class_dev;
int minor;
unsigned int *readback;
};
/**
* struct comedi_buf_page - Describe a page of a COMEDI buffer
* @virt_addr: Kernel address of page.
* @dma_addr: DMA address of page if in DMA coherent memory.
*/
struct comedi_buf_page {
void *virt_addr;
dma_addr_t dma_addr;
};
/**
* struct comedi_buf_map - Describe pages in a COMEDI buffer
* @dma_hw_dev: Low-level hardware &struct device pointer copied from the
* COMEDI device's hw_dev member.
* @page_list: Pointer to array of &struct comedi_buf_page, one for each
* page in the buffer.
* @n_pages: Number of pages in the buffer.
* @dma_dir: DMA direction used to allocate pages of DMA coherent memory,
* or %DMA_NONE if pages allocated from regular memory.
* @refcount: &struct kref reference counter used to free the buffer.
*
* A COMEDI data buffer is allocated as individual pages, either in
* conventional memory or DMA coherent memory, depending on the attached,
* low-level hardware device. (The buffer pages also get mapped into the
* kernel's contiguous virtual address space pointed to by the 'prealloc_buf'
* member of &struct comedi_async.)
*
* The buffer is normally freed when the COMEDI device is detached from the
* low-level driver (which may happen due to device removal), but if it happens
* to be mmapped at the time, the pages cannot be freed until the buffer has
* been munmapped. That is what the reference counter is for. (The virtual
* address space pointed by 'prealloc_buf' is freed when the COMEDI device is
* detached.)
*/
staging: comedi: protect buffer from being freed while mmapped If a comedi device is automatically detached by `comedi_auto_unconfig()` any data buffers associated with subdevices that support asynchronous commands will be freed. If the buffer is mmapped at the time, bad things are likely to happen! Prevent this by moving some of the buffer details from `struct comedi_async` into a new, dynamically allocated, and kref-counted `struct comedi_buf_map`. This holds a list of pages, a reference count, and enough information to free the pages. The new member `buf_map` of `struct comedi_async` points to a `struct comedi_buf_map` when the buffer size is non-zero. Provide a new helper function `comedi_buf_is_mapped()` to check whether an a buffer is mmapped. If it is mmapped, the buffer is not allowed to be resized and the device is not allowed to be manually detached by the `COMEDI_DEVCONFIG` ioctl. Provide helper functions `comedi_buf_map_get()` and `comedi_buf_map_put()` to manipulate the reference count of the `struct comedi_buf_map`, which will be freed along with its contents via the 'release' callback of the `kref_put()` call. The reference count is manipulated by the vma operations and the mmap file operation. Now, when the comedi device is automatically detached, the buffer will be effectively freed by calling `comedi_buf_alloc()` with a new buffer size of 0. That calls local function `__comedi_buf_free()` which calls `comedi_buf_map_put()` on the `buf_map` member to free it. It won't actually be freed until the final 'put'. Signed-off-by: Ian Abbott <abbotti@mev.co.uk> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2013-11-08 23:03:43 +08:00
struct comedi_buf_map {
struct device *dma_hw_dev;
struct comedi_buf_page *page_list;
unsigned int n_pages;
enum dma_data_direction dma_dir;
struct kref refcount;
};
/**
* struct comedi_async - Control data for asynchronous COMEDI commands
* @prealloc_buf: Kernel virtual address of allocated acquisition buffer.
* @prealloc_bufsz: Buffer size (in bytes).
* @buf_map: Map of buffer pages.
* @max_bufsize: Maximum allowed buffer size (in bytes).
* @buf_write_count: "Write completed" count (in bytes, modulo 2**32).
* @buf_write_alloc_count: "Allocated for writing" count (in bytes,
* modulo 2**32).
* @buf_read_count: "Read completed" count (in bytes, modulo 2**32).
* @buf_read_alloc_count: "Allocated for reading" count (in bytes,
* modulo 2**32).
* @buf_write_ptr: Buffer position for writer.
* @buf_read_ptr: Buffer position for reader.
* @cur_chan: Current position in chanlist for scan (for those drivers that
* use it).
* @scans_done: The number of scans completed.
* @scan_progress: Amount received or sent for current scan (in bytes).
* @munge_chan: Current position in chanlist for "munging".
* @munge_count: "Munge" count (in bytes, modulo 2**32).
* @munge_ptr: Buffer position for "munging".
* @events: Bit-vector of events that have occurred.
* @cmd: Details of comedi command in progress.
* @wait_head: Task wait queue for file reader or writer.
* @cb_mask: Bit-vector of events that should wake waiting tasks.
* @inttrig: Software trigger function for command, or NULL.
*
* Note about the ..._count and ..._ptr members:
*
* Think of the _Count values being integers of unlimited size, indexing
* into a buffer of infinite length (though only an advancing portion
* of the buffer of fixed length prealloc_bufsz is accessible at any
* time). Then:
*
* Buf_Read_Count <= Buf_Read_Alloc_Count <= Munge_Count <=
* Buf_Write_Count <= Buf_Write_Alloc_Count <=
* (Buf_Read_Count + prealloc_bufsz)
*
* (Those aren't the actual members, apart from prealloc_bufsz.) When the
* buffer is reset, those _Count values start at 0 and only increase in value,
* maintaining the above inequalities until the next time the buffer is
* reset. The buffer is divided into the following regions by the inequalities:
*
* [0, Buf_Read_Count):
* old region no longer accessible
*
* [Buf_Read_Count, Buf_Read_Alloc_Count):
* filled and munged region allocated for reading but not yet read
*
* [Buf_Read_Alloc_Count, Munge_Count):
* filled and munged region not yet allocated for reading
*
* [Munge_Count, Buf_Write_Count):
* filled region not yet munged
*
* [Buf_Write_Count, Buf_Write_Alloc_Count):
* unfilled region allocated for writing but not yet written
*
* [Buf_Write_Alloc_Count, Buf_Read_Count + prealloc_bufsz):
* unfilled region not yet allocated for writing
*
* [Buf_Read_Count + prealloc_bufsz, infinity):
* unfilled region not yet accessible
*
* Data needs to be written into the buffer before it can be read out,
* and may need to be converted (or "munged") between the two
* operations. Extra unfilled buffer space may need to allocated for
* writing (advancing Buf_Write_Alloc_Count) before new data is written.
* After writing new data, the newly filled space needs to be released
* (advancing Buf_Write_Count). This also results in the new data being
* "munged" (advancing Munge_Count). Before data is read out of the
* buffer, extra space may need to be allocated for reading (advancing
* Buf_Read_Alloc_Count). After the data has been read out, the space
* needs to be released (advancing Buf_Read_Count).
*
* The actual members, buf_read_count, buf_read_alloc_count,
* munge_count, buf_write_count, and buf_write_alloc_count take the
* value of the corresponding capitalized _Count values modulo 2^32
* (UINT_MAX+1). Subtracting a "higher" _count value from a "lower"
* _count value gives the same answer as subtracting a "higher" _Count
* value from a lower _Count value because prealloc_bufsz < UINT_MAX+1.
* The modulo operation is done implicitly.
*
* The buf_read_ptr, munge_ptr, and buf_write_ptr members take the value
* of the corresponding capitalized _Count values modulo prealloc_bufsz.
* These correspond to byte indices in the physical buffer. The modulo
* operation is done by subtracting prealloc_bufsz when the value
* exceeds prealloc_bufsz (assuming prealloc_bufsz plus the increment is
* less than or equal to UINT_MAX).
*/
struct comedi_async {
void *prealloc_buf;
unsigned int prealloc_bufsz;
struct comedi_buf_map *buf_map;
unsigned int max_bufsize;
unsigned int buf_write_count;
unsigned int buf_write_alloc_count;
unsigned int buf_read_count;
unsigned int buf_read_alloc_count;
unsigned int buf_write_ptr;
unsigned int buf_read_ptr;
unsigned int cur_chan;
unsigned int scans_done;
unsigned int scan_progress;
unsigned int munge_chan;
unsigned int munge_count;
unsigned int munge_ptr;
unsigned int events;
struct comedi_cmd cmd;
wait_queue_head_t wait_head;
unsigned int cb_mask;
int (*inttrig)(struct comedi_device *dev, struct comedi_subdevice *s,
unsigned int x);
};
/**
* enum comedi_cb - &struct comedi_async callback "events"
* @COMEDI_CB_EOS: end-of-scan
* @COMEDI_CB_EOA: end-of-acquisition/output
* @COMEDI_CB_BLOCK: data has arrived, wakes up read() / write()
* @COMEDI_CB_EOBUF: DEPRECATED: end of buffer
* @COMEDI_CB_ERROR: card error during acquisition
* @COMEDI_CB_OVERFLOW: buffer overflow/underflow
* @COMEDI_CB_ERROR_MASK: events that indicate an error has occurred
* @COMEDI_CB_CANCEL_MASK: events that will cancel an async command
*/
enum comedi_cb {
COMEDI_CB_EOS = BIT(0),
COMEDI_CB_EOA = BIT(1),
COMEDI_CB_BLOCK = BIT(2),
COMEDI_CB_EOBUF = BIT(3),
COMEDI_CB_ERROR = BIT(4),
COMEDI_CB_OVERFLOW = BIT(5),
/* masks */
COMEDI_CB_ERROR_MASK = (COMEDI_CB_ERROR | COMEDI_CB_OVERFLOW),
COMEDI_CB_CANCEL_MASK = (COMEDI_CB_EOA | COMEDI_CB_ERROR_MASK)
};
/**
* struct comedi_driver - COMEDI driver registration
* @driver_name: Name of driver.
* @module: Owning module.
* @attach: The optional "attach" handler for manually configured COMEDI
* devices.
* @detach: The "detach" handler for deconfiguring COMEDI devices.
* @auto_attach: The optional "auto_attach" handler for automatically
* configured COMEDI devices.
* @num_names: Optional number of "board names" supported.
* @board_name: Optional pointer to a pointer to a board name. The pointer
* to a board name is embedded in an element of a driver-defined array
* of static, read-only board type information.
* @offset: Optional size of each element of the driver-defined array of
* static, read-only board type information, i.e. the offset between each
* pointer to a board name.
*
* This is used with comedi_driver_register() and comedi_driver_unregister() to
* register and unregister a low-level COMEDI driver with the COMEDI core.
*
* If @num_names is non-zero, @board_name should be non-NULL, and @offset
* should be at least sizeof(*board_name). These are used by the handler for
* the %COMEDI_DEVCONFIG ioctl to match a hardware device and its driver by
* board name. If @num_names is zero, the %COMEDI_DEVCONFIG ioctl matches a
* hardware device and its driver by driver name. This is only useful if the
* @attach handler is set. If @num_names is non-zero, the driver's @attach
* handler will be called with the COMEDI device structure's board_ptr member
* pointing to the matched pointer to a board name within the driver's private
* array of static, read-only board type information.
*
* The @detach handler has two roles. If a COMEDI device was successfully
* configured by the @attach or @auto_attach handler, it is called when the
* device is being deconfigured (by the %COMEDI_DEVCONFIG ioctl, or due to
* unloading of the driver, or due to device removal). It is also called when
* the @attach or @auto_attach handler returns an error. Therefore, the
* @attach or @auto_attach handlers can defer clean-up on error until the
* @detach handler is called. If the @attach or @auto_attach handlers free
* any resources themselves, they must prevent the @detach handler from
* freeing the same resources. The @detach handler must not assume that all
* resources requested by the @attach or @auto_attach handler were
* successfully allocated.
*/
struct comedi_driver {
/* private: */
struct comedi_driver *next; /* Next in list of COMEDI drivers. */
/* public: */
const char *driver_name;
struct module *module;
int (*attach)(struct comedi_device *dev, struct comedi_devconfig *it);
void (*detach)(struct comedi_device *dev);
int (*auto_attach)(struct comedi_device *dev, unsigned long context);
unsigned int num_names;
const char *const *board_name;
int offset;
};
/**
* struct comedi_device - Working data for a COMEDI device
* @use_count: Number of open file objects.
* @driver: Low-level COMEDI driver attached to this COMEDI device.
* @pacer: Optional pointer to a dynamically allocated acquisition pacer
* control. It is freed automatically after the COMEDI device is
* detached from the low-level driver.
* @private: Optional pointer to private data allocated by the low-level
* driver. It is freed automatically after the COMEDI device is
* detached from the low-level driver.
* @class_dev: Sysfs comediX device.
* @minor: Minor device number of COMEDI char device (0-47).
* @detach_count: Counter incremented every time the COMEDI device is detached.
* Used for checking a previous attachment is still valid.
* @hw_dev: Optional pointer to the low-level hardware &struct device. It is
* required for automatically configured COMEDI devices and optional for
* COMEDI devices configured by the %COMEDI_DEVCONFIG ioctl, although
* the bus-specific COMEDI functions only work if it is set correctly.
* It is also passed to dma_alloc_coherent() for COMEDI subdevices that
* have their 'async_dma_dir' member set to something other than
* %DMA_NONE.
* @board_name: Pointer to a COMEDI board name or a COMEDI driver name. When
* the low-level driver's "attach" handler is called by the handler for
* the %COMEDI_DEVCONFIG ioctl, it either points to a matched board name
* string if the 'num_names' member of the &struct comedi_driver is
* non-zero, otherwise it points to the low-level driver name string.
* When the low-lever driver's "auto_attach" handler is called for an
* automatically configured COMEDI device, it points to the low-level
* driver name string. The low-level driver is free to change it in its
* "attach" or "auto_attach" handler if it wishes.
* @board_ptr: Optional pointer to private, read-only board type information in
* the low-level driver. If the 'num_names' member of the &struct
* comedi_driver is non-zero, the handler for the %COMEDI_DEVCONFIG ioctl
* will point it to a pointer to a matched board name string within the
* driver's private array of static, read-only board type information when
* calling the driver's "attach" handler. The low-level driver is free to
* change it.
* @attached: Flag indicating that the COMEDI device is attached to a low-level
* driver.
* @ioenabled: Flag used to indicate that a PCI device has been enabled and
* its regions requested.
* @spinlock: Generic spin-lock for use by the low-level driver.
* @mutex: Generic mutex for use by the COMEDI core module.
* @attach_lock: &struct rw_semaphore used to guard against the COMEDI device
* being detached while an operation is in progress. The down_write()
* operation is only allowed while @mutex is held and is used when
* changing @attached and @detach_count and calling the low-level driver's
* "detach" handler. The down_read() operation is generally used without
* holding @mutex.
* @refcount: &struct kref reference counter for freeing COMEDI device.
* @n_subdevices: Number of COMEDI subdevices allocated by the low-level
* driver for this device.
* @subdevices: Dynamically allocated array of COMEDI subdevices.
* @mmio: Optional pointer to a remapped MMIO region set by the low-level
* driver.
* @iobase: Optional base of an I/O port region requested by the low-level
* driver.
* @iolen: Length of I/O port region requested at @iobase.
* @irq: Optional IRQ number requested by the low-level driver.
* @read_subdev: Optional pointer to a default COMEDI subdevice operated on by
* the read() file operation. Set by the low-level driver.
* @write_subdev: Optional pointer to a default COMEDI subdevice operated on by
* the write() file operation. Set by the low-level driver.
* @async_queue: Storage for fasync_helper().
* @open: Optional pointer to a function set by the low-level driver to be
* called when @use_count changes from 0 to 1.
* @close: Optional pointer to a function set by the low-level driver to be
* called when @use_count changed from 1 to 0.
* @insn_device_config: Optional pointer to a handler for all sub-instructions
* except %INSN_DEVICE_CONFIG_GET_ROUTES of the %INSN_DEVICE_CONFIG
* instruction. If this is not initialized by the low-level driver, a
* default handler will be set during post-configuration.
* @get_valid_routes: Optional pointer to a handler for the
* %INSN_DEVICE_CONFIG_GET_ROUTES sub-instruction of the
* %INSN_DEVICE_CONFIG instruction set. If this is not initialized by the
* low-level driver, a default handler that copies zero routes back to the
* user will be used.
*
* This is the main control data structure for a COMEDI device (as far as the
* COMEDI core is concerned). There are two groups of COMEDI devices -
* "legacy" devices that are configured by the handler for the
* %COMEDI_DEVCONFIG ioctl, and automatically configured devices resulting
* from a call to comedi_auto_config() as a result of a bus driver probe in
* a low-level COMEDI driver. The "legacy" COMEDI devices are allocated
* during module initialization if the "comedi_num_legacy_minors" module
* parameter is non-zero and use minor device numbers from 0 to
* comedi_num_legacy_minors minus one. The automatically configured COMEDI
* devices are allocated on demand and use minor device numbers from
* comedi_num_legacy_minors to 47.
*/
struct comedi_device {
int use_count;
struct comedi_driver *driver;
struct comedi_8254 *pacer;
void *private;
struct device *class_dev;
int minor;
unsigned int detach_count;
struct device *hw_dev;
const char *board_name;
const void *board_ptr;
unsigned int attached:1;
unsigned int ioenabled:1;
spinlock_t spinlock; /* generic spin-lock for low-level driver */
struct mutex mutex; /* generic mutex for COMEDI core */
struct rw_semaphore attach_lock;
struct kref refcount;
int n_subdevices;
struct comedi_subdevice *subdevices;
/* dumb */
void __iomem *mmio;
unsigned long iobase;
unsigned long iolen;
unsigned int irq;
struct comedi_subdevice *read_subdev;
struct comedi_subdevice *write_subdev;
struct fasync_struct *async_queue;
int (*open)(struct comedi_device *dev);
void (*close)(struct comedi_device *dev);
int (*insn_device_config)(struct comedi_device *dev,
struct comedi_insn *insn, unsigned int *data);
unsigned int (*get_valid_routes)(struct comedi_device *dev,
unsigned int n_pairs,
unsigned int *pair_data);
};
/*
* function prototypes
*/
void comedi_event(struct comedi_device *dev, struct comedi_subdevice *s);
struct comedi_device *comedi_dev_get_from_minor(unsigned int minor);
int comedi_dev_put(struct comedi_device *dev);
bool comedi_is_subdevice_running(struct comedi_subdevice *s);
void *comedi_alloc_spriv(struct comedi_subdevice *s, size_t size);
void comedi_set_spriv_auto_free(struct comedi_subdevice *s);
int comedi_check_chanlist(struct comedi_subdevice *s,
int n,
unsigned int *chanlist);
/* range stuff */
#define RANGE(a, b) {(a) * 1e6, (b) * 1e6, 0}
#define RANGE_ext(a, b) {(a) * 1e6, (b) * 1e6, RF_EXTERNAL}
#define RANGE_mA(a, b) {(a) * 1e6, (b) * 1e6, UNIT_mA}
#define RANGE_unitless(a, b) {(a) * 1e6, (b) * 1e6, 0}
#define BIP_RANGE(a) {-(a) * 1e6, (a) * 1e6, 0}
#define UNI_RANGE(a) {0, (a) * 1e6, 0}
extern const struct comedi_lrange range_bipolar10;
extern const struct comedi_lrange range_bipolar5;
extern const struct comedi_lrange range_bipolar2_5;
extern const struct comedi_lrange range_unipolar10;
extern const struct comedi_lrange range_unipolar5;
extern const struct comedi_lrange range_unipolar2_5;
extern const struct comedi_lrange range_0_20mA;
extern const struct comedi_lrange range_4_20mA;
extern const struct comedi_lrange range_0_32mA;
extern const struct comedi_lrange range_unknown;
#define range_digital range_unipolar5
/**
* struct comedi_lrange - Describes a COMEDI range table
* @length: Number of entries in the range table.
* @range: Array of &struct comedi_krange, one for each range.
*
* Each element of @range[] describes the minimum and maximum physical range
* and the type of units. Typically, the type of unit is %UNIT_volt
* (i.e. volts) and the minimum and maximum are in millionths of a volt.
* There may also be a flag that indicates the minimum and maximum are merely
* scale factors for an unknown, external reference.
*/
struct comedi_lrange {
int length;
struct comedi_krange range[];
};
/**
* comedi_range_is_bipolar() - Test if subdevice range is bipolar
* @s: COMEDI subdevice.
* @range: Index of range within a range table.
*
* Tests whether a range is bipolar by checking whether its minimum value
* is negative.
*
* Assumes @range is valid. Does not work for subdevices using a
* channel-specific range table list.
*
* Return:
* %true if the range is bipolar.
* %false if the range is unipolar.
*/
static inline bool comedi_range_is_bipolar(struct comedi_subdevice *s,
unsigned int range)
{
return s->range_table->range[range].min < 0;
}
/**
* comedi_range_is_unipolar() - Test if subdevice range is unipolar
* @s: COMEDI subdevice.
* @range: Index of range within a range table.
*
* Tests whether a range is unipolar by checking whether its minimum value
* is at least 0.
*
* Assumes @range is valid. Does not work for subdevices using a
* channel-specific range table list.
*
* Return:
* %true if the range is unipolar.
* %false if the range is bipolar.
*/
static inline bool comedi_range_is_unipolar(struct comedi_subdevice *s,
unsigned int range)
{
return s->range_table->range[range].min >= 0;
}
/**
* comedi_range_is_external() - Test if subdevice range is external
* @s: COMEDI subdevice.
* @range: Index of range within a range table.
*
* Tests whether a range is externally reference by checking whether its
* %RF_EXTERNAL flag is set.
*
* Assumes @range is valid. Does not work for subdevices using a
* channel-specific range table list.
*
* Return:
* %true if the range is external.
* %false if the range is internal.
*/
static inline bool comedi_range_is_external(struct comedi_subdevice *s,
unsigned int range)
{
return !!(s->range_table->range[range].flags & RF_EXTERNAL);
}
/**
* comedi_chan_range_is_bipolar() - Test if channel-specific range is bipolar
* @s: COMEDI subdevice.
* @chan: The channel number.
* @range: Index of range within a range table.
*
* Tests whether a range is bipolar by checking whether its minimum value
* is negative.
*
* Assumes @chan and @range are valid. Only works for subdevices with a
* channel-specific range table list.
*
* Return:
* %true if the range is bipolar.
* %false if the range is unipolar.
*/
static inline bool comedi_chan_range_is_bipolar(struct comedi_subdevice *s,
unsigned int chan,
unsigned int range)
{
return s->range_table_list[chan]->range[range].min < 0;
}
/**
* comedi_chan_range_is_unipolar() - Test if channel-specific range is unipolar
* @s: COMEDI subdevice.
* @chan: The channel number.
* @range: Index of range within a range table.
*
* Tests whether a range is unipolar by checking whether its minimum value
* is at least 0.
*
* Assumes @chan and @range are valid. Only works for subdevices with a
* channel-specific range table list.
*
* Return:
* %true if the range is unipolar.
* %false if the range is bipolar.
*/
static inline bool comedi_chan_range_is_unipolar(struct comedi_subdevice *s,
unsigned int chan,
unsigned int range)
{
return s->range_table_list[chan]->range[range].min >= 0;
}
/**
* comedi_chan_range_is_external() - Test if channel-specific range is external
* @s: COMEDI subdevice.
* @chan: The channel number.
* @range: Index of range within a range table.
*
* Tests whether a range is externally reference by checking whether its
* %RF_EXTERNAL flag is set.
*
* Assumes @chan and @range are valid. Only works for subdevices with a
* channel-specific range table list.
*
* Return:
* %true if the range is bipolar.
* %false if the range is unipolar.
*/
static inline bool comedi_chan_range_is_external(struct comedi_subdevice *s,
unsigned int chan,
unsigned int range)
{
return !!(s->range_table_list[chan]->range[range].flags & RF_EXTERNAL);
}
/**
* comedi_offset_munge() - Convert between offset binary and 2's complement
* @s: COMEDI subdevice.
* @val: Value to be converted.
*
* Toggles the highest bit of a sample value to toggle between offset binary
* and 2's complement. Assumes that @s->maxdata is a power of 2 minus 1.
*
* Return: The converted value.
*/
static inline unsigned int comedi_offset_munge(struct comedi_subdevice *s,
unsigned int val)
{
return val ^ s->maxdata ^ (s->maxdata >> 1);
}
/**
* comedi_bytes_per_sample() - Determine subdevice sample size
* @s: COMEDI subdevice.
*
* The sample size will be 4 (sizeof int) or 2 (sizeof short) depending on
* whether the %SDF_LSAMPL subdevice flag is set or not.
*
* Return: The subdevice sample size.
*/
static inline unsigned int comedi_bytes_per_sample(struct comedi_subdevice *s)
{
return s->subdev_flags & SDF_LSAMPL ? sizeof(int) : sizeof(short);
}
/**
* comedi_sample_shift() - Determine log2 of subdevice sample size
* @s: COMEDI subdevice.
*
* The sample size will be 4 (sizeof int) or 2 (sizeof short) depending on
* whether the %SDF_LSAMPL subdevice flag is set or not. The log2 of the
* sample size will be 2 or 1 and can be used as the right operand of a
* bit-shift operator to multiply or divide something by the sample size.
*
* Return: log2 of the subdevice sample size.
*/
static inline unsigned int comedi_sample_shift(struct comedi_subdevice *s)
{
return s->subdev_flags & SDF_LSAMPL ? 2 : 1;
}
/**
* comedi_bytes_to_samples() - Convert a number of bytes to a number of samples
* @s: COMEDI subdevice.
* @nbytes: Number of bytes
*
* Return: The number of bytes divided by the subdevice sample size.
*/
static inline unsigned int comedi_bytes_to_samples(struct comedi_subdevice *s,
unsigned int nbytes)
{
return nbytes >> comedi_sample_shift(s);
}
/**
* comedi_samples_to_bytes() - Convert a number of samples to a number of bytes
* @s: COMEDI subdevice.
* @nsamples: Number of samples.
*
* Return: The number of samples multiplied by the subdevice sample size.
* (Does not check for arithmetic overflow.)
*/
static inline unsigned int comedi_samples_to_bytes(struct comedi_subdevice *s,
unsigned int nsamples)
{
return nsamples << comedi_sample_shift(s);
}
/**
* comedi_check_trigger_src() - Trivially validate a comedi_cmd trigger source
* @src: Pointer to the trigger source to validate.
* @flags: Bitmask of valid %TRIG_* for the trigger.
*
* This is used in "step 1" of the do_cmdtest functions of comedi drivers
* to validate the comedi_cmd triggers. The mask of the @src against the
* @flags allows the userspace comedilib to pass all the comedi_cmd
* triggers as %TRIG_ANY and get back a bitmask of the valid trigger sources.
*
* Return:
* 0 if trigger sources in *@src are all supported.
* -EINVAL if any trigger source in *@src is unsupported.
*/
static inline int comedi_check_trigger_src(unsigned int *src,
unsigned int flags)
{
unsigned int orig_src = *src;
*src = orig_src & flags;
if (*src == TRIG_INVALID || *src != orig_src)
return -EINVAL;
return 0;
}
/**
* comedi_check_trigger_is_unique() - Make sure a trigger source is unique
* @src: The trigger source to check.
*
* Return:
* 0 if no more than one trigger source is set.
* -EINVAL if more than one trigger source is set.
*/
static inline int comedi_check_trigger_is_unique(unsigned int src)
{
/* this test is true if more than one _src bit is set */
if ((src & (src - 1)) != 0)
return -EINVAL;
return 0;
}
/**
* comedi_check_trigger_arg_is() - Trivially validate a trigger argument
* @arg: Pointer to the trigger arg to validate.
* @val: The value the argument should be.
*
* Forces *@arg to be @val.
*
* Return:
* 0 if *@arg was already @val.
* -EINVAL if *@arg differed from @val.
*/
static inline int comedi_check_trigger_arg_is(unsigned int *arg,
unsigned int val)
{
if (*arg != val) {
*arg = val;
return -EINVAL;
}
return 0;
}
/**
* comedi_check_trigger_arg_min() - Trivially validate a trigger argument min
* @arg: Pointer to the trigger arg to validate.
* @val: The minimum value the argument should be.
*
* Forces *@arg to be at least @val, setting it to @val if necessary.
*
* Return:
* 0 if *@arg was already at least @val.
* -EINVAL if *@arg was less than @val.
*/
static inline int comedi_check_trigger_arg_min(unsigned int *arg,
unsigned int val)
{
if (*arg < val) {
*arg = val;
return -EINVAL;
}
return 0;
}
/**
* comedi_check_trigger_arg_max() - Trivially validate a trigger argument max
* @arg: Pointer to the trigger arg to validate.
* @val: The maximum value the argument should be.
*
* Forces *@arg to be no more than @val, setting it to @val if necessary.
*
* Return:
* 0 if*@arg was already no more than @val.
* -EINVAL if *@arg was greater than @val.
*/
static inline int comedi_check_trigger_arg_max(unsigned int *arg,
unsigned int val)
{
if (*arg > val) {
*arg = val;
return -EINVAL;
}
return 0;
}
/*
* Must set dev->hw_dev if you wish to dma directly into comedi's buffer.
* Also useful for retrieving a previously configured hardware device of
* known bus type. Set automatically for auto-configured devices.
* Automatically set to NULL when detaching hardware device.
*/
int comedi_set_hw_dev(struct comedi_device *dev, struct device *hw_dev);
/**
* comedi_buf_n_bytes_ready - Determine amount of unread data in buffer
* @s: COMEDI subdevice.
*
* Determines the number of bytes of unread data in the asynchronous
* acquisition data buffer for a subdevice. The data in question might not
* have been fully "munged" yet.
*
* Returns: The amount of unread data in bytes.
*/
static inline unsigned int comedi_buf_n_bytes_ready(struct comedi_subdevice *s)
{
return s->async->buf_write_count - s->async->buf_read_count;
}
unsigned int comedi_buf_write_alloc(struct comedi_subdevice *s, unsigned int n);
unsigned int comedi_buf_write_free(struct comedi_subdevice *s, unsigned int n);
unsigned int comedi_buf_read_n_available(struct comedi_subdevice *s);
unsigned int comedi_buf_read_alloc(struct comedi_subdevice *s, unsigned int n);
unsigned int comedi_buf_read_free(struct comedi_subdevice *s, unsigned int n);
unsigned int comedi_buf_write_samples(struct comedi_subdevice *s,
const void *data, unsigned int nsamples);
unsigned int comedi_buf_read_samples(struct comedi_subdevice *s,
void *data, unsigned int nsamples);
/* drivers.c - general comedi driver functions */
staging: comedi: introduce comedi_timeout() Introduce a comedi core helper function to handle the boilerplate needed by the drivers to busy- wait for a condition to occur. Typically this condition is the analog input/output end-of-conversion used with the comedi (*insn_read) and (*insn_write) operations. To use this function, the drivers just need to provide a callback that checks for the desired condition. The callback should return 0 if the condition is met or -EBUSY if it is still waiting. Any other errno will be returned to the caller. If the timeout occurs before the condition is met -ETIMEDOUT will be returned. The parameters to the callback function are the comedi_device, comedi_subdevice, and comedi_insn pointers that were passed to the (*insn_read) or (*insn_write) as well as an unsigned long, driver specific, 'context' that can be used to pass any other information that might be needed in the callback. This 'context' could be anything such as the register offset to read the status or the bits needed to check the status. The comedi_timeout() function itself does not use any of these parameters. This will help remove all the crazy "wait this many loops" used by some of the drivers. It also creates a common errno for comedi to detect when a timeout occurs. ADC/DAC conversion times are typically pretty fast, usually around 100K samples/sec (10 usec). A conservative timeout of 1 second is used in comedi_timeout(). Signed-off-by: H Hartley Sweeten <hsweeten@visionengravers.com> Cc: Ian Abbott <abbotti@mev.co.uk> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-02-11 02:49:00 +08:00
#define COMEDI_TIMEOUT_MS 1000
int comedi_timeout(struct comedi_device *dev, struct comedi_subdevice *s,
struct comedi_insn *insn,
int (*cb)(struct comedi_device *dev,
struct comedi_subdevice *s,
struct comedi_insn *insn, unsigned long context),
staging: comedi: introduce comedi_timeout() Introduce a comedi core helper function to handle the boilerplate needed by the drivers to busy- wait for a condition to occur. Typically this condition is the analog input/output end-of-conversion used with the comedi (*insn_read) and (*insn_write) operations. To use this function, the drivers just need to provide a callback that checks for the desired condition. The callback should return 0 if the condition is met or -EBUSY if it is still waiting. Any other errno will be returned to the caller. If the timeout occurs before the condition is met -ETIMEDOUT will be returned. The parameters to the callback function are the comedi_device, comedi_subdevice, and comedi_insn pointers that were passed to the (*insn_read) or (*insn_write) as well as an unsigned long, driver specific, 'context' that can be used to pass any other information that might be needed in the callback. This 'context' could be anything such as the register offset to read the status or the bits needed to check the status. The comedi_timeout() function itself does not use any of these parameters. This will help remove all the crazy "wait this many loops" used by some of the drivers. It also creates a common errno for comedi to detect when a timeout occurs. ADC/DAC conversion times are typically pretty fast, usually around 100K samples/sec (10 usec). A conservative timeout of 1 second is used in comedi_timeout(). Signed-off-by: H Hartley Sweeten <hsweeten@visionengravers.com> Cc: Ian Abbott <abbotti@mev.co.uk> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-02-11 02:49:00 +08:00
unsigned long context);
unsigned int comedi_handle_events(struct comedi_device *dev,
struct comedi_subdevice *s);
int comedi_dio_insn_config(struct comedi_device *dev,
struct comedi_subdevice *s,
struct comedi_insn *insn, unsigned int *data,
unsigned int mask);
unsigned int comedi_dio_update_state(struct comedi_subdevice *s,
unsigned int *data);
staging: comedi: ni_mio_common: Fix divide-by-zero for DIO cmdtest `ni_cdio_cmdtest()` validates Comedi asynchronous commands for the DIO subdevice (subdevice 2) of supported National Instruments M-series cards. It is called when handling the `COMEDI_CMD` and `COMEDI_CMDTEST` ioctls for this subdevice. There are two causes for a possible divide-by-zero error when validating that the `stop_arg` member of the passed-in command is not too large. The first cause for the divide-by-zero is that calls to `comedi_bytes_per_scan()` are only valid once the command has been copied to `s->async->cmd`, but that copy is only done for the `COMEDI_CMD` ioctl. For the `COMEDI_CMDTEST` ioctl, it will use whatever was left there by the previous `COMEDI_CMD` ioctl, if any. (This is very likely, as it is usual for the application to use `COMEDI_CMDTEST` before `COMEDI_CMD`.) If there has been no previous, valid `COMEDI_CMD` for this subdevice, then `comedi_bytes_per_scan()` will return 0, so the subsequent division in `ni_cdio_cmdtest()` of `s->async->prealloc_bufsz / comedi_bytes_per_scan(s)` will be a divide-by-zero error. To fix this error, call a new function `comedi_bytes_per_scan_cmd(s, cmd)`, based on the existing `comedi_bytes_per_scan(s)` but using a specified `struct comedi_cmd` for its calculations. (Also refactor `comedi_bytes_per_scan()` to call the new function.) Once the first cause for the divide-by-zero has been fixed, the second cause is that `comedi_bytes_per_scan_cmd()` can legitimately return 0 if the `scan_end_arg` member of the `struct comedi_cmd` being tested is 0. Fix it by only performing the division (and validating that `stop_arg` is no more than the maximum value) if `comedi_bytes_per_scan_cmd()` returns a non-zero value. The problem was reported on the COMEDI mailing list here: https://groups.google.com/forum/#!topic/comedi_list/4t9WlHzMhKM Reported-by: Ivan Vasilyev <grabesstimme@gmail.com> Tested-by: Ivan Vasilyev <grabesstimme@gmail.com> Fixes: f164cbf98fa8 ("staging: comedi: ni_mio_common: add finite regeneration to dio output") Cc: <stable@vger.kernel.org> # 4.6+ Cc: Spencer E. Olson <olsonse@umich.edu> Signed-off-by: Ian Abbott <abbotti@mev.co.uk> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2019-03-04 22:33:54 +08:00
unsigned int comedi_bytes_per_scan_cmd(struct comedi_subdevice *s,
struct comedi_cmd *cmd);
unsigned int comedi_bytes_per_scan(struct comedi_subdevice *s);
unsigned int comedi_nscans_left(struct comedi_subdevice *s,
unsigned int nscans);
unsigned int comedi_nsamples_left(struct comedi_subdevice *s,
unsigned int nsamples);
void comedi_inc_scan_progress(struct comedi_subdevice *s,
unsigned int num_bytes);
void *comedi_alloc_devpriv(struct comedi_device *dev, size_t size);
int comedi_alloc_subdevices(struct comedi_device *dev, int num_subdevices);
int comedi_alloc_subdev_readback(struct comedi_subdevice *s);
int comedi_readback_insn_read(struct comedi_device *dev,
struct comedi_subdevice *s,
struct comedi_insn *insn, unsigned int *data);
int comedi_load_firmware(struct comedi_device *dev, struct device *hw_dev,
const char *name,
int (*cb)(struct comedi_device *dev,
const u8 *data, size_t size,
unsigned long context),
unsigned long context);
int __comedi_request_region(struct comedi_device *dev,
unsigned long start, unsigned long len);
int comedi_request_region(struct comedi_device *dev,
unsigned long start, unsigned long len);
void comedi_legacy_detach(struct comedi_device *dev);
int comedi_auto_config(struct device *hardware_device,
struct comedi_driver *driver, unsigned long context);
void comedi_auto_unconfig(struct device *hardware_device);
int comedi_driver_register(struct comedi_driver *driver);
void comedi_driver_unregister(struct comedi_driver *driver);
/**
* module_comedi_driver() - Helper macro for registering a comedi driver
* @__comedi_driver: comedi_driver struct
*
* Helper macro for comedi drivers which do not do anything special in module
* init/exit. This eliminates a lot of boilerplate. Each module may only use
* this macro once, and calling it replaces module_init() and module_exit().
*/
#define module_comedi_driver(__comedi_driver) \
module_driver(__comedi_driver, comedi_driver_register, \
comedi_driver_unregister)
#endif /* _COMEDIDEV_H */