Il 09/11/23 11:05, Chen-Yu Tsai ha scritto:
Hi everyone, This v2 series continues Doug's "of: device: Support 2nd sources of probeable but undiscoverable devices" [1] series, but follows the scheme suggested by Rob, marking all second source component device nodes as "fail-needs-probe-XXX", and having a hardware prober driver enable the one of them. I tried to include everyone from the original Cc: list. Please let me know if you would like to be dropped from future submissions. For the I2C component (touchscreens and trackpads) case from the original series, the hardware prober driver finds the particular class of device in the device tree, gets its parent I2C adapter, and tries to initiate a simple I2C read for each device under that I2C bus. When it finds one that responds, it considers that one present, marks it as "okay", and returns, letting the driver core actually probe the device. This works fine in most cases since these components are connected via ribbon cable and always have the same resources. The driver as implemented currently doesn't deal with regulators or GPIO pins, since in the existing device trees they are either always on for regulators, or have GPIO hogs or pinmux and pinconfig directly tied to the pin controller. Another case this driver could handle is selecting components based on some identifier passed in by the firmware. On Chromebooks we have a SKU ID which is inserted by the bootloader at /firmware/coreboot/sku-id. When a new combination of components is introduced, a new SKU ID is allocated to it. To have SKU ID based device trees, we would need to have one per SKU ID. This ends up increasing the number of device trees we have a lot. The recent MT8186 devices already have 10+10 SKUs [2], with possibly more to come. Instead, we could have just one device tree for each device, with component options listed and marked as "fail-needs-probe-XXX", and let the hardware prober enable one of them based on the given SKU ID. The driver will also fix up OF graph remote endpoints to point to the enabled component. The MT8186 Corsola series [2] can also benefit from this, though I haven't implemented anything yet. Patch 1 adds of_device_is_fail() for the new driver to use. Patch 2 implements the first case, probing the I2C bus for presence of components. This initial version targets the Hana Chromebooks. Patch 3 modifies the Hana device tree and marks the touchscreens and trackpads as "fail-needs-probe-XXX", ready for the driver to probe. Patch 4 adds a missing touchscreen variant to Hana. Patch 5 implements the second case, selectively enabling components based on the SKU ID. This initial version targets the Krane ChromeOS tablet, which has two possible MIPI DSI display panel options. Patch 6 drops Krane's SKU-specific compatible strings from the bindings. Patch 7 merges Krane's SKU-specific device trees into one, with the device tree now containing two possible panels. This unfortunately introduces a dtc warning: arch/arm64/boot/dts/mediatek/mt8183-kukui-krane.dts:81.13-83.6: Warning (graph_endpoint): /soc/dsi@14014000/panel2@0/port/endpoint: graph connection to node '/soc/dsi@14014000/ports/port/endpoint' is not bidirectional Please take a look. Johan, I'm not sure if this works as is for the Lenovo Thinkpad 13S case, since it looks like the trackpad shares the I2C bus with the keyboard. Thanks ChenYu Background as given in Doug's cover letter: Support for multiple "equivalent" sources for components (also known as second sourcing components) is a standard practice that helps keep cost down and also makes sure that if one component is unavailable due to a shortage that we don't need to stop production for the whole product. Some components are very easy to second source. eMMC, for instance, is fully discoverable and probable so you can stuff a wide variety of similar eMMC chips on your board and things will work without a hitch. Some components are more difficult to second source, specifically because it's difficult for software to probe what component is present on any given board. In cases like this software is provided supplementary information to help it, like a GPIO strap or a SKU ID programmed into an EEPROM. This helpful information can allow the bootloader to select a different device tree. The various different "SKUs" of different Chromebooks are examples of this. Some components are somewhere in between. These in-between components are the subject of this patch. Specifically, these components are easily "probeable" but not easily "discoverable". A good example of a probeable but undiscoverable device is an i2c-connected touchscreen or trackpad. Two separate components may be electrically compatible with each other and may have compatible power sequencing requirements but may require different software. If software is told about the different possible components (because it can't discover them), it can safely probe them to figure out which ones are present. On systems using device tree, if we want to tell the OS about all of the different components we need to list them all in the device tree. This leads to a problem. The multiple sources for components likely use the same resources (GPIOs, interrupts, regulators). If the OS tries to probe all of these components at the same time then it will detect a resource conflict and that's a fatal error. The fact that Linux can't handle these probeable but undiscoverable devices well has had a few consequences: 1. In some cases, we've abandoned the idea of second sourcing components for a given board, which increases cost / generates manufacturing headaches. 2. In some cases, we've been forced to add some sort of strapping / EEPROM to indicate which component is present. This adds difficulty to manufacturing / refurb processes. 3. In some cases, we've managed to make things work by the skin of our teeth through slightly hacky solutions. Specifically, if we remove the "pinctrl" entry from the various options then it won't conflict. Regulators inherently can have more than one consumer, so as long as there are no GPIOs involved in power sequencing and probing devices then things can work. This is how "sc8280xp-lenovo-thinkpad-x13s" works and also how "mt8173-elm-hana" works. End of background from Doug's cover letter.
I think that using "status" is not a good idea, I find that confusing. Perhaps we could have a node like something { device-class-one = <&device1>, <&device2>, <&device3>; device-class-two = <&device4>, <&device5>, <&device6>; } so that'd be more or less hw-prober { trackpads = <&tp1>, <&tp2>; keyboards = <&kb1>, <&kb2>; touchscreens = <&ts1>, <&ts2>; } Besides, something else I can suggest here is to make this more generic: actually, this issue is spread across way more devices than you maybe think... for example, I know of some smartphones that may have the same situation with DSI displays and they're sometimes distinguished by an ADC value, sometimes by reading back the manufacturer ID (or panel id) through DSI. Also, if Chromebooks really need something "special", such as that coreboot sku-id parameter, I think that this should be registered externally into the hw prober and not embedded inside of the *generic* hw prober driver. We can even reuse of_device_id instead of inventing a new hw_prober_entry struct... Idea: drivers/platform/chrome/cros_of_hw_prober.c static int cros_sku_hw_prober(struct platform_device *pdev, const void *data) { ...this is your cros_sku_component_selector() function, anyway... } static const struct of_device_id cros_hw_prober_ids[] = { { .compatible = "google,hana", .data = something }, { /* sentinel */ } }; static int some_kind_of_early_init_function(something) { int a,b,c,ret,something; .. some logic if necessary .. return of_hw_prober_register(cros_sku_hw_prober, cros_hw_prober_ids); } Btw, thanks for starting that. If this will be done the right way, it's going to be useful to many, many people. Regards, Angelo
[1] https://lore.kernel.org/all/20230921102420.RFC.1.I9dddd99ccdca175e3ceb1b9fa1827df0928c5101@changeid/ [2] https://lore.kernel.org/linux-mediatek/20231012230237.2676469-1-wenst@xxxxxxxxxxxx/ Chen-Yu Tsai (7): of: base: Add of_device_is_fail of: Introduce hardware prober driver arm64: dts: mediatek: mt8173-elm-hana: Mark touchscreens and trackpads as fail arm64: dts: mediatek: mt8173-elm-hana: Add G2touch G7500 touchscreen of: hw_prober: Support Chromebook SKU ID based component selection dt-bindings: arm: mediatek: Remove SKU specific compatibles for Google Krane arm64: dts: mediatek: mt8183-kukui: Merge Krane device trees .../devicetree/bindings/arm/mediatek.yaml | 3 - arch/arm64/boot/dts/mediatek/Makefile | 3 +- .../boot/dts/mediatek/mt8173-elm-hana.dtsi | 20 ++ .../dts/mediatek/mt8183-kukui-krane-sku0.dts | 24 -- .../mediatek/mt8183-kukui-krane-sku176.dts | 24 -- ...ukui-krane.dtsi => mt8183-kukui-krane.dts} | 47 ++- drivers/of/Kconfig | 13 + drivers/of/Makefile | 1 + drivers/of/base.c | 20 ++ drivers/of/hw_prober.c | 314 ++++++++++++++++++ include/linux/of.h | 6 + 11 files changed, 418 insertions(+), 57 deletions(-) delete mode 100644 arch/arm64/boot/dts/mediatek/mt8183-kukui-krane-sku0.dts delete mode 100644 arch/arm64/boot/dts/mediatek/mt8183-kukui-krane-sku176.dts rename arch/arm64/boot/dts/mediatek/{mt8183-kukui-krane.dtsi => mt8183-kukui-krane.dts} (86%) create mode 100644 drivers/of/hw_prober.c