mirror of https://gitee.com/openkylin/linux.git
312 lines
14 KiB
Plaintext
312 lines
14 KiB
Plaintext
FMC Device
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**********
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Within the Linux bus framework, the FMC device is created and
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registered by the carrier driver. For example, the PCI driver for the
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SPEC card fills a data structure for each SPEC that it drives, and
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registers an associated FMC device for each card. The SVEC driver can
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do exactly the same for the VME carrier (actually, it should do it
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twice, because the SVEC carries two FMC mezzanines). Similarly, an
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Etherbone driver will be able to register its own FMC devices, offering
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communication primitives through frame exchange.
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The contents of the EEPROM within the FMC are used for identification
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purposes, i.e. for matching the device with its own driver. For this
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reason the device structure includes a complete copy of the EEPROM
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(actually, the carrier driver may choose whether or not to return it -
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for example we most likely won't have the whole EEPROM available for
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Etherbone devices.
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The following listing shows the current structure defining a device.
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Please note that all the machinery is in place but some details may
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still change in the future. For this reason, there is a version field
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at the beginning of the structure. As usual, the minor number will
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change for compatible changes (like a new flag) and the major number
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will increase when an incompatible change happens (for example, a
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change in layout of some fmc data structures). Device writers should
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just set it to the value FMC_VERSION, and be ready to get back -EINVAL
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at registration time.
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struct fmc_device {
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unsigned long version;
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unsigned long flags;
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struct module *owner; /* char device must pin it */
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struct fmc_fru_id id; /* for EEPROM-based match */
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struct fmc_operations *op; /* carrier-provided */
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int irq; /* according to host bus. 0 == none */
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int eeprom_len; /* Usually 8kB, may be less */
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int eeprom_addr; /* 0x50, 0x52 etc */
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uint8_t *eeprom; /* Full contents or leading part */
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char *carrier_name; /* "SPEC" or similar, for special use */
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void *carrier_data; /* "struct spec *" or equivalent */
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__iomem void *fpga_base; /* May be NULL (Etherbone) */
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__iomem void *slot_base; /* Set by the driver */
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struct fmc_device **devarray; /* Allocated by the bus */
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int slot_id; /* Index in the slot array */
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int nr_slots; /* Number of slots in this carrier */
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unsigned long memlen; /* Used for the char device */
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struct device dev; /* For Linux use */
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struct device *hwdev; /* The underlying hardware device */
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unsigned long sdbfs_entry;
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struct sdb_array *sdb;
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uint32_t device_id; /* Filled by the device */
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char *mezzanine_name; /* Defaults to ``fmc'' */
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void *mezzanine_data;
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};
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The meaning of most fields is summarized in the code comment above.
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The following fields must be filled by the carrier driver before
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registration:
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* version: must be set to FMC_VERSION.
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* owner: set to MODULE_OWNER.
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* op: the operations to act on the device.
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* irq: number for the mezzanine; may be zero.
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* eeprom_len: length of the following array.
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* eeprom_addr: 0x50 for first mezzanine and so on.
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* eeprom: the full content of the I2C EEPROM.
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* carrier_name.
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* carrier_data: a unique pointer for the carrier.
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* fpga_base: the I/O memory address (may be NULL).
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* slot_id: the index of this slot (starting from zero).
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* memlen: if fpga_base is valid, the length of I/O memory.
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* hwdev: to be used in some dev_err() calls.
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* device_id: a slot-specific unique integer number.
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Please note that the carrier should read its own EEPROM memory before
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registering the device, as well as fill all other fields listed above.
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The following fields should not be assigned, because they are filled
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later by either the bus or the device driver:
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* flags.
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* fru_id: filled by the bus, parsing the eeprom.
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* slot_base: filled and used by the driver, if useful to it.
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* devarray: an array og all mezzanines driven by a singe FPGA.
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* nr_slots: set by the core at registration time.
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* dev: used by Linux.
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* sdb: FPGA contents, scanned according to driver's directions.
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* sdbfs_entry: SDB entry point in EEPROM: autodetected.
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* mezzanine_data: available for the driver.
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* mezzanine_name: filled by fmc-bus during identification.
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Note: mezzanine_data may be redundant, because Linux offers the drvdata
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approach, so the field may be removed in later versions of this bus
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implementation.
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As I write this, she SPEC carrier is already completely functional in
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the fmc-bus environment, and is a good reference to look at.
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The API Offered by Carriers
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===========================
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The carrier provides a number of methods by means of the
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`fmc_operations' structure, which currently is defined like this
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(again, it is a moving target, please refer to the header rather than
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this document):
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struct fmc_operations {
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uint32_t (*readl)(struct fmc_device *fmc, int offset);
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void (*writel)(struct fmc_device *fmc, uint32_t value, int offset);
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int (*reprogram)(struct fmc_device *f, struct fmc_driver *d, char *gw);
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int (*validate)(struct fmc_device *fmc, struct fmc_driver *drv);
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int (*irq_request)(struct fmc_device *fmc, irq_handler_t h,
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char *name, int flags);
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void (*irq_ack)(struct fmc_device *fmc);
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int (*irq_free)(struct fmc_device *fmc);
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int (*gpio_config)(struct fmc_device *fmc, struct fmc_gpio *gpio,
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int ngpio);
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int (*read_ee)(struct fmc_device *fmc, int pos, void *d, int l);
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int (*write_ee)(struct fmc_device *fmc, int pos, const void *d, int l);
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};
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The individual methods perform the following tasks:
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`readl'
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`writel'
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These functions access FPGA registers by whatever means the
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carrier offers. They are not expected to fail, and most of the time
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they will just make a memory access to the host bus. If the
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carrier provides a fpga_base pointer, the driver may use direct
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access through that pointer. For this reason the header offers the
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inline functions fmc_readl and fmc_writel that access fpga_base if
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the respective method is NULL. A driver that wants to be portable
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and efficient should use fmc_readl and fmc_writel. For Etherbone,
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or other non-local carriers, error-management is still to be
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defined.
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`validate'
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Module parameters are used to manage different applications for
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two or more boards of the same kind. Validation is based on the
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busid module parameter, if provided, and returns the matching
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index in the associated array. See *note Module Parameters:: in in
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doubt. If no match is found, `-ENOENT' is returned; if the user
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didn't pass `busid=', all devices will pass validation. The value
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returned by the validate method can be used as index into other
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parameters (for example, some drivers use the `lm32=' parameter in
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this way). Such "generic parameters" are documented in *note
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Module Parameters::, below. The validate method is used by
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`fmc-trivial.ko', described in *note fmc-trivial::.
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`reprogram'
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The carrier enumerates FMC devices by loading a standard (or
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golden) FPGA binary that allows EEPROM access. Each driver, then,
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will need to reprogram the FPGA by calling this function. If the
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name argument is NULL, the carrier should reprogram the golden
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binary. If the gateware name has been overridden through module
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parameters (in a carrier-specific way) the file loaded will match
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the parameters. Per-device gateware names can be specified using
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the `gateware=' parameter, see *note Module Parameters::. Note:
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Clients should call rhe new helper, fmc_reprogram, which both
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calls this method and parse the SDB tree of the FPGA.
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`irq_request'
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`irq_ack'
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`irq_free'
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Interrupt management is carrier-specific, so it is abstracted as
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operations. The interrupt number is listed in the device
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structure, and for the mezzanine driver the number is only
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informative. The handler will receive the fmc pointer as dev_id;
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the flags argument is passed to the Linux request_irq function,
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but fmc-specific flags may be added in the future. You'll most
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likely want to pass the `IRQF_SHARED' flag.
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`gpio_config'
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The method allows to configure a GPIO pin in the carrier, and read
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its current value if it is configured as input. See *note The GPIO
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Abstraction:: for details.
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`read_ee'
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`write_ee'
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Read or write the EEPROM. The functions are expected to be only
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called before reprogramming and the carrier should refuse them
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with `ENODEV' after reprogramming. The offset is expected to be
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within 8kB (the current size), but addresses up to 1MB are
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reserved to fit bigger I2C devices in the future. Carriers may
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offer access to other internal flash memories using these same
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methods: for example the SPEC driver may define that its carrier
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I2C memory is seen at offset 1M and the internal SPI flash is seen
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at offset 16M. This multiplexing of several flash memories in the
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same address space is carrier-specific and should only be used
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by a driver that has verified the `carrier_name' field.
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The GPIO Abstraction
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====================
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Support for GPIO pins in the fmc-bus environment is not very
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straightforward and deserves special discussion.
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While the general idea of a carrier-independent driver seems to fly,
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configuration of specific signals within the carrier needs at least
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some knowledge of the carrier itself. For this reason, the specific
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driver can request to configure carrier-specific GPIO pins, numbered
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from 0 to at most 4095. Configuration is performed by passing a
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pointer to an array of struct fmc_gpio items, as well as the length of
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the array. This is the data structure:
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struct fmc_gpio {
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char *carrier_name;
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int gpio;
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int _gpio; /* internal use by the carrier */
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int mode; /* GPIOF_DIR_OUT etc, from <linux/gpio.h> */
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int irqmode; /* IRQF_TRIGGER_LOW and so on */
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};
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By specifying a carrier_name for each pin, the driver may access
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different pins in different carriers. The gpio_config method is
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expected to return the number of pins successfully configured, ignoring
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requests for other carriers. However, if no pin is configured (because
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no structure at all refers to the current carrier_name), the operation
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returns an error so the caller will know that it is running under a
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yet-unsupported carrier.
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So, for example, a driver that has been developed and tested on both
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the SPEC and the SVEC may request configuration of two different GPIO
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pins, and expect one such configuration to succeed - if none succeeds
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it most likely means that the current carrier is a still-unknown one.
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If, however, your GPIO pin has a specific known role, you can pass a
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special number in the gpio field, using one of the following macros:
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#define FMC_GPIO_RAW(x) (x) /* 4096 of them */
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#define FMC_GPIO_IRQ(x) ((x) + 0x1000) /* 256 of them */
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#define FMC_GPIO_LED(x) ((x) + 0x1100) /* 256 of them */
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#define FMC_GPIO_KEY(x) ((x) + 0x1200) /* 256 of them */
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#define FMC_GPIO_TP(x) ((x) + 0x1300) /* 256 of them */
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#define FMC_GPIO_USER(x) ((x) + 0x1400) /* 256 of them */
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Use of virtual GPIO numbers (anything but FMC_GPIO_RAW) is allowed
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provided the carrier_name field in the data structure is left
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unspecified (NULL). Each carrier is responsible for providing a mapping
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between virtual and physical GPIO numbers. The carrier may then use the
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_gpio field to cache the result of this mapping.
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All carriers must map their I/O lines to the sets above starting from
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zero. The SPEC, for example, maps interrupt pins 0 and 1, and test
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points 0 through 3 (even if the test points on the PCB are called
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5,6,7,8).
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If, for example, a driver requires a free LED and a test point (for a
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scope probe to be plugged at some point during development) it may ask
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for FMC_GPIO_LED(0) and FMC_GPIO_TP(0). Each carrier will provide
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suitable GPIO pins. Clearly, the person running the drivers will know
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the order used by the specific carrier driver in assigning leds and
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testpoints, so to make a carrier-dependent use of the diagnostic tools.
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In theory, some form of autodetection should be possible: a driver like
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the wr-nic (which uses IRQ(1) on the SPEC card) should configure
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IRQ(0), make a test with software-generated interrupts and configure
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IRQ(1) if the test fails. This probing step should be used because even
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if the wr-nic gateware is known to use IRQ1 on the SPEC, the driver
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should be carrier-independent and thus use IRQ(0) as a first bet -
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actually, the knowledge that IRQ0 may fail is carrier-dependent
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information, but using it doesn't make the driver unsuitable for other
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carriers.
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The return value of gpio_config is defined as follows:
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* If no pin in the array can be used by the carrier, `-ENODEV'.
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* If at least one virtual GPIO number cannot be mapped, `-ENOENT'.
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* On success, 0 or positive. The value returned is the number of
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high input bits (if no input is configured, the value for success
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is 0).
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While I admit the procedure is not completely straightforward, it
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allows configuration, input and output with a single carrier operation.
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Given the typical use case of FMC devices, GPIO operations are not
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expected to ever by in hot paths, and GPIO access so fare has only been
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used to configure the interrupt pin, mode and polarity. Especially
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reading inputs is not expected to be common. If your device has GPIO
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capabilities in the hot path, you should consider using the kernel's
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GPIO mechanisms.
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