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e160f7d430
At present devices use a simple integer offset to record the device tree node associated with the device. In preparation for supporting a live device tree, which uses a node pointer instead, refactor existing code to access this field through an inline function. Signed-off-by: Simon Glass <sjg@chromium.org>
628 lines
18 KiB
Text
628 lines
18 KiB
Text
How to port a SPI driver to driver model
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========================================
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Here is a rough step-by-step guide. It is based around converting the
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exynos SPI driver to driver model (DM) and the example code is based
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around U-Boot v2014.10-rc2 (commit be9f643). This has been updated for
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v2015.04.
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It is quite long since it includes actual code examples.
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Before driver model, SPI drivers have their own private structure which
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contains 'struct spi_slave'. With driver model, 'struct spi_slave' still
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exists, but now it is 'per-child data' for the SPI bus. Each child of the
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SPI bus is a SPI slave. The information that was stored in the
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driver-specific slave structure can now be port in private data for the
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SPI bus.
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For example, struct tegra_spi_slave looks like this:
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struct tegra_spi_slave {
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struct spi_slave slave;
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struct tegra_spi_ctrl *ctrl;
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};
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In this case 'slave' will be in per-child data, and 'ctrl' will be in the
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SPI's buses private data.
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0. How long does this take?
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You should be able to complete this within 2 hours, including testing but
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excluding preparing the patches. The API is basically the same as before
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with only minor changes:
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- methods to set speed and mode are separated out
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- cs_info is used to get information on a chip select
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1. Enable driver mode for SPI and SPI flash
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Add these to your board config:
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CONFIG_DM_SPI
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CONFIG_DM_SPI_FLASH
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2. Add the skeleton
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Put this code at the bottom of your existing driver file:
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struct spi_slave *spi_setup_slave(unsigned int busnum, unsigned int cs,
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unsigned int max_hz, unsigned int mode)
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{
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return NULL;
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}
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struct spi_slave *spi_setup_slave_fdt(const void *blob, int slave_node,
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int spi_node)
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{
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return NULL;
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}
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static int exynos_spi_ofdata_to_platdata(struct udevice *dev)
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{
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return -ENODEV;
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}
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static int exynos_spi_probe(struct udevice *dev)
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{
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return -ENODEV;
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}
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static int exynos_spi_remove(struct udevice *dev)
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{
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return -ENODEV;
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}
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static int exynos_spi_claim_bus(struct udevice *dev)
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{
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return -ENODEV;
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}
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static int exynos_spi_release_bus(struct udevice *dev)
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{
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return -ENODEV;
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}
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static int exynos_spi_xfer(struct udevice *dev, unsigned int bitlen,
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const void *dout, void *din, unsigned long flags)
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{
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return -ENODEV;
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}
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static int exynos_spi_set_speed(struct udevice *dev, uint speed)
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{
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return -ENODEV;
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}
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static int exynos_spi_set_mode(struct udevice *dev, uint mode)
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{
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return -ENODEV;
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}
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static int exynos_cs_info(struct udevice *bus, uint cs,
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struct spi_cs_info *info)
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{
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return -ENODEV;
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}
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static const struct dm_spi_ops exynos_spi_ops = {
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.claim_bus = exynos_spi_claim_bus,
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.release_bus = exynos_spi_release_bus,
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.xfer = exynos_spi_xfer,
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.set_speed = exynos_spi_set_speed,
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.set_mode = exynos_spi_set_mode,
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.cs_info = exynos_cs_info,
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};
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static const struct udevice_id exynos_spi_ids[] = {
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{ .compatible = "samsung,exynos-spi" },
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{ }
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};
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U_BOOT_DRIVER(exynos_spi) = {
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.name = "exynos_spi",
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.id = UCLASS_SPI,
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.of_match = exynos_spi_ids,
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.ops = &exynos_spi_ops,
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.ofdata_to_platdata = exynos_spi_ofdata_to_platdata,
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.probe = exynos_spi_probe,
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.remove = exynos_spi_remove,
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};
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3. Replace 'exynos' in the above code with your driver name
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4. #ifdef out all of the code in your driver except for the above
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This will allow you to get it building, which means you can work
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incrementally. Since all the methods return an error initially, there is
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less chance that you will accidentally leave something in.
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Also, even though your conversion is basically a rewrite, it might help
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reviewers if you leave functions in the same place in the file,
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particularly for large drivers.
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5. Add some includes
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Add these includes to your driver:
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#include <dm.h>
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#include <errno.h>
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6. Build
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At this point you should be able to build U-Boot for your board with the
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empty SPI driver. You still have empty methods in your driver, but we will
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write these one by one.
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If you have spi_init() functions or the like that are called from your
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board then the build will fail. Remove these calls and make a note of the
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init that needs to be done.
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7. Set up your platform data structure
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This will hold the information your driver to operate, like its hardware
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address or maximum frequency.
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You may already have a struct like this, or you may need to create one
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from some of the #defines or global variables in the driver.
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Note that this information is not the run-time information. It should not
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include state that changes. It should be fixed throughout the live of
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U-Boot. Run-time information comes later.
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Here is what was in the exynos spi driver:
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struct spi_bus {
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enum periph_id periph_id;
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s32 frequency; /* Default clock frequency, -1 for none */
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struct exynos_spi *regs;
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int inited; /* 1 if this bus is ready for use */
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int node;
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uint deactivate_delay_us; /* Delay to wait after deactivate */
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};
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Of these, inited is handled by DM and node is the device tree node, which
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DM tells you. The name is not quite right. So in this case we would use:
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struct exynos_spi_platdata {
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enum periph_id periph_id;
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s32 frequency; /* Default clock frequency, -1 for none */
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struct exynos_spi *regs;
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uint deactivate_delay_us; /* Delay to wait after deactivate */
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};
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8a. Write ofdata_to_platdata() [for device tree only]
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This method will convert information in the device tree node into a C
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structure in your driver (called platform data). If you are not using
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device tree, go to 8b.
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DM will automatically allocate the struct for us when we are using device
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tree, but we need to tell it the size:
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U_BOOT_DRIVER(spi_exynos) = {
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...
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.platdata_auto_alloc_size = sizeof(struct exynos_spi_platdata),
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Here is a sample function. It gets a pointer to the platform data and
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fills in the fields from device tree.
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static int exynos_spi_ofdata_to_platdata(struct udevice *bus)
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{
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struct exynos_spi_platdata *plat = bus->platdata;
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const void *blob = gd->fdt_blob;
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int node = dev_of_offset(bus);
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plat->regs = (struct exynos_spi *)fdtdec_get_addr(blob, node, "reg");
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plat->periph_id = pinmux_decode_periph_id(blob, node);
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if (plat->periph_id == PERIPH_ID_NONE) {
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debug("%s: Invalid peripheral ID %d\n", __func__,
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plat->periph_id);
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return -FDT_ERR_NOTFOUND;
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}
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/* Use 500KHz as a suitable default */
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plat->frequency = fdtdec_get_int(blob, node, "spi-max-frequency",
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500000);
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plat->deactivate_delay_us = fdtdec_get_int(blob, node,
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"spi-deactivate-delay", 0);
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debug("%s: regs=%p, periph_id=%d, max-frequency=%d, deactivate_delay=%d\n",
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__func__, plat->regs, plat->periph_id, plat->frequency,
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plat->deactivate_delay_us);
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return 0;
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}
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8b. Add the platform data [non-device-tree only]
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Specify this data in a U_BOOT_DEVICE() declaration in your board file:
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struct exynos_spi_platdata platdata_spi0 = {
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.periph_id = ...
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.frequency = ...
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.regs = ...
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.deactivate_delay_us = ...
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};
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U_BOOT_DEVICE(board_spi0) = {
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.name = "exynos_spi",
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.platdata = &platdata_spi0,
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};
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You will unfortunately need to put the struct definition into a header file
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in this case so that your board file can use it.
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9. Add the device private data
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Most devices have some private data which they use to keep track of things
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while active. This is the run-time information and needs to be stored in
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a structure. There is probably a structure in the driver that includes a
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'struct spi_slave', so you can use that.
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struct exynos_spi_slave {
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struct spi_slave slave;
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struct exynos_spi *regs;
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unsigned int freq; /* Default frequency */
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unsigned int mode;
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enum periph_id periph_id; /* Peripheral ID for this device */
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unsigned int fifo_size;
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int skip_preamble;
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struct spi_bus *bus; /* Pointer to our SPI bus info */
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ulong last_transaction_us; /* Time of last transaction end */
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};
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We should rename this to make its purpose more obvious, and get rid of
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the slave structure, so we have:
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struct exynos_spi_priv {
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struct exynos_spi *regs;
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unsigned int freq; /* Default frequency */
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unsigned int mode;
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enum periph_id periph_id; /* Peripheral ID for this device */
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unsigned int fifo_size;
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int skip_preamble;
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ulong last_transaction_us; /* Time of last transaction end */
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};
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DM can auto-allocate this also:
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U_BOOT_DRIVER(spi_exynos) = {
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...
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.priv_auto_alloc_size = sizeof(struct exynos_spi_priv),
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Note that this is created before the probe method is called, and destroyed
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after the remove method is called. It will be zeroed when the probe
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method is called.
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10. Add the probe() and remove() methods
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Note: It's a good idea to build repeatedly as you are working, to avoid a
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huge amount of work getting things compiling at the end.
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The probe method is supposed to set up the hardware. U-Boot used to use
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spi_setup_slave() to do this. So take a look at this function and see
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what you can copy out to set things up.
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static int exynos_spi_probe(struct udevice *bus)
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{
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struct exynos_spi_platdata *plat = dev_get_platdata(bus);
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struct exynos_spi_priv *priv = dev_get_priv(bus);
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priv->regs = plat->regs;
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if (plat->periph_id == PERIPH_ID_SPI1 ||
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plat->periph_id == PERIPH_ID_SPI2)
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priv->fifo_size = 64;
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else
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priv->fifo_size = 256;
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priv->skip_preamble = 0;
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priv->last_transaction_us = timer_get_us();
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priv->freq = plat->frequency;
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priv->periph_id = plat->periph_id;
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return 0;
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}
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This implementation doesn't actually touch the hardware, which is somewhat
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unusual for a driver. In this case we will do that when the device is
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claimed by something that wants to use the SPI bus.
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For remove we could shut down the clocks, but in this case there is
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nothing to do. DM frees any memory that it allocated, so we can just
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remove exynos_spi_remove() and its reference in U_BOOT_DRIVER.
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11. Implement set_speed()
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This should set up clocks so that the SPI bus is running at the right
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speed. With the old API spi_claim_bus() would normally do this and several
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of the following functions, so let's look at that function:
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int spi_claim_bus(struct spi_slave *slave)
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{
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struct exynos_spi_slave *spi_slave = to_exynos_spi(slave);
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struct exynos_spi *regs = spi_slave->regs;
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u32 reg = 0;
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int ret;
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ret = set_spi_clk(spi_slave->periph_id,
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spi_slave->freq);
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if (ret < 0) {
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debug("%s: Failed to setup spi clock\n", __func__);
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return ret;
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}
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exynos_pinmux_config(spi_slave->periph_id, PINMUX_FLAG_NONE);
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spi_flush_fifo(slave);
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reg = readl(®s->ch_cfg);
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reg &= ~(SPI_CH_CPHA_B | SPI_CH_CPOL_L);
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if (spi_slave->mode & SPI_CPHA)
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reg |= SPI_CH_CPHA_B;
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if (spi_slave->mode & SPI_CPOL)
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reg |= SPI_CH_CPOL_L;
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writel(reg, ®s->ch_cfg);
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writel(SPI_FB_DELAY_180, ®s->fb_clk);
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return 0;
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}
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It sets up the speed, mode, pinmux, feedback delay and clears the FIFOs.
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With DM these will happen in separate methods.
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Here is an example for the speed part:
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static int exynos_spi_set_speed(struct udevice *bus, uint speed)
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{
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struct exynos_spi_platdata *plat = bus->platdata;
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struct exynos_spi_priv *priv = dev_get_priv(bus);
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int ret;
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if (speed > plat->frequency)
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speed = plat->frequency;
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ret = set_spi_clk(priv->periph_id, speed);
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if (ret)
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return ret;
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priv->freq = speed;
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debug("%s: regs=%p, speed=%d\n", __func__, priv->regs, priv->freq);
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return 0;
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}
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12. Implement set_mode()
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This should adjust the SPI mode (polarity, etc.). Again this code probably
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comes from the old spi_claim_bus(). Here is an example:
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static int exynos_spi_set_mode(struct udevice *bus, uint mode)
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{
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struct exynos_spi_priv *priv = dev_get_priv(bus);
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uint32_t reg;
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reg = readl(&priv->regs->ch_cfg);
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reg &= ~(SPI_CH_CPHA_B | SPI_CH_CPOL_L);
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if (mode & SPI_CPHA)
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reg |= SPI_CH_CPHA_B;
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if (mode & SPI_CPOL)
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reg |= SPI_CH_CPOL_L;
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writel(reg, &priv->regs->ch_cfg);
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priv->mode = mode;
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debug("%s: regs=%p, mode=%d\n", __func__, priv->regs, priv->mode);
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return 0;
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}
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13. Implement claim_bus()
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This is where a client wants to make use of the bus, so claims it first.
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At this point we need to make sure everything is set up ready for data
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transfer. Note that this function is wholly internal to the driver - at
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present the SPI uclass never calls it.
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Here again we look at the old claim function and see some code that is
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needed. It is anything unrelated to speed and mode:
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static int exynos_spi_claim_bus(struct udevice *bus)
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{
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struct exynos_spi_priv *priv = dev_get_priv(bus);
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exynos_pinmux_config(priv->periph_id, PINMUX_FLAG_NONE);
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spi_flush_fifo(priv->regs);
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writel(SPI_FB_DELAY_180, &priv->regs->fb_clk);
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return 0;
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}
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The spi_flush_fifo() function is in the removed part of the code, so we
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need to expose it again (perhaps with an #endif before it and '#if 0'
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after it). It only needs access to priv->regs which is why we have
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passed that in:
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/**
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* Flush spi tx, rx fifos and reset the SPI controller
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*
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* @param regs Pointer to SPI registers
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*/
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static void spi_flush_fifo(struct exynos_spi *regs)
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{
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clrsetbits_le32(®s->ch_cfg, SPI_CH_HS_EN, SPI_CH_RST);
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clrbits_le32(®s->ch_cfg, SPI_CH_RST);
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setbits_le32(®s->ch_cfg, SPI_TX_CH_ON | SPI_RX_CH_ON);
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}
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14. Implement release_bus()
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This releases the bus - in our example the old code in spi_release_bus()
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is a call to spi_flush_fifo, so we add:
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static int exynos_spi_release_bus(struct udevice *bus)
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{
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struct exynos_spi_priv *priv = dev_get_priv(bus);
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spi_flush_fifo(priv->regs);
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return 0;
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}
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15. Implement xfer()
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This is the final method that we need to create, and it is where all the
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work happens. The method parameters are the same as the old spi_xfer() with
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the addition of a 'struct udevice' so conversion is pretty easy. Start
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by copying the contents of spi_xfer() to your new xfer() method and proceed
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from there.
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If (flags & SPI_XFER_BEGIN) is non-zero then xfer() normally calls an
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activate function, something like this:
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void spi_cs_activate(struct spi_slave *slave)
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{
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struct exynos_spi_slave *spi_slave = to_exynos_spi(slave);
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/* If it's too soon to do another transaction, wait */
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if (spi_slave->bus->deactivate_delay_us &&
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spi_slave->last_transaction_us) {
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ulong delay_us; /* The delay completed so far */
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delay_us = timer_get_us() - spi_slave->last_transaction_us;
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if (delay_us < spi_slave->bus->deactivate_delay_us)
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udelay(spi_slave->bus->deactivate_delay_us - delay_us);
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|
}
|
|
|
|
clrbits_le32(&spi_slave->regs->cs_reg, SPI_SLAVE_SIG_INACT);
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|
debug("Activate CS, bus %d\n", spi_slave->slave.bus);
|
|
spi_slave->skip_preamble = spi_slave->mode & SPI_PREAMBLE;
|
|
}
|
|
|
|
The new version looks like this:
|
|
|
|
static void spi_cs_activate(struct udevice *dev)
|
|
{
|
|
struct udevice *bus = dev->parent;
|
|
struct exynos_spi_platdata *pdata = dev_get_platdata(bus);
|
|
struct exynos_spi_priv *priv = dev_get_priv(bus);
|
|
|
|
/* If it's too soon to do another transaction, wait */
|
|
if (pdata->deactivate_delay_us &&
|
|
priv->last_transaction_us) {
|
|
ulong delay_us; /* The delay completed so far */
|
|
delay_us = timer_get_us() - priv->last_transaction_us;
|
|
if (delay_us < pdata->deactivate_delay_us)
|
|
udelay(pdata->deactivate_delay_us - delay_us);
|
|
}
|
|
|
|
clrbits_le32(&priv->regs->cs_reg, SPI_SLAVE_SIG_INACT);
|
|
debug("Activate CS, bus '%s'\n", bus->name);
|
|
priv->skip_preamble = priv->mode & SPI_PREAMBLE;
|
|
}
|
|
|
|
All we have really done here is change the pointers and print the device name
|
|
instead of the bus number. Other local static functions can be treated in
|
|
the same way.
|
|
|
|
|
|
16. Set up the per-child data and child pre-probe function
|
|
|
|
To minimise the pain and complexity of the SPI subsystem while the driver
|
|
model change-over is in place, struct spi_slave is used to reference a
|
|
SPI bus slave, even though that slave is actually a struct udevice. In fact
|
|
struct spi_slave is the device's child data. We need to make sure this space
|
|
is available. It is possible to allocate more space that struct spi_slave
|
|
needs, but this is the minimum.
|
|
|
|
U_BOOT_DRIVER(exynos_spi) = {
|
|
...
|
|
.per_child_auto_alloc_size = sizeof(struct spi_slave),
|
|
}
|
|
|
|
|
|
17. Optional: Set up cs_info() if you want it
|
|
|
|
Sometimes it is useful to know whether a SPI chip select is valid, but this
|
|
is not obvious from outside the driver. In this case you can provide a
|
|
method for cs_info() to deal with this. If you don't provide it, then the
|
|
device tree will be used to determine what chip selects are valid.
|
|
|
|
Return -ENODEV if the supplied chip select is invalid, or 0 if it is valid.
|
|
If you don't provide the cs_info() method, -ENODEV is assumed for all
|
|
chip selects that do not appear in the device tree.
|
|
|
|
|
|
18. Test it
|
|
|
|
Now that you have the code written and it compiles, try testing it using
|
|
the 'sf test' command. You may need to enable CONFIG_CMD_SF_TEST for your
|
|
board.
|
|
|
|
|
|
19. Prepare patches and send them to the mailing lists
|
|
|
|
You can use 'tools/patman/patman' to prepare, check and send patches for
|
|
your work. See the README for details.
|
|
|
|
20. A little note about SPI uclass features:
|
|
|
|
The SPI uclass keeps some information about each device 'dev' on the bus:
|
|
|
|
struct dm_spi_slave_platdata - this is device_get_parent_platdata(dev)
|
|
This is where the chip select number is stored, along with
|
|
the default bus speed and mode. It is automatically read
|
|
from the device tree in spi_child_post_bind(). It must not
|
|
be changed at run-time after being set up because platform
|
|
data is supposed to be immutable at run-time.
|
|
struct spi_slave - this is device_get_parentdata(dev)
|
|
Already mentioned above. It holds run-time information about
|
|
the device.
|
|
|
|
There are also some SPI uclass methods that get called behind the scenes:
|
|
|
|
spi_post_bind() - called when a new bus is bound
|
|
This scans the device tree for devices on the bus, and binds
|
|
each one. This in turn causes spi_child_post_bind() to be
|
|
called for each, which reads the device tree information
|
|
into the parent (per-child) platform data.
|
|
spi_child_post_bind() - called when a new child is bound
|
|
As mentioned above this reads the device tree information
|
|
into the per-child platform data
|
|
spi_child_pre_probe() - called before a new child is probed
|
|
This sets up the mode and speed in struct spi_slave by
|
|
copying it from the parent's platform data for this child.
|
|
It also sets the 'dev' pointer, needed to permit passing
|
|
'struct spi_slave' around the place without needing a
|
|
separate 'struct udevice' pointer.
|
|
|
|
The above housekeeping makes it easier to write your SPI driver.
|