874 строки
32 KiB
Cheetah
874 строки
32 KiB
Cheetah
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<?xml version="1.0" encoding="UTF-8"?>
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<!DOCTYPE book PUBLIC "-//OASIS//DTD DocBook XML V4.1.2//EN"
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"http://www.oasis-open.org/docbook/xml/4.1.2/docbookx.dtd" []>
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<book id="Writing-MUSB-Glue-Layer">
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<bookinfo>
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<title>Writing an MUSB Glue Layer</title>
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<authorgroup>
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<author>
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<firstname>Apelete</firstname>
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<surname>Seketeli</surname>
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<affiliation>
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<address>
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<email>apelete at seketeli.net</email>
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</address>
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</affiliation>
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</author>
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</authorgroup>
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<copyright>
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<year>2014</year>
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<holder>Apelete Seketeli</holder>
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</copyright>
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<legalnotice>
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<para>
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This documentation is free software; you can redistribute it
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and/or modify it under the terms of the GNU General Public
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License as published by the Free Software Foundation; either
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version 2 of the License, or (at your option) any later version.
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</para>
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<para>
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This documentation is distributed in the hope that it will be
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useful, but WITHOUT ANY WARRANTY; without even the implied
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warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
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See the GNU General Public License for more details.
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</para>
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<para>
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You should have received a copy of the GNU General Public License
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along with this documentation; if not, write to the Free Software
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Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
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02111-1307 USA
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</para>
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<para>
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For more details see the file COPYING in the Linux kernel source
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tree.
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</para>
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</legalnotice>
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</bookinfo>
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<toc></toc>
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<chapter id="introduction">
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<title>Introduction</title>
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<para>
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The Linux MUSB subsystem is part of the larger Linux USB
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subsystem. It provides support for embedded USB Device Controllers
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(UDC) that do not use Universal Host Controller Interface (UHCI)
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or Open Host Controller Interface (OHCI).
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</para>
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<para>
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Instead, these embedded UDC rely on the USB On-the-Go (OTG)
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specification which they implement at least partially. The silicon
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reference design used in most cases is the Multipoint USB
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Highspeed Dual-Role Controller (MUSB HDRC) found in the Mentor
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Graphics Inventra™ design.
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</para>
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<para>
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As a self-taught exercise I have written an MUSB glue layer for
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the Ingenic JZ4740 SoC, modelled after the many MUSB glue layers
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in the kernel source tree. This layer can be found at
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drivers/usb/musb/jz4740.c. In this documentation I will walk
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through the basics of the jz4740.c glue layer, explaining the
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different pieces and what needs to be done in order to write your
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own device glue layer.
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</para>
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</chapter>
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<chapter id="linux-musb-basics">
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<title>Linux MUSB Basics</title>
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<para>
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To get started on the topic, please read USB On-the-Go Basics (see
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Resources) which provides an introduction of USB OTG operation at
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the hardware level. A couple of wiki pages by Texas Instruments
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and Analog Devices also provide an overview of the Linux kernel
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MUSB configuration, albeit focused on some specific devices
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provided by these companies. Finally, getting acquainted with the
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USB specification at USB home page may come in handy, with
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practical instance provided through the Writing USB Device Drivers
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documentation (again, see Resources).
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</para>
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<para>
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Linux USB stack is a layered architecture in which the MUSB
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controller hardware sits at the lowest. The MUSB controller driver
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abstract the MUSB controller hardware to the Linux USB stack.
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</para>
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<programlisting>
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------------------------
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| | <------- drivers/usb/gadget
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| Linux USB Core Stack | <------- drivers/usb/host
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| | <------- drivers/usb/core
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------------------------
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⬍
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--------------------------
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| | <------ drivers/usb/musb/musb_gadget.c
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| MUSB Controller driver | <------ drivers/usb/musb/musb_host.c
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| | <------ drivers/usb/musb/musb_core.c
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--------------------------
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⬍
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---------------------------------
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| MUSB Platform Specific Driver |
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| | <-- drivers/usb/musb/jz4740.c
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| aka "Glue Layer" |
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---------------------------------
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⬍
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---------------------------------
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| MUSB Controller Hardware |
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---------------------------------
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</programlisting>
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<para>
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As outlined above, the glue layer is actually the platform
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specific code sitting in between the controller driver and the
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controller hardware.
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</para>
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<para>
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Just like a Linux USB driver needs to register itself with the
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Linux USB subsystem, the MUSB glue layer needs first to register
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itself with the MUSB controller driver. This will allow the
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controller driver to know about which device the glue layer
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supports and which functions to call when a supported device is
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detected or released; remember we are talking about an embedded
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controller chip here, so no insertion or removal at run-time.
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</para>
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<para>
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All of this information is passed to the MUSB controller driver
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through a platform_driver structure defined in the glue layer as:
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</para>
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<programlisting linenumbering="numbered">
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static struct platform_driver jz4740_driver = {
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.probe = jz4740_probe,
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.remove = jz4740_remove,
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.driver = {
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.name = "musb-jz4740",
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},
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};
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</programlisting>
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<para>
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The probe and remove function pointers are called when a matching
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device is detected and, respectively, released. The name string
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describes the device supported by this glue layer. In the current
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case it matches a platform_device structure declared in
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arch/mips/jz4740/platform.c. Note that we are not using device
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tree bindings here.
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</para>
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<para>
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In order to register itself to the controller driver, the glue
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layer goes through a few steps, basically allocating the
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controller hardware resources and initialising a couple of
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circuits. To do so, it needs to keep track of the information used
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throughout these steps. This is done by defining a private
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jz4740_glue structure:
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</para>
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<programlisting linenumbering="numbered">
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struct jz4740_glue {
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struct device *dev;
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struct platform_device *musb;
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struct clk *clk;
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};
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</programlisting>
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<para>
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The dev and musb members are both device structure variables. The
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first one holds generic information about the device, since it's
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the basic device structure, and the latter holds information more
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closely related to the subsystem the device is registered to. The
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clk variable keeps information related to the device clock
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operation.
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</para>
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<para>
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Let's go through the steps of the probe function that leads the
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glue layer to register itself to the controller driver.
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</para>
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<para>
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N.B.: For the sake of readability each function will be split in
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logical parts, each part being shown as if it was independent from
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the others.
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</para>
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<programlisting linenumbering="numbered">
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static int jz4740_probe(struct platform_device *pdev)
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{
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struct platform_device *musb;
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struct jz4740_glue *glue;
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struct clk *clk;
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int ret;
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glue = devm_kzalloc(&pdev->dev, sizeof(*glue), GFP_KERNEL);
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if (!glue)
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return -ENOMEM;
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musb = platform_device_alloc("musb-hdrc", PLATFORM_DEVID_AUTO);
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if (!musb) {
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dev_err(&pdev->dev, "failed to allocate musb device\n");
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return -ENOMEM;
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}
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clk = devm_clk_get(&pdev->dev, "udc");
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if (IS_ERR(clk)) {
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dev_err(&pdev->dev, "failed to get clock\n");
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ret = PTR_ERR(clk);
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goto err_platform_device_put;
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}
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ret = clk_prepare_enable(clk);
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if (ret) {
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dev_err(&pdev->dev, "failed to enable clock\n");
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goto err_platform_device_put;
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}
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musb->dev.parent = &pdev->dev;
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glue->dev = &pdev->dev;
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glue->musb = musb;
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glue->clk = clk;
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return 0;
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err_platform_device_put:
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platform_device_put(musb);
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return ret;
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}
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</programlisting>
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<para>
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The first few lines of the probe function allocate and assign the
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glue, musb and clk variables. The GFP_KERNEL flag (line 8) allows
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the allocation process to sleep and wait for memory, thus being
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usable in a blocking situation. The PLATFORM_DEVID_AUTO flag (line
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12) allows automatic allocation and management of device IDs in
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order to avoid device namespace collisions with explicit IDs. With
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devm_clk_get() (line 18) the glue layer allocates the clock -- the
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<literal>devm_</literal> prefix indicates that clk_get() is
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managed: it automatically frees the allocated clock resource data
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when the device is released -- and enable it.
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</para>
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<para>
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Then comes the registration steps:
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</para>
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<programlisting linenumbering="numbered">
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static int jz4740_probe(struct platform_device *pdev)
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{
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struct musb_hdrc_platform_data *pdata = &jz4740_musb_platform_data;
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pdata->platform_ops = &jz4740_musb_ops;
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platform_set_drvdata(pdev, glue);
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ret = platform_device_add_resources(musb, pdev->resource,
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pdev->num_resources);
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if (ret) {
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dev_err(&pdev->dev, "failed to add resources\n");
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goto err_clk_disable;
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}
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ret = platform_device_add_data(musb, pdata, sizeof(*pdata));
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if (ret) {
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dev_err(&pdev->dev, "failed to add platform_data\n");
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goto err_clk_disable;
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}
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return 0;
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err_clk_disable:
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clk_disable_unprepare(clk);
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err_platform_device_put:
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platform_device_put(musb);
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return ret;
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}
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</programlisting>
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<para>
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The first step is to pass the device data privately held by the
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glue layer on to the controller driver through
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platform_set_drvdata() (line 7). Next is passing on the device
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resources information, also privately held at that point, through
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platform_device_add_resources() (line 9).
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</para>
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<para>
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Finally comes passing on the platform specific data to the
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controller driver (line 16). Platform data will be discussed in
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<link linkend="device-platform-data">Chapter 4</link>, but here
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we are looking at the platform_ops function pointer (line 5) in
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musb_hdrc_platform_data structure (line 3). This function
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pointer allows the MUSB controller driver to know which function
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to call for device operation:
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</para>
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<programlisting linenumbering="numbered">
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static const struct musb_platform_ops jz4740_musb_ops = {
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.init = jz4740_musb_init,
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.exit = jz4740_musb_exit,
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};
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</programlisting>
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<para>
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Here we have the minimal case where only init and exit functions
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are called by the controller driver when needed. Fact is the
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JZ4740 MUSB controller is a basic controller, lacking some
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features found in other controllers, otherwise we may also have
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pointers to a few other functions like a power management function
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or a function to switch between OTG and non-OTG modes, for
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instance.
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</para>
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<para>
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At that point of the registration process, the controller driver
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actually calls the init function:
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</para>
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<programlisting linenumbering="numbered">
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static int jz4740_musb_init(struct musb *musb)
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{
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musb->xceiv = usb_get_phy(USB_PHY_TYPE_USB2);
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if (!musb->xceiv) {
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pr_err("HS UDC: no transceiver configured\n");
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return -ENODEV;
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}
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/* Silicon does not implement ConfigData register.
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* Set dyn_fifo to avoid reading EP config from hardware.
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*/
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musb->dyn_fifo = true;
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musb->isr = jz4740_musb_interrupt;
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return 0;
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}
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</programlisting>
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<para>
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The goal of jz4740_musb_init() is to get hold of the transceiver
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driver data of the MUSB controller hardware and pass it on to the
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MUSB controller driver, as usual. The transceiver is the circuitry
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inside the controller hardware responsible for sending/receiving
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the USB data. Since it is an implementation of the physical layer
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of the OSI model, the transceiver is also referred to as PHY.
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</para>
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<para>
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Getting hold of the MUSB PHY driver data is done with
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usb_get_phy() which returns a pointer to the structure
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containing the driver instance data. The next couple of
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instructions (line 12 and 14) are used as a quirk and to setup
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IRQ handling respectively. Quirks and IRQ handling will be
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discussed later in <link linkend="device-quirks">Chapter
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5</link> and <link linkend="handling-irqs">Chapter 3</link>.
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</para>
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<programlisting linenumbering="numbered">
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static int jz4740_musb_exit(struct musb *musb)
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{
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usb_put_phy(musb->xceiv);
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return 0;
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}
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</programlisting>
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<para>
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Acting as the counterpart of init, the exit function releases the
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MUSB PHY driver when the controller hardware itself is about to be
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released.
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</para>
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<para>
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Again, note that init and exit are fairly simple in this case due
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to the basic set of features of the JZ4740 controller hardware.
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When writing an musb glue layer for a more complex controller
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hardware, you might need to take care of more processing in those
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two functions.
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</para>
|
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<para>
|
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Returning from the init function, the MUSB controller driver jumps
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back into the probe function:
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</para>
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<programlisting linenumbering="numbered">
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static int jz4740_probe(struct platform_device *pdev)
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{
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ret = platform_device_add(musb);
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if (ret) {
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dev_err(&pdev->dev, "failed to register musb device\n");
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goto err_clk_disable;
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}
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|
|
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return 0;
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err_clk_disable:
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clk_disable_unprepare(clk);
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err_platform_device_put:
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platform_device_put(musb);
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return ret;
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}
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|
</programlisting>
|
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|
<para>
|
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|
This is the last part of the device registration process where the
|
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|
glue layer adds the controller hardware device to Linux kernel
|
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|
device hierarchy: at this stage, all known information about the
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|
device is passed on to the Linux USB core stack.
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|
</para>
|
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|
<programlisting linenumbering="numbered">
|
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|
static int jz4740_remove(struct platform_device *pdev)
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{
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struct jz4740_glue *glue = platform_get_drvdata(pdev);
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|
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platform_device_unregister(glue->musb);
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clk_disable_unprepare(glue->clk);
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return 0;
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}
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|
</programlisting>
|
||
|
<para>
|
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|
Acting as the counterpart of probe, the remove function unregister
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the MUSB controller hardware (line 5) and disable the clock (line
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|
6), allowing it to be gated.
|
||
|
</para>
|
||
|
</chapter>
|
||
|
|
||
|
<chapter id="handling-irqs">
|
||
|
<title>Handling IRQs</title>
|
||
|
<para>
|
||
|
Additionally to the MUSB controller hardware basic setup and
|
||
|
registration, the glue layer is also responsible for handling the
|
||
|
IRQs:
|
||
|
</para>
|
||
|
<programlisting linenumbering="numbered">
|
||
|
static irqreturn_t jz4740_musb_interrupt(int irq, void *__hci)
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|
{
|
||
|
unsigned long flags;
|
||
|
irqreturn_t retval = IRQ_NONE;
|
||
|
struct musb *musb = __hci;
|
||
|
|
||
|
spin_lock_irqsave(&musb->lock, flags);
|
||
|
|
||
|
musb->int_usb = musb_readb(musb->mregs, MUSB_INTRUSB);
|
||
|
musb->int_tx = musb_readw(musb->mregs, MUSB_INTRTX);
|
||
|
musb->int_rx = musb_readw(musb->mregs, MUSB_INTRRX);
|
||
|
|
||
|
/*
|
||
|
* The controller is gadget only, the state of the host mode IRQ bits is
|
||
|
* undefined. Mask them to make sure that the musb driver core will
|
||
|
* never see them set
|
||
|
*/
|
||
|
musb->int_usb &= MUSB_INTR_SUSPEND | MUSB_INTR_RESUME |
|
||
|
MUSB_INTR_RESET | MUSB_INTR_SOF;
|
||
|
|
||
|
if (musb->int_usb || musb->int_tx || musb->int_rx)
|
||
|
retval = musb_interrupt(musb);
|
||
|
|
||
|
spin_unlock_irqrestore(&musb->lock, flags);
|
||
|
|
||
|
return retval;
|
||
|
}
|
||
|
</programlisting>
|
||
|
<para>
|
||
|
Here the glue layer mostly has to read the relevant hardware
|
||
|
registers and pass their values on to the controller driver which
|
||
|
will handle the actual event that triggered the IRQ.
|
||
|
</para>
|
||
|
<para>
|
||
|
The interrupt handler critical section is protected by the
|
||
|
spin_lock_irqsave() and counterpart spin_unlock_irqrestore()
|
||
|
functions (line 7 and 24 respectively), which prevent the
|
||
|
interrupt handler code to be run by two different threads at the
|
||
|
same time.
|
||
|
</para>
|
||
|
<para>
|
||
|
Then the relevant interrupt registers are read (line 9 to 11):
|
||
|
</para>
|
||
|
<itemizedlist>
|
||
|
<listitem>
|
||
|
<para>
|
||
|
MUSB_INTRUSB: indicates which USB interrupts are currently
|
||
|
active,
|
||
|
</para>
|
||
|
</listitem>
|
||
|
<listitem>
|
||
|
<para>
|
||
|
MUSB_INTRTX: indicates which of the interrupts for TX
|
||
|
endpoints are currently active,
|
||
|
</para>
|
||
|
</listitem>
|
||
|
<listitem>
|
||
|
<para>
|
||
|
MUSB_INTRRX: indicates which of the interrupts for TX
|
||
|
endpoints are currently active.
|
||
|
</para>
|
||
|
</listitem>
|
||
|
</itemizedlist>
|
||
|
<para>
|
||
|
Note that musb_readb() is used to read 8-bit registers at most,
|
||
|
while musb_readw() allows us to read at most 16-bit registers.
|
||
|
There are other functions that can be used depending on the size
|
||
|
of your device registers. See musb_io.h for more information.
|
||
|
</para>
|
||
|
<para>
|
||
|
Instruction on line 18 is another quirk specific to the JZ4740
|
||
|
USB device controller, which will be discussed later in <link
|
||
|
linkend="device-quirks">Chapter 5</link>.
|
||
|
</para>
|
||
|
<para>
|
||
|
The glue layer still needs to register the IRQ handler though.
|
||
|
Remember the instruction on line 14 of the init function:
|
||
|
</para>
|
||
|
<programlisting linenumbering="numbered">
|
||
|
static int jz4740_musb_init(struct musb *musb)
|
||
|
{
|
||
|
musb->isr = jz4740_musb_interrupt;
|
||
|
|
||
|
return 0;
|
||
|
}
|
||
|
</programlisting>
|
||
|
<para>
|
||
|
This instruction sets a pointer to the glue layer IRQ handler
|
||
|
function, in order for the controller hardware to call the handler
|
||
|
back when an IRQ comes from the controller hardware. The interrupt
|
||
|
handler is now implemented and registered.
|
||
|
</para>
|
||
|
</chapter>
|
||
|
|
||
|
<chapter id="device-platform-data">
|
||
|
<title>Device Platform Data</title>
|
||
|
<para>
|
||
|
In order to write an MUSB glue layer, you need to have some data
|
||
|
describing the hardware capabilities of your controller hardware,
|
||
|
which is called the platform data.
|
||
|
</para>
|
||
|
<para>
|
||
|
Platform data is specific to your hardware, though it may cover a
|
||
|
broad range of devices, and is generally found somewhere in the
|
||
|
arch/ directory, depending on your device architecture.
|
||
|
</para>
|
||
|
<para>
|
||
|
For instance, platform data for the JZ4740 SoC is found in
|
||
|
arch/mips/jz4740/platform.c. In the platform.c file each device of
|
||
|
the JZ4740 SoC is described through a set of structures.
|
||
|
</para>
|
||
|
<para>
|
||
|
Here is the part of arch/mips/jz4740/platform.c that covers the
|
||
|
USB Device Controller (UDC):
|
||
|
</para>
|
||
|
<programlisting linenumbering="numbered">
|
||
|
/* USB Device Controller */
|
||
|
struct platform_device jz4740_udc_xceiv_device = {
|
||
|
.name = "usb_phy_gen_xceiv",
|
||
|
.id = 0,
|
||
|
};
|
||
|
|
||
|
static struct resource jz4740_udc_resources[] = {
|
||
|
[0] = {
|
||
|
.start = JZ4740_UDC_BASE_ADDR,
|
||
|
.end = JZ4740_UDC_BASE_ADDR + 0x10000 - 1,
|
||
|
.flags = IORESOURCE_MEM,
|
||
|
},
|
||
|
[1] = {
|
||
|
.start = JZ4740_IRQ_UDC,
|
||
|
.end = JZ4740_IRQ_UDC,
|
||
|
.flags = IORESOURCE_IRQ,
|
||
|
.name = "mc",
|
||
|
},
|
||
|
};
|
||
|
|
||
|
struct platform_device jz4740_udc_device = {
|
||
|
.name = "musb-jz4740",
|
||
|
.id = -1,
|
||
|
.dev = {
|
||
|
.dma_mask = &jz4740_udc_device.dev.coherent_dma_mask,
|
||
|
.coherent_dma_mask = DMA_BIT_MASK(32),
|
||
|
},
|
||
|
.num_resources = ARRAY_SIZE(jz4740_udc_resources),
|
||
|
.resource = jz4740_udc_resources,
|
||
|
};
|
||
|
</programlisting>
|
||
|
<para>
|
||
|
The jz4740_udc_xceiv_device platform device structure (line 2)
|
||
|
describes the UDC transceiver with a name and id number.
|
||
|
</para>
|
||
|
<para>
|
||
|
At the time of this writing, note that
|
||
|
"usb_phy_gen_xceiv" is the specific name to be used for
|
||
|
all transceivers that are either built-in with reference USB IP or
|
||
|
autonomous and doesn't require any PHY programming. You will need
|
||
|
to set CONFIG_NOP_USB_XCEIV=y in the kernel configuration to make
|
||
|
use of the corresponding transceiver driver. The id field could be
|
||
|
set to -1 (equivalent to PLATFORM_DEVID_NONE), -2 (equivalent to
|
||
|
PLATFORM_DEVID_AUTO) or start with 0 for the first device of this
|
||
|
kind if we want a specific id number.
|
||
|
</para>
|
||
|
<para>
|
||
|
The jz4740_udc_resources resource structure (line 7) defines the
|
||
|
UDC registers base addresses.
|
||
|
</para>
|
||
|
<para>
|
||
|
The first array (line 9 to 11) defines the UDC registers base
|
||
|
memory addresses: start points to the first register memory
|
||
|
address, end points to the last register memory address and the
|
||
|
flags member defines the type of resource we are dealing with. So
|
||
|
IORESOURCE_MEM is used to define the registers memory addresses.
|
||
|
The second array (line 14 to 17) defines the UDC IRQ registers
|
||
|
addresses. Since there is only one IRQ register available for the
|
||
|
JZ4740 UDC, start and end point at the same address. The
|
||
|
IORESOURCE_IRQ flag tells that we are dealing with IRQ resources,
|
||
|
and the name "mc" is in fact hard-coded in the MUSB core
|
||
|
in order for the controller driver to retrieve this IRQ resource
|
||
|
by querying it by its name.
|
||
|
</para>
|
||
|
<para>
|
||
|
Finally, the jz4740_udc_device platform device structure (line 21)
|
||
|
describes the UDC itself.
|
||
|
</para>
|
||
|
<para>
|
||
|
The "musb-jz4740" name (line 22) defines the MUSB
|
||
|
driver that is used for this device; remember this is in fact
|
||
|
the name that we used in the jz4740_driver platform driver
|
||
|
structure in <link linkend="linux-musb-basics">Chapter
|
||
|
2</link>. The id field (line 23) is set to -1 (equivalent to
|
||
|
PLATFORM_DEVID_NONE) since we do not need an id for the device:
|
||
|
the MUSB controller driver was already set to allocate an
|
||
|
automatic id in <link linkend="linux-musb-basics">Chapter
|
||
|
2</link>. In the dev field we care for DMA related information
|
||
|
here. The dma_mask field (line 25) defines the width of the DMA
|
||
|
mask that is going to be used, and coherent_dma_mask (line 26)
|
||
|
has the same purpose but for the alloc_coherent DMA mappings: in
|
||
|
both cases we are using a 32 bits mask. Then the resource field
|
||
|
(line 29) is simply a pointer to the resource structure defined
|
||
|
before, while the num_resources field (line 28) keeps track of
|
||
|
the number of arrays defined in the resource structure (in this
|
||
|
case there were two resource arrays defined before).
|
||
|
</para>
|
||
|
<para>
|
||
|
With this quick overview of the UDC platform data at the arch/
|
||
|
level now done, let's get back to the MUSB glue layer specific
|
||
|
platform data in drivers/usb/musb/jz4740.c:
|
||
|
</para>
|
||
|
<programlisting linenumbering="numbered">
|
||
|
static struct musb_hdrc_config jz4740_musb_config = {
|
||
|
/* Silicon does not implement USB OTG. */
|
||
|
.multipoint = 0,
|
||
|
/* Max EPs scanned, driver will decide which EP can be used. */
|
||
|
.num_eps = 4,
|
||
|
/* RAMbits needed to configure EPs from table */
|
||
|
.ram_bits = 9,
|
||
|
.fifo_cfg = jz4740_musb_fifo_cfg,
|
||
|
.fifo_cfg_size = ARRAY_SIZE(jz4740_musb_fifo_cfg),
|
||
|
};
|
||
|
|
||
|
static struct musb_hdrc_platform_data jz4740_musb_platform_data = {
|
||
|
.mode = MUSB_PERIPHERAL,
|
||
|
.config = &jz4740_musb_config,
|
||
|
};
|
||
|
</programlisting>
|
||
|
<para>
|
||
|
First the glue layer configures some aspects of the controller
|
||
|
driver operation related to the controller hardware specifics.
|
||
|
This is done through the jz4740_musb_config musb_hdrc_config
|
||
|
structure.
|
||
|
</para>
|
||
|
<para>
|
||
|
Defining the OTG capability of the controller hardware, the
|
||
|
multipoint member (line 3) is set to 0 (equivalent to false)
|
||
|
since the JZ4740 UDC is not OTG compatible. Then num_eps (line
|
||
|
5) defines the number of USB endpoints of the controller
|
||
|
hardware, including endpoint 0: here we have 3 endpoints +
|
||
|
endpoint 0. Next is ram_bits (line 7) which is the width of the
|
||
|
RAM address bus for the MUSB controller hardware. This
|
||
|
information is needed when the controller driver cannot
|
||
|
automatically configure endpoints by reading the relevant
|
||
|
controller hardware registers. This issue will be discussed when
|
||
|
we get to device quirks in <link linkend="device-quirks">Chapter
|
||
|
5</link>. Last two fields (line 8 and 9) are also about device
|
||
|
quirks: fifo_cfg points to the USB endpoints configuration table
|
||
|
and fifo_cfg_size keeps track of the size of the number of
|
||
|
entries in that configuration table. More on that later in <link
|
||
|
linkend="device-quirks">Chapter 5</link>.
|
||
|
</para>
|
||
|
<para>
|
||
|
Then this configuration is embedded inside
|
||
|
jz4740_musb_platform_data musb_hdrc_platform_data structure (line
|
||
|
11): config is a pointer to the configuration structure itself,
|
||
|
and mode tells the controller driver if the controller hardware
|
||
|
may be used as MUSB_HOST only, MUSB_PERIPHERAL only or MUSB_OTG
|
||
|
which is a dual mode.
|
||
|
</para>
|
||
|
<para>
|
||
|
Remember that jz4740_musb_platform_data is then used to convey
|
||
|
platform data information as we have seen in the probe function
|
||
|
in <link linkend="linux-musb-basics">Chapter 2</link>
|
||
|
</para>
|
||
|
</chapter>
|
||
|
|
||
|
<chapter id="device-quirks">
|
||
|
<title>Device Quirks</title>
|
||
|
<para>
|
||
|
Completing the platform data specific to your device, you may also
|
||
|
need to write some code in the glue layer to work around some
|
||
|
device specific limitations. These quirks may be due to some
|
||
|
hardware bugs, or simply be the result of an incomplete
|
||
|
implementation of the USB On-the-Go specification.
|
||
|
</para>
|
||
|
<para>
|
||
|
The JZ4740 UDC exhibits such quirks, some of which we will discuss
|
||
|
here for the sake of insight even though these might not be found
|
||
|
in the controller hardware you are working on.
|
||
|
</para>
|
||
|
<para>
|
||
|
Let's get back to the init function first:
|
||
|
</para>
|
||
|
<programlisting linenumbering="numbered">
|
||
|
static int jz4740_musb_init(struct musb *musb)
|
||
|
{
|
||
|
musb->xceiv = usb_get_phy(USB_PHY_TYPE_USB2);
|
||
|
if (!musb->xceiv) {
|
||
|
pr_err("HS UDC: no transceiver configured\n");
|
||
|
return -ENODEV;
|
||
|
}
|
||
|
|
||
|
/* Silicon does not implement ConfigData register.
|
||
|
* Set dyn_fifo to avoid reading EP config from hardware.
|
||
|
*/
|
||
|
musb->dyn_fifo = true;
|
||
|
|
||
|
musb->isr = jz4740_musb_interrupt;
|
||
|
|
||
|
return 0;
|
||
|
}
|
||
|
</programlisting>
|
||
|
<para>
|
||
|
Instruction on line 12 helps the MUSB controller driver to work
|
||
|
around the fact that the controller hardware is missing registers
|
||
|
that are used for USB endpoints configuration.
|
||
|
</para>
|
||
|
<para>
|
||
|
Without these registers, the controller driver is unable to read
|
||
|
the endpoints configuration from the hardware, so we use line 12
|
||
|
instruction to bypass reading the configuration from silicon, and
|
||
|
rely on a hard-coded table that describes the endpoints
|
||
|
configuration instead:
|
||
|
</para>
|
||
|
<programlisting linenumbering="numbered">
|
||
|
static struct musb_fifo_cfg jz4740_musb_fifo_cfg[] = {
|
||
|
{ .hw_ep_num = 1, .style = FIFO_TX, .maxpacket = 512, },
|
||
|
{ .hw_ep_num = 1, .style = FIFO_RX, .maxpacket = 512, },
|
||
|
{ .hw_ep_num = 2, .style = FIFO_TX, .maxpacket = 64, },
|
||
|
};
|
||
|
</programlisting>
|
||
|
<para>
|
||
|
Looking at the configuration table above, we see that each
|
||
|
endpoints is described by three fields: hw_ep_num is the endpoint
|
||
|
number, style is its direction (either FIFO_TX for the controller
|
||
|
driver to send packets in the controller hardware, or FIFO_RX to
|
||
|
receive packets from hardware), and maxpacket defines the maximum
|
||
|
size of each data packet that can be transmitted over that
|
||
|
endpoint. Reading from the table, the controller driver knows that
|
||
|
endpoint 1 can be used to send and receive USB data packets of 512
|
||
|
bytes at once (this is in fact a bulk in/out endpoint), and
|
||
|
endpoint 2 can be used to send data packets of 64 bytes at once
|
||
|
(this is in fact an interrupt endpoint).
|
||
|
</para>
|
||
|
<para>
|
||
|
Note that there is no information about endpoint 0 here: that one
|
||
|
is implemented by default in every silicon design, with a
|
||
|
predefined configuration according to the USB specification. For
|
||
|
more examples of endpoint configuration tables, see musb_core.c.
|
||
|
</para>
|
||
|
<para>
|
||
|
Let's now get back to the interrupt handler function:
|
||
|
</para>
|
||
|
<programlisting linenumbering="numbered">
|
||
|
static irqreturn_t jz4740_musb_interrupt(int irq, void *__hci)
|
||
|
{
|
||
|
unsigned long flags;
|
||
|
irqreturn_t retval = IRQ_NONE;
|
||
|
struct musb *musb = __hci;
|
||
|
|
||
|
spin_lock_irqsave(&musb->lock, flags);
|
||
|
|
||
|
musb->int_usb = musb_readb(musb->mregs, MUSB_INTRUSB);
|
||
|
musb->int_tx = musb_readw(musb->mregs, MUSB_INTRTX);
|
||
|
musb->int_rx = musb_readw(musb->mregs, MUSB_INTRRX);
|
||
|
|
||
|
/*
|
||
|
* The controller is gadget only, the state of the host mode IRQ bits is
|
||
|
* undefined. Mask them to make sure that the musb driver core will
|
||
|
* never see them set
|
||
|
*/
|
||
|
musb->int_usb &= MUSB_INTR_SUSPEND | MUSB_INTR_RESUME |
|
||
|
MUSB_INTR_RESET | MUSB_INTR_SOF;
|
||
|
|
||
|
if (musb->int_usb || musb->int_tx || musb->int_rx)
|
||
|
retval = musb_interrupt(musb);
|
||
|
|
||
|
spin_unlock_irqrestore(&musb->lock, flags);
|
||
|
|
||
|
return retval;
|
||
|
}
|
||
|
</programlisting>
|
||
|
<para>
|
||
|
Instruction on line 18 above is a way for the controller driver to
|
||
|
work around the fact that some interrupt bits used for USB host
|
||
|
mode operation are missing in the MUSB_INTRUSB register, thus left
|
||
|
in an undefined hardware state, since this MUSB controller
|
||
|
hardware is used in peripheral mode only. As a consequence, the
|
||
|
glue layer masks these missing bits out to avoid parasite
|
||
|
interrupts by doing a logical AND operation between the value read
|
||
|
from MUSB_INTRUSB and the bits that are actually implemented in
|
||
|
the register.
|
||
|
</para>
|
||
|
<para>
|
||
|
These are only a couple of the quirks found in the JZ4740 USB
|
||
|
device controller. Some others were directly addressed in the MUSB
|
||
|
core since the fixes were generic enough to provide a better
|
||
|
handling of the issues for others controller hardware eventually.
|
||
|
</para>
|
||
|
</chapter>
|
||
|
|
||
|
<chapter id="conclusion">
|
||
|
<title>Conclusion</title>
|
||
|
<para>
|
||
|
Writing a Linux MUSB glue layer should be a more accessible task,
|
||
|
as this documentation tries to show the ins and outs of this
|
||
|
exercise.
|
||
|
</para>
|
||
|
<para>
|
||
|
The JZ4740 USB device controller being fairly simple, I hope its
|
||
|
glue layer serves as a good example for the curious mind. Used
|
||
|
with the current MUSB glue layers, this documentation should
|
||
|
provide enough guidance to get started; should anything gets out
|
||
|
of hand, the linux-usb mailing list archive is another helpful
|
||
|
resource to browse through.
|
||
|
</para>
|
||
|
</chapter>
|
||
|
|
||
|
<chapter id="acknowledgements">
|
||
|
<title>Acknowledgements</title>
|
||
|
<para>
|
||
|
Many thanks to Lars-Peter Clausen and Maarten ter Huurne for
|
||
|
answering my questions while I was writing the JZ4740 glue layer
|
||
|
and for helping me out getting the code in good shape.
|
||
|
</para>
|
||
|
<para>
|
||
|
I would also like to thank the Qi-Hardware community at large for
|
||
|
its cheerful guidance and support.
|
||
|
</para>
|
||
|
</chapter>
|
||
|
|
||
|
<chapter id="resources">
|
||
|
<title>Resources</title>
|
||
|
<para>
|
||
|
USB Home Page:
|
||
|
<ulink url="http://www.usb.org">http://www.usb.org</ulink>
|
||
|
</para>
|
||
|
<para>
|
||
|
linux-usb Mailing List Archives:
|
||
|
<ulink url="http://marc.info/?l=linux-usb">http://marc.info/?l=linux-usb</ulink>
|
||
|
</para>
|
||
|
<para>
|
||
|
USB On-the-Go Basics:
|
||
|
<ulink url="http://www.maximintegrated.com/app-notes/index.mvp/id/1822">http://www.maximintegrated.com/app-notes/index.mvp/id/1822</ulink>
|
||
|
</para>
|
||
|
<para>
|
||
|
Writing USB Device Drivers:
|
||
|
<ulink url="https://www.kernel.org/doc/htmldocs/writing_usb_driver/index.html">https://www.kernel.org/doc/htmldocs/writing_usb_driver/index.html</ulink>
|
||
|
</para>
|
||
|
<para>
|
||
|
Texas Instruments USB Configuration Wiki Page:
|
||
|
<ulink url="http://processors.wiki.ti.com/index.php/Usbgeneralpage">http://processors.wiki.ti.com/index.php/Usbgeneralpage</ulink>
|
||
|
</para>
|
||
|
<para>
|
||
|
Analog Devices Blackfin MUSB Configuration:
|
||
|
<ulink url="http://docs.blackfin.uclinux.org/doku.php?id=linux-kernel:drivers:musb">http://docs.blackfin.uclinux.org/doku.php?id=linux-kernel:drivers:musb</ulink>
|
||
|
</para>
|
||
|
</chapter>
|
||
|
|
||
|
</book>
|