1. Article purpose[edit source]
The purpose of this article is to explain how to configure the RCC internal peripheral clocks using the device tree mechanism, relying on the bindings documentation, that is the description of the required and optional device-tree properties.
The peripheral can be assigned to different contexts/software components, depending on the final product needs. Refer to How to assign an internal peripheral to a runtime context article for guidelines on this configuration .
2. DT bindings documentation[edit source]
The device tree binding documents are stored either in the given applicable components listed below, or in the Linux kernel repository:
- TF-A BL2:
- for STM32MP13x lines docs/devicetree/bindings/clock/st,stm32mp13-rcc.txt
- for STM32MP15x lines docs/devicetree/bindings/clock/st,stm32mp1-rcc.txt
- for STM32MP13x lines docs/devicetree/bindings/clock/st,stm32mp13-rcc.txt
- OP-TEE:
- for STM32MP13x lines documentation/devicetree/bindings/clock/st,stm32mp13-rcc.yaml
- for STM32MP13x lines documentation/devicetree/bindings/clock/st,stm32mp13-rcc.yaml
- U-Boot, Linux® OS:
- for example: STM32MP1x device tree bindings: Documentation/devicetree/bindings/clock/st,stm32mp1-rcc.yaml
3. DT configuration[edit source]
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 organization.
STM32CubeMX can be used to generate the board device tree. Refer to How to configure the DT using STM32CubeMX for more details.
3.1. DT configuration (STM32/SoC level)[edit source]
The RCC node is located in the device tree file for the software components, supporting the peripheral and listed in the above DT bindings documentation paragraph.
3.2. DT configuration (board level)[edit source]
The objective of this chapter is to explain how to configure a clock tree related to the board.
Using this chapter, the end-user can configure any
parameters via the DT to adapt to a new board.
3.2.1. STM32MP15x lines [edit source]
Clock tree configuration it's only done in TF-A BL2. It is only copied in OP-TEE DT for a functional check purpose.
This an example a clock configuration tree:
&rcc { 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 >; st,clkdiv = < 1 /*MPU*/ 0 /*AXI*/ 0 /*MCU*/ 1 /*APB1*/ 1 /*APB2*/ 1 /*APB3*/ 1 /*APB4*/ 2 /*APB5*/ 23 /*RTC*/ 0 /*MCO1*/ 0 /*MCO2*/ >; st,pkcs = < CLK_CKPER_HSE CLK_FMC_ACLK CLK_QSPI_ACLK CLK_ETH_PLL4P CLK_SDMMC12_PLL4P CLK_DSI_DSIPLL CLK_STGEN_HSE CLK_USBPHY_HSE CLK_SPI2S1_PLL3Q ... >; /* VCO = 1066.0 MHz => P = 266 (AXI), Q = 533 (GPU), R = 533 (DDR) */ pll2: st,pll@1 { compatible = "st,stm32mp1-pll"; reg = <1>; cfg = <2 65 1 0 0 PQR(1,1,1)>; frac = <0x1400>; }; /* VCO = 417.8 MHz => P = 209, Q = 24, R = 11 */ pll3: st,pll@2 { compatible = "st,stm32mp1-pll"; reg = <2>; cfg = <1 33 1 16 36 PQR(1,1,1)>; frac = <0x1a04>; }; /* VCO = 594.0 MHz => P = 99, Q = 74, R = 74 */ pll4: st,pll@3 { compatible = "st,stm32mp1-pll"; reg = <3>; cfg = <3 98 5 7 7 PQR(1,1,1)>; }; };
You can find a full example of the board configuration here stm32mp15xx-dkx.dtsi
3.2.2. STM32MP13x lines [edit source]
Clock tree configuration it's done in TF-A and in OP-TEE.
Usually a minimal configuration is applied in TF-A BL2 and the full configuration in OP-TEE.
This an example a clock configuration tree:
&rcc { compatible = "st,stm32mp13-rcc", "syscon", "st,stm32mp13-rcc-mco"; pinctrl-0 = <&rcc_mco_pins_a>; pinctrl-names = "default"; st,clksrc = < CLK_MPU_PLL1P CLK_AXI_PLL2P CLK_MLAHBS_PLL3 CLK_RTC_LSE CLK_MCO1_HSE ... >; st,clkdiv = < DIV(DIV_MPU, 1) DIV(DIV_AXI, 0) DIV(DIV_MLAHB, 0) ... >; st,pll_vco { pll3_vco_417_8Mhz: pll3-vco-417_8Mhz { src = < CLK_PLL3_HSE >; divmn = < 1 33 >; frac = < 0x1a04 >; }; pll4_vco_600Mhz: pll4-vco-600Mhz { src = < CLK_PLL4_HSE >; divmn = < 1 49 >; }; }; /* VCO = 417.8 MHz => P = 209, Q = 24, R = 11 */ pll3:st,pll@2 { compatible = "st,stm32mp1-pll"; reg = <2>; st,pll = < &pll3_cfg1 >; pll3_cfg1: pll3_cfg1 { st,pll_vco = < &pll3_vco_417_8Mhz >; st,pll_div_pqr = < 1 16 36 >; }; }; /* VCO = 600.0 MHz => P = 50, Q = 10, R = 50 */ pll4:st,pll@3 { compatible = "st,stm32mp1-pll"; reg = <3>; st,pll = < &pll4_cfg1 >; pll4_cfg1: pll4_cfg1 { st,pll_vco = < &pll4_vco_600Mhz >; st,pll_div_pqr = < 11 59 11 >; }; }; };
You can find a full example of the board configuration here stm32mp135f-dk.dts
4. How to configure the DT using STM32CubeMX[edit source]
The STM32CubeMX tool can be used to configure the STM32MPU device and get the corresponding platform configuration device tree files.
STM32CubeMX may not support all the properties described in DT binding files listed 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.
5. References[edit source]
Please refer to the following links for additional information: