u-boot/lib/acpi/acpi_device.c
Simon Glass caa4daa2ae dm: treewide: Rename 'platdata' variables to just 'plat'
We use 'priv' for private data but often use 'platdata' for platform data.
We can't really use 'pdata' since that is ambiguous (it could mean private
or platform data).

Rename some of the latter variables to end with 'plat' for consistency.

Signed-off-by: Simon Glass <sjg@chromium.org>
2020-12-13 16:51:08 -07:00

866 lines
22 KiB
C

// SPDX-License-Identifier: GPL-2.0
/*
* Generation of tables for particular device types
*
* Copyright 2019 Google LLC
* Mostly taken from coreboot file of the same name
*/
#include <common.h>
#include <dm.h>
#include <irq.h>
#include <log.h>
#include <usb.h>
#include <acpi/acpigen.h>
#include <acpi/acpi_device.h>
#include <acpi/acpigen.h>
#include <asm-generic/gpio.h>
#include <dm/acpi.h>
/**
* acpi_device_path_fill() - Find the root device and build a path from there
*
* This recursively reaches back to the root device and progressively adds path
* elements until the device is reached.
*
* @dev: Device to return path of
* @buf: Buffer to hold the path
* @buf_len: Length of buffer
* @cur: Current position in the buffer
* @return new position in buffer after adding @dev, or -ve on error
*/
static int acpi_device_path_fill(const struct udevice *dev, char *buf,
size_t buf_len, int cur)
{
char name[ACPI_NAME_MAX];
int next = 0;
int ret;
ret = acpi_get_name(dev, name);
if (ret)
return ret;
/*
* Make sure this name segment will fit, including the path segment
* separator and possible NULL terminator, if this is the last segment.
*/
if (cur + strlen(name) + 2 > buf_len)
return -ENOSPC;
/* Walk up the tree to the root device */
if (dev_get_parent(dev)) {
next = acpi_device_path_fill(dev_get_parent(dev), buf, buf_len,
cur);
if (next < 0)
return next;
}
/* Fill in the path from the root device */
next += snprintf(buf + next, buf_len - next, "%s%s",
dev_get_parent(dev) && *name ? "." : "", name);
return next;
}
int acpi_device_path(const struct udevice *dev, char *buf, int maxlen)
{
int ret;
ret = acpi_device_path_fill(dev, buf, maxlen, 0);
if (ret < 0)
return ret;
return 0;
}
int acpi_device_scope(const struct udevice *dev, char *scope, int maxlen)
{
int ret;
if (!dev_get_parent(dev))
return log_msg_ret("noparent", -EINVAL);
ret = acpi_device_path_fill(dev_get_parent(dev), scope, maxlen, 0);
if (ret < 0)
return log_msg_ret("fill", ret);
return 0;
}
enum acpi_dev_status acpi_device_status(const struct udevice *dev)
{
return ACPI_DSTATUS_ALL_ON;
}
/**
* largeres_write_len_f() - Write a placeholder word value
*
* Write a forward length for a large resource (2 bytes)
*
* @return pointer to the zero word (for fixing up later)
*/
static void *largeres_write_len_f(struct acpi_ctx *ctx)
{
u8 *p = acpigen_get_current(ctx);
acpigen_emit_word(ctx, 0);
return p;
}
/**
* largeres_fill_from_len() - Fill in a length value
*
* This calculated the number of bytes since the provided @start and writes it
* to @ptr, which was previous returned by largeres_write_len_f().
*
* @ptr: Word to update
* @start: Start address to count from to calculated the length
*/
static void largeres_fill_from_len(struct acpi_ctx *ctx, char *ptr, u8 *start)
{
u16 len = acpigen_get_current(ctx) - start;
ptr[0] = len & 0xff;
ptr[1] = (len >> 8) & 0xff;
}
/**
* largeres_fill_len() - Fill in a length value, excluding the length itself
*
* Fill in the length field with the value calculated from after the 16bit
* field to acpigen current. This is useful since the length value does not
* include the length field itself.
*
* This calls acpi_device_largeres_fill_len() passing @ptr + 2 as @start
*
* @ptr: Word to update.
*/
static void largeres_fill_len(struct acpi_ctx *ctx, void *ptr)
{
largeres_fill_from_len(ctx, ptr, ptr + sizeof(u16));
}
/* ACPI 6.3 section 6.4.3.6: Extended Interrupt Descriptor */
static int acpi_device_write_interrupt(struct acpi_ctx *ctx,
const struct acpi_irq *irq)
{
void *desc_length;
u8 flags;
if (!irq->pin)
return -ENOENT;
/* This is supported by GpioInt() but not Interrupt() */
if (irq->polarity == ACPI_IRQ_ACTIVE_BOTH)
return -EINVAL;
/* Byte 0: Descriptor Type */
acpigen_emit_byte(ctx, ACPI_DESCRIPTOR_INTERRUPT);
/* Byte 1-2: Length (filled in later) */
desc_length = largeres_write_len_f(ctx);
/*
* Byte 3: Flags
* [7:5]: Reserved
* [4]: Wake (0=NO_WAKE 1=WAKE)
* [3]: Sharing (0=EXCLUSIVE 1=SHARED)
* [2]: Polarity (0=HIGH 1=LOW)
* [1]: Mode (0=LEVEL 1=EDGE)
* [0]: Resource (0=PRODUCER 1=CONSUMER)
*/
flags = BIT(0); /* ResourceConsumer */
if (irq->mode == ACPI_IRQ_EDGE_TRIGGERED)
flags |= BIT(1);
if (irq->polarity == ACPI_IRQ_ACTIVE_LOW)
flags |= BIT(2);
if (irq->shared == ACPI_IRQ_SHARED)
flags |= BIT(3);
if (irq->wake == ACPI_IRQ_WAKE)
flags |= BIT(4);
acpigen_emit_byte(ctx, flags);
/* Byte 4: Interrupt Table Entry Count */
acpigen_emit_byte(ctx, 1);
/* Byte 5-8: Interrupt Number */
acpigen_emit_dword(ctx, irq->pin);
/* Fill in Descriptor Length (account for len word) */
largeres_fill_len(ctx, desc_length);
return 0;
}
int acpi_device_write_interrupt_irq(struct acpi_ctx *ctx,
const struct irq *req_irq)
{
struct acpi_irq irq;
int ret;
ret = irq_get_acpi(req_irq, &irq);
if (ret)
return log_msg_ret("get", ret);
ret = acpi_device_write_interrupt(ctx, &irq);
if (ret)
return log_msg_ret("write", ret);
return irq.pin;
}
/* ACPI 6.3 section 6.4.3.8.1 - GPIO Interrupt or I/O */
int acpi_device_write_gpio(struct acpi_ctx *ctx, const struct acpi_gpio *gpio)
{
void *start, *desc_length;
void *pin_table_offset, *vendor_data_offset, *resource_offset;
u16 flags = 0;
int pin;
if (gpio->type > ACPI_GPIO_TYPE_IO)
return -EINVAL;
start = acpigen_get_current(ctx);
/* Byte 0: Descriptor Type */
acpigen_emit_byte(ctx, ACPI_DESCRIPTOR_GPIO);
/* Byte 1-2: Length (fill in later) */
desc_length = largeres_write_len_f(ctx);
/* Byte 3: Revision ID */
acpigen_emit_byte(ctx, ACPI_GPIO_REVISION_ID);
/* Byte 4: GpioIo or GpioInt */
acpigen_emit_byte(ctx, gpio->type);
/*
* Byte 5-6: General Flags
* [15:1]: 0 => Reserved
* [0]: 1 => ResourceConsumer
*/
acpigen_emit_word(ctx, 1 << 0);
switch (gpio->type) {
case ACPI_GPIO_TYPE_INTERRUPT:
/*
* Byte 7-8: GPIO Interrupt Flags
* [15:5]: 0 => Reserved
* [4]: Wake (0=NO_WAKE 1=WAKE)
* [3]: Sharing (0=EXCLUSIVE 1=SHARED)
* [2:1]: Polarity (0=HIGH 1=LOW 2=BOTH)
* [0]: Mode (0=LEVEL 1=EDGE)
*/
if (gpio->irq.mode == ACPI_IRQ_EDGE_TRIGGERED)
flags |= 1 << 0;
if (gpio->irq.shared == ACPI_IRQ_SHARED)
flags |= 1 << 3;
if (gpio->irq.wake == ACPI_IRQ_WAKE)
flags |= 1 << 4;
switch (gpio->irq.polarity) {
case ACPI_IRQ_ACTIVE_HIGH:
flags |= 0 << 1;
break;
case ACPI_IRQ_ACTIVE_LOW:
flags |= 1 << 1;
break;
case ACPI_IRQ_ACTIVE_BOTH:
flags |= 2 << 1;
break;
}
break;
case ACPI_GPIO_TYPE_IO:
/*
* Byte 7-8: GPIO IO Flags
* [15:4]: 0 => Reserved
* [3]: Sharing (0=EXCLUSIVE 1=SHARED)
* [2]: 0 => Reserved
* [1:0]: IO Restriction
* 0 => IoRestrictionNone
* 1 => IoRestrictionInputOnly
* 2 => IoRestrictionOutputOnly
* 3 => IoRestrictionNoneAndPreserve
*/
flags |= gpio->io_restrict & 3;
if (gpio->io_shared)
flags |= 1 << 3;
break;
}
acpigen_emit_word(ctx, flags);
/*
* Byte 9: Pin Configuration
* 0x01 => Default (no configuration applied)
* 0x02 => Pull-up
* 0x03 => Pull-down
* 0x04-0x7F => Reserved
* 0x80-0xff => Vendor defined
*/
acpigen_emit_byte(ctx, gpio->pull);
/* Byte 10-11: Output Drive Strength in 1/100 mA */
acpigen_emit_word(ctx, gpio->output_drive_strength);
/* Byte 12-13: Debounce Timeout in 1/100 ms */
acpigen_emit_word(ctx, gpio->interrupt_debounce_timeout);
/* Byte 14-15: Pin Table Offset, relative to start */
pin_table_offset = largeres_write_len_f(ctx);
/* Byte 16: Reserved */
acpigen_emit_byte(ctx, 0);
/* Byte 17-18: Resource Source Name Offset, relative to start */
resource_offset = largeres_write_len_f(ctx);
/* Byte 19-20: Vendor Data Offset, relative to start */
vendor_data_offset = largeres_write_len_f(ctx);
/* Byte 21-22: Vendor Data Length */
acpigen_emit_word(ctx, 0);
/* Fill in Pin Table Offset */
largeres_fill_from_len(ctx, pin_table_offset, start);
/* Pin Table, one word for each pin */
for (pin = 0; pin < gpio->pin_count; pin++)
acpigen_emit_word(ctx, gpio->pins[pin]);
/* Fill in Resource Source Name Offset */
largeres_fill_from_len(ctx, resource_offset, start);
/* Resource Source Name String */
acpigen_emit_string(ctx, gpio->resource);
/* Fill in Vendor Data Offset */
largeres_fill_from_len(ctx, vendor_data_offset, start);
/* Fill in GPIO Descriptor Length (account for len word) */
largeres_fill_len(ctx, desc_length);
return gpio->pins[0];
}
int acpi_device_write_gpio_desc(struct acpi_ctx *ctx,
const struct gpio_desc *desc)
{
struct acpi_gpio gpio;
int ret;
ret = gpio_get_acpi(desc, &gpio);
if (ret)
return log_msg_ret("desc", ret);
ret = acpi_device_write_gpio(ctx, &gpio);
if (ret < 0)
return log_msg_ret("gpio", ret);
return ret;
}
int acpi_device_write_interrupt_or_gpio(struct acpi_ctx *ctx,
struct udevice *dev, const char *prop)
{
struct irq req_irq;
int pin;
int ret;
ret = irq_get_by_index(dev, 0, &req_irq);
if (!ret) {
ret = acpi_device_write_interrupt_irq(ctx, &req_irq);
if (ret < 0)
return log_msg_ret("irq", ret);
pin = ret;
} else {
struct gpio_desc req_gpio;
ret = gpio_request_by_name(dev, prop, 0, &req_gpio,
GPIOD_IS_IN);
if (ret)
return log_msg_ret("no gpio", ret);
ret = acpi_device_write_gpio_desc(ctx, &req_gpio);
if (ret < 0)
return log_msg_ret("gpio", ret);
pin = ret;
}
return pin;
}
/* PowerResource() with Enable and/or Reset control */
int acpi_device_add_power_res(struct acpi_ctx *ctx, u32 tx_state_val,
const char *dw0_read, const char *dw0_write,
const struct gpio_desc *reset_gpio,
uint reset_delay_ms, uint reset_off_delay_ms,
const struct gpio_desc *enable_gpio,
uint enable_delay_ms, uint enable_off_delay_ms,
const struct gpio_desc *stop_gpio,
uint stop_delay_ms, uint stop_off_delay_ms)
{
static const char *const power_res_dev_states[] = { "_PR0", "_PR3" };
struct acpi_gpio reset, enable, stop;
bool has_reset, has_enable, has_stop;
int ret;
gpio_get_acpi(reset_gpio, &reset);
gpio_get_acpi(enable_gpio, &enable);
gpio_get_acpi(stop_gpio, &stop);
has_reset = reset.pins[0];
has_enable = enable.pins[0];
has_stop = stop.pins[0];
if (!has_reset && !has_enable && !has_stop)
return -EINVAL;
/* PowerResource (PRIC, 0, 0) */
acpigen_write_power_res(ctx, "PRIC", 0, 0, power_res_dev_states,
ARRAY_SIZE(power_res_dev_states));
/* Method (_STA, 0, NotSerialized) { Return (0x1) } */
acpigen_write_sta(ctx, 0x1);
/* Method (_ON, 0, Serialized) */
acpigen_write_method_serialized(ctx, "_ON", 0);
if (has_reset) {
ret = acpigen_set_enable_tx_gpio(ctx, tx_state_val, dw0_read,
dw0_write, &reset, true);
if (ret)
return log_msg_ret("reset1", ret);
}
if (has_enable) {
ret = acpigen_set_enable_tx_gpio(ctx, tx_state_val, dw0_read,
dw0_write, &enable, true);
if (ret)
return log_msg_ret("enable1", ret);
if (enable_delay_ms)
acpigen_write_sleep(ctx, enable_delay_ms);
}
if (has_reset) {
ret = acpigen_set_enable_tx_gpio(ctx, tx_state_val, dw0_read,
dw0_write, &reset, false);
if (ret)
return log_msg_ret("reset2", ret);
if (reset_delay_ms)
acpigen_write_sleep(ctx, reset_delay_ms);
}
if (has_stop) {
ret = acpigen_set_enable_tx_gpio(ctx, tx_state_val, dw0_read,
dw0_write, &stop, false);
if (ret)
return log_msg_ret("stop1", ret);
if (stop_delay_ms)
acpigen_write_sleep(ctx, stop_delay_ms);
}
acpigen_pop_len(ctx); /* _ON method */
/* Method (_OFF, 0, Serialized) */
acpigen_write_method_serialized(ctx, "_OFF", 0);
if (has_stop) {
ret = acpigen_set_enable_tx_gpio(ctx, tx_state_val, dw0_read,
dw0_write, &stop, true);
if (ret)
return log_msg_ret("stop2", ret);
if (stop_off_delay_ms)
acpigen_write_sleep(ctx, stop_off_delay_ms);
}
if (has_reset) {
ret = acpigen_set_enable_tx_gpio(ctx, tx_state_val, dw0_read,
dw0_write, &reset, true);
if (ret)
return log_msg_ret("reset3", ret);
if (reset_off_delay_ms)
acpigen_write_sleep(ctx, reset_off_delay_ms);
}
if (has_enable) {
ret = acpigen_set_enable_tx_gpio(ctx, tx_state_val, dw0_read,
dw0_write, &enable, false);
if (ret)
return log_msg_ret("enable2", ret);
if (enable_off_delay_ms)
acpigen_write_sleep(ctx, enable_off_delay_ms);
}
acpigen_pop_len(ctx); /* _OFF method */
acpigen_pop_len(ctx); /* PowerResource PRIC */
return 0;
}
int acpi_device_write_dsm_i2c_hid(struct acpi_ctx *ctx,
int hid_desc_reg_offset)
{
int ret;
acpigen_write_dsm_start(ctx);
ret = acpigen_write_dsm_uuid_start(ctx, ACPI_DSM_I2C_HID_UUID);
if (ret)
return log_ret(ret);
acpigen_write_dsm_uuid_start_cond(ctx, 0);
/* ToInteger (Arg1, Local2) */
acpigen_write_to_integer(ctx, ARG1_OP, LOCAL2_OP);
/* If (LEqual (Local2, 0x0)) */
acpigen_write_if_lequal_op_int(ctx, LOCAL2_OP, 0x0);
/* Return (Buffer (One) { 0x1f }) */
acpigen_write_return_singleton_buffer(ctx, 0x1f);
acpigen_pop_len(ctx); /* Pop : If */
/* Else */
acpigen_write_else(ctx);
/* If (LEqual (Local2, 0x1)) */
acpigen_write_if_lequal_op_int(ctx, LOCAL2_OP, 0x1);
/* Return (Buffer (One) { 0x3f }) */
acpigen_write_return_singleton_buffer(ctx, 0x3f);
acpigen_pop_len(ctx); /* Pop : If */
/* Else */
acpigen_write_else(ctx);
/* Return (Buffer (One) { 0x0 }) */
acpigen_write_return_singleton_buffer(ctx, 0x0);
acpigen_pop_len(ctx); /* Pop : Else */
acpigen_pop_len(ctx); /* Pop : Else */
acpigen_write_dsm_uuid_end_cond(ctx);
acpigen_write_dsm_uuid_start_cond(ctx, 1);
acpigen_write_return_byte(ctx, hid_desc_reg_offset);
acpigen_write_dsm_uuid_end_cond(ctx);
acpigen_write_dsm_uuid_end(ctx);
acpigen_write_dsm_end(ctx);
return 0;
}
/* ACPI 6.3 section 6.4.3.8.2.1 - I2cSerialBusV2() */
static void acpi_device_write_i2c(struct acpi_ctx *ctx,
const struct acpi_i2c *i2c)
{
void *desc_length, *type_length;
/* Byte 0: Descriptor Type */
acpigen_emit_byte(ctx, ACPI_DESCRIPTOR_SERIAL_BUS);
/* Byte 1+2: Length (filled in later) */
desc_length = largeres_write_len_f(ctx);
/* Byte 3: Revision ID */
acpigen_emit_byte(ctx, ACPI_I2C_SERIAL_BUS_REVISION_ID);
/* Byte 4: Resource Source Index is Reserved */
acpigen_emit_byte(ctx, 0);
/* Byte 5: Serial Bus Type is I2C */
acpigen_emit_byte(ctx, ACPI_SERIAL_BUS_TYPE_I2C);
/*
* Byte 6: Flags
* [7:2]: 0 => Reserved
* [1]: 1 => ResourceConsumer
* [0]: 0 => ControllerInitiated
*/
acpigen_emit_byte(ctx, 1 << 1);
/*
* Byte 7-8: Type Specific Flags
* [15:1]: 0 => Reserved
* [0]: 0 => 7bit, 1 => 10bit
*/
acpigen_emit_word(ctx, i2c->mode_10bit);
/* Byte 9: Type Specific Revision ID */
acpigen_emit_byte(ctx, ACPI_I2C_TYPE_SPECIFIC_REVISION_ID);
/* Byte 10-11: I2C Type Data Length */
type_length = largeres_write_len_f(ctx);
/* Byte 12-15: I2C Bus Speed */
acpigen_emit_dword(ctx, i2c->speed);
/* Byte 16-17: I2C Slave Address */
acpigen_emit_word(ctx, i2c->address);
/* Fill in Type Data Length */
largeres_fill_len(ctx, type_length);
/* Byte 18+: ResourceSource */
acpigen_emit_string(ctx, i2c->resource);
/* Fill in I2C Descriptor Length */
largeres_fill_len(ctx, desc_length);
}
/**
* acpi_device_set_i2c() - Set up an ACPI I2C struct from a device
*
* The value of @scope is not copied, but only referenced. This implies the
* caller has to ensure it stays valid for the lifetime of @i2c.
*
* @dev: I2C device to convert
* @i2c: Place to put the new structure
* @scope: Scope of the I2C device (this is the controller path)
* @return chip address of device
*/
static int acpi_device_set_i2c(const struct udevice *dev, struct acpi_i2c *i2c,
const char *scope)
{
struct dm_i2c_chip *chip = dev_get_parent_plat(dev);
struct udevice *bus = dev_get_parent(dev);
memset(i2c, '\0', sizeof(*i2c));
i2c->address = chip->chip_addr;
i2c->mode_10bit = 0;
/*
* i2c_bus->speed_hz is set if this device is probed, but if not we
* must use the device tree
*/
i2c->speed = dev_read_u32_default(bus, "clock-frequency",
I2C_SPEED_STANDARD_RATE);
i2c->resource = scope;
return i2c->address;
}
int acpi_device_write_i2c_dev(struct acpi_ctx *ctx, const struct udevice *dev)
{
char scope[ACPI_PATH_MAX];
struct acpi_i2c i2c;
int ret;
ret = acpi_device_scope(dev, scope, sizeof(scope));
if (ret)
return log_msg_ret("scope", ret);
ret = acpi_device_set_i2c(dev, &i2c, scope);
if (ret < 0)
return log_msg_ret("set", ret);
acpi_device_write_i2c(ctx, &i2c);
return ret;
}
#ifdef CONFIG_SPI
/* ACPI 6.1 section 6.4.3.8.2.2 - SpiSerialBus() */
static void acpi_device_write_spi(struct acpi_ctx *ctx, const struct acpi_spi *spi)
{
void *desc_length, *type_length;
u16 flags = 0;
/* Byte 0: Descriptor Type */
acpigen_emit_byte(ctx, ACPI_DESCRIPTOR_SERIAL_BUS);
/* Byte 1+2: Length (filled in later) */
desc_length = largeres_write_len_f(ctx);
/* Byte 3: Revision ID */
acpigen_emit_byte(ctx, ACPI_SPI_SERIAL_BUS_REVISION_ID);
/* Byte 4: Resource Source Index is Reserved */
acpigen_emit_byte(ctx, 0);
/* Byte 5: Serial Bus Type is SPI */
acpigen_emit_byte(ctx, ACPI_SERIAL_BUS_TYPE_SPI);
/*
* Byte 6: Flags
* [7:2]: 0 => Reserved
* [1]: 1 => ResourceConsumer
* [0]: 0 => ControllerInitiated
*/
acpigen_emit_byte(ctx, BIT(1));
/*
* Byte 7-8: Type Specific Flags
* [15:2]: 0 => Reserveda
* [1]: 0 => ActiveLow, 1 => ActiveHigh
* [0]: 0 => FourWire, 1 => ThreeWire
*/
if (spi->wire_mode == SPI_3_WIRE_MODE)
flags |= BIT(0);
if (spi->device_select_polarity == SPI_POLARITY_HIGH)
flags |= BIT(1);
acpigen_emit_word(ctx, flags);
/* Byte 9: Type Specific Revision ID */
acpigen_emit_byte(ctx, ACPI_SPI_TYPE_SPECIFIC_REVISION_ID);
/* Byte 10-11: SPI Type Data Length */
type_length = largeres_write_len_f(ctx);
/* Byte 12-15: Connection Speed */
acpigen_emit_dword(ctx, spi->speed);
/* Byte 16: Data Bit Length */
acpigen_emit_byte(ctx, spi->data_bit_length);
/* Byte 17: Clock Phase */
acpigen_emit_byte(ctx, spi->clock_phase);
/* Byte 18: Clock Polarity */
acpigen_emit_byte(ctx, spi->clock_polarity);
/* Byte 19-20: Device Selection */
acpigen_emit_word(ctx, spi->device_select);
/* Fill in Type Data Length */
largeres_fill_len(ctx, type_length);
/* Byte 21+: ResourceSource String */
acpigen_emit_string(ctx, spi->resource);
/* Fill in SPI Descriptor Length */
largeres_fill_len(ctx, desc_length);
}
/**
* acpi_device_set_spi() - Set up an ACPI SPI struct from a device
*
* The value of @scope is not copied, but only referenced. This implies the
* caller has to ensure it stays valid for the lifetime of @spi.
*
* @dev: SPI device to convert
* @spi: Place to put the new structure
* @scope: Scope of the SPI device (this is the controller path)
* @return 0 (always)
*/
static int acpi_device_set_spi(const struct udevice *dev, struct acpi_spi *spi,
const char *scope)
{
struct dm_spi_slave_platdata *plat;
struct spi_slave *slave = dev_get_parent_priv(dev);
plat = dev_get_parent_plat(slave->dev);
memset(spi, '\0', sizeof(*spi));
spi->device_select = plat->cs;
spi->device_select_polarity = SPI_POLARITY_LOW;
spi->wire_mode = SPI_4_WIRE_MODE;
spi->speed = plat->max_hz;
spi->data_bit_length = slave->wordlen;
spi->clock_phase = plat->mode & SPI_CPHA ?
SPI_CLOCK_PHASE_SECOND : SPI_CLOCK_PHASE_FIRST;
spi->clock_polarity = plat->mode & SPI_CPOL ?
SPI_POLARITY_HIGH : SPI_POLARITY_LOW;
spi->resource = scope;
return 0;
}
int acpi_device_write_spi_dev(struct acpi_ctx *ctx, const struct udevice *dev)
{
char scope[ACPI_PATH_MAX];
struct acpi_spi spi;
int ret;
ret = acpi_device_scope(dev, scope, sizeof(scope));
if (ret)
return log_msg_ret("scope", ret);
ret = acpi_device_set_spi(dev, &spi, scope);
if (ret)
return log_msg_ret("set", ret);
acpi_device_write_spi(ctx, &spi);
return 0;
}
#endif /* CONFIG_SPI */
static const char *acpi_name_from_id(enum uclass_id id)
{
switch (id) {
case UCLASS_USB_HUB:
/* Root Hub */
return "RHUB";
/* DSDT: acpi/northbridge.asl */
case UCLASS_NORTHBRIDGE:
return "MCHC";
/* DSDT: acpi/lpc.asl */
case UCLASS_LPC:
return "LPCB";
/* DSDT: acpi/xhci.asl */
case UCLASS_USB:
/* This only supports USB3.0 controllers at present */
return "XHCI";
case UCLASS_PWM:
return "PWM";
default:
return NULL;
}
}
static int acpi_check_seq(const struct udevice *dev)
{
if (dev->req_seq == -1) {
log_warning("Device '%s' has no seq\n", dev->name);
return log_msg_ret("no seq", -ENXIO);
}
return dev->req_seq;
}
/* If you change this function, add test cases to dm_test_acpi_get_name() */
int acpi_device_infer_name(const struct udevice *dev, char *out_name)
{
enum uclass_id parent_id = UCLASS_INVALID;
enum uclass_id id;
const char *name = NULL;
id = device_get_uclass_id(dev);
if (dev_get_parent(dev))
parent_id = device_get_uclass_id(dev_get_parent(dev));
if (id == UCLASS_SOUND)
name = "HDAS";
else if (id == UCLASS_PCI)
name = "PCI0";
else if (device_is_on_pci_bus(dev))
name = acpi_name_from_id(id);
if (!name) {
switch (parent_id) {
case UCLASS_USB: {
struct usb_device *udev = dev_get_parent_priv(dev);
sprintf(out_name, udev->speed >= USB_SPEED_SUPER ?
"HS%02d" : "FS%02d", udev->portnr);
name = out_name;
break;
}
default:
break;
}
}
if (!name) {
int num;
switch (id) {
/* DSDT: acpi/lpss.asl */
case UCLASS_SERIAL:
num = acpi_check_seq(dev);
if (num < 0)
return num;
sprintf(out_name, "URT%d", num);
name = out_name;
break;
case UCLASS_I2C:
num = acpi_check_seq(dev);
if (num < 0)
return num;
sprintf(out_name, "I2C%d", num);
name = out_name;
break;
case UCLASS_SPI:
num = acpi_check_seq(dev);
if (num < 0)
return num;
sprintf(out_name, "SPI%d", num);
name = out_name;
break;
default:
break;
}
}
if (!name) {
log_warning("No name for device '%s'\n", dev->name);
return -ENOENT;
}
if (name != out_name)
acpi_copy_name(out_name, name);
return 0;
}