/* * Google Gru (and derivatives) board device tree source * * Copyright 2016 Google, Inc * * This file is dual-licensed: you can use it either under the terms * of the GPL or the X11 license, at your option. Note that this dual * licensing only applies to this file, and not this project as a * whole. * * a) This file is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License as * published by the Free Software Foundation; either version 2 of the * License, or (at your option) any later version. * * This file is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * Or, alternatively, * * b) Permission is hereby granted, free of charge, to any person * obtaining a copy of this software and associated documentation * files (the "Software"), to deal in the Software without * restriction, including without limitation the rights to use, * copy, modify, merge, publish, distribute, sublicense, and/or * sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following * conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES * OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT * HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, * WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. */ #include #include #include "rk3399.dtsi" / { /* * Power Tree * * In general an attempt is made to include all rails called out by * the schematic as long as those rails interact in some way with * the AP. AKA: * - Rails that only connect to the EC (or devices that the EC talks to) * are not included. * - Rails _are_ included if the rails go to the AP even if the AP * doesn't currently care about them / they are always on. The idea * here is that it makes it easier to map to the schematic or extend * later. * * If two rails are substantially the same from the AP's point of * view, though, we won't create a full fixed regulator. We'll just * put the child rail as an alias of the parent rail. Sometimes rails * look the same to the AP because one of these is true: * - The EC controls the enable and the EC always enables a rail as * long as the AP is running. * - The rails are actually connected to each other by a jumper and * the distinction is just there to add clarity/flexibility to the * schematic. */ /* parentless regulators */ ppvar_sys: ppvar-sys { compatible = "regulator-fixed"; regulator-name = "ppvar_sys"; regulator-always-on; regulator-boot-on; }; /* ppvar_sys children, sorted by name */ pp900_ap: pp900-ap { compatible = "regulator-fixed"; regulator-name = "pp900_ap"; /* EC turns on w/ pp900_ap_en; always on for AP */ regulator-always-on; regulator-boot-on; regulator-min-microvolt = <900000>; regulator-max-microvolt = <900000>; vin-supply = <&ppvar_sys>; }; pp1200_lpddr: pp1200-lpddr { compatible = "regulator-fixed"; regulator-name = "pp1200_lpddr"; /* EC turns on w/ lpddr_pwr_en; always on for AP */ regulator-always-on; regulator-boot-on; regulator-min-microvolt = <1200000>; regulator-max-microvolt = <1200000>; vin-supply = <&ppvar_sys>; }; pp1800: pp1800 { compatible = "regulator-fixed"; regulator-name = "pp1800"; /* Always on when ppvar_sys shows power good */ regulator-always-on; regulator-boot-on; regulator-min-microvolt = <1800000>; regulator-max-microvolt = <1800000>; vin-supply = <&ppvar_sys>; }; pp3000: pp3000 { compatible = "regulator-fixed"; regulator-name = "pp3000"; pinctrl-names = "default"; pinctrl-0 = <&pp3000_en>; enable-active-high; gpio = <&gpio0 12 GPIO_ACTIVE_HIGH>; regulator-always-on; regulator-boot-on; regulator-min-microvolt = <3000000>; regulator-max-microvolt = <3000000>; vin-supply = <&ppvar_sys>; }; pp3300: pp3300 { compatible = "regulator-fixed"; regulator-name = "pp3300"; /* Always on; plain and simple */ regulator-always-on; regulator-boot-on; regulator-min-microvolt = <3300000>; regulator-max-microvolt = <3300000>; vin-supply = <&ppvar_sys>; }; pp5000: pp5000 { compatible = "regulator-fixed"; regulator-name = "pp5000"; /* EC turns on w/ pp5000_en; always on for AP */ regulator-always-on; regulator-boot-on; regulator-min-microvolt = <5000000>; regulator-max-microvolt = <5000000>; vin-supply = <&ppvar_sys>; }; ppvar_bigcpu: ppvar-bigcpu { compatible = "pwm-regulator"; regulator-name = "ppvar_bigcpu"; status = "okay"; pwms = <&pwm1 0 3333 0>; // TODO: where's the mapping of duty cycle to voltage??? // TODO: we probably need in-flight PWM regulator series? /* EC turns on w/ ap_core_en; always on for AP */ regulator-always-on; regulator-boot-on; regulator-min-microvolt = <800000>; regulator-max-microvolt = <1500000>; pwm-supply = <&ppvar_sys>; }; ppvar_litcpu: ppvar-litcpu { compatible = "pwm-regulator"; regulator-name = "ppvar_litcpu"; status = "okay"; pwms = <&pwm2 0 3333 0>; /* EC turns on w/ ap_core_en; always on for AP */ regulator-always-on; regulator-boot-on; regulator-min-microvolt = <800000>; regulator-max-microvolt = <1500000>; pwm-supply = <&ppvar_sys>; }; ppvar_gpu: ppvar-gpu { compatible = "pwm-regulator"; regulator-name = "ppvar_gpu"; status = "okay"; pwms = <&pwm0 0 3333 0>; /* EC turns on w/ ap_core_en; always on for AP */ regulator-always-on; regulator-boot-on; regulator-min-microvolt = <800000>; regulator-max-microvolt = <1500000>; pwm-supply = <&ppvar_sys>; }; ppvar_centerlogic: ppvar-centerlogic { compatible = "pwm-regulator"; regulator-name = "ppvar_centerlogic"; status = "okay"; pwms = <&pwm3 0 3333 0>; /* EC turns on w/ ppvar_centerlogic_en; always on for AP */ regulator-always-on; regulator-boot-on; regulator-min-microvolt = <800000>; regulator-max-microvolt = <1500000>; pwm-supply = <&ppvar_sys>; }; /* Schematics call this PPVAR even though it's fixed */ ppvar_logic: ppvar-logic { compatible = "regulator-fixed"; regulator-name = "ppvar_logic"; /* EC turns on w/ ppvar_logic_en; always on for AP */ regulator-always-on; regulator-boot-on; regulator-min-microvolt = <900000>; regulator-max-microvolt = <900000>; vin-supply = <&ppvar_sys>; }; /* pp900_ap aliases; these are always on for AP so just use alias */ /* EC turns on w/ pp900_ddrpll_en */ pp900_ddrpll: pp900_ap { }; /* EC turns on w/ pp900_pcie_en */ pp900_pcie: pp900_ap { }; /* EC turns on w/ pp900_pll_en */ pp900_pll: pp900_ap { }; /* EC turns on w/ pp900_pmu_en */ pp900_pmu: pp900_ap { }; /* EC turns on w/ pp900_usb_en */ pp900_usb: pp900_ap { }; /* pp1800 aliases; these are always on for AP so just use alias */ /* EC turns on w/ pp1800_s0_en_l */ pp1800_ap_io: pp1800_emmc: pp1800_nfc: pp1800_s0: pp1800 { }; /* EC turns on w/ pp1800_avdd_en_l */ pp1800_avdd: pp1800 { }; /* EC turns on w/ pp1800_lid_en_l */ pp1800_lid: pp1800_mic: pp1800 { }; /* EC turns on w/ lpddr_pwr_en */ pp1800_lpddr: pp1800 { }; /* EC turns on w/ pp1800_pmu_en_l */ pp1800_pmu: pp1800 { }; /* EC turns on w/ pp1800_sensor_en_l */ // TODO: Only for EC and things EC talks to I think; remove? pp1800_sensor: pp1800 { }; /* EC turns on w/ pp1800_usb_en_l */ pp1800_usb: pp1800 { }; /* pp1800 children */ /* EC turns on w/ pp1200_hsic_en */ // TODO: Might be removed in future schematics? pp1200_hsic: pp1200-hsic { compatible = "regulator-fixed"; regulator-name = "pp1200_hsic"; regulator-always-on; regulator-boot-on; regulator-min-microvolt = <1200000>; regulator-max-microvolt = <1200000>; vin-supply = <&pp1800>; }; pp1500_ap_io: pp1500-ap-io { compatible = "regulator-fixed"; regulator-name = "pp1500_ap_io"; pinctrl-names = "default"; pinctrl-0 = <&pp1500_en>; enable-active-high; gpio = <&gpio1 11 GPIO_ACTIVE_HIGH>; regulator-always-on; regulator-boot-on; regulator-min-microvolt = <1500000>; regulator-max-microvolt = <1500000>; vin-supply = <&pp1800>; // TODO: DNS for 3.3?? }; pp1800_audio: pp1800-audio { compatible = "regulator-fixed"; regulator-name = "pp1800_audio"; pinctrl-names = "default"; pinctrl-0 = <&pp1800_audio_en>; regulator-always-on; regulator-boot-on; enable-active-high; gpio = <&gpio0 2 GPIO_ACTIVE_HIGH>; vin-supply = <&pp1800>; }; pp1800_pcie: pp1800-pcie { compatible = "regulator-fixed"; regulator-name = "pp1800_pcie"; pinctrl-names = "default"; pinctrl-0 = <&wlan_module_pd_l>; regulator-always-on; // TODO: for bringup??? regulator-boot-on; // TODO: for bringup??? enable-active-high; gpio = <&gpio0 4 GPIO_ACTIVE_HIGH>; vin-supply = <&pp1800>; }; /* pp3000 aliases; these are always on for AP so just use alias */ /* Always on; plain and simple */ pp3000_ap: pp3000_emmc: pp3000 { }; /* pp3000 children */ pp3000_sd_slot: pp3000-sd-slot { compatible = "regulator-fixed"; regulator-name = "pp3000_sd_slot"; pinctrl-names = "default"; pinctrl-0 = <&sd_slot_pwr_en>; // regulator-always-on; // TODO: for bringup??? // regulator-boot-on; // TODO: for bringup??? enable-active-high; gpio = <&gpio4 29 GPIO_ACTIVE_HIGH>; vin-supply = <&pp3000>; }; ppvar_sd_card_io: ppvar-sd-card-io { compatible = "regulator-gpio"; regulator-name = "ppvar_sd_card_io"; pinctrl-names = "default"; pinctrl-0 = <&sd_io_pwr_en &sd_pwr_1800_sel>; // regulator-always-on; // TODO: for bringup??? // regulator-boot-on; // TODO: for bringup??? enable-active-high; enable-gpio = <&gpio2 2 GPIO_ACTIVE_HIGH>; gpios = <&gpio2 28 GPIO_ACTIVE_HIGH>; states = <1800000 0x1 3000000 0x0>; regulator-min-microvolt = <1800000>; regulator-max-microvolt = <3000000>; // TODO: add support in driver for input supplies. // ...and specify pp3000 and pp1800. }; /* pp3300 aliases; these are always on for AP so just use alias */ /* EC turns on w/ pp3300_trackpad_en_l */ pp3300_trackpad: pp3300-trackpad { }; /* EC turns on w/ pp3300_usb_en_l */ pp3300_usb: pp3300 { }; /* pp3300 children */ pp3300_disp: pp3300-disp { compatible = "regulator-fixed"; regulator-name = "pp3300_disp"; pinctrl-names = "default"; pinctrl-0 = <&pp3300_disp_en>; enable-active-high; // TODO: for bringup; we should reference (and enable) this // regulator with a panel (?) or backlight (?) driver regulator-always-on; regulator-boot-on; gpio = <&gpio4 27 GPIO_ACTIVE_HIGH>; vin-supply = <&pp3300>; }; pp3300_wifi_bt:pp3300-wifi-bt { compatible = "regulator-fixed"; regulator-name = "pp3300_wifi_bt"; /* NOTE: wlan_module_pd_l pinctrl in pp1800_pcie */ regulator-always-on; // TODO: for bringup??? regulator-boot-on; // TODO: for bringup??? enable-active-high; // TODO: I _think_ it's OK to specify the same GPIO in two // regulator-fixed regulators. See pp1800_pcie gpio = <&gpio0 8 GPIO_ACTIVE_HIGH>; vin-supply = <&pp3300>; }; /* END REGULATORS */ sound { compatible = "rockchip,rockchip-audio-da7219"; rockchip,model = "audio-da7219"; rockchip,i2s-controller = <&i2s0>; rockchip,audio-codec = <&codec>; }; backlight: backlight { compatible = "gpio-backlight"; pinctrl-names = "default"; pinctrl-0 = <&bl_en>; gpios = <&gpio1 17 GPIO_ACTIVE_HIGH>; }; edp_panel: edp-panel { compatible = "samsung,lsn122dl01-c01", "panel-simple"; backlight = <&backlight>; power-supply = <&pp3300_disp>; ports { panel_in_edp: endpoint { remote-endpoint = <&edp_out_panel>; }; }; }; }; &cpu_l0 { cpu-supply = <&ppvar_litcpu>; }; &cpu_l1 { cpu-supply = <&ppvar_litcpu>; }; &cpu_l2 { cpu-supply = <&ppvar_litcpu>; }; &cpu_l3 { cpu-supply = <&ppvar_litcpu>; }; &cpu_b0 { cpu-supply = <&ppvar_bigcpu>; }; &cpu_b1 { cpu-supply = <&ppvar_bigcpu>; }; &emmc_phy { status = "okay"; }; ap_i2c_mic: &i2c1 { status = "okay"; // TODO: bus speed // ...with no speed, it should just use 100kHz // TODO: rise / fall times? // TODO: This is in mainline, but not the Rockchip private kernel // TODO: Need to hook this into the rest of audio stuff... // TODO: any pinctrl needed for this codec??? headsetcodec: rt5514@57 { compatible = "realtek,rt5514"; reg = <0x57>; pinctrl-names = "default"; pinctrl-0 = <&mic_int>; /* * NOTE: Interrupts aren't part of the binding and driver * doesn't support it, but throw it in anyway. */ interrupt-parent = <&gpio1>; interrupts = <13 IRQ_TYPE_LEVEL_HIGH>; }; }; ap_i2c_ts: &i2c3 { status = "okay"; // TODO: bus speed // ...with no speed, it should just use 100kHz // TODO: rise / fall times? // TODO: Add the proper touchscreen reference... // TODO: Might need to go in sub boards???? }; ap_i2c_tp: &i2c5 { status = "okay"; /* * Note strange pullup enable. Apparently this avoids leakage but * still allows us to get nice 4.7K pullups for high speed i2c * transfers. Basically we want the pullup on whenever the ap is * alive, so the "en" pin just gets set to output high. */ pinctrl-0 = <&i2c5_xfer &ap_i2c_tp_pu_en>; clock-frequency = <400000>; /* These are relatively safe rise/fall times; TODO: measure */ i2c-scl-falling-time-ns = <50>; i2c-scl-rising-time-ns = <300>; }; ap_i2c_audio: &i2c8 { status = "okay"; // TODO: bus speed // ...with no speed, it should just use 100kHz // TODO: rise / fall times? // ...on gru-gru this is on a sub board, so expect bad rise/fall times // TODO: copied from sample. Double-check... codec: da7219@1a { compatible = "dlg,da7219"; reg = <0x1a>; pinctrl-names = "default"; pinctrl-0 = <&headset_int_l>; interrupt-parent = <&gpio1>; interrupts = <23 IRQ_TYPE_LEVEL_LOW>; VDD-supply = <&pp1800>; VDDMIC-supply = <&pp3300>; VDDIO-supply = <&pp1800>; // TODO: I THINK this is right, but it's a bit of a guess. clocks = <&cru SCLK_I2S_8CH_OUT>; clock-names = "mclk"; // Below is from bindings; we need to adjust for our SoC / board. dlg,ldo-lvl = <1200>; dlg,micbias-lvl = <2600>; dlg,mic-amp-in-sel = "diff"; da7219_aad { dlg,btn-cfg = <50>; dlg,mic-det-thr = <500>; dlg,jack-ins-deb = <20>; dlg,jack-det-rate = "32ms_64ms"; dlg,jack-rem-deb = <1>; dlg,a-d-btn-thr = <0xa>; dlg,d-b-btn-thr = <0x16>; dlg,b-c-btn-thr = <0x21>; dlg,c-mic-btn-thr = <0x3E>; dlg,btn-avg = <4>; dlg,adc-1bit-rpt = <1>; }; }; }; &i2s0 { status = "okay"; }; &io_domains { status = "okay"; bt656-supply = <&pp1800_ap_io>; /* APIO2_VDD; 2a 2b */ audio-supply = <&pp1800_audio>; /* APIO5_VDD; 3d 4a */ sdmmc-supply = <&ppvar_sd_card_io>; /* SDMMC0_VDD; 4b */ gpio1830-supply = <&pp3000_ap>; /* APIO4_VDD; 4c 4d */ }; &pwm0 { status = "okay"; }; &pwm1 { status = "okay"; }; &pwm2 { status = "okay"; }; &pwm3 { status = "okay"; }; &emmc_phy { status = "okay"; }; &sdhci { bus-width = <8>; mmc-hs400-1_8v; supports-emmc; non-removable; status = "okay"; }; &sdmmc { status = "okay"; /* * Note: configure "sdmmc_cd" as card detect even though it's actually * hooked to ground. Because we specified "cd-gpios" below dw_mmc * should be ignoring card detect anyway. Specifying the pin as * sdmmc_cd means that even if you've got GRF_SOC_CON7[12] (force_jtag) * turned on that the system will still make sure the port is * configured as SDMMC and not JTAG. */ pinctrl-names = "default"; pinctrl-0 = <&sdmmc_clk &sdmmc_cmd &sdmmc_cd &sdmmc_cd_gpio &sdmmc_bus4>; // HACK: supports-sd is not in mainline. supports-sd; // HACK: Limit freq for now // ...as of 160330 confirmed that things break if you remove this. clock-frequency = <37500000>; clock-freq-min-max = <400000 37500000>; bus-width = <4>; cd-gpios = <&gpio4 24 GPIO_ACTIVE_LOW>; disable-wp; cap-mmc-highspeed; cap-sd-highspeed; // TODO: enable once tested... //sd-uhs-sdr12; //sd-uhs-sdr25; //sd-uhs-sdr50; //sd-uhs-sdr104; // Comment out until we turn on gpio-regulator config vmmc-supply = <&pp3000_sd_slot>; vqmmc-supply = <&ppvar_sd_card_io>; }; &spi0 { status = "okay"; // TODO: more properly. Hacky spidev for now??? // A few notes: // - We either have a Haven here or a Infineon SLB9670. The SLB9670 // is supposed to be a fallback if Haven is broken. // - Either TPM is supposed to be TPM 2.0 hooked up to SPI. I see some // kernel support for TPM 2.0 on x86 (hooked up with ACPI) but no // generic way to say "we have a SPI TPM 2.0". We'll need to add // a driver for whichever way we go. // - wfrichar@ says that for Haven if it has gone to sleep we might // need to add a delay after asserting chip select. Presumably // haven-specific driver will need to handle this logic (keeping // track when we last talked and adding an extra delay if it's been // a while). tpm@0 { compatible = "spidev"; // TODO: can run faster once verified. // TODO: add rx-sample-delay-ns. spi-max-frequency = <10000000>; reg = <0>; }; }; &spi1 { status = "okay"; // TODO: Ideally we want to use MTD for this, but presumably // we'll wait until we can test it and also bring it up in our // kernel tree. spiflash@0 { compatible = "spidev"; // TODO: can run faster once verified. // TODO: add rx-sample-delay-ns. spi-max-frequency = <10000000>; reg = <0>; }; }; &spi2 { status = "okay"; // TODO: more properly. Hacky spidev for now??? wacky_spi_audio@0 { compatible = "spidev"; // TODO: can run faster once verified. // TODO: add rx-sample-delay-ns. spi-max-frequency = <10000000>; reg = <0>; }; }; &spi5 { status = "okay"; cros_ec: ec@0 { compatible = "google,cros-ec-spi"; reg = <0>; pinctrl-names = "default"; pinctrl-0 = <&ec_ap_int_l>; google,cros-ec-spi-pre-delay = <30>; // TODO: check interrupt-parent = <&gpio0>; interrupts = <1 IRQ_TYPE_LEVEL_LOW>; spi-max-frequency = <3000000>; // TODO: check; TODO: rx-sample-delay-ns? i2c_tunnel: i2c-tunnel { compatible = "google,cros-ec-i2c-tunnel"; google,remote-bus = <0>; #address-cells = <1>; #size-cells = <0>; }; }; }; // TODO: // - double-check that hw-tshut-mode is same as EVB // - double check that hw-tshut-polarity is the same as EVB &tsadc { status = "okay"; rockchip,hw-tshut-mode = <1>; /* tshut mode 0:CRU 1:GPIO */ rockchip,hw-tshut-polarity = <1>; /* tshut polarity 0:LOW 1:HIGH */ }; &uart2 { status = "okay"; }; &usb_host0_ehci { status = "okay"; }; &usb_host0_ohci { status = "okay"; }; &usb_host1_ehci { status = "okay"; }; &usb_host1_ohci { status = "okay"; }; &usbdrd3_0 { status = "okay"; }; &usbdrd_dwc3_0 { status = "okay"; dr_mode = "host"; // TODO: needed? }; &usbdrd3_1 { status = "okay"; }; &usbdrd_dwc3_1 { status = "okay"; dr_mode = "host"; // TODO: needed? }; &edp { status = "okay"; ports { edp_out: port@1 { reg = <1>; #address-cells = <1>; #size-cells = <0>; edp_out_panel: endpoint@0 { reg = <0>; remote-endpoint = <&panel_in_edp>; }; }; }; }; &vopb { status = "okay"; }; &vopb_mmu { status = "okay"; }; &vopl { status = "okay"; }; &vopl_mmu { status = "okay"; }; &display_subsystem { status = "okay"; }; &gpu { mali-supply = <&ppvar_gpu>; status = "okay"; }; /* HACKS: Poorly formatted on purpose so you know they're hacks */ /* HACK THE PWM REGULATOR OUT * * We'll hack them all to pretend they are fixed regulators * and at exactly .9V, which is where cpufreq wants them. * * We'll also set all PWMs to disabled so we know that the PWM * framework won't touch them. * * This relies on PWM clock being a critical clock. */ &ppvar_bigcpu { compatible = "regulator-fixed"; regulator-min-microvolt = <900000>; regulator-max-microvolt = <900000>; }; &ppvar_centerlogic { compatible = "regulator-fixed"; regulator-min-microvolt = <900000>; regulator-max-microvolt = <900000>; }; &ppvar_litcpu { compatible = "regulator-fixed"; regulator-min-microvolt = <900000>; regulator-max-microvolt = <900000>; }; &ppvar_gpu { compatible = "regulator-fixed"; regulator-min-microvolt = <900000>; regulator-max-microvolt = <900000>; }; &pwm0 { status = "disabled"; }; &pwm1 { status = "disabled"; }; &pwm2 { status = "disabled"; }; &pwm3 { status = "disabled"; }; &pvtm { status = "okay"; }; &pmu_pvtm { status = "okay"; }; &pmu_io_domains { status = "okay"; pmu1830-supply = <&pp1800_pmu>; /* PMUIO2_VDD */ }; /* PINCTRL: always below everything else */ &pinctrl { pcfg_output_high: pcfg-output-high { output-high; }; cros-ec { ec_ap_int_l: ec-ap-int-l { rockchip,pins = ; }; }; discrete-regulators { pp1500_en: pp1500-en { rockchip,pins = ; }; pp1800_audio_en: pp1800-audio-en { rockchip,pins = ; }; pp3300_disp_en: pp3300-disp-en { rockchip,pins = ; }; pp3000_en: pp3000-en { rockchip,pins = ; }; sd_io_pwr_en: sd-io-pwr-en { rockchip,pins = ; }; sd_pwr_1800_sel: sd-pwr-1800-sel { rockchip,pins = ; }; sd_slot_pwr_en: sd-slot-pwr-en { rockchip,pins = ; }; wlan_module_pd_l: wlan-module-pd-l { rockchip,pins = ; }; }; codec { /* Has external pullup */ headset_int_l: headset-int-l { rockchip,pins = <1 23 RK_FUNC_GPIO &pcfg_pull_none>; }; // TODO: check pull. From signal name assume active high. mic_int: mic-int { rockchip,pins = <1 13 RK_FUNC_GPIO &pcfg_pull_down>; }; }; sdmmc { /* * We have external pulls on SDMMC, so diable internals * * TODO: * - On veyron we found that we needed to drive at 8mA. Do we * need to that here? If so, 8mA or 12mA? */ sdmmc_bus4: sdmmc-bus4 { rockchip,pins = <4 8 RK_FUNC_1 &pcfg_pull_none>, <4 9 RK_FUNC_1 &pcfg_pull_none>, <4 10 RK_FUNC_1 &pcfg_pull_none>, <4 11 RK_FUNC_1 &pcfg_pull_none>; }; sdmmc_clk: sdmmc-clk { rockchip,pins = <4 12 RK_FUNC_1 &pcfg_pull_none>; }; sdmmc_cmd: sdmmc-cmd { rockchip,pins = <4 13 RK_FUNC_1 &pcfg_pull_none>; }; /* * In our case the official card detect is hooked to ground * to avoid getting access to JTAG just by sticking something * in the SD card slot (see the force_jtag bit in the TRM). * * We still configure it as card detect because it doesn't * hurt and dw_mmc will ignore it. We make sure to disable * the pull though so we don't burn needless power. */ sdmmc_cd: sdmcc-cd { rockchip,pins = <0 7 RK_FUNC_1 &pcfg_pull_none>; }; /* This is where we actually hook up CD; has external pull */ sdmmc_cd_gpio: sdmmc-cd-gpio { rockchip,pins = <4 24 RK_FUNC_GPIO &pcfg_pull_none>; }; }; trackpad { ap_i2c_tp_pu_en: ap-i2c-tp-pu-en { rockchip,pins = <3 12 RK_FUNC_GPIO &pcfg_output_high>; }; trackpad_int_l: trackpad-int-l { rockchip,pins = <1 4 RK_FUNC_GPIO &pcfg_pull_up>; }; }; backlight-enable { bl_en: bl-en { rockchip,pins = <1 17 RK_FUNC_GPIO &pcfg_pull_none>; }; }; }; /* DON'T PUT ANYTHING BELOW HERE. PUT IT ABOVE PINCTRL */ /* DON'T PUT ANYTHING BELOW HERE. PUT IT ABOVE PINCTRL */ /* DON'T PUT ANYTHING BELOW HERE. PUT IT ABOVE PINCTRL */