“Clock device tree configuration - Bootloader specif”的版本间的差异

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* [[U-Boot_overview#SPL:_FSBL_for_basic_boot|U-Boot SPL]]对于基本启动链
 
* [[U-Boot_overview#SPL:_FSBL_for_basic_boot|U-Boot SPL]]对于基本启动链
  
{{Warning|本文介绍了如何在启动时在 [[RCC_internal_peripheral|RCC]] 中配置时钟树。<br/>然后,您可以参考[[[Clock device tree configuration|clock device tree configuration]] 文章来了解如何在Linux中导出每个内部外围设备时钟树<sup>&reg;</sup> OS from the [[RCC_internal_peripheral|RCC]] 时钟树。}}
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{{Warning|本文介绍了如何在启动时在 [[RCC_internal_peripheral|RCC]] 中配置时钟树。<br/>然后,您可以参考[[Clock device tree configuration|clock device tree configuration]] 文章来了解如何在Linux中导出每个内部外围设备时钟树<sup>&reg;</sup> OS from the [[RCC_internal_peripheral|RCC]] 时钟树。}}
  
 
配置使用 [[Device tree|device tree]] 机制执行,该机制提供了 [[RCC_internal_peripheral|RCC]] 外围设备的硬件描述。
 
配置使用 [[Device tree|device tree]] 机制执行,该机制提供了 [[RCC_internal_peripheral|RCC]] 外围设备的硬件描述。

2020年11月3日 (二) 17:52的版本

Article purpose

本文介绍了由 first stage bootloader 执行的特定RCC internal peripheral 配置:

Warning.png 本文介绍了如何在启动时在 RCC 中配置时钟树。
然后,您可以参考clock device tree configuration 文章来了解如何在Linux中导出每个内部外围设备时钟树® OS from the RCC 时钟树。

配置使用 device tree 机制执行,该机制提供了 RCC 外围设备的硬件描述。

此时钟树仅在引导链FSBL的设备树中使用; 所以在TF-A设备树中为OpenSTLinux正式交付(或在SPL中仅用于DDR调优工具)。

即使 U-Boot 设备树中也存在时钟树信息,该SSBL在引导过程中都不会使用它。

DT bindings documentation

The bootloader clock device tree bindings correspond to the vendor clock DT bindings used by the clk-stm32mp1 driver of the FSBL (TF-A or U-Boot SPL), it is based on:

This binding document explains how to write the device tree files for clocks on the bootloader side:

  • TF-A: tf-a/docs/devicetree/bindings/clock/st,stm32mp1-rcc.txt"[1]
  • U-Boot SPL: doc/device-tree-bindings/clock/st,stm32mp1.txt[2]

DT configuration

This hardware description is a combination of the STM32 microprocessor device tree files (.dtsi extension) and board device tree files (.dts extension). See the Device tree for an explanation of the device tree file split.

STM32CubeMX can be used to generate the board device tree. Refer to How to configure the DT using STM32CubeMX for more details.

DT configuration (STM32 level)

The STM32MP1 clock nodes are located in stm32mp157c.dtsi[3] (see Device tree for more explanations):

 / {
 ...
 	clocks {
 		clk_hse: clk-hse {
 			#clock-cells = <0>;
 			compatible = "fixed-clock";
 			clock-frequency = <24000000>;
 		};
 
 ...
   	};
 ...
 	soc {
 ...
 		rcc: rcc@50000000 {
 			compatible = "st,stm32mp1-rcc", "syscon";
 			reg = <0x50000000 0x1000>;
 			#clock-cells = <1>;
 			#reset-cells = <1>;
 			interrupts = <GIC_SPI 5 IRQ_TYPE_LEVEL_HIGH>;
 		};
...
 
 	};
 
 };

Please refer to clock device tree configuration for the bindings common with Linux® kernel.

DT configuration (board level)

Clock node

The clock tree is also based on five fixed clocks in the clock node. They are used to define the state of associated ST32MP1 oscillators:

  • clk-lsi
  • clk-lse
  • clk-hsi
  • clk-hse
  • clk-csi

Please refer to clock device tree configuration for detailed information.

At boot time, the clock tree initialization performs the following tasks:

  • enabling of the oscillators present in the device tree and not disabled (node with status="disabled"),
  • disabling of the HSI oscillator if the node is absent or disabled (HSI is always activated by the ROM code).

This information is located in the following files:

  • STM32MP157C-EV:
  • STM32MP157X-DK:
Optional properties for "clk-lse" and "clk-hse" external oscillators

For external oscillator HSE and LSE, the default clock configuration is an external crystal/ceramic resonator.

Four optional fields are supported:

  • "st,bypass" configures the external analog clock source (set HSEBYP, LSEBYP),
  • "st,digbypass" configures the external digital clock source (set DIGBYP and HSEBYP, LSEBYP),
  • "st,css" activates the clock security system (HSECSSON, LSECSSON),
  • "st,drive" (LSE only) contains the value of the drive for the oscillator (see LSEDRV_ defined in the file stm32mp1-clksrc.h[8]).
DT configuration for HSE

The HSE can accept an external crystal/ceramic or external clock source on OSC_IN, digital or analog : the user needs to select the correct frequency and the correct configuration in the device tree, corresponding to the hardware setup.

All the ST boards are using a digital external clock configuration (so device tree with = st,digbypass).

For example with the same 24MHz frequency, we have 3 configurations:

Hse config.jpg
  • Digital external clock = st,digbypass
 	/ {
 		clocks {
 			clk_hse: clk-hse {
 				#clock-cells = <0>;
 				compatible = "fixed-clock";
 				clock-frequency = <24000000>;
 				st,digbypass;
 			};
 	};
  • Analog external clock = st,bypass
 	/ {
 		clocks {
 			clk_hse: clk-hse {
 				#clock-cells = <0>;
 				compatible = "fixed-clock";
 				clock-frequency = <24000000>;
 				st,bypass;
			};
 	};
  • Crystal/ ceramic resonators configuration
 	/ {
 		clocks {
 			clk_hse: clk-hse {
 				#clock-cells = <0>;
 				compatible = "fixed-clock";
 				clock-frequency = <24000000>;
 			};
 	};
DT configuration for LSE

Below an example of LSE on board file with 32,768kHz crystal resonators, the drive set to medium high and with activated clock security system.

 	/ {
 		clocks {
 			clk_lse: clk-lse {
 				#clock-cells = <0>;
 				compatible = "fixed-clock";
 				clock-frequency = <32768>;
 				st,css;
 				st,drive = <LSEDRV_MEDIUM_HIGH>;
 			};
 	};
Optional property for "clk-hsi" internal oscillator

The HSI clock frequency is internally fixed to 64 MHz for the STM32MP15 devices.

In the device tree, clk-hsi is the clock after HSIDIV divider (more information on clk_hsi can be found in the RCC chapter in the reference manual).
As a result the frequency of this fixed clock is used to compute the expected HSIDIV for the clock tree initialization.

Below an example with HSIDIV = 1/1:

 	/ {
 		clocks {
 			clk_hsi: clk-hsi {
 				#clock-cells = <0>;
 				compatible = "fixed-clock";
 				clock-frequency = <64000000>;
 			};
 	};

Below an example with HSIDIV = 1/2:

 	/ {
 		clocks {
 			clk_hsi: clk-hsi {
 				#clock-cells = <0>;
 				compatible = "fixed-clock";
 				clock-frequency = <32000000>;
 			};
 	};
Clock node example

An example of clocks node with:

  • all oscillators switched on (HSE, HSI, LSE, LSI, CSI)
  • HSI at 64MHZ (HSIDIV = 1/1)
  • HSE using a digital external clock at 24MHz
  • LSE using an external crystal a 32.768kHz (the typical frequency)

We highlight the customized parts:

 / {
 	clocks {
 		clk_hse: clk-hse {
 			#clock-cells = <0>;
 			compatible = "fixed-clock";
 			clock-frequency = <24000000>;
 			st,digbypass;
 		};
 
 		clk_hsi: clk-hsi {
 			#clock-cells = <0>;
 			compatible = "fixed-clock";
 			clock-frequency = <64000000>;
 		};
 
 		clk_lse: clk-lse {
 			#clock-cells = <0>;
 			compatible = "fixed-clock";
 			clock-frequency = <32768>;
 		};
 
 		clk_lsi: clk-lsi {
 			#clock-cells = <0>;
 			compatible = "fixed-clock";
 			clock-frequency = <32000>;
 		};
 
 		clk_csi: clk-csi {
 			#clock-cells = <0>;
 			compatible = "fixed-clock";
 			clock-frequency = <4000000>;
 		};
 	};
 };

So the resulting board device tree, based on SoC device tree "stm32mp157c.dtsi", is :

 #include "stm32mp157c.dtsi"
 &clk_hse {
 	clock-frequency = <24000000>;
 	st,digbypass;
 };
 
 &clk_hsi {
 	clock-frequency = <64000000>;
 };
 
 &clk_lse {
 	clock-frequency = <32768>;
 };

It is the configuration used by TF-A for STM32MP157C-EV [4]

STM32MP1 clock node

Please refer to clock device tree configuration for information on how to specify the number of cells in a clock specifier.

The bootloader performs a global clock initialization, as described below. The information related to a given board can be found in the board specific device tree files listed in clock node.

The bootloader uses other properties for RCC node ("st,stm32mp1-rcc" compatible):

  • secure-status: related to TZEN bit configuration in RCC_TZCR register that allows to restrict RCC and PWR registers write access
  • st,clksrc: clock source configuration array
  • st,clkdiv: clock divider configuration array
  • st,pll: specific PLL configuration
  • st,pkcs: peripheral kernel clock distribution configuration array.

All the available clocks are defined as preprocessor macros in stm32mp1-clks.h[9] and can be used in device tree sources.

Defining clock source distribution with st,clksrc property

This property can be used to configure the clock distribution tree. When used, it must describe the whole distribution tree.

There are nine clock source selectors for the STM32MP15 devices. They must be configured in the following order: MPU, AXI, MCU, PLL12, PLL3, PLL4, RTC, MCO1, and MCO2.

The clock source configuration values are defined by the CLK_<NAME>_<SOURCE> macros located in stm32mp1-clksrc.h[8].

Example:

        st,clksrc = <
                CLK_MPU_PLL1P
                CLK_AXI_PLL2P
                CLK_MCU_PLL3P
                CLK_PLL12_HSE
                CLK_PLL3_HSE
                CLK_PLL4_HSE
                CLK_RTC_LSE
                CLK_MCO1_DISABLED
                CLK_MCO2_DISABLED
        >;
Defining clock dividers with st,clkdiv property

This property can be used to configure the value of the clock main dividers. When used, it must describe the whole clock divider tree.

There are 11 dividers values for the STM32MP15 devices. They must be configured in the following order: MPU, AXI, MCU, APB1, APB2, APB3, APB4, APB5, RTC, MCO1 and MCO2.

Each divider value uses the DIV coding defined in the RCC associated register, RCC_xxxDIVR. In most cases, this value is the following:

  • 0x0: not divided
  • 0x1: division by 2
  • 0x2: division by 4
  • 0x3: division by 8
  • ...

Note that the coding differs for RTC MCO1 and MCO2:

  • 0x0: not divided
  • 0x1: division by 2
  • 0x2: division by 3
  • 0x3: division by 4
  • ...

Example:

        st,clkdiv = <
                1 /*MPU*/
                0 /*AXI*/
                0 /*MCU*/
                1 /*APB1*/
                1 /*APB2*/
                1 /*APB3*/
                1 /*APB4*/
                2 /*APB5*/
                23 /*RTC*/
                0 /*MCO1*/
                0 /*MCO2*/
        >;
Defining peripheral PLL frequencies with st,pll property

This property can be used to configure PLL frequencies.

The PLL children nodes for PLL1 to PLL4 (see reference manual for details) are associated with an index from 0 to 3 (st,pll@0 to st,pll@3). PLLx is off when the associated node is absent.

For ecosystem release ≥ v1.2.0{{#set:Ecosystem release=revision of a previous flow 1.2.0}} , TF-A automatically selects the most suitable operating point for the platform (please refer to 如何更改CPU频率), so the PLL1 node is no longer necessary.

Below the available properties for each PLL node:

  • cfg contains the PLL configuration parameters in the following order: DIVM, DIVN, DIVP, DIVQ, DIVR, output.
DIVx values are defined as in RCC:
  • 0x0: bypass (division by 1)
  • 0x1: division by 2
  • 0x2: division by 3
  • 0x3: division by 4
  • ...
Output contains a bitfield for each output value (1:ON / 0:OFF)
  • BIT(0) → output P : DIVPEN
  • BIT(1) → output Q : DIVQEN
  • BIT(2) → output R : DIVREN
Note: PQR(p,q,r) macro can be used to build this value with p, q, r = 0 or 1.
  • frac: fractional part of the multiplication factor (optional, when absent PLL is in integer mode).
  • csg contains the clock spreading generator parameters (optional) in the following order: MOD_PER, INC_STEP and SSCG_MODE.
MOD_PER: modulation period adjustment
INC_STEP: modulation depth adjustment
SSCG_MODE: Spread spectrum clock generator mode, defined in stm32mp1-clksrc.h[8]:
  • SSCG_MODE_CENTER_SPREAD = 0
  • SSCG_MODE_DOWN_SPREAD = 1

Example:

	st,pll@0 {
		cfg = < 1 53 0 0 0 1 >;
		frac = < 0x810 >;
	};
	st,pll@1 {
		cfg = < 1 43 1 0 0 PQR(0,1,1) >;
		csg = < 10 20 1 >;
	};
	st,pll@2 {
		cfg = < 2 85 3 13 3 0 >;
		csg = < 10 20 SSCG_MODE_CENTER_SPREAD >;
	};
	st,pll@3 {
		cfg = < 2 78 4 7 9 3 >;
	};
Defining peripheral kernel clock tree distribution with st,pkcs property

This property can be used to configure the peripheral kernel clock selection.

It is a list of peripheral kernel clock source identifiers defined by the CLK_<KERNEL-CLOCK>_<PARENT-CLOCK> macros in the stm32mp1-clksrc.h[8] header file.

st,pkcs may not list all the kernel clocks. No specific order is required.

Example:

	st,pkcs = <
		CLK_STGEN_HSE
		CLK_CKPER_HSI
		CLK_USBPHY_PLL2P
		CLK_DSI_PLL2Q
                CLK_I2C46_HSI
                CLK_UART1_HSI
                CLK_UART24_HSI
	>;
HSI and CSI clocks calibration

The calibration is an optional feature that can be enabled from the device tree. It allows requesting the HSI or CSI clock calibration by several means:

  • SiP SMC service
  • Periodic calibration every X seconds
  • Interrupt raised by the MCU

This feature requires that a hardware timer is assigned to the calibration sequence.

A dedicated interrupt must be defined using "mcu_sev" name to start a calibration on detection of an interrupt raised by the MCU.

  • st,hsi-cal: used to enable HSI clock calibration feature.
  • st,csi-cal; used to enable CSI clock calibration feature.
  • st,cal-sec: used to enable periodic calibration at specified time intervals from the secure monitor. The time interval must be given in seconds. If not specified, a calibration is only processed for each incoming request.

Example:

	&rcc {
		st,hsi-cal;
		st,csi-cal;
		st,cal-sec = <15>;
		secure-interrupts = <GIC_SPI 144 IRQ_TYPE_LEVEL_HIGH>,
				<GIC_SPI 145 IRQ_TYPE_LEVEL_HIGH>;
		interrupt-names = "mcu_sev", "wakeup";
	};

How to configure the DT using STM32CubeMX

The STM32CubeMX tool can be used to configure the STM32MPU device and get the corresponding platform configuration device tree files.

The STM32CubeMX may not support all the properties described in the above DT bindings documentation paragraph.
If so, the tool inserts user sections in the generated device tree.
These sections can then be edited to add some properties and they are preserved from one generation to another.

Refer to STM32CubeMX user manual for further information.

References

Please refer to the following links for additional information: