lib/acpi/acpi_device.c - platform/external/u-boot - Gitiles

 // 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_plat *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;
 	}
 }

 /* 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) {
 		switch (id) {
 		/* DSDT: acpi/lpss.asl */
 		case UCLASS_SERIAL:
 			sprintf(out_name, "URT%d", dev_seq(dev));
 			name = out_name;
 			break;
 		case UCLASS_I2C:
 			sprintf(out_name, "I2C%d", dev_seq(dev));
 			name = out_name;
 			break;
 		case UCLASS_SPI:
 			sprintf(out_name, "SPI%d", dev_seq(dev));
 			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;
 }
	// 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_plat *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;
	}
	}

	/* 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) {
	switch (id) {
	/* DSDT: acpi/lpss.asl */
	case UCLASS_SERIAL:
	sprintf(out_name, "URT%d", dev_seq(dev));
	name = out_name;
	break;
	case UCLASS_I2C:
	sprintf(out_name, "I2C%d", dev_seq(dev));
	name = out_name;
	break;
	case UCLASS_SPI:
	sprintf(out_name, "SPI%d", dev_seq(dev));
	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;
	}