dts/arm/silabs/efr32bg2x.dtsi - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2021 Sateesh Kotapati
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #include <arm/armv8-m.dtsi>
 #include <arm/silabs/gpio_gecko.h>
 #include <dt-bindings/gpio/gpio.h>
 #include <dt-bindings/i2c/i2c.h>
 #include <dt-bindings/pinctrl/gecko-pinctrl.h>
 #include <dt-bindings/adc/adc.h>

 / {
 	chosen {
 		zephyr,flash-controller = &msc;
 		zephyr,entropy = &trng;
 	};

 	power-states {
 		/*
 		 * EM1 is a basic "CPU WFI idle", all high-freq clocks remain
 		 * enabled.
 		 */
 		pstate_em1: em1 {
 			compatible = "zephyr,power-state";
 			power-state-name = "runtime-idle";
 			min-residency-us = <4>;
 			/* HFXO remains active */
 			exit-latency-us = <2>;
 		};

 		/*
 		 * EM2 is a deepsleep with HF clocks disabled by HW, voltages
 		 * scaled down, etc.
 		 */
 		pstate_em2: em2 {
 			compatible = "zephyr,power-state";
 			power-state-name = "suspend-to-idle";
 			min-residency-us = <260>;
 			exit-latency-us = <250>;
 		};

 		/*
 		 * EM3 seems to be exactly the same as EM2 except that
 		 * LFXO & LFRCO should be disabled, so you must use ULFRCO
 		 * as BURTC clock for the system to not lose track of time and
 		 * wake up.
 		 */
 		pstate_em3: em3 {
 			compatible = "zephyr,power-state";
 			power-state-name = "standby";
 			min-residency-us = <20000>;
 			exit-latency-us = <2000>;
 		};

 		/*
 		 * EM4 does not preserve CPU or RAM state, so system runs
 		 * through a cold boot upon wake up. BURTC can wake up the
 		 * system from EM4 but that has to be manually configured
 		 * by the application in BURTC registers.
 		 */
 		pstate_em4: em4 {
 			compatible = "zephyr,power-state";
 			power-state-name = "soft-off";
 			min-residency-us = <100000>;
 			exit-latency-us = <80000>;
 		};
 	};

 	cpus {
 		#address-cells = <1>;
 		#size-cells = <0>;
 		cpu0: cpu@0 {
 			device_type = "cpu";
 			compatible = "arm,cortex-m33";
 			reg = <0>;
 			/*
 			 * EM1 is enabled by default because it is
 			 * unconditionally safe.
 			 *
 			 * EM2/3 can be enabled by the board code if proper
 			 * timing configuration is ensured:
 			 * - for EM2, EM3: BURTC used as sys_clock
 			 * - for EM3: BURTC clocked from ULFRCO
 			 * Using BURTC as sys_clock instead of SysTick
 			 * has implications on system performance. Read
 			 * KConfig documentation entry before enabling it.
 			 */
 			cpu-power-states = <&pstate_em1>;
 		};
 	};

 	sram0: memory@20000000 {
 		compatible = "mmio-sram";
 	};

 	soc {
 		msc: flash-controller@50030000 {
 			compatible = "silabs,gecko-flash-controller";
 			reg = <0x50030000 0xC69>;
 			interrupts = <49 0>;

 			#address-cells = <1>;
 			#size-cells = <1>;
 		};

 		usart0: usart@5005c000 {
 			compatible = "silabs,gecko-spi-usart";
 			reg = <0x5005C000 0x400>;
 			interrupt-names = "rx", "tx";
 			status = "disabled";

 			#address-cells = <1>;
 			#size-cells = <0>;

 			status = "disabled";
 		};

 		usart1: usart@50060000 {
 			compatible = "silabs,gecko-usart";
 			reg = <0x50060000 0x400>;
 			interrupt-names = "rx", "tx";
 			status = "disabled";
 		};

 		burtc0: burtc@50064000 {
 			compatible = "silabs,gecko-burtc";
 			reg = <0x50064000 0x3034>;
 			status = "disabled";
 		};

 		stimer0: stimer@58000000 {
 			compatible = "silabs,gecko-stimer";
 			reg = <0x58000000 0x3054>;
 			clock-frequency = <32768>;
 			prescaler = <1>;
 			status = "disabled";
 		};

 		trng: trng@4c021000 {
 			compatible = "silabs,gecko-trng";
 			reg = <0x4C021000 0x1000>;
 			status = "disabled";
 			interrupts = <0x1 0x0>;
 		};

 		i2c0: i2c@5a010000 {
 			compatible = "silabs,gecko-i2c";
 			clock-frequency = <I2C_BITRATE_STANDARD>;
 			reg = <0x5a010000 0x3044>;
 			#address-cells = <1>;
 			#size-cells = <0>;
 			status = "disabled";
 		};

 		i2c1: i2c@50068000 {
 			compatible = "silabs,gecko-i2c";
 			clock-frequency = <I2C_BITRATE_STANDARD>;
 			reg = <0x50068000 0x3044>;
 			#address-cells = <1>;
 			#size-cells = <0>;
 			status = "disabled";
 		};

 		gpio: gpio@5003c000 {
 			compatible = "silabs,gecko-gpio";
 			reg = <0x5003C000 0x3660>;
 			interrupt-names = "GPIO_EVEN", "GPIO_ODD";

 			ranges;
 			#address-cells = <1>;
 			#size-cells = <1>;

 			gpioa: gpio@5003c000 {
 				compatible = "silabs,gecko-gpio-port";
 				reg = <0x5003C000 0x30>;
 				gpio-controller;
 				#gpio-cells = <2>;
 				status = "disabled";
 			};

 			gpiob: gpio@5003c030 {
 				compatible = "silabs,gecko-gpio-port";
 				reg = <0x5003C030 0x30>;
 				gpio-controller;
 				#gpio-cells = <2>;
 				status = "disabled";
 			};

 			gpioc: gpio@5003c060 {
 				compatible = "silabs,gecko-gpio-port";
 				reg = <0x5003C060 0x30>;
 				gpio-controller;
 				#gpio-cells = <2>;
 				status = "disabled";
 			};

 			gpiod: gpio@5003c090 {
 				compatible = "silabs,gecko-gpio-port";
 				reg = <0x5003C090 0x30>;
 				gpio-controller;
 				#gpio-cells = <2>;
 				status = "disabled";
 			};

 			gpiof: gpio@5003c0c0 {
 				compatible = "silabs,gecko-gpio-port";
 				reg = <0x5003C0C0 0x30>;
 				gpio-controller;
 				#gpio-cells = <2>;
 				status = "disabled";
 			};

 		};

 		wdog0: wdog@4a018000 {
 			compatible = "silabs,gecko-wdog";
 			reg = <0x4A018000 0x3028>;
 			peripheral-id = <0>;
 			interrupts = <43 0>;
 			status = "disabled";
 		};

 		adc0: adc@5a004000 {
 			compatible = "silabs,gecko-iadc";
 			reg = <0x5a004000 0x4000>;
 			interrupts = <48 0>;
 			status = "disabled";
 			#io-channel-cells = <1>;
 		};
 	};
 };

 / {
 	pinctrl: pin-controller {
 		/* Pin controller is a "virtual" device since SiLabs SoCs do pin
 		 * control in a distributed way (GPIO registers and PSEL
 		 * registers on each peripheral).
 		 */
 		compatible = "silabs,gecko-pinctrl";
 	};
 };

 &nvic {
 	arm,num-irq-priority-bits = <4>;
 };
	/*
	* Copyright (c) 2021 Sateesh Kotapati
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#include <arm/armv8-m.dtsi>
	#include <arm/silabs/gpio_gecko.h>
	#include <dt-bindings/gpio/gpio.h>
	#include <dt-bindings/i2c/i2c.h>
	#include <dt-bindings/pinctrl/gecko-pinctrl.h>
	#include <dt-bindings/adc/adc.h>

	/ {
	chosen {
	zephyr,flash-controller = &msc;
	zephyr,entropy = &trng;
	};

	power-states {
	/*
	* EM1 is a basic "CPU WFI idle", all high-freq clocks remain
	* enabled.
	*/
	pstate_em1: em1 {
	compatible = "zephyr,power-state";
	power-state-name = "runtime-idle";
	min-residency-us = <4>;
	/* HFXO remains active */
	exit-latency-us = <2>;
	};

	/*
	* EM2 is a deepsleep with HF clocks disabled by HW, voltages
	* scaled down, etc.
	*/
	pstate_em2: em2 {
	compatible = "zephyr,power-state";
	power-state-name = "suspend-to-idle";
	min-residency-us = <260>;
	exit-latency-us = <250>;
	};

	/*
	* EM3 seems to be exactly the same as EM2 except that
	* LFXO & LFRCO should be disabled, so you must use ULFRCO
	* as BURTC clock for the system to not lose track of time and
	* wake up.
	*/
	pstate_em3: em3 {
	compatible = "zephyr,power-state";
	power-state-name = "standby";
	min-residency-us = <20000>;
	exit-latency-us = <2000>;
	};

	/*
	* EM4 does not preserve CPU or RAM state, so system runs
	* through a cold boot upon wake up. BURTC can wake up the
	* system from EM4 but that has to be manually configured
	* by the application in BURTC registers.
	*/
	pstate_em4: em4 {
	compatible = "zephyr,power-state";
	power-state-name = "soft-off";
	min-residency-us = <100000>;
	exit-latency-us = <80000>;
	};
	};

	cpus {
	#address-cells = <1>;
	#size-cells = <0>;
	cpu0: cpu@0 {
	device_type = "cpu";
	compatible = "arm,cortex-m33";
	reg = <0>;
	/*
	* EM1 is enabled by default because it is
	* unconditionally safe.
	*
	* EM2/3 can be enabled by the board code if proper
	* timing configuration is ensured:
	* - for EM2, EM3: BURTC used as sys_clock
	* - for EM3: BURTC clocked from ULFRCO
	* Using BURTC as sys_clock instead of SysTick
	* has implications on system performance. Read
	* KConfig documentation entry before enabling it.
	*/
	cpu-power-states = <&pstate_em1>;
	};
	};

	sram0: memory@20000000 {
	compatible = "mmio-sram";
	};

	soc {
	msc: flash-controller@50030000 {
	compatible = "silabs,gecko-flash-controller";
	reg = <0x50030000 0xC69>;
	interrupts = <49 0>;

	#address-cells = <1>;
	#size-cells = <1>;
	};

	usart0: usart@5005c000 {
	compatible = "silabs,gecko-spi-usart";
	reg = <0x5005C000 0x400>;
	interrupt-names = "rx", "tx";
	status = "disabled";

	#address-cells = <1>;
	#size-cells = <0>;

	status = "disabled";
	};

	usart1: usart@50060000 {
	compatible = "silabs,gecko-usart";
	reg = <0x50060000 0x400>;
	interrupt-names = "rx", "tx";
	status = "disabled";
	};

	burtc0: burtc@50064000 {
	compatible = "silabs,gecko-burtc";
	reg = <0x50064000 0x3034>;
	status = "disabled";
	};

	stimer0: stimer@58000000 {
	compatible = "silabs,gecko-stimer";
	reg = <0x58000000 0x3054>;
	clock-frequency = <32768>;
	prescaler = <1>;
	status = "disabled";
	};

	trng: trng@4c021000 {
	compatible = "silabs,gecko-trng";
	reg = <0x4C021000 0x1000>;
	status = "disabled";
	interrupts = <0x1 0x0>;
	};

	i2c0: i2c@5a010000 {
	compatible = "silabs,gecko-i2c";
	clock-frequency = <I2C_BITRATE_STANDARD>;
	reg = <0x5a010000 0x3044>;
	#address-cells = <1>;
	#size-cells = <0>;
	status = "disabled";
	};

	i2c1: i2c@50068000 {
	compatible = "silabs,gecko-i2c";
	clock-frequency = <I2C_BITRATE_STANDARD>;
	reg = <0x50068000 0x3044>;
	#address-cells = <1>;
	#size-cells = <0>;
	status = "disabled";
	};

	gpio: gpio@5003c000 {
	compatible = "silabs,gecko-gpio";
	reg = <0x5003C000 0x3660>;
	interrupt-names = "GPIO_EVEN", "GPIO_ODD";

	ranges;
	#address-cells = <1>;
	#size-cells = <1>;

	gpioa: gpio@5003c000 {
	compatible = "silabs,gecko-gpio-port";
	reg = <0x5003C000 0x30>;
	gpio-controller;
	#gpio-cells = <2>;
	status = "disabled";
	};

	gpiob: gpio@5003c030 {
	compatible = "silabs,gecko-gpio-port";
	reg = <0x5003C030 0x30>;
	gpio-controller;
	#gpio-cells = <2>;
	status = "disabled";
	};

	gpioc: gpio@5003c060 {
	compatible = "silabs,gecko-gpio-port";
	reg = <0x5003C060 0x30>;
	gpio-controller;
	#gpio-cells = <2>;
	status = "disabled";
	};

	gpiod: gpio@5003c090 {
	compatible = "silabs,gecko-gpio-port";
	reg = <0x5003C090 0x30>;
	gpio-controller;
	#gpio-cells = <2>;
	status = "disabled";
	};

	gpiof: gpio@5003c0c0 {
	compatible = "silabs,gecko-gpio-port";
	reg = <0x5003C0C0 0x30>;
	gpio-controller;
	#gpio-cells = <2>;
	status = "disabled";
	};

	};

	wdog0: wdog@4a018000 {
	compatible = "silabs,gecko-wdog";
	reg = <0x4A018000 0x3028>;
	peripheral-id = <0>;
	interrupts = <43 0>;
	status = "disabled";
	};

	adc0: adc@5a004000 {
	compatible = "silabs,gecko-iadc";
	reg = <0x5a004000 0x4000>;
	interrupts = <48 0>;
	status = "disabled";
	#io-channel-cells = <1>;
	};
	};
	};

	/ {
	pinctrl: pin-controller {
	/* Pin controller is a "virtual" device since SiLabs SoCs do pin
	* control in a distributed way (GPIO registers and PSEL
	* registers on each peripheral).
	*/
	compatible = "silabs,gecko-pinctrl";
	};
	};

	&nvic {
	arm,num-irq-priority-bits = <4>;
	};