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== Article purpose ==
 
== Article purpose ==
This article explains how to configure the [[SAI internal peripheral]] when it is assigned to the '''Linux<sup>&reg;</sup> OS'''. In that case, it is controlled by the [[ALSA_overview|ALSA framework]].
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本文介绍如何在将 [[SAI internal peripheral]] 分配给 '''Linux<sup>&reg;</sup> OS'''时对其进行配置。在这种情况下,它由 [[ALSA_overview|ALSA framework]]控制。
  
The configuration is performed using the [[Device_tree|device tree]] mechanism that provides a hardware description of the SAI peripheral, used by the [[SAI_Linux_driver|SAI linux driver]].
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使用[[Device_tree|device tree]] 机制执行配置,该机制提供由[[SAI_Linux_driver|SAI linux driver]]使用的SAI外围设备的硬件描述。
  
If the peripheral is assigned to another execution context, refer to [[How to assign an internal peripheral to a runtime context]] article for guidelines on peripheral assignment and configuration.
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如果外围设备已分配给另一个执行上下文,请参阅 [[How to assign an internal peripheral to a runtime context]] 文章,以获取有关外围设备分配和配置的准则。
  
 
== DT bindings documentation ==
 
== DT bindings documentation ==
STM32 SAI device tree bindings <ref name="sai bindings">[https://www.kernel.org/doc/Documentation/devicetree/bindings/sound/st%2Cstm32-sai.txt STM32 SAI bindings]</ref> document describes all the required and optional configuration properties.
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STM32 SAI设备树绑定 <ref name="sai bindings">[https://www.kernel.org/doc/Documentation/devicetree/bindings/sound/st%2Cstm32-sai.txt STM32 SAI bindings]</ref> 本文档介绍了所有必需的和可选的配置属性。
  
 
== DT configuration ==
 
== 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.<br>
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该硬件描述是'''STM32微处理器'''设备树文件(扩展名为.dtsi)和'''板子'''设备树文件(扩展名为.dts)的组合。 有关设备树文件分割的说明,请参见[[Device tree]]<br>
The SAI is used as a component of a sound card through Linux<sup>&reg;</sup> kernel ALSA framework. The device tree nodes related to the sound card are described in [[#DT_configuration_.28board_level.29|board device tree]].
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通过Linux <sup>&reg;</sup> 内核ALSA框架,SAI用作声卡的组件。 与声卡相关的设备树节点在[[#DT_configuration_.28board_level.29|board device tree]]中进行了描述。
  
The STM32 SAI peripheral includes two independent audio subblocks that share common resources.
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STM32 SAI外设包括两个共享公共资源的独立音频子块。
The SAI device tree nodes reflects this architecture, as shown in the SAI DT sample below.
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SAI设备树节点反映了这种体系结构,如下面的SAI DT示例所示。
 
{{
 
{{
 
ImageMap|
 
ImageMap|
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  };
 
  };
  
The '''STM32CubeMX''' can be used to generate the board device tree. Refer to [[#How_to_configure_the_DT_using_STM32CubeMX|How to configure the DT using STM32CubeMX]] for more details.
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'''STM32CubeMX''' 可用于生成板卡设备树。有关更多详细信息,请参考[[#How_to_configure_the_DT_using_STM32CubeMX|How to configure the DT using STM32CubeMX]]
  
 
=== DT configuration (STM32 level) ===
 
=== DT configuration (STM32 level) ===
The SAI nodes are declared in STM32 microprocessor device tree. They describe hardware parameters such as registers address, interrupt and DMA. This set of properties may not vary for a given STM32MPU. For STM32MP1, the corresponding DT file is stm32mp157c.dtsi<ref name="stm32mp157c.dtsi">{{CodeSource | Linux kernel | arch/arm/boot/dts/stm32mp157c.dtsi}}</ref>.
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SAI节点在STM32微处理器设备树中声明。它们描述了硬件参数,例如寄存器地址,中断和DMA。 对于给定的STM32MPU,这组属性可能不会改变。 对于STM32MP1,对应的DT文件为stm32mp157c.dtsi <ref name="stm32mp157c.dtsi">{{CodeSource | Linux kernel | arch/arm/boot/dts/stm32mp157c.dtsi}}</ref>.
{{Warning|This device tree part is related to STM32 microprocessors. It should be kept as is, without being modified by the end-user.}}
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{{Warning|该设备树部分与STM32微处理器有关。它应保持原样,而不应由最终用户修改。}}
  
 
=== DT configuration (board level) ===
 
=== DT configuration (board level) ===
  
The SAI configuration is board dependent, whether is it connected or not to an external component such as an audio codec. The links between the SAI and the other components define a soundcard. This soundcard has to be configured in the board device tree. Refer to [[Soundcard configuration|soundcard configuration]] for examples of SAI configuration on various STM32MPU boards.
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SAI配置是否取决于板,是否连接到外部组件(例如音频编解码器)。 SAI与其他组件之间的链接定义了声卡。 必须在主板设备树中配置此声卡。有关各种STM32MPU板上SAI配置的示例,请参考[[Soundcard configuration|soundcard configuration]]
  
 
=== DT configuration examples ===
 
=== DT configuration examples ===
  
This chapter describes in details advanced SAI configurations. These examples are based on [[:Category:Getting_started_with_STM32MP1_boards|STM32MP1 boards]] SAI use cases. The corresponding device trees can be found in [[Soundcard configuration|soundcard]] article.
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本章详细介绍高级SAI配置。 这些示例基于 [[:Category:Getting_started_with_STM32MP1_boards|STM32MP1 boards]] SAI用例。 相应的设备树可以在 [[Soundcard configuration|soundcard]] 文章中找到。
{{Info|In this chapter, "SAI" stands for an SAI subblock, SAIxA or SAIxB.}}
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{{Info|在本章中,“ SAI”代表SAI子块SAIxA或SAIxB.}}
  
 
==== Setting SAI as a master clock provider ====
 
==== Setting SAI as a master clock provider ====
The SAI peripheral can provide a clock to an external component (such as a codec) through the mclk output pin. In this case, it acts as master clock (mclk) provider. The below DT sample gives an example of SAI configuration as mclk provider.
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SAI外设可以通过mclk输出引脚为外部组件 (例如编解码器)提供时钟。 在这种情况下,它充当主时钟(mclk)提供程序。下面的DT示例提供了一个作为mclk provider的SAI配置示例。
 +
在此示例中,编解码器驱动程序支持基于ASoC DAPM机制的mclk输入。
 +
如果不是这种情况,则必须调整编解码器驱动程序。这可以通过将DAPM时钟供应小部件添加到编解码器驱动程序来实现。 所需的DAPM时钟供应小部件的示例可以在Cirrus CS42L51编解码器源代码<ref name="CS42L51 code">{{CodeSource | Linux kernel | sound/soc/codecs/cs42l51.c}}</ref>.
 +
在下面的设备树示例中,编解码器DAPM时钟窗口小部件名为“MCLKX”。
  
In this example the codec driver supports mclk input based on ASoC DAPM mechanism.
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为了允许mclk激活/停用,必须在DT中定义DAPM路由。此路由在sound节点中定义,如下所示。
If this is not the case, the codec driver has to be adapted. This can be achieved by adding a DAPM clock supply widget to the codec driver. An example of the required DAPM clock supply widget can be found in Cirrus CS42L51 codec source code<ref name="CS42L51 code">{{CodeSource | Linux kernel | sound/soc/codecs/cs42l51.c}}</ref>.
 
In the below device tree example, the codec DAPM clock widget is named "MCLKX".
 
 
 
To allow mclk activation/deactivation, a DAPM route must be defined in the DT. This route is defined in the sound node, as shown below.
 
  
 
  soundcard {
 
  soundcard {
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==== Sharing master clock between two SAIs ====
 
==== Sharing master clock between two SAIs ====
  
When an SAI is set as a master clock provider, another SAI can share this master clock.
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将SAI设置为主时钟提供者时,另一个SAI可以共享该主时钟。
This can be achieved by setting the SAI as a mclk consumer through DT configuration.
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这可以通过通过DT配置将SAI设置为mclk使用者来实现。
This means that the mclk consumer SAI can request to change the mclk rate, according to its own audio stream sampling rate.
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这意味着mclk使用者SAI可以请求根据其自己的音频流采样率更改mclk速率。
This implies that audio sampling rates must be identical when both SAI subblocks are used.
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这意味着当使用两个SAI子块时,音频采样率必须相同。
  
 
  &sai2 {
 
  &sai2 {
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==== Sharing the codec interface between two SAIs ====
 
==== Sharing the codec interface between two SAIs ====
  
Two SAIs can be connected to the same codec interface, by sharing the I2S bus (i.e. FS and SCK clocks).
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通过共享I2S总线(即FS和SCK时钟),两个SAI可以连接到同一编解码器接口。
  
 
[[Image:sai_shared_codec.png {{!}} frame {{!}} center{{!}} SAIs sharing the same codec interface|link=]]
 
[[Image:sai_shared_codec.png {{!}} frame {{!}} center{{!}} SAIs sharing the same codec interface|link=]]
  
In such case:
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在这种情况下:
*The codec has to be master on the I2S bus.
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*编解码器必须是I2S总线上的主机。
*Only one SAI is connected to the bus clocks. The other SAI has to be configured as a slave of the SAI connected to the bus.
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*总线时钟仅连接一个SAI。 另一个SAI必须配置为连接到总线的SAI的从设备。
*The I2S bus I/O pins must be managed at parent level, so that the corresponding pins are activated whatever the running SAI.
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*I2S总线 I/O 引脚必须在父级进行管理,以便无论正在运行的SAI如何激活相应的引脚。
  
From ASoC point of view:<BR>
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从ASoC的角度来看:<BR>
Two CPU DAIs have to be connected to the same codec DAI. Such topology is not supported natively by the ASoC audio graph card. Indeed, when the audio graph card parses the codec nodes, it expects to find DAI interface indexes, matching the endpoints indexes. A workaround consists in implementing the of_xlate_dai_id callback in the codec driver, to allow using the same DAI interface for both endpoints. An example of code can be found below or in the Cirrus CS42L51 codec source code<ref name="CS42L51 code">{{CodeSource | Linux kernel | sound/soc/codecs/cs42l51.c}}</ref>.
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必须将两个CPU DAI连接到同一编解码器DAI。 ASoC音频图形卡本身不支持这种拓扑。 实际上,当音频图形卡解析编解码器节点时,它期望找到与端点索引匹配的DAI接口索引。 一种解决方法是在编解码器驱动程序中实现of_xlate_dai_id回调,以允许对两个端点使用相同的DAI接口。可以在下面或在Cirrus CS42L51编解码器源代码中找到代码示例。<ref name="CS42L51 code">{{CodeSource | Linux kernel | sound/soc/codecs/cs42l51.c}}</ref>.
  
* Code example
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* 代码示例
  
 
<syntaxhighlight lang="c">
 
<syntaxhighlight lang="c">
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==How to configure the DT using STM32CubeMX==
 
==How to configure the DT using STM32CubeMX==
The [[STM32CubeMX]] tool can be used to configure the STM32MPU device and get the corresponding [[Device_tree#STM32|platform configuration device tree]] files.<br />
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[[STM32CubeMX]] 工具可用于配置STM32MPU设备并获取相应的[[Device_tree#STM32|platform configuration device tree]] 文件。<br />
The STM32CubeMX may not support all the properties described in the above [[#DT bindings documentation|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.
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STM32CubeMX可能不支持上述 [[#DT bindings documentation|DT bindings documentation]] 段落中描述的所有属性。 如果是这样,该工具会在生成的设备树中插入 '''用户部分''' 。然后可以编辑这些部分以添加一些属性,并将它们一代一代地保留下来。 有关更多信息,请参见[[STM32CubeMX]]用户手册。
{{Warning|The STM32CubeMX does not allow the generation of all the nodes required to configure a soundcard. The soundcard node and the codec nodes have to be filled manually through user sections.}}
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{{Warning|STM32CubeMX不允许生成配置声卡所需的所有节点。 声卡节点和编解码器节点必须通过用户部分手动填充。}}
  
 
==References==
 
==References==
 
<references />
 
<references />
 
<noinclude>
 
{{ArticleBasedOnModel | Peripheral or framework device tree configuration model}}
 
{{PublicationRequestId | 14728 | 2020-01-28 | AnneJ (9809)}}
 
 
[[Category:Device tree configuration]]
 
[[Category:ALSA]]
 
</noinclude>
 

2020年11月5日 (四) 15:56的最新版本

Article purpose

本文介绍如何在将 SAI internal peripheral 分配给 Linux® OS时对其进行配置。在这种情况下,它由 ALSA framework控制。

使用device tree 机制执行配置,该机制提供由SAI linux driver使用的SAI外围设备的硬件描述。

如果外围设备已分配给另一个执行上下文,请参阅 How to assign an internal peripheral to a runtime context 文章,以获取有关外围设备分配和配置的准则。

DT bindings documentation

STM32 SAI设备树绑定 [1] 本文档介绍了所有必需的和可选的配置属性。

DT configuration

该硬件描述是STM32微处理器设备树文件(扩展名为.dtsi)和板子设备树文件(扩展名为.dts)的组合。 有关设备树文件分割的说明,请参见Device tree
通过Linux ® 内核ALSA框架,SAI用作声卡的组件。 与声卡相关的设备树节点在board device tree中进行了描述。

STM32 SAI外设包括两个共享公共资源的独立音频子块。 SAI设备树节点反映了这种体系结构,如下面的SAI DT示例所示。

Clock overview Pinctrl overview
SAI device tree configuration
&saix {
	/* SAIx parent node. Configure common ressources  */
	clock-names = "pclk", "x8k", "x11k"; /* Peripheral and parent clock configuration.  */
	... 

	saixa {
		/* child node. Configure ressources dedicated to SAIxA subblock */
		clock-names = "sai_ck"; /* SAIxA kernel clock confguration.  */
		pinctrl-names = "default"; /* GPIOsA configuration.  */
		... 
	};

	saixb {
		/* child node. Configure ressources dedicated to SAIxB subblock */
		clock-names = "sai_ck"; /* SAIxB kernel clock confguration.  */
		pinctrl-names = "default"; /* GPIOsB configuration.  */
		...
	};
};

STM32CubeMX 可用于生成板卡设备树。有关更多详细信息,请参考How to configure the DT using STM32CubeMX

DT configuration (STM32 level)

SAI节点在STM32微处理器设备树中声明。它们描述了硬件参数,例如寄存器地址,中断和DMA。 对于给定的STM32MPU,这组属性可能不会改变。 对于STM32MP1,对应的DT文件为stm32mp157c.dtsi [2].

Warning.png 该设备树部分与STM32微处理器有关。它应保持原样,而不应由最终用户修改。

DT configuration (board level)

SAI配置是否取决于板,是否连接到外部组件(例如音频编解码器)。 SAI与其他组件之间的链接定义了声卡。 必须在主板设备树中配置此声卡。有关各种STM32MPU板上SAI配置的示例,请参考soundcard configuration

DT configuration examples

本章详细介绍高级SAI配置。 这些示例基于 STM32MP1 boards SAI用例。 相应的设备树可以在 soundcard 文章中找到。

Info.png 在本章中,“ SAI”代表SAI子块SAIxA或SAIxB.

Setting SAI as a master clock provider

SAI外设可以通过mclk输出引脚为外部组件 (例如编解码器)提供时钟。 在这种情况下,它充当主时钟(mclk)提供程序。下面的DT示例提供了一个作为mclk provider的SAI配置示例。 在此示例中,编解码器驱动程序支持基于ASoC DAPM机制的mclk输入。 如果不是这种情况,则必须调整编解码器驱动程序。这可以通过将DAPM时钟供应小部件添加到编解码器驱动程序来实现。 所需的DAPM时钟供应小部件的示例可以在Cirrus CS42L51编解码器源代码[3]. 在下面的设备树示例中,编解码器DAPM时钟窗口小部件名为“MCLKX”。

为了允许mclk激活/停用,必须在DT中定义DAPM路由。此路由在sound节点中定义,如下所示。 

soundcard {
	routing =
		"Playback" , "MCLKX", /* Set a route between "MCLKX" and "playback" widgets */
		"Capture" , "MCLKX";
	...
};

codec: {
	clocks = <&sai2a>;     /* The codec is a consumer of SAI2A master clock */
	clock-names = "MCLKX"; /* Feed MCLKX codec clock with SAI2A master clock provider */
	...
};

&sai2 {
	...
		
	sai2a: audio-controller@4400b004 {
		#clock-cells = <0>; /* Set SAI2A as master clock provider */
		...
		sai2a_endpoint: endpoint {
			mclk-fs = <256>; /* Set mclk/fs ratio. (256 or 512) */
		};
	};
};

Sharing master clock between two SAIs

将SAI设置为主时钟提供者时,另一个SAI可以共享该主时钟。 这可以通过通过DT配置将SAI设置为mclk使用者来实现。 这意味着mclk使用者SAI可以请求根据其自己的音频流采样率更改mclk速率。 这意味着当使用两个SAI子块时,音频采样率必须相同。 

&sai2 {
	...
		
	sai2a: audio-controller@4400b004 {
		#clock-cells = <0>; /* Set SAI2A as master clock provider */
		...
	};

	sai2b: audio-controller@4400b024 {
		clocks = <&rcc SAI2_K>, <&sai2a>; /* SAI2B is a consumer of SAI2A master clock */
		clock-names = "sai_ck", "MCLK";   /* Feed SAI2B MCLK clock with SAI2A master clock provider */
		...
		sai2b_endpoint: endpoint {
			mclk-fs = <256>; /* Set mclk/fs ratio. (256 or 512) */
		};
	};
};

Sharing the codec interface between two SAIs

通过共享I2S总线(即FS和SCK时钟),两个SAI可以连接到同一编解码器接口。

SAIs sharing the same codec interface

在这种情况下:

  • 编解码器必须是I2S总线上的主机。
  • 总线时钟仅连接一个SAI。 另一个SAI必须配置为连接到总线的SAI的从设备。
  • I2S总线 I/O 引脚必须在父级进行管理,以便无论正在运行的SAI如何激活相应的引脚。

从ASoC的角度来看:
必须将两个CPU DAI连接到同一编解码器DAI。 ASoC音频图形卡本身不支持这种拓扑。 实际上,当音频图形卡解析编解码器节点时,它期望找到与端点索引匹配的DAI接口索引。 一种解决方法是在编解码器驱动程序中实现of_xlate_dai_id回调,以允许对两个端点使用相同的DAI接口。可以在下面或在Cirrus CS42L51编解码器源代码中找到代码示例。[3].

  • 代码示例
static int codec_of_xlate_dai_id(struct snd_soc_component *component,
				   struct device_node *endpoint)
{
	/* return dai id 0, whatever the endpoint index */
	return 0;
}
  • DT example
codec {
	...
	codec_port {
		codec_tx_endpoint {
			remote-endpoint = <&sai2a_endpoint>;
			frame-master;    /* Set codec as master of SAI2A for FS clock. */
			bitclock-master; /* Set codec as master of SAI2A for SCK clock. */
		};

		codec_rx_endpoint { /* Second endpoint mapped on codec DAI 0 via of_xlate */
			remote-endpoint = <&sai2b_endpoint>;
			frame-master;    /* Set codec as master of SAI2B for FS clock. */
			bitclock-master; /* Set codec as master of SAI2B for SCK clock. */
		};
	};
};

&sai2 {
	pinctrl-names = "default", "sleep"; /* Defines SAI2A/B GPIOs at parent level. */
	pinctrl-0 = <&sai2a_pins_a>, <&sai2b_pins_b>;
	pinctrl-1 = <&sai2a_sleep_pins_a>, <&sai2b_sleep_pins_b>;
	...

	sai2a: audio-controller@4400b004 {
		remote-endpoint = <&codec_tx_endpoint>;
		...
	};

	sai2b: audio-controller@4400b024 {
		remote-endpoint = <&codec_rx_endpoint>;
		st,sync = <&sai2a 2>; /* Set SAI2B as slave of SAI2A. */
	};
};

How to configure the DT using STM32CubeMX

STM32CubeMX 工具可用于配置STM32MPU设备并获取相应的platform configuration device tree 文件。
STM32CubeMX可能不支持上述 DT bindings documentation 段落中描述的所有属性。 如果是这样,该工具会在生成的设备树中插入 用户部分 。然后可以编辑这些部分以添加一些属性,并将它们一代一代地保留下来。 有关更多信息,请参见STM32CubeMX用户手册。

Warning.png STM32CubeMX不允许生成配置声卡所需的所有节点。 声卡节点和编解码器节点必须通过用户部分手动填充。

References

  1. STM32 SAI bindings
  2. arch/arm/boot/dts/stm32mp157c.dtsi| |}} arch/arm/boot/dts/stm32mp157c.dtsi
  3. 3.03.1 sound/soc/codecs/cs42l51.c| |}} sound/soc/codecs/cs42l51.c
取自“http://wiki.100ask.org/index.php?title=SAI_device_tree_configuration&oldid=7437