6b46c2b156
Instead of just using text for functions and structs, use the C domain tags, in order to allow cross-referencing with the kernel-doc markups. Signed-off-by: Mauro Carvalho Chehab <mchehab@s-opensource.com>
1031 lines
38 KiB
ReStructuredText
1031 lines
38 KiB
ReStructuredText
========================
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libATA Developer's Guide
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========================
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:Author: Jeff Garzik
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Introduction
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============
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libATA is a library used inside the Linux kernel to support ATA host
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controllers and devices. libATA provides an ATA driver API, class
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transports for ATA and ATAPI devices, and SCSI<->ATA translation for ATA
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devices according to the T10 SAT specification.
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This Guide documents the libATA driver API, library functions, library
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internals, and a couple sample ATA low-level drivers.
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libata Driver API
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=================
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:c:type:`struct ata_port_operations <ata_port_operations>`
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is defined for every low-level libata
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hardware driver, and it controls how the low-level driver interfaces
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with the ATA and SCSI layers.
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FIS-based drivers will hook into the system with ``->qc_prep()`` and
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``->qc_issue()`` high-level hooks. Hardware which behaves in a manner
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similar to PCI IDE hardware may utilize several generic helpers,
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defining at a bare minimum the bus I/O addresses of the ATA shadow
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register blocks.
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:c:type:`struct ata_port_operations <ata_port_operations>`
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----------------------------------------------------------
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Disable ATA port
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~~~~~~~~~~~~~~~~
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::
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void (*port_disable) (struct ata_port *);
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Called from :c:func:`ata_bus_probe` error path, as well as when unregistering
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from the SCSI module (rmmod, hot unplug). This function should do
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whatever needs to be done to take the port out of use. In most cases,
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:c:func:`ata_port_disable` can be used as this hook.
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Called from :c:func:`ata_bus_probe` on a failed probe. Called from
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:c:func:`ata_scsi_release`.
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Post-IDENTIFY device configuration
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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::
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void (*dev_config) (struct ata_port *, struct ata_device *);
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Called after IDENTIFY [PACKET] DEVICE is issued to each device found.
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Typically used to apply device-specific fixups prior to issue of SET
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FEATURES - XFER MODE, and prior to operation.
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This entry may be specified as NULL in ata_port_operations.
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Set PIO/DMA mode
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~~~~~~~~~~~~~~~~
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::
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void (*set_piomode) (struct ata_port *, struct ata_device *);
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void (*set_dmamode) (struct ata_port *, struct ata_device *);
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void (*post_set_mode) (struct ata_port *);
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unsigned int (*mode_filter) (struct ata_port *, struct ata_device *, unsigned int);
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Hooks called prior to the issue of SET FEATURES - XFER MODE command. The
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optional ``->mode_filter()`` hook is called when libata has built a mask of
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the possible modes. This is passed to the ``->mode_filter()`` function
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which should return a mask of valid modes after filtering those
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unsuitable due to hardware limits. It is not valid to use this interface
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to add modes.
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``dev->pio_mode`` and ``dev->dma_mode`` are guaranteed to be valid when
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``->set_piomode()`` and when ``->set_dmamode()`` is called. The timings for
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any other drive sharing the cable will also be valid at this point. That
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is the library records the decisions for the modes of each drive on a
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channel before it attempts to set any of them.
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``->post_set_mode()`` is called unconditionally, after the SET FEATURES -
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XFER MODE command completes successfully.
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``->set_piomode()`` is always called (if present), but ``->set_dma_mode()``
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is only called if DMA is possible.
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Taskfile read/write
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~~~~~~~~~~~~~~~~~~~
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::
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void (*sff_tf_load) (struct ata_port *ap, struct ata_taskfile *tf);
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void (*sff_tf_read) (struct ata_port *ap, struct ata_taskfile *tf);
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``->tf_load()`` is called to load the given taskfile into hardware
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registers / DMA buffers. ``->tf_read()`` is called to read the hardware
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registers / DMA buffers, to obtain the current set of taskfile register
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values. Most drivers for taskfile-based hardware (PIO or MMIO) use
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:c:func:`ata_sff_tf_load` and :c:func:`ata_sff_tf_read` for these hooks.
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PIO data read/write
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~~~~~~~~~~~~~~~~~~~
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::
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void (*sff_data_xfer) (struct ata_device *, unsigned char *, unsigned int, int);
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All bmdma-style drivers must implement this hook. This is the low-level
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operation that actually copies the data bytes during a PIO data
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transfer. Typically the driver will choose one of
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:c:func:`ata_sff_data_xfer_noirq`, :c:func:`ata_sff_data_xfer`, or
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:c:func:`ata_sff_data_xfer32`.
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ATA command execute
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~~~~~~~~~~~~~~~~~~~
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::
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void (*sff_exec_command)(struct ata_port *ap, struct ata_taskfile *tf);
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causes an ATA command, previously loaded with ``->tf_load()``, to be
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initiated in hardware. Most drivers for taskfile-based hardware use
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:c:func:`ata_sff_exec_command` for this hook.
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Per-cmd ATAPI DMA capabilities filter
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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::
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int (*check_atapi_dma) (struct ata_queued_cmd *qc);
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Allow low-level driver to filter ATA PACKET commands, returning a status
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indicating whether or not it is OK to use DMA for the supplied PACKET
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command.
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This hook may be specified as NULL, in which case libata will assume
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that atapi dma can be supported.
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Read specific ATA shadow registers
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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::
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u8 (*sff_check_status)(struct ata_port *ap);
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u8 (*sff_check_altstatus)(struct ata_port *ap);
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Reads the Status/AltStatus ATA shadow register from hardware. On some
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hardware, reading the Status register has the side effect of clearing
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the interrupt condition. Most drivers for taskfile-based hardware use
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:c:func:`ata_sff_check_status` for this hook.
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Write specific ATA shadow register
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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::
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void (*sff_set_devctl)(struct ata_port *ap, u8 ctl);
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Write the device control ATA shadow register to the hardware. Most
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drivers don't need to define this.
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Select ATA device on bus
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~~~~~~~~~~~~~~~~~~~~~~~~
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::
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void (*sff_dev_select)(struct ata_port *ap, unsigned int device);
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Issues the low-level hardware command(s) that causes one of N hardware
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devices to be considered 'selected' (active and available for use) on
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the ATA bus. This generally has no meaning on FIS-based devices.
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Most drivers for taskfile-based hardware use :c:func:`ata_sff_dev_select` for
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this hook.
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Private tuning method
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~~~~~~~~~~~~~~~~~~~~~
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::
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void (*set_mode) (struct ata_port *ap);
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By default libata performs drive and controller tuning in accordance
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with the ATA timing rules and also applies blacklists and cable limits.
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Some controllers need special handling and have custom tuning rules,
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typically raid controllers that use ATA commands but do not actually do
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drive timing.
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**Warning**
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This hook should not be used to replace the standard controller
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tuning logic when a controller has quirks. Replacing the default
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tuning logic in that case would bypass handling for drive and bridge
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quirks that may be important to data reliability. If a controller
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needs to filter the mode selection it should use the mode_filter
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hook instead.
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Control PCI IDE BMDMA engine
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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::
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void (*bmdma_setup) (struct ata_queued_cmd *qc);
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void (*bmdma_start) (struct ata_queued_cmd *qc);
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void (*bmdma_stop) (struct ata_port *ap);
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u8 (*bmdma_status) (struct ata_port *ap);
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When setting up an IDE BMDMA transaction, these hooks arm
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(``->bmdma_setup``), fire (``->bmdma_start``), and halt (``->bmdma_stop``) the
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hardware's DMA engine. ``->bmdma_status`` is used to read the standard PCI
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IDE DMA Status register.
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These hooks are typically either no-ops, or simply not implemented, in
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FIS-based drivers.
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Most legacy IDE drivers use :c:func:`ata_bmdma_setup` for the
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:c:func:`bmdma_setup` hook. :c:func:`ata_bmdma_setup` will write the pointer
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to the PRD table to the IDE PRD Table Address register, enable DMA in the DMA
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Command register, and call :c:func:`exec_command` to begin the transfer.
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Most legacy IDE drivers use :c:func:`ata_bmdma_start` for the
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:c:func:`bmdma_start` hook. :c:func:`ata_bmdma_start` will write the
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ATA_DMA_START flag to the DMA Command register.
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Many legacy IDE drivers use :c:func:`ata_bmdma_stop` for the
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:c:func:`bmdma_stop` hook. :c:func:`ata_bmdma_stop` clears the ATA_DMA_START
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flag in the DMA command register.
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Many legacy IDE drivers use :c:func:`ata_bmdma_status` as the
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:c:func:`bmdma_status` hook.
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High-level taskfile hooks
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~~~~~~~~~~~~~~~~~~~~~~~~~
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::
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void (*qc_prep) (struct ata_queued_cmd *qc);
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int (*qc_issue) (struct ata_queued_cmd *qc);
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Higher-level hooks, these two hooks can potentially supercede several of
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the above taskfile/DMA engine hooks. ``->qc_prep`` is called after the
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buffers have been DMA-mapped, and is typically used to populate the
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hardware's DMA scatter-gather table. Most drivers use the standard
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:c:func:`ata_qc_prep` helper function, but more advanced drivers roll their
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own.
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``->qc_issue`` is used to make a command active, once the hardware and S/G
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tables have been prepared. IDE BMDMA drivers use the helper function
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:c:func:`ata_qc_issue_prot` for taskfile protocol-based dispatch. More
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advanced drivers implement their own ``->qc_issue``.
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:c:func:`ata_qc_issue_prot` calls ``->tf_load()``, ``->bmdma_setup()``, and
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``->bmdma_start()`` as necessary to initiate a transfer.
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Exception and probe handling (EH)
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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::
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void (*eng_timeout) (struct ata_port *ap);
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void (*phy_reset) (struct ata_port *ap);
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Deprecated. Use ``->error_handler()`` instead.
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::
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void (*freeze) (struct ata_port *ap);
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void (*thaw) (struct ata_port *ap);
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:c:func:`ata_port_freeze` is called when HSM violations or some other
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condition disrupts normal operation of the port. A frozen port is not
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allowed to perform any operation until the port is thawed, which usually
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follows a successful reset.
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The optional ``->freeze()`` callback can be used for freezing the port
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hardware-wise (e.g. mask interrupt and stop DMA engine). If a port
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cannot be frozen hardware-wise, the interrupt handler must ack and clear
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interrupts unconditionally while the port is frozen.
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The optional ``->thaw()`` callback is called to perform the opposite of
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``->freeze()``: prepare the port for normal operation once again. Unmask
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interrupts, start DMA engine, etc.
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::
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void (*error_handler) (struct ata_port *ap);
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``->error_handler()`` is a driver's hook into probe, hotplug, and recovery
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and other exceptional conditions. The primary responsibility of an
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implementation is to call :c:func:`ata_do_eh` or :c:func:`ata_bmdma_drive_eh`
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with a set of EH hooks as arguments:
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'prereset' hook (may be NULL) is called during an EH reset, before any
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other actions are taken.
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'postreset' hook (may be NULL) is called after the EH reset is
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performed. Based on existing conditions, severity of the problem, and
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hardware capabilities,
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Either 'softreset' (may be NULL) or 'hardreset' (may be NULL) will be
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called to perform the low-level EH reset.
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::
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void (*post_internal_cmd) (struct ata_queued_cmd *qc);
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Perform any hardware-specific actions necessary to finish processing
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after executing a probe-time or EH-time command via
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:c:func:`ata_exec_internal`.
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Hardware interrupt handling
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~~~~~~~~~~~~~~~~~~~~~~~~~~~
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::
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irqreturn_t (*irq_handler)(int, void *, struct pt_regs *);
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void (*irq_clear) (struct ata_port *);
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``->irq_handler`` is the interrupt handling routine registered with the
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system, by libata. ``->irq_clear`` is called during probe just before the
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interrupt handler is registered, to be sure hardware is quiet.
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The second argument, dev_instance, should be cast to a pointer to
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:c:type:`struct ata_host_set <ata_host_set>`.
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Most legacy IDE drivers use :c:func:`ata_sff_interrupt` for the irq_handler
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hook, which scans all ports in the host_set, determines which queued
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command was active (if any), and calls ata_sff_host_intr(ap,qc).
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Most legacy IDE drivers use :c:func:`ata_sff_irq_clear` for the
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:c:func:`irq_clear` hook, which simply clears the interrupt and error flags
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in the DMA status register.
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SATA phy read/write
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~~~~~~~~~~~~~~~~~~~
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::
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int (*scr_read) (struct ata_port *ap, unsigned int sc_reg,
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u32 *val);
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int (*scr_write) (struct ata_port *ap, unsigned int sc_reg,
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u32 val);
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Read and write standard SATA phy registers. Currently only used if
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``->phy_reset`` hook called the :c:func:`sata_phy_reset` helper function.
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sc_reg is one of SCR_STATUS, SCR_CONTROL, SCR_ERROR, or SCR_ACTIVE.
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Init and shutdown
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~~~~~~~~~~~~~~~~~
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::
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int (*port_start) (struct ata_port *ap);
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void (*port_stop) (struct ata_port *ap);
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void (*host_stop) (struct ata_host_set *host_set);
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``->port_start()`` is called just after the data structures for each port
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are initialized. Typically this is used to alloc per-port DMA buffers /
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tables / rings, enable DMA engines, and similar tasks. Some drivers also
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use this entry point as a chance to allocate driver-private memory for
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``ap->private_data``.
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Many drivers use :c:func:`ata_port_start` as this hook or call it from their
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own :c:func:`port_start` hooks. :c:func:`ata_port_start` allocates space for
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a legacy IDE PRD table and returns.
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``->port_stop()`` is called after ``->host_stop()``. Its sole function is to
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release DMA/memory resources, now that they are no longer actively being
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used. Many drivers also free driver-private data from port at this time.
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``->host_stop()`` is called after all ``->port_stop()`` calls have completed.
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The hook must finalize hardware shutdown, release DMA and other
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resources, etc. This hook may be specified as NULL, in which case it is
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not called.
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Error handling
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==============
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This chapter describes how errors are handled under libata. Readers are
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advised to read SCSI EH (Documentation/scsi/scsi_eh.txt) and ATA
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exceptions doc first.
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Origins of commands
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-------------------
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In libata, a command is represented with
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:c:type:`struct ata_queued_cmd <ata_queued_cmd>` or qc.
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qc's are preallocated during port initialization and repetitively used
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for command executions. Currently only one qc is allocated per port but
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yet-to-be-merged NCQ branch allocates one for each tag and maps each qc
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to NCQ tag 1-to-1.
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libata commands can originate from two sources - libata itself and SCSI
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midlayer. libata internal commands are used for initialization and error
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handling. All normal blk requests and commands for SCSI emulation are
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passed as SCSI commands through queuecommand callback of SCSI host
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template.
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How commands are issued
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-----------------------
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Internal commands
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First, qc is allocated and initialized using :c:func:`ata_qc_new_init`.
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Although :c:func:`ata_qc_new_init` doesn't implement any wait or retry
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mechanism when qc is not available, internal commands are currently
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issued only during initialization and error recovery, so no other
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command is active and allocation is guaranteed to succeed.
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Once allocated qc's taskfile is initialized for the command to be
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executed. qc currently has two mechanisms to notify completion. One
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is via ``qc->complete_fn()`` callback and the other is completion
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``qc->waiting``. ``qc->complete_fn()`` callback is the asynchronous path
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used by normal SCSI translated commands and ``qc->waiting`` is the
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synchronous (issuer sleeps in process context) path used by internal
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commands.
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Once initialization is complete, host_set lock is acquired and the
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qc is issued.
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SCSI commands
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All libata drivers use :c:func:`ata_scsi_queuecmd` as
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``hostt->queuecommand`` callback. scmds can either be simulated or
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translated. No qc is involved in processing a simulated scmd. The
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result is computed right away and the scmd is completed.
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For a translated scmd, :c:func:`ata_qc_new_init` is invoked to allocate a
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qc and the scmd is translated into the qc. SCSI midlayer's
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completion notification function pointer is stored into
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``qc->scsidone``.
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``qc->complete_fn()`` callback is used for completion notification. ATA
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commands use :c:func:`ata_scsi_qc_complete` while ATAPI commands use
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:c:func:`atapi_qc_complete`. Both functions end up calling ``qc->scsidone``
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to notify upper layer when the qc is finished. After translation is
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completed, the qc is issued with :c:func:`ata_qc_issue`.
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Note that SCSI midlayer invokes hostt->queuecommand while holding
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host_set lock, so all above occur while holding host_set lock.
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How commands are processed
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--------------------------
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Depending on which protocol and which controller are used, commands are
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processed differently. For the purpose of discussion, a controller which
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uses taskfile interface and all standard callbacks is assumed.
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Currently 6 ATA command protocols are used. They can be sorted into the
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following four categories according to how they are processed.
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ATA NO DATA or DMA
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ATA_PROT_NODATA and ATA_PROT_DMA fall into this category. These
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types of commands don't require any software intervention once
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issued. Device will raise interrupt on completion.
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ATA PIO
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ATA_PROT_PIO is in this category. libata currently implements PIO
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with polling. ATA_NIEN bit is set to turn off interrupt and
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pio_task on ata_wq performs polling and IO.
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ATAPI NODATA or DMA
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ATA_PROT_ATAPI_NODATA and ATA_PROT_ATAPI_DMA are in this
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category. packet_task is used to poll BSY bit after issuing PACKET
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command. Once BSY is turned off by the device, packet_task
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transfers CDB and hands off processing to interrupt handler.
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ATAPI PIO
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ATA_PROT_ATAPI is in this category. ATA_NIEN bit is set and, as
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in ATAPI NODATA or DMA, packet_task submits cdb. However, after
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submitting cdb, further processing (data transfer) is handed off to
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pio_task.
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How commands are completed
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--------------------------
|
|
|
|
Once issued, all qc's are either completed with :c:func:`ata_qc_complete` or
|
|
time out. For commands which are handled by interrupts,
|
|
:c:func:`ata_host_intr` invokes :c:func:`ata_qc_complete`, and, for PIO tasks,
|
|
pio_task invokes :c:func:`ata_qc_complete`. In error cases, packet_task may
|
|
also complete commands.
|
|
|
|
:c:func:`ata_qc_complete` does the following.
|
|
|
|
1. DMA memory is unmapped.
|
|
|
|
2. ATA_QCFLAG_ACTIVE is cleared from qc->flags.
|
|
|
|
3. :c:func:`qc->complete_fn` callback is invoked. If the return value of the
|
|
callback is not zero. Completion is short circuited and
|
|
:c:func:`ata_qc_complete` returns.
|
|
|
|
4. :c:func:`__ata_qc_complete` is called, which does
|
|
|
|
1. ``qc->flags`` is cleared to zero.
|
|
|
|
2. ``ap->active_tag`` and ``qc->tag`` are poisoned.
|
|
|
|
3. ``qc->waiting`` is cleared & completed (in that order).
|
|
|
|
4. qc is deallocated by clearing appropriate bit in ``ap->qactive``.
|
|
|
|
So, it basically notifies upper layer and deallocates qc. One exception
|
|
is short-circuit path in #3 which is used by :c:func:`atapi_qc_complete`.
|
|
|
|
For all non-ATAPI commands, whether it fails or not, almost the same
|
|
code path is taken and very little error handling takes place. A qc is
|
|
completed with success status if it succeeded, with failed status
|
|
otherwise.
|
|
|
|
However, failed ATAPI commands require more handling as REQUEST SENSE is
|
|
needed to acquire sense data. If an ATAPI command fails,
|
|
:c:func:`ata_qc_complete` is invoked with error status, which in turn invokes
|
|
:c:func:`atapi_qc_complete` via ``qc->complete_fn()`` callback.
|
|
|
|
This makes :c:func:`atapi_qc_complete` set ``scmd->result`` to
|
|
SAM_STAT_CHECK_CONDITION, complete the scmd and return 1. As the
|
|
sense data is empty but ``scmd->result`` is CHECK CONDITION, SCSI midlayer
|
|
will invoke EH for the scmd, and returning 1 makes :c:func:`ata_qc_complete`
|
|
to return without deallocating the qc. This leads us to
|
|
:c:func:`ata_scsi_error` with partially completed qc.
|
|
|
|
:c:func:`ata_scsi_error`
|
|
------------------------
|
|
|
|
:c:func:`ata_scsi_error` is the current ``transportt->eh_strategy_handler()``
|
|
for libata. As discussed above, this will be entered in two cases -
|
|
timeout and ATAPI error completion. This function calls low level libata
|
|
driver's :c:func:`eng_timeout` callback, the standard callback for which is
|
|
:c:func:`ata_eng_timeout`. It checks if a qc is active and calls
|
|
:c:func:`ata_qc_timeout` on the qc if so. Actual error handling occurs in
|
|
:c:func:`ata_qc_timeout`.
|
|
|
|
If EH is invoked for timeout, :c:func:`ata_qc_timeout` stops BMDMA and
|
|
completes the qc. Note that as we're currently in EH, we cannot call
|
|
scsi_done. As described in SCSI EH doc, a recovered scmd should be
|
|
either retried with :c:func:`scsi_queue_insert` or finished with
|
|
:c:func:`scsi_finish_command`. Here, we override ``qc->scsidone`` with
|
|
:c:func:`scsi_finish_command` and calls :c:func:`ata_qc_complete`.
|
|
|
|
If EH is invoked due to a failed ATAPI qc, the qc here is completed but
|
|
not deallocated. The purpose of this half-completion is to use the qc as
|
|
place holder to make EH code reach this place. This is a bit hackish,
|
|
but it works.
|
|
|
|
Once control reaches here, the qc is deallocated by invoking
|
|
:c:func:`__ata_qc_complete` explicitly. Then, internal qc for REQUEST SENSE
|
|
is issued. Once sense data is acquired, scmd is finished by directly
|
|
invoking :c:func:`scsi_finish_command` on the scmd. Note that as we already
|
|
have completed and deallocated the qc which was associated with the
|
|
scmd, we don't need to/cannot call :c:func:`ata_qc_complete` again.
|
|
|
|
Problems with the current EH
|
|
----------------------------
|
|
|
|
- Error representation is too crude. Currently any and all error
|
|
conditions are represented with ATA STATUS and ERROR registers.
|
|
Errors which aren't ATA device errors are treated as ATA device
|
|
errors by setting ATA_ERR bit. Better error descriptor which can
|
|
properly represent ATA and other errors/exceptions is needed.
|
|
|
|
- When handling timeouts, no action is taken to make device forget
|
|
about the timed out command and ready for new commands.
|
|
|
|
- EH handling via :c:func:`ata_scsi_error` is not properly protected from
|
|
usual command processing. On EH entrance, the device is not in
|
|
quiescent state. Timed out commands may succeed or fail any time.
|
|
pio_task and atapi_task may still be running.
|
|
|
|
- Too weak error recovery. Devices / controllers causing HSM mismatch
|
|
errors and other errors quite often require reset to return to known
|
|
state. Also, advanced error handling is necessary to support features
|
|
like NCQ and hotplug.
|
|
|
|
- ATA errors are directly handled in the interrupt handler and PIO
|
|
errors in pio_task. This is problematic for advanced error handling
|
|
for the following reasons.
|
|
|
|
First, advanced error handling often requires context and internal qc
|
|
execution.
|
|
|
|
Second, even a simple failure (say, CRC error) needs information
|
|
gathering and could trigger complex error handling (say, resetting &
|
|
reconfiguring). Having multiple code paths to gather information,
|
|
enter EH and trigger actions makes life painful.
|
|
|
|
Third, scattered EH code makes implementing low level drivers
|
|
difficult. Low level drivers override libata callbacks. If EH is
|
|
scattered over several places, each affected callbacks should perform
|
|
its part of error handling. This can be error prone and painful.
|
|
|
|
libata Library
|
|
==============
|
|
|
|
.. kernel-doc:: drivers/ata/libata-core.c
|
|
:export:
|
|
|
|
libata Core Internals
|
|
=====================
|
|
|
|
.. kernel-doc:: drivers/ata/libata-core.c
|
|
:internal:
|
|
|
|
.. kernel-doc:: drivers/ata/libata-eh.c
|
|
|
|
libata SCSI translation/emulation
|
|
=================================
|
|
|
|
.. kernel-doc:: drivers/ata/libata-scsi.c
|
|
:export:
|
|
|
|
.. kernel-doc:: drivers/ata/libata-scsi.c
|
|
:internal:
|
|
|
|
ATA errors and exceptions
|
|
=========================
|
|
|
|
This chapter tries to identify what error/exception conditions exist for
|
|
ATA/ATAPI devices and describe how they should be handled in
|
|
implementation-neutral way.
|
|
|
|
The term 'error' is used to describe conditions where either an explicit
|
|
error condition is reported from device or a command has timed out.
|
|
|
|
The term 'exception' is either used to describe exceptional conditions
|
|
which are not errors (say, power or hotplug events), or to describe both
|
|
errors and non-error exceptional conditions. Where explicit distinction
|
|
between error and exception is necessary, the term 'non-error exception'
|
|
is used.
|
|
|
|
Exception categories
|
|
--------------------
|
|
|
|
Exceptions are described primarily with respect to legacy taskfile + bus
|
|
master IDE interface. If a controller provides other better mechanism
|
|
for error reporting, mapping those into categories described below
|
|
shouldn't be difficult.
|
|
|
|
In the following sections, two recovery actions - reset and
|
|
reconfiguring transport - are mentioned. These are described further in
|
|
`EH recovery actions <#exrec>`__.
|
|
|
|
HSM violation
|
|
~~~~~~~~~~~~~
|
|
|
|
This error is indicated when STATUS value doesn't match HSM requirement
|
|
during issuing or execution any ATA/ATAPI command.
|
|
|
|
- ATA_STATUS doesn't contain !BSY && DRDY && !DRQ while trying to
|
|
issue a command.
|
|
|
|
- !BSY && !DRQ during PIO data transfer.
|
|
|
|
- DRQ on command completion.
|
|
|
|
- !BSY && ERR after CDB transfer starts but before the last byte of CDB
|
|
is transferred. ATA/ATAPI standard states that "The device shall not
|
|
terminate the PACKET command with an error before the last byte of
|
|
the command packet has been written" in the error outputs description
|
|
of PACKET command and the state diagram doesn't include such
|
|
transitions.
|
|
|
|
In these cases, HSM is violated and not much information regarding the
|
|
error can be acquired from STATUS or ERROR register. IOW, this error can
|
|
be anything - driver bug, faulty device, controller and/or cable.
|
|
|
|
As HSM is violated, reset is necessary to restore known state.
|
|
Reconfiguring transport for lower speed might be helpful too as
|
|
transmission errors sometimes cause this kind of errors.
|
|
|
|
ATA/ATAPI device error (non-NCQ / non-CHECK CONDITION)
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
These are errors detected and reported by ATA/ATAPI devices indicating
|
|
device problems. For this type of errors, STATUS and ERROR register
|
|
values are valid and describe error condition. Note that some of ATA bus
|
|
errors are detected by ATA/ATAPI devices and reported using the same
|
|
mechanism as device errors. Those cases are described later in this
|
|
section.
|
|
|
|
For ATA commands, this type of errors are indicated by !BSY && ERR
|
|
during command execution and on completion.
|
|
|
|
For ATAPI commands,
|
|
|
|
- !BSY && ERR && ABRT right after issuing PACKET indicates that PACKET
|
|
command is not supported and falls in this category.
|
|
|
|
- !BSY && ERR(==CHK) && !ABRT after the last byte of CDB is transferred
|
|
indicates CHECK CONDITION and doesn't fall in this category.
|
|
|
|
- !BSY && ERR(==CHK) && ABRT after the last byte of CDB is transferred
|
|
\*probably\* indicates CHECK CONDITION and doesn't fall in this
|
|
category.
|
|
|
|
Of errors detected as above, the following are not ATA/ATAPI device
|
|
errors but ATA bus errors and should be handled according to
|
|
`ATA bus error <#excatATAbusErr>`__.
|
|
|
|
CRC error during data transfer
|
|
This is indicated by ICRC bit in the ERROR register and means that
|
|
corruption occurred during data transfer. Up to ATA/ATAPI-7, the
|
|
standard specifies that this bit is only applicable to UDMA
|
|
transfers but ATA/ATAPI-8 draft revision 1f says that the bit may be
|
|
applicable to multiword DMA and PIO.
|
|
|
|
ABRT error during data transfer or on completion
|
|
Up to ATA/ATAPI-7, the standard specifies that ABRT could be set on
|
|
ICRC errors and on cases where a device is not able to complete a
|
|
command. Combined with the fact that MWDMA and PIO transfer errors
|
|
aren't allowed to use ICRC bit up to ATA/ATAPI-7, it seems to imply
|
|
that ABRT bit alone could indicate transfer errors.
|
|
|
|
However, ATA/ATAPI-8 draft revision 1f removes the part that ICRC
|
|
errors can turn on ABRT. So, this is kind of gray area. Some
|
|
heuristics are needed here.
|
|
|
|
ATA/ATAPI device errors can be further categorized as follows.
|
|
|
|
Media errors
|
|
This is indicated by UNC bit in the ERROR register. ATA devices
|
|
reports UNC error only after certain number of retries cannot
|
|
recover the data, so there's nothing much else to do other than
|
|
notifying upper layer.
|
|
|
|
READ and WRITE commands report CHS or LBA of the first failed sector
|
|
but ATA/ATAPI standard specifies that the amount of transferred data
|
|
on error completion is indeterminate, so we cannot assume that
|
|
sectors preceding the failed sector have been transferred and thus
|
|
cannot complete those sectors successfully as SCSI does.
|
|
|
|
Media changed / media change requested error
|
|
<<TODO: fill here>>
|
|
|
|
Address error
|
|
This is indicated by IDNF bit in the ERROR register. Report to upper
|
|
layer.
|
|
|
|
Other errors
|
|
This can be invalid command or parameter indicated by ABRT ERROR bit
|
|
or some other error condition. Note that ABRT bit can indicate a lot
|
|
of things including ICRC and Address errors. Heuristics needed.
|
|
|
|
Depending on commands, not all STATUS/ERROR bits are applicable. These
|
|
non-applicable bits are marked with "na" in the output descriptions but
|
|
up to ATA/ATAPI-7 no definition of "na" can be found. However,
|
|
ATA/ATAPI-8 draft revision 1f describes "N/A" as follows.
|
|
|
|
3.2.3.3a N/A
|
|
A keyword the indicates a field has no defined value in this
|
|
standard and should not be checked by the host or device. N/A
|
|
fields should be cleared to zero.
|
|
|
|
So, it seems reasonable to assume that "na" bits are cleared to zero by
|
|
devices and thus need no explicit masking.
|
|
|
|
ATAPI device CHECK CONDITION
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
ATAPI device CHECK CONDITION error is indicated by set CHK bit (ERR bit)
|
|
in the STATUS register after the last byte of CDB is transferred for a
|
|
PACKET command. For this kind of errors, sense data should be acquired
|
|
to gather information regarding the errors. REQUEST SENSE packet command
|
|
should be used to acquire sense data.
|
|
|
|
Once sense data is acquired, this type of errors can be handled
|
|
similarly to other SCSI errors. Note that sense data may indicate ATA
|
|
bus error (e.g. Sense Key 04h HARDWARE ERROR && ASC/ASCQ 47h/00h SCSI
|
|
PARITY ERROR). In such cases, the error should be considered as an ATA
|
|
bus error and handled according to `ATA bus error <#excatATAbusErr>`__.
|
|
|
|
ATA device error (NCQ)
|
|
~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
NCQ command error is indicated by cleared BSY and set ERR bit during NCQ
|
|
command phase (one or more NCQ commands outstanding). Although STATUS
|
|
and ERROR registers will contain valid values describing the error, READ
|
|
LOG EXT is required to clear the error condition, determine which
|
|
command has failed and acquire more information.
|
|
|
|
READ LOG EXT Log Page 10h reports which tag has failed and taskfile
|
|
register values describing the error. With this information the failed
|
|
command can be handled as a normal ATA command error as in
|
|
`ATA/ATAPI device error (non-NCQ / non-CHECK CONDITION) <#excatDevErr>`__
|
|
and all other in-flight commands must be retried. Note that this retry
|
|
should not be counted - it's likely that commands retried this way would
|
|
have completed normally if it were not for the failed command.
|
|
|
|
Note that ATA bus errors can be reported as ATA device NCQ errors. This
|
|
should be handled as described in `ATA bus error <#excatATAbusErr>`__.
|
|
|
|
If READ LOG EXT Log Page 10h fails or reports NQ, we're thoroughly
|
|
screwed. This condition should be treated according to
|
|
`HSM violation <#excatHSMviolation>`__.
|
|
|
|
ATA bus error
|
|
~~~~~~~~~~~~~
|
|
|
|
ATA bus error means that data corruption occurred during transmission
|
|
over ATA bus (SATA or PATA). This type of errors can be indicated by
|
|
|
|
- ICRC or ABRT error as described in
|
|
`ATA/ATAPI device error (non-NCQ / non-CHECK CONDITION) <#excatDevErr>`__.
|
|
|
|
- Controller-specific error completion with error information
|
|
indicating transmission error.
|
|
|
|
- On some controllers, command timeout. In this case, there may be a
|
|
mechanism to determine that the timeout is due to transmission error.
|
|
|
|
- Unknown/random errors, timeouts and all sorts of weirdities.
|
|
|
|
As described above, transmission errors can cause wide variety of
|
|
symptoms ranging from device ICRC error to random device lockup, and,
|
|
for many cases, there is no way to tell if an error condition is due to
|
|
transmission error or not; therefore, it's necessary to employ some kind
|
|
of heuristic when dealing with errors and timeouts. For example,
|
|
encountering repetitive ABRT errors for known supported command is
|
|
likely to indicate ATA bus error.
|
|
|
|
Once it's determined that ATA bus errors have possibly occurred,
|
|
lowering ATA bus transmission speed is one of actions which may
|
|
alleviate the problem. See `Reconfigure transport <#exrecReconf>`__ for
|
|
more information.
|
|
|
|
PCI bus error
|
|
~~~~~~~~~~~~~
|
|
|
|
Data corruption or other failures during transmission over PCI (or other
|
|
system bus). For standard BMDMA, this is indicated by Error bit in the
|
|
BMDMA Status register. This type of errors must be logged as it
|
|
indicates something is very wrong with the system. Resetting host
|
|
controller is recommended.
|
|
|
|
Late completion
|
|
~~~~~~~~~~~~~~~
|
|
|
|
This occurs when timeout occurs and the timeout handler finds out that
|
|
the timed out command has completed successfully or with error. This is
|
|
usually caused by lost interrupts. This type of errors must be logged.
|
|
Resetting host controller is recommended.
|
|
|
|
Unknown error (timeout)
|
|
~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
This is when timeout occurs and the command is still processing or the
|
|
host and device are in unknown state. When this occurs, HSM could be in
|
|
any valid or invalid state. To bring the device to known state and make
|
|
it forget about the timed out command, resetting is necessary. The timed
|
|
out command may be retried.
|
|
|
|
Timeouts can also be caused by transmission errors. Refer to
|
|
`ATA bus error <#excatATAbusErr>`__ for more details.
|
|
|
|
Hotplug and power management exceptions
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
<<TODO: fill here>>
|
|
|
|
EH recovery actions
|
|
-------------------
|
|
|
|
This section discusses several important recovery actions.
|
|
|
|
Clearing error condition
|
|
~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
Many controllers require its error registers to be cleared by error
|
|
handler. Different controllers may have different requirements.
|
|
|
|
For SATA, it's strongly recommended to clear at least SError register
|
|
during error handling.
|
|
|
|
Reset
|
|
~~~~~
|
|
|
|
During EH, resetting is necessary in the following cases.
|
|
|
|
- HSM is in unknown or invalid state
|
|
|
|
- HBA is in unknown or invalid state
|
|
|
|
- EH needs to make HBA/device forget about in-flight commands
|
|
|
|
- HBA/device behaves weirdly
|
|
|
|
Resetting during EH might be a good idea regardless of error condition
|
|
to improve EH robustness. Whether to reset both or either one of HBA and
|
|
device depends on situation but the following scheme is recommended.
|
|
|
|
- When it's known that HBA is in ready state but ATA/ATAPI device is in
|
|
unknown state, reset only device.
|
|
|
|
- If HBA is in unknown state, reset both HBA and device.
|
|
|
|
HBA resetting is implementation specific. For a controller complying to
|
|
taskfile/BMDMA PCI IDE, stopping active DMA transaction may be
|
|
sufficient iff BMDMA state is the only HBA context. But even mostly
|
|
taskfile/BMDMA PCI IDE complying controllers may have implementation
|
|
specific requirements and mechanism to reset themselves. This must be
|
|
addressed by specific drivers.
|
|
|
|
OTOH, ATA/ATAPI standard describes in detail ways to reset ATA/ATAPI
|
|
devices.
|
|
|
|
PATA hardware reset
|
|
This is hardware initiated device reset signalled with asserted PATA
|
|
RESET- signal. There is no standard way to initiate hardware reset
|
|
from software although some hardware provides registers that allow
|
|
driver to directly tweak the RESET- signal.
|
|
|
|
Software reset
|
|
This is achieved by turning CONTROL SRST bit on for at least 5us.
|
|
Both PATA and SATA support it but, in case of SATA, this may require
|
|
controller-specific support as the second Register FIS to clear SRST
|
|
should be transmitted while BSY bit is still set. Note that on PATA,
|
|
this resets both master and slave devices on a channel.
|
|
|
|
EXECUTE DEVICE DIAGNOSTIC command
|
|
Although ATA/ATAPI standard doesn't describe exactly, EDD implies
|
|
some level of resetting, possibly similar level with software reset.
|
|
Host-side EDD protocol can be handled with normal command processing
|
|
and most SATA controllers should be able to handle EDD's just like
|
|
other commands. As in software reset, EDD affects both devices on a
|
|
PATA bus.
|
|
|
|
Although EDD does reset devices, this doesn't suit error handling as
|
|
EDD cannot be issued while BSY is set and it's unclear how it will
|
|
act when device is in unknown/weird state.
|
|
|
|
ATAPI DEVICE RESET command
|
|
This is very similar to software reset except that reset can be
|
|
restricted to the selected device without affecting the other device
|
|
sharing the cable.
|
|
|
|
SATA phy reset
|
|
This is the preferred way of resetting a SATA device. In effect,
|
|
it's identical to PATA hardware reset. Note that this can be done
|
|
with the standard SCR Control register. As such, it's usually easier
|
|
to implement than software reset.
|
|
|
|
One more thing to consider when resetting devices is that resetting
|
|
clears certain configuration parameters and they need to be set to their
|
|
previous or newly adjusted values after reset.
|
|
|
|
Parameters affected are.
|
|
|
|
- CHS set up with INITIALIZE DEVICE PARAMETERS (seldom used)
|
|
|
|
- Parameters set with SET FEATURES including transfer mode setting
|
|
|
|
- Block count set with SET MULTIPLE MODE
|
|
|
|
- Other parameters (SET MAX, MEDIA LOCK...)
|
|
|
|
ATA/ATAPI standard specifies that some parameters must be maintained
|
|
across hardware or software reset, but doesn't strictly specify all of
|
|
them. Always reconfiguring needed parameters after reset is required for
|
|
robustness. Note that this also applies when resuming from deep sleep
|
|
(power-off).
|
|
|
|
Also, ATA/ATAPI standard requires that IDENTIFY DEVICE / IDENTIFY PACKET
|
|
DEVICE is issued after any configuration parameter is updated or a
|
|
hardware reset and the result used for further operation. OS driver is
|
|
required to implement revalidation mechanism to support this.
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Reconfigure transport
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~~~~~~~~~~~~~~~~~~~~~
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For both PATA and SATA, a lot of corners are cut for cheap connectors,
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|
cables or controllers and it's quite common to see high transmission
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error rate. This can be mitigated by lowering transmission speed.
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The following is a possible scheme Jeff Garzik suggested.
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If more than $N (3?) transmission errors happen in 15 minutes,
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- if SATA, decrease SATA PHY speed. if speed cannot be decreased,
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|
|
- decrease UDMA xfer speed. if at UDMA0, switch to PIO4,
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|
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- decrease PIO xfer speed. if at PIO3, complain, but continue
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|
|
ata_piix Internals
|
|
===================
|
|
|
|
.. kernel-doc:: drivers/ata/ata_piix.c
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|
:internal:
|
|
|
|
sata_sil Internals
|
|
===================
|
|
|
|
.. kernel-doc:: drivers/ata/sata_sil.c
|
|
:internal:
|
|
|
|
Thanks
|
|
======
|
|
|
|
The bulk of the ATA knowledge comes thanks to long conversations with
|
|
Andre Hedrick (www.linux-ide.org), and long hours pondering the ATA and
|
|
SCSI specifications.
|
|
|
|
Thanks to Alan Cox for pointing out similarities between SATA and SCSI,
|
|
and in general for motivation to hack on libata.
|
|
|
|
libata's device detection method, ata_pio_devchk, and in general all
|
|
the early probing was based on extensive study of Hale Landis's
|
|
probe/reset code in his ATADRVR driver (www.ata-atapi.com).
|