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5627ecb837
Pull i2c updates from Wolfram Sang: - tracepoints when Linux acts as an I2C client - added support for AMD PSP - whole subsystem now uses generic_handle_irq_safe() - piix4 driver gained MMIO access enabling so far missed controllers with AMD chipsets - a bulk of device driver updates, refactorization, and fixes. * 'i2c/for-mergewindow' of git://git.kernel.org/pub/scm/linux/kernel/git/wsa/linux: (61 commits) i2c: mux: demux-pinctrl: do not deactivate a master that is not active i2c: meson: Fix wrong speed use from probe i2c: add tracepoints for I2C slave events i2c: designware: Remove code duplication i2c: cros-ec-tunnel: Fix syntax errors in comments MAINTAINERS: adjust XLP9XX I2C DRIVER after removing the devicetree binding i2c: designware: Mark dw_i2c_plat_{suspend,resume}() as __maybe_unused i2c: mediatek: Add i2c compatible for Mediatek MT8168 dt-bindings: i2c: update bindings for MT8168 SoC i2c: mt65xx: Simplify with clk-bulk i2c: i801: Drop two outdated comments i2c: xiic: Make bus names unique i2c: i801: Add support for the Process Call command i2c: i801: Drop useless masking in i801_access i2c: tegra: Add SMBus block read function i2c: designware: Use the i2c_mark_adapter_suspended/resumed() helpers i2c: designware: Lock the adapter while setting the suspended flag i2c: mediatek: remove redundant null check i2c: mediatek: modify bus speed calculation formula i2c: designware: Fix improper usage of readl ...
667 lines
21 KiB
ReStructuredText
667 lines
21 KiB
ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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=============================
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ACPI Based Device Enumeration
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=============================
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ACPI 5 introduced a set of new resources (UartTSerialBus, I2cSerialBus,
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SpiSerialBus, GpioIo and GpioInt) which can be used in enumerating slave
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devices behind serial bus controllers.
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In addition we are starting to see peripherals integrated in the
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SoC/Chipset to appear only in ACPI namespace. These are typically devices
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that are accessed through memory-mapped registers.
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In order to support this and re-use the existing drivers as much as
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possible we decided to do following:
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- Devices that have no bus connector resource are represented as
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platform devices.
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- Devices behind real busses where there is a connector resource
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are represented as struct spi_device or struct i2c_device. Note
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that standard UARTs are not busses so there is no struct uart_device,
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although some of them may be represented by sturct serdev_device.
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As both ACPI and Device Tree represent a tree of devices (and their
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resources) this implementation follows the Device Tree way as much as
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possible.
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The ACPI implementation enumerates devices behind busses (platform, SPI,
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I2C, and in some cases UART), creates the physical devices and binds them
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to their ACPI handle in the ACPI namespace.
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This means that when ACPI_HANDLE(dev) returns non-NULL the device was
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enumerated from ACPI namespace. This handle can be used to extract other
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device-specific configuration. There is an example of this below.
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Platform bus support
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====================
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Since we are using platform devices to represent devices that are not
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connected to any physical bus we only need to implement a platform driver
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for the device and add supported ACPI IDs. If this same IP-block is used on
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some other non-ACPI platform, the driver might work out of the box or needs
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some minor changes.
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Adding ACPI support for an existing driver should be pretty
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straightforward. Here is the simplest example::
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static const struct acpi_device_id mydrv_acpi_match[] = {
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/* ACPI IDs here */
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{ }
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};
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MODULE_DEVICE_TABLE(acpi, mydrv_acpi_match);
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static struct platform_driver my_driver = {
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...
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.driver = {
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.acpi_match_table = mydrv_acpi_match,
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},
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};
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If the driver needs to perform more complex initialization like getting and
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configuring GPIOs it can get its ACPI handle and extract this information
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from ACPI tables.
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DMA support
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===========
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DMA controllers enumerated via ACPI should be registered in the system to
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provide generic access to their resources. For example, a driver that would
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like to be accessible to slave devices via generic API call
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dma_request_chan() must register itself at the end of the probe function like
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this::
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err = devm_acpi_dma_controller_register(dev, xlate_func, dw);
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/* Handle the error if it's not a case of !CONFIG_ACPI */
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and implement custom xlate function if needed (usually acpi_dma_simple_xlate()
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is enough) which converts the FixedDMA resource provided by struct
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acpi_dma_spec into the corresponding DMA channel. A piece of code for that case
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could look like::
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#ifdef CONFIG_ACPI
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struct filter_args {
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/* Provide necessary information for the filter_func */
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...
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};
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static bool filter_func(struct dma_chan *chan, void *param)
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{
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/* Choose the proper channel */
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...
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}
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static struct dma_chan *xlate_func(struct acpi_dma_spec *dma_spec,
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struct acpi_dma *adma)
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{
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dma_cap_mask_t cap;
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struct filter_args args;
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/* Prepare arguments for filter_func */
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...
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return dma_request_channel(cap, filter_func, &args);
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}
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#else
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static struct dma_chan *xlate_func(struct acpi_dma_spec *dma_spec,
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struct acpi_dma *adma)
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{
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return NULL;
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}
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#endif
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dma_request_chan() will call xlate_func() for each registered DMA controller.
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In the xlate function the proper channel must be chosen based on
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information in struct acpi_dma_spec and the properties of the controller
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provided by struct acpi_dma.
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Clients must call dma_request_chan() with the string parameter that corresponds
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to a specific FixedDMA resource. By default "tx" means the first entry of the
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FixedDMA resource array, "rx" means the second entry. The table below shows a
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layout::
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Device (I2C0)
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{
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...
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Method (_CRS, 0, NotSerialized)
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{
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Name (DBUF, ResourceTemplate ()
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{
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FixedDMA (0x0018, 0x0004, Width32bit, _Y48)
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FixedDMA (0x0019, 0x0005, Width32bit, )
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})
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...
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}
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}
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So, the FixedDMA with request line 0x0018 is "tx" and next one is "rx" in
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this example.
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In robust cases the client unfortunately needs to call
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acpi_dma_request_slave_chan_by_index() directly and therefore choose the
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specific FixedDMA resource by its index.
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Named Interrupts
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================
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Drivers enumerated via ACPI can have names to interrupts in the ACPI table
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which can be used to get the IRQ number in the driver.
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The interrupt name can be listed in _DSD as 'interrupt-names'. The names
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should be listed as an array of strings which will map to the Interrupt()
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resource in the ACPI table corresponding to its index.
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The table below shows an example of its usage::
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Device (DEV0) {
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...
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Name (_CRS, ResourceTemplate() {
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...
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Interrupt (ResourceConsumer, Level, ActiveHigh, Exclusive) {
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0x20,
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0x24
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}
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})
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Name (_DSD, Package () {
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ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"),
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Package () {
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Package () {"interrupt-names",
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Package (2) {"default", "alert"}},
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}
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...
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})
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}
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The interrupt name 'default' will correspond to 0x20 in Interrupt()
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resource and 'alert' to 0x24. Note that only the Interrupt() resource
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is mapped and not GpioInt() or similar.
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The driver can call the function - fwnode_irq_get_byname() with the fwnode
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and interrupt name as arguments to get the corresponding IRQ number.
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SPI serial bus support
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======================
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Slave devices behind SPI bus have SpiSerialBus resource attached to them.
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This is extracted automatically by the SPI core and the slave devices are
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enumerated once spi_register_master() is called by the bus driver.
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Here is what the ACPI namespace for a SPI slave might look like::
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Device (EEP0)
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{
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Name (_ADR, 1)
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Name (_CID, Package () {
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"ATML0025",
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"AT25",
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})
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...
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Method (_CRS, 0, NotSerialized)
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{
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SPISerialBus(1, PolarityLow, FourWireMode, 8,
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ControllerInitiated, 1000000, ClockPolarityLow,
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ClockPhaseFirst, "\\_SB.PCI0.SPI1",)
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}
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...
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The SPI device drivers only need to add ACPI IDs in a similar way than with
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the platform device drivers. Below is an example where we add ACPI support
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to at25 SPI eeprom driver (this is meant for the above ACPI snippet)::
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static const struct acpi_device_id at25_acpi_match[] = {
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{ "AT25", 0 },
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{ }
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};
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MODULE_DEVICE_TABLE(acpi, at25_acpi_match);
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static struct spi_driver at25_driver = {
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.driver = {
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...
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.acpi_match_table = at25_acpi_match,
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},
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};
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Note that this driver actually needs more information like page size of the
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eeprom, etc. This information can be passed via _DSD method like::
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Device (EEP0)
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{
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...
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Name (_DSD, Package ()
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{
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ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"),
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Package ()
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{
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Package () { "size", 1024 },
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Package () { "pagesize", 32 },
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Package () { "address-width", 16 },
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}
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})
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}
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Then the at25 SPI driver can get this configuration by calling device property
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APIs during ->probe() phase like::
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err = device_property_read_u32(dev, "size", &size);
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if (err)
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...error handling...
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err = device_property_read_u32(dev, "pagesize", &page_size);
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if (err)
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...error handling...
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err = device_property_read_u32(dev, "address-width", &addr_width);
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if (err)
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...error handling...
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I2C serial bus support
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======================
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The slaves behind I2C bus controller only need to add the ACPI IDs like
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with the platform and SPI drivers. The I2C core automatically enumerates
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any slave devices behind the controller device once the adapter is
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registered.
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Below is an example of how to add ACPI support to the existing mpu3050
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input driver::
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static const struct acpi_device_id mpu3050_acpi_match[] = {
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{ "MPU3050", 0 },
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{ }
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};
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MODULE_DEVICE_TABLE(acpi, mpu3050_acpi_match);
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static struct i2c_driver mpu3050_i2c_driver = {
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.driver = {
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.name = "mpu3050",
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.pm = &mpu3050_pm,
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.of_match_table = mpu3050_of_match,
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.acpi_match_table = mpu3050_acpi_match,
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},
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.probe = mpu3050_probe,
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.remove = mpu3050_remove,
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.id_table = mpu3050_ids,
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};
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module_i2c_driver(mpu3050_i2c_driver);
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Reference to PWM device
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=======================
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Sometimes a device can be a consumer of PWM channel. Obviously OS would like
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to know which one. To provide this mapping the special property has been
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introduced, i.e.::
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Device (DEV)
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{
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Name (_DSD, Package ()
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{
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ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"),
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Package () {
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Package () { "compatible", Package () { "pwm-leds" } },
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Package () { "label", "alarm-led" },
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Package () { "pwms",
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Package () {
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"\\_SB.PCI0.PWM", // <PWM device reference>
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0, // <PWM index>
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600000000, // <PWM period>
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0, // <PWM flags>
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}
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}
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}
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})
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...
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}
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In the above example the PWM-based LED driver references to the PWM channel 0
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of \_SB.PCI0.PWM device with initial period setting equal to 600 ms (note that
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value is given in nanoseconds).
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GPIO support
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============
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ACPI 5 introduced two new resources to describe GPIO connections: GpioIo
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and GpioInt. These resources can be used to pass GPIO numbers used by
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the device to the driver. ACPI 5.1 extended this with _DSD (Device
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Specific Data) which made it possible to name the GPIOs among other things.
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For example::
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Device (DEV)
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{
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Method (_CRS, 0, NotSerialized)
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{
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Name (SBUF, ResourceTemplate()
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{
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// Used to power on/off the device
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GpioIo (Exclusive, PullNone, 0, 0, IoRestrictionOutputOnly,
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"\\_SB.PCI0.GPI0", 0, ResourceConsumer) { 85 }
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// Interrupt for the device
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GpioInt (Edge, ActiveHigh, ExclusiveAndWake, PullNone, 0,
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"\\_SB.PCI0.GPI0", 0, ResourceConsumer) { 88 }
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}
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Return (SBUF)
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}
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// ACPI 5.1 _DSD used for naming the GPIOs
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Name (_DSD, Package ()
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{
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ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"),
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Package ()
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{
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Package () { "power-gpios", Package () { ^DEV, 0, 0, 0 } },
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Package () { "irq-gpios", Package () { ^DEV, 1, 0, 0 } },
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}
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})
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...
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}
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These GPIO numbers are controller relative and path "\\_SB.PCI0.GPI0"
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specifies the path to the controller. In order to use these GPIOs in Linux
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we need to translate them to the corresponding Linux GPIO descriptors.
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There is a standard GPIO API for that and is documented in
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Documentation/admin-guide/gpio/.
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In the above example we can get the corresponding two GPIO descriptors with
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a code like this::
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#include <linux/gpio/consumer.h>
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...
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struct gpio_desc *irq_desc, *power_desc;
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irq_desc = gpiod_get(dev, "irq");
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if (IS_ERR(irq_desc))
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/* handle error */
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power_desc = gpiod_get(dev, "power");
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if (IS_ERR(power_desc))
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/* handle error */
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/* Now we can use the GPIO descriptors */
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There are also devm_* versions of these functions which release the
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descriptors once the device is released.
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See Documentation/firmware-guide/acpi/gpio-properties.rst for more information
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about the _DSD binding related to GPIOs.
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MFD devices
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===========
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The MFD devices register their children as platform devices. For the child
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devices there needs to be an ACPI handle that they can use to reference
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parts of the ACPI namespace that relate to them. In the Linux MFD subsystem
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we provide two ways:
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- The children share the parent ACPI handle.
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- The MFD cell can specify the ACPI id of the device.
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For the first case, the MFD drivers do not need to do anything. The
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resulting child platform device will have its ACPI_COMPANION() set to point
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to the parent device.
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If the ACPI namespace has a device that we can match using an ACPI id or ACPI
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adr, the cell should be set like::
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static struct mfd_cell_acpi_match my_subdevice_cell_acpi_match = {
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.pnpid = "XYZ0001",
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.adr = 0,
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};
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static struct mfd_cell my_subdevice_cell = {
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.name = "my_subdevice",
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/* set the resources relative to the parent */
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.acpi_match = &my_subdevice_cell_acpi_match,
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};
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The ACPI id "XYZ0001" is then used to lookup an ACPI device directly under
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the MFD device and if found, that ACPI companion device is bound to the
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resulting child platform device.
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Device Tree namespace link device ID
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====================================
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The Device Tree protocol uses device identification based on the "compatible"
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property whose value is a string or an array of strings recognized as device
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identifiers by drivers and the driver core. The set of all those strings may be
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regarded as a device identification namespace analogous to the ACPI/PNP device
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ID namespace. Consequently, in principle it should not be necessary to allocate
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a new (and arguably redundant) ACPI/PNP device ID for a devices with an existing
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identification string in the Device Tree (DT) namespace, especially if that ID
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is only needed to indicate that a given device is compatible with another one,
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presumably having a matching driver in the kernel already.
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In ACPI, the device identification object called _CID (Compatible ID) is used to
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list the IDs of devices the given one is compatible with, but those IDs must
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belong to one of the namespaces prescribed by the ACPI specification (see
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Section 6.1.2 of ACPI 6.0 for details) and the DT namespace is not one of them.
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Moreover, the specification mandates that either a _HID or an _ADR identification
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object be present for all ACPI objects representing devices (Section 6.1 of ACPI
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6.0). For non-enumerable bus types that object must be _HID and its value must
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be a device ID from one of the namespaces prescribed by the specification too.
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The special DT namespace link device ID, PRP0001, provides a means to use the
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existing DT-compatible device identification in ACPI and to satisfy the above
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requirements following from the ACPI specification at the same time. Namely,
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if PRP0001 is returned by _HID, the ACPI subsystem will look for the
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"compatible" property in the device object's _DSD and will use the value of that
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property to identify the corresponding device in analogy with the original DT
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device identification algorithm. If the "compatible" property is not present
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or its value is not valid, the device will not be enumerated by the ACPI
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subsystem. Otherwise, it will be enumerated automatically as a platform device
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(except when an I2C or SPI link from the device to its parent is present, in
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which case the ACPI core will leave the device enumeration to the parent's
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driver) and the identification strings from the "compatible" property value will
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be used to find a driver for the device along with the device IDs listed by _CID
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(if present).
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Analogously, if PRP0001 is present in the list of device IDs returned by _CID,
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the identification strings listed by the "compatible" property value (if present
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and valid) will be used to look for a driver matching the device, but in that
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case their relative priority with respect to the other device IDs listed by
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_HID and _CID depends on the position of PRP0001 in the _CID return package.
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Specifically, the device IDs returned by _HID and preceding PRP0001 in the _CID
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return package will be checked first. Also in that case the bus type the device
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will be enumerated to depends on the device ID returned by _HID.
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For example, the following ACPI sample might be used to enumerate an lm75-type
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I2C temperature sensor and match it to the driver using the Device Tree
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namespace link::
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Device (TMP0)
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{
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Name (_HID, "PRP0001")
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Name (_DSD, Package () {
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ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"),
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Package () {
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Package () { "compatible", "ti,tmp75" },
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}
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})
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Method (_CRS, 0, Serialized)
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{
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Name (SBUF, ResourceTemplate ()
|
|
{
|
|
I2cSerialBusV2 (0x48, ControllerInitiated,
|
|
400000, AddressingMode7Bit,
|
|
"\\_SB.PCI0.I2C1", 0x00,
|
|
ResourceConsumer, , Exclusive,)
|
|
})
|
|
Return (SBUF)
|
|
}
|
|
}
|
|
|
|
It is valid to define device objects with a _HID returning PRP0001 and without
|
|
the "compatible" property in the _DSD or a _CID as long as one of their
|
|
ancestors provides a _DSD with a valid "compatible" property. Such device
|
|
objects are then simply regarded as additional "blocks" providing hierarchical
|
|
configuration information to the driver of the composite ancestor device.
|
|
|
|
However, PRP0001 can only be returned from either _HID or _CID of a device
|
|
object if all of the properties returned by the _DSD associated with it (either
|
|
the _DSD of the device object itself or the _DSD of its ancestor in the
|
|
"composite device" case described above) can be used in the ACPI environment.
|
|
Otherwise, the _DSD itself is regarded as invalid and therefore the "compatible"
|
|
property returned by it is meaningless.
|
|
|
|
Refer to Documentation/firmware-guide/acpi/DSD-properties-rules.rst for more
|
|
information.
|
|
|
|
PCI hierarchy representation
|
|
============================
|
|
|
|
Sometimes could be useful to enumerate a PCI device, knowing its position on the
|
|
PCI bus.
|
|
|
|
For example, some systems use PCI devices soldered directly on the mother board,
|
|
in a fixed position (ethernet, Wi-Fi, serial ports, etc.). In this conditions it
|
|
is possible to refer to these PCI devices knowing their position on the PCI bus
|
|
topology.
|
|
|
|
To identify a PCI device, a complete hierarchical description is required, from
|
|
the chipset root port to the final device, through all the intermediate
|
|
bridges/switches of the board.
|
|
|
|
For example, let us assume to have a system with a PCIe serial port, an
|
|
Exar XR17V3521, soldered on the main board. This UART chip also includes
|
|
16 GPIOs and we want to add the property ``gpio-line-names`` [1] to these pins.
|
|
In this case, the ``lspci`` output for this component is::
|
|
|
|
07:00.0 Serial controller: Exar Corp. XR17V3521 Dual PCIe UART (rev 03)
|
|
|
|
The complete ``lspci`` output (manually reduced in length) is::
|
|
|
|
00:00.0 Host bridge: Intel Corp... Host Bridge (rev 0d)
|
|
...
|
|
00:13.0 PCI bridge: Intel Corp... PCI Express Port A #1 (rev fd)
|
|
00:13.1 PCI bridge: Intel Corp... PCI Express Port A #2 (rev fd)
|
|
00:13.2 PCI bridge: Intel Corp... PCI Express Port A #3 (rev fd)
|
|
00:14.0 PCI bridge: Intel Corp... PCI Express Port B #1 (rev fd)
|
|
00:14.1 PCI bridge: Intel Corp... PCI Express Port B #2 (rev fd)
|
|
...
|
|
05:00.0 PCI bridge: Pericom Semiconductor Device 2404 (rev 05)
|
|
06:01.0 PCI bridge: Pericom Semiconductor Device 2404 (rev 05)
|
|
06:02.0 PCI bridge: Pericom Semiconductor Device 2404 (rev 05)
|
|
06:03.0 PCI bridge: Pericom Semiconductor Device 2404 (rev 05)
|
|
07:00.0 Serial controller: Exar Corp. XR17V3521 Dual PCIe UART (rev 03) <-- Exar
|
|
...
|
|
|
|
The bus topology is::
|
|
|
|
-[0000:00]-+-00.0
|
|
...
|
|
+-13.0-[01]----00.0
|
|
+-13.1-[02]----00.0
|
|
+-13.2-[03]--
|
|
+-14.0-[04]----00.0
|
|
+-14.1-[05-09]----00.0-[06-09]--+-01.0-[07]----00.0 <-- Exar
|
|
| +-02.0-[08]----00.0
|
|
| \-03.0-[09]--
|
|
...
|
|
\-1f.1
|
|
|
|
To describe this Exar device on the PCI bus, we must start from the ACPI name
|
|
of the chipset bridge (also called "root port") with address::
|
|
|
|
Bus: 0 - Device: 14 - Function: 1
|
|
|
|
To find this information is necessary disassemble the BIOS ACPI tables, in
|
|
particular the DSDT (see also [2])::
|
|
|
|
mkdir ~/tables/
|
|
cd ~/tables/
|
|
acpidump > acpidump
|
|
acpixtract -a acpidump
|
|
iasl -e ssdt?.* -d dsdt.dat
|
|
|
|
Now, in the dsdt.dsl, we have to search the device whose address is related to
|
|
0x14 (device) and 0x01 (function). In this case we can find the following
|
|
device::
|
|
|
|
Scope (_SB.PCI0)
|
|
{
|
|
... other definitions follow ...
|
|
Device (RP02)
|
|
{
|
|
Method (_ADR, 0, NotSerialized) // _ADR: Address
|
|
{
|
|
If ((RPA2 != Zero))
|
|
{
|
|
Return (RPA2) /* \RPA2 */
|
|
}
|
|
Else
|
|
{
|
|
Return (0x00140001)
|
|
}
|
|
}
|
|
... other definitions follow ...
|
|
|
|
and the _ADR method [3] returns exactly the device/function couple that
|
|
we are looking for. With this information and analyzing the above ``lspci``
|
|
output (both the devices list and the devices tree), we can write the following
|
|
ACPI description for the Exar PCIe UART, also adding the list of its GPIO line
|
|
names::
|
|
|
|
Scope (_SB.PCI0.RP02)
|
|
{
|
|
Device (BRG1) //Bridge
|
|
{
|
|
Name (_ADR, 0x0000)
|
|
|
|
Device (BRG2) //Bridge
|
|
{
|
|
Name (_ADR, 0x00010000)
|
|
|
|
Device (EXAR)
|
|
{
|
|
Name (_ADR, 0x0000)
|
|
|
|
Name (_DSD, Package ()
|
|
{
|
|
ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"),
|
|
Package ()
|
|
{
|
|
Package ()
|
|
{
|
|
"gpio-line-names",
|
|
Package ()
|
|
{
|
|
"mode_232",
|
|
"mode_422",
|
|
"mode_485",
|
|
"misc_1",
|
|
"misc_2",
|
|
"misc_3",
|
|
"",
|
|
"",
|
|
"aux_1",
|
|
"aux_2",
|
|
"aux_3",
|
|
}
|
|
}
|
|
}
|
|
})
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
The location "_SB.PCI0.RP02" is obtained by the above investigation in the
|
|
dsdt.dsl table, whereas the device names "BRG1", "BRG2" and "EXAR" are
|
|
created analyzing the position of the Exar UART in the PCI bus topology.
|
|
|
|
References
|
|
==========
|
|
|
|
[1] Documentation/firmware-guide/acpi/gpio-properties.rst
|
|
|
|
[2] Documentation/admin-guide/acpi/initrd_table_override.rst
|
|
|
|
[3] ACPI Specifications, Version 6.3 - Paragraph 6.1.1 _ADR Address)
|
|
https://uefi.org/sites/default/files/resources/ACPI_6_3_May16.pdf,
|
|
referenced 2020-11-18
|