U-Boot

/* SPDX-License-Identifier: GPL-2.0 */
/*
 * Core ACPI (Advanced Configuration and Power Interface) support
 *
 * Copyright 2019 Google LLC
 *
 * Modified from coreboot file acpigen.h
 */

#ifndef __ACPI_ACPIGEN_H
#define __ACPI_ACPIGEN_H

#include <acpi/acpi_table.h>
#include <linux/types.h>

struct acpi_cstate;
struct acpi_ctx;
struct acpi_gen_regaddr;
struct acpi_gpio;

/* Top 4 bits of the value used to indicate a three-byte length value */
#define ACPI_PKG_LEN_3_BYTES	0x80

#define ACPI_METHOD_NARGS_MASK		0x7
#define ACPI_METHOD_SERIALIZED_MASK	BIT(3)

#define ACPI_END_TAG			0x79

/* ACPI Op/Prefix codes */
enum {
	ZERO_OP			= 0x00,
	ONE_OP			= 0x01,
	NAME_OP			= 0x08,
	BYTE_PREFIX		= 0x0a,
	WORD_PREFIX		= 0x0b,
	DWORD_PREFIX		= 0x0c,
	STRING_PREFIX		= 0x0d,
	QWORD_PREFIX		= 0x0e,
	SCOPE_OP		= 0x10,
	BUFFER_OP		= 0x11,
	PACKAGE_OP		= 0x12,
	METHOD_OP		= 0x14,
	SLEEP_OP		= 0x22,
	DUAL_NAME_PREFIX	= 0x2e,
	MULTI_NAME_PREFIX	= 0x2f,
	DEBUG_OP		= 0x31,
	EXT_OP_PREFIX		= 0x5b,
	ROOT_PREFIX		= 0x5c,
	LOCAL0_OP		= 0x60,
	LOCAL1_OP		= 0x61,
	LOCAL2_OP		= 0x62,
	LOCAL3_OP		= 0x63,
	LOCAL4_OP		= 0x64,
	LOCAL5_OP		= 0x65,
	LOCAL6_OP		= 0x66,
	LOCAL7_OP		= 0x67,
	ARG0_OP			= 0x68,
	ARG1_OP			= 0x69,
	ARG2_OP			= 0x6a,
	ARG3_OP			= 0x6b,
	ARG4_OP			= 0x6c,
	ARG5_OP			= 0x6d,
	ARG6_OP			= 0x6e,
	STORE_OP		= 0x70,
	AND_OP			= 0x7b,
	OR_OP			= 0x7d,
	NOT_OP			= 0x80,
	DEVICE_OP		= 0x82,
	PROCESSOR_OP		= 0x83,
	POWER_RES_OP		= 0x84,
	NOTIFY_OP		= 0x86,
	LEQUAL_OP		= 0x93,
	TO_BUFFER_OP		= 0x96,
	TO_INTEGER_OP		= 0x99,
	IF_OP			= 0xa0,
	ELSE_OP			= 0xa1,
	RETURN_OP		= 0xa4,
};

/**
 * enum psd_coord - Coordination types for P-states
 *
 * The type of coordination that exists (hardware) or is required (software) as
 * a result of the underlying hardware dependency
 */
enum psd_coord {
	SW_ALL = 0xfc,
	SW_ANY = 0xfd,
	HW_ALL = 0xfe
};

/**
 * enum csd_coord -  Coordination types for C-states
 *
 * The type of coordination that exists (hardware) or is required (software) as
 * a result of the underlying hardware dependency
 */
enum csd_coord {
	CSD_HW_ALL = 0xfe,
};

/**
 * struct acpi_cstate - Information about a C-State
 *
 * @ctype: C State type (1=C1, 2=C2, 3=C3)
 * @latency: Worst-case latency to enter and exit the C State (in uS)
 * @power: Average power consumption of the processor when in this C-State (mW)
 * @resource: Register to read to place the processor in this state
 */
struct acpi_cstate {
	uint ctype;
	uint latency;
	uint power;
	struct acpi_gen_regaddr resource;
};

/**
 * struct acpi_tstate - Information about a Throttling Supported State
 *
 * See ACPI v6.3 section 8.4.5.2: _TSS (Throttling Supported States)
 *
 * @percent: Percent of the core CPU operating frequency that will be
 *	available when this throttling state is invoked
 * @power: Throttling state's maximum power dissipation (mw)
 * @latency: Worst-case latency (uS) that the CPU is unavailable during a
 *	transition from any throttling state to this throttling state
 * @control: Value to be written to the Processor Control Register
 *	(THROTTLE_CTRL) to initiate a transition to this throttling state
 * @status: Value in THROTTLE_STATUS when in this state
 */
struct acpi_tstate {
	uint percent;
	uint power;
	uint latency;
	uint control;
	uint status;
};

/**
 * acpigen_get_current() - Get the current ACPI code output pointer
 *
 * @ctx: ACPI context pointer
 * Return: output pointer
 */
u8 *acpigen_get_current(struct acpi_ctx *ctx);

/**
 * acpigen_emit_byte() - Emit a byte to the ACPI code
 *
 * @ctx: ACPI context pointer
 * @data: Value to output
 */
void acpigen_emit_byte(struct acpi_ctx *ctx, uint data);

/**
 * acpigen_emit_word() - Emit a 16-bit word to the ACPI code
 *
 * @ctx: ACPI context pointer
 * @data: Value to output
 */
void acpigen_emit_word(struct acpi_ctx *ctx, uint data);

/**
 * acpigen_emit_dword() - Emit a 32-bit 'double word' to the ACPI code
 *
 * @ctx: ACPI context pointer
 * @data: Value to output
 */
void acpigen_emit_dword(struct acpi_ctx *ctx, uint data);

/**
 * acpigen_emit_stream() - Emit a stream of bytes
 *
 * @ctx: ACPI context pointer
 * @data: Data to output
 * @size: Size of data in bytes
 */
void acpigen_emit_stream(struct acpi_ctx *ctx, const char *data, int size);

/**
 * acpigen_emit_string() - Emit a string
 *
 * Emit a string with a null terminator
 *
 * @ctx: ACPI context pointer
 * @str: String to output, or NULL for an empty string
 */
void acpigen_emit_string(struct acpi_ctx *ctx, const char *str);

/**
 * acpigen_write_len_f() - Write a 'forward' length placeholder
 *
 * This adds space for a length value in the ACPI stream and pushes the current
 * position (before the length) on the stack. After calling this you can write
 * some data and then call acpigen_pop_len() to update the length value.
 *
 * Usage:
 *
 *    acpigen_write_len_f() ------\
 *    acpigen_write...()          |
 *    acpigen_write...()          |
 *      acpigen_write_len_f() --\ |
 *      acpigen_write...()      | |
 *      acpigen_write...()      | |
 *      acpigen_pop_len() ------/ |
 *    acpigen_write...()          |
 *    acpigen_pop_len() ----------/
 *
 * See ACPI 6.3 section 20.2.4 Package Length Encoding
 *
 * This implementation always uses a 3-byte packet length for simplicity. It
 * could be adjusted to support other lengths.
 *
 * @ctx: ACPI context pointer
 */
void acpigen_write_len_f(struct acpi_ctx *ctx);

/**
 * acpigen_pop_len() - Update the previously stacked length placeholder
 *
 * Call this after the data for the block has been written. It updates the
 * top length value in the stack and pops it off.
 *
 * @ctx: ACPI context pointer
 */
void acpigen_pop_len(struct acpi_ctx *ctx);

/**
 * acpigen_write_package() - Start writing a package
 *
 * A package collects together a number of elements in the ACPI code. To write
 * a package use:
 *
 * acpigen_write_package(ctx, 3);
 * ...write things
 * acpigen_pop_len()
 *
 * If you don't know the number of elements in advance, acpigen_write_package()
 * returns a pointer to the value so you can update it later:
 *
 * char *num_elements = acpigen_write_package(ctx, 0);
 * ...write things
 * *num_elements += 1;
 * ...write things
 * *num_elements += 1;
 * acpigen_pop_len()
 *
 * @ctx: ACPI context pointer
 * @nr_el: Number of elements (0 if not known)
 * @returns pointer to the number of elements, which can be updated by the
 *	caller if needed
 */
char *acpigen_write_package(struct acpi_ctx *ctx, int nr_el);

/**
 * acpigen_write_byte() - Write a byte
 *
 * @ctx: ACPI context pointer
 * @data: Value to write
 */
void acpigen_write_byte(struct acpi_ctx *ctx, unsigned int data);

/**
 * acpigen_write_word() - Write a word
 *
 * @ctx: ACPI context pointer
 * @data: Value to write
 */
void acpigen_write_word(struct acpi_ctx *ctx, unsigned int data);

/**
 * acpigen_write_dword() - Write a dword
 *
 * @ctx: ACPI context pointer
 * @data: Value to write
 */
void acpigen_write_dword(struct acpi_ctx *ctx, unsigned int data);

/**
 * acpigen_write_qword() - Write a qword
 *
 * @ctx: ACPI context pointer
 * @data: Value to write
 */
void acpigen_write_qword(struct acpi_ctx *ctx, u64 data);

/**
 * acpigen_write_zero() - Write zero
 *
 * @ctx: ACPI context pointer
 */
void acpigen_write_zero(struct acpi_ctx *ctx);

/**
 * acpigen_write_one() - Write one
 *
 * @ctx: ACPI context pointer
 */
void acpigen_write_one(struct acpi_ctx *ctx);

/**
 * acpigen_write_integer() - Write an integer
 *
 * This writes an operation (BYTE_OP, WORD_OP, DWORD_OP, QWORD_OP depending on
 * the integer size) and an integer value. Note that WORD means 16 bits in ACPI.
 *
 * @ctx: ACPI context pointer
 * @data: Integer to write
 */
void acpigen_write_integer(struct acpi_ctx *ctx, u64 data);

/**
 * acpigen_write_name_zero() - Write a named zero value
 *
 * @ctx: ACPI context pointer
 * @name: Name of the value
 */
void acpigen_write_name_zero(struct acpi_ctx *ctx, const char *name);

/**
 * acpigen_write_name_one() - Write a named one value
 *
 * @ctx: ACPI context pointer
 * @name: Name of the value
 */
void acpigen_write_name_one(struct acpi_ctx *ctx, const char *name);

/**
 * acpigen_write_name_byte() - Write a named byte value
 *
 * @ctx: ACPI context pointer
 * @name: Name of the value
 * @val: Value to write
 */
void acpigen_write_name_byte(struct acpi_ctx *ctx, const char *name, uint val);

/**
 * acpigen_write_name_word() - Write a named word value
 *
 * @ctx: ACPI context pointer
 * @name: Name of the value
 * @val: Value to write
 */
void acpigen_write_name_word(struct acpi_ctx *ctx, const char *name, uint val);

/**
 * acpigen_write_name_dword() - Write a named dword value
 *
 * @ctx: ACPI context pointer
 * @name: Name of the value
 * @val: Value to write
 */
void acpigen_write_name_dword(struct acpi_ctx *ctx, const char *name, uint val);

/**
 * acpigen_write_name_qword() - Write a named qword value
 *
 * @ctx: ACPI context pointer
 * @name: Name of the value
 * @val: Value to write
 */
void acpigen_write_name_qword(struct acpi_ctx *ctx, const char *name, u64 val);

/**
 * acpigen_write_name_integer() - Write a named integer value
 *
 * @ctx: ACPI context pointer
 * @name: Name of the value
 * @val: Value to write
 */
void acpigen_write_name_integer(struct acpi_ctx *ctx, const char *name,
				u64 val);

/**
 * acpigen_write_name_string() - Write a named string value
 *
 * @ctx: ACPI context pointer
 * @name: Name of the value
 * @string: String to write
 */
void acpigen_write_name_string(struct acpi_ctx *ctx, const char *name,
			       const char *string);

/**
 * acpigen_write_string() - Write a string
 *
 * This writes a STRING_PREFIX followed by a null-terminated string
 *
 * @ctx: ACPI context pointer
 * @str: String to write
 */
void acpigen_write_string(struct acpi_ctx *ctx, const char *str);

/**
 * acpigen_emit_namestring() - Emit an ACPI name
 *
 * This writes out an ACPI name or path in the required special format. It does
 * not add the NAME_OP prefix.
 *
 * @ctx: ACPI context pointer
 * @namepath: Name / path to emit
 */
void acpigen_emit_namestring(struct acpi_ctx *ctx, const char *namepath);

/**
 * acpigen_write_name() - Write out an ACPI name
 *
 * This writes out an ACPI name or path in the required special format with a
 * NAME_OP prefix.
 *
 * @ctx: ACPI context pointer
 * @namepath: Name / path to emit
 */
void acpigen_write_name(struct acpi_ctx *ctx, const char *namepath);

/**
 * acpigen_write_scope() - Write a scope
 *
 * @ctx: ACPI context pointer
 * @scope: Scope to write (e.g. "\\_SB.ABCD")
 */
void acpigen_write_scope(struct acpi_ctx *ctx, const char *scope);

/**
 * acpigen_write_uuid() - Write a UUID
 *
 * This writes out a UUID in the format used by ACPI, with a BUFFER_OP prefix.
 *
 * @ctx: ACPI context pointer
 * @uuid: UUID to write in the form aabbccdd-eeff-gghh-iijj-kkllmmnnoopp
 * Return: 0 if OK, -EINVAL if the format is incorrect
 */
int acpigen_write_uuid(struct acpi_ctx *ctx, const char *uuid);

/**
 * acpigen_emit_ext_op() - Emit an extended op with the EXT_OP_PREFIX prefix
 *
 * @ctx: ACPI context pointer
 * @op: Operation code (e.g. SLEEP_OP)
 */
void acpigen_emit_ext_op(struct acpi_ctx *ctx, uint op);

/**
 * acpigen_write_method() - Write a method header
 *
 * @ctx: ACPI context pointer
 * @name: Method name (4 characters)
 * @nargs: Number of method arguments (0 if none)
 */
void acpigen_write_method(struct acpi_ctx *ctx, const char *name, int nargs);

/**
 * acpigen_write_method_serialized() - Write a method header
 *
 * This sets the 'serialized' flag so that the method is thread-safe
 *
 * @ctx: ACPI context pointer
 * @name: Method name (4 characters)
 * @nargs: Number of method arguments (0 if none)
 */
void acpigen_write_method_serialized(struct acpi_ctx *ctx, const char *name,
				     int nargs);

/**
 * acpigen_write_device() - Write an ACPI device
 *
 * @ctx: ACPI context pointer
 * @name: Device name to write
 */
void acpigen_write_device(struct acpi_ctx *ctx, const char *name);

/**
 * acpigen_write_sta() - Write a _STA method
 *
 * @ctx: ACPI context pointer
 * @status: Status value to return
 */
void acpigen_write_sta(struct acpi_ctx *ctx, uint status);

/**
 * acpigen_write_resourcetemplate_header() - Write a ResourceTemplate header
 *
 * @ctx: ACPI context pointer
 */
void acpigen_write_resourcetemplate_header(struct acpi_ctx *ctx);

/**
 * acpigen_write_resourcetemplate_footer() - Write a ResourceTemplate footer
 *
 * @ctx: ACPI context pointer
 */
void acpigen_write_resourcetemplate_footer(struct acpi_ctx *ctx);

/**
 * acpigen_write_register_resource() - Write a register resource
 *
 * This writes a header, the address information and a footer
 *
 * @ctx: ACPI context pointer
 * @addr: Address to write
 */
void acpigen_write_register_resource(struct acpi_ctx *ctx,
				     const struct acpi_gen_regaddr *addr);

/**
 * acpigen_write_sleep() - Write a sleep operation
 *
 * @ctx: ACPI context pointer
 * @sleep_ms: Number of milliseconds to sleep for
 */
void acpigen_write_sleep(struct acpi_ctx *ctx, u64 sleep_ms);

/**
 * acpigen_write_store() - Write a store operation
 *
 * @ctx: ACPI context pointer
 */
void acpigen_write_store(struct acpi_ctx *ctx);

/**
 * acpigen_write_debug_string() - Write a debug string
 *
 * This writes a debug operation with an associated string
 *
 * @ctx: ACPI context pointer
 * @str: String to write
 */
void acpigen_write_debug_string(struct acpi_ctx *ctx, const char *str);

/**
 * acpigen_write_or() - Write a bitwise OR operation
 *
 * res = arg1 | arg2
 *
 * @ctx: ACPI context pointer
 * @arg1: ACPI opcode for operand 1 (e.g. LOCAL0_OP)
 * @arg2: ACPI opcode for operand 2 (e.g. LOCAL1_OP)
 * @res: ACPI opcode for result (e.g. LOCAL2_OP)
 */
void acpigen_write_or(struct acpi_ctx *ctx, u8 arg1, u8 arg2, u8 res);

/**
 * acpigen_write_and() - Write a bitwise AND operation
 *
 * res = arg1 & arg2
 *
 * @ctx: ACPI context pointer
 * @arg1: ACPI opcode for operand 1 (e.g. LOCAL0_OP)
 * @arg2: ACPI opcode for operand 2 (e.g. LOCAL1_OP)
 * @res: ACPI opcode for result (e.g. LOCAL2_OP)
 */
void acpigen_write_and(struct acpi_ctx *ctx, u8 arg1, u8 arg2, u8 res);

/**
 * acpigen_write_not() - Write a bitwise NOT operation
 *
 * res = ~arg1
 *
 * @ctx: ACPI context pointer
 * @arg: ACPI opcode for operand (e.g. LOCAL0_OP)
 * @res: ACPI opcode for result (e.g. LOCAL2_OP)
 */
void acpigen_write_not(struct acpi_ctx *ctx, u8 arg, u8 res);

/**
 * acpigen_write_power_res() - Write a power resource
 *
 * Name (_PRx, Package(One) { name })
 * ...
 * PowerResource (name, level, order)
 *
 * The caller should fill in the rest of the power resource and then call
 * acpigen_pop_len() to close it off
 *
 * @ctx: ACPI context pointer
 * @name: Name of power resource (e.g. "PRIC")
 * @level: Deepest sleep level that this resource must be kept on (0=S0, 3=S3)
 * @order: Order that this must be enabled/disabled (e.g. 0)
 * @dev_stats: List of states to define, e.g. {"_PR0", "_PR3"}
 * @dev_states_count: Number of dev states
 */
void acpigen_write_power_res(struct acpi_ctx *ctx, const char *name, uint level,
			     uint order, const char *const dev_states[],
			     size_t dev_states_count);

/**
 * acpigen_set_enable_tx_gpio() - Emit ACPI code to enable/disable a GPIO
 *
 * This emits code to either enable to disable a Tx GPIO. It takes account of
 * the GPIO polarity.
 *
 * The code needs access to the DW0 register for the pad being used. This is
 * provided by gpio->pin0_addr and ACPI methods must be defined for the board
 * which can read and write the pad's DW0 register given this address:
 *    @dw0_read: takes a single argument, the DW0 address
 *		 returns the DW0 value
 *    @dw0:write: takes two arguments, the DW0 address and the value to write
 *		 no return value
 *
 * Example code (-- means comment):
 *
 *	-- Get Pad Configuration DW0 register value
 *	Method (GPC0, 0x1, Serialized)
 *	{
 *		-- Arg0 - GPIO DW0 address
 *		Store (Arg0, Local0)
 *		OperationRegion (PDW0, SystemMemory, Local0, 4)
 *		Field (PDW0, AnyAcc, NoLock, Preserve) {
 *			TEMP, 32
 *		}
 *		Return (TEMP)
 *	}
 *
 *	-- Set Pad Configuration DW0 register value
 *	Method (SPC0, 0x2, Serialized)
 *	{
 *		-- Arg0 - GPIO DW0 address
 *		-- Arg1 - Value for DW0 register
 *		Store (Arg0, Local0)
 *		OperationRegion (PDW0, SystemMemory, Local0, 4)
 *		Field (PDW0, AnyAcc, NoLock, Preserve) {
 *			TEMP,32
 *		}
 *		Store (Arg1, TEMP)
 *	}
 *
 *
 * @ctx: ACPI context pointer
 * @tx_state_val: Mask to use to toggle the TX state on the GPIO pin, e,g.
 *	PAD_CFG0_TX_STATE
 * @dw0_read: Method name to use to read dw0, e.g. "\\_SB.GPC0"
 * @dw0_write: Method name to use to read dw0, e.g. "\\_SB.SPC0"
 * @gpio: GPIO to change
 * @enable: true to enable GPIO, false to disable
 * Returns 0 on success, -ve on error.
 */
int acpigen_set_enable_tx_gpio(struct acpi_ctx *ctx, u32 tx_state_val,
			       const char *dw0_read, const char *dw0_write,
			       struct acpi_gpio *gpio, bool enable);

/**
 * acpigen_write_prw() - Write a power resource for wake (_PRW)
 *
 * @ctx: ACPI context pointer
 * @wake: GPE that wakes up the device
 * @level: Deepest power system sleeping state that can be entered while still
 *	providing wake functionality
 */
void acpigen_write_prw(struct acpi_ctx *ctx, uint wake, uint level);

/**
 * acpigen_write_if() - Write an If block
 *
 * This requires a call to acpigen_pop_len() to complete the block
 *
 * @ctx: ACPI context pointer
 */
void acpigen_write_if(struct acpi_ctx *ctx);

/**
 * acpigen_write_if_lequal_op_int() - Write comparison between op and integer
 *
 * Generates ACPI code for checking if operand1 and operand2 are equal
 *
 * If (Lequal (op, val))
 *
 * @ctx: ACPI context pointer
 * @op: Operand to check
 * @val: Value to check against
 */
void acpigen_write_if_lequal_op_int(struct acpi_ctx *ctx, uint op, u64 val);

/**
 * acpigen_write_else() - Write an Ef block
 *
 * This requires a call to acpigen_pop_len() to complete the block
 *
 * @ctx: ACPI context pointer
 */
void acpigen_write_else(struct acpi_ctx *ctx);

/**
 * acpigen_write_to_buffer() - Write a ToBuffer operation
 *
 * E.g.: to generate: ToBuffer (Arg0, Local0)
 * use acpigen_write_to_buffer(ctx, ARG0_OP, LOCAL0_OP)
 *
 * @ctx: ACPI context pointer
 * @src: Source argument
 * @dst: Destination argument
 */
void acpigen_write_to_buffer(struct acpi_ctx *ctx, uint src, uint dst);

/**
 * acpigen_write_to_integer() - Write a ToInteger operation
 *
 * E.g.: to generate: ToInteger (Arg0, Local0)
 * use acpigen_write_to_integer(ctx, ARG0_OP, LOCAL0_OP)
 *
 * @ctx: ACPI context pointer
 * @src: Source argument
 * @dst: Destination argument
 */
void acpigen_write_to_integer(struct acpi_ctx *ctx, uint src, uint dst);

/**
 * acpigen_write_return_byte_buffer() - Write a return of a byte buffer
 *
 * @ctx: ACPI context pointer
 * @arr: Array of bytes to return
 * @size: Number of bytes
 */
void acpigen_write_return_byte_buffer(struct acpi_ctx *ctx, u8 *arr,
				      size_t size);

/**
 * acpigen_write_return_singleton_buffer() - Write a return of a 1-byte buffer
 *
 * @ctx: ACPI context pointer
 * @arg: Byte to return
 */
void acpigen_write_return_singleton_buffer(struct acpi_ctx *ctx, uint arg);

/**
 * acpigen_write_return_byte() - Write a return of a byte
 *
 * @ctx: ACPI context pointer
 * @arg: Byte to return
 */
void acpigen_write_return_byte(struct acpi_ctx *ctx, uint arg);

/**
 * acpigen_write_dsm_start() - Start a _DSM method
 *
 * Generate ACPI AML code to start the _DSM method.
 *
 * The functions need to be called in the correct sequence as below.
 *
 * Within the <generate-code-here> region, Local0 and Local1 must be are left
 * untouched, but Local2-Local7 can be used
 *
 * Arguments passed into _DSM method:
 * Arg0 = UUID
 * Arg1 = Revision
 * Arg2 = Function index
 * Arg3 = Function-specific arguments
 *
 * AML code generated looks like this:
 * Method (_DSM, 4, Serialized) {   -- acpigen_write_dsm_start)
 *	ToBuffer (Arg0, Local0)
 *	If (LEqual (Local0, ToUUID(uuid))) {  -- acpigen_write_dsm_uuid_start
 *		ToInteger (Arg2, Local1)
 *		If (LEqual (Local1, 0)) {  -- acpigen_write_dsm_uuid_start_cond
 *			<generate-code-here>
 *		}                          -- acpigen_write_dsm_uuid_end_cond
 *		...
 *		If (LEqual (Local1, n)) {  -- acpigen_write_dsm_uuid_start_cond
 *			<generate-code-here>
 *		}                          -- acpigen_write_dsm_uuid_end_cond
 *		Return (Buffer (One) { 0x0 })
 *	}                                  -- acpigen_write_dsm_uuid_end
 *	...
 *	If (LEqual (Local0, ToUUID(uuidn))) {
 *	...
 *	}
 *	Return (Buffer (One) { 0x0 })  -- acpigen_write_dsm_end
 * }
 *
 * @ctx: ACPI context pointer
 */
void acpigen_write_dsm_start(struct acpi_ctx *ctx);

/**
 * acpigen_write_dsm_uuid_start() - Start a new UUID block
 *
 * This starts generation of code to handle a particular UUID:
 *
 *	If (LEqual (Local0, ToUUID(uuid))) {
 *		ToInteger (Arg2, Local1)
 *
 * @ctx: ACPI context pointer
 */
int acpigen_write_dsm_uuid_start(struct acpi_ctx *ctx, const char *uuid);

/**
 * acpigen_write_dsm_uuid_start_cond() - Start a new condition block
 *
 * This starts generation of condition-checking code to handle a particular
 * function:
 *
 *		If (LEqual (Local1, i))
 *
 * @ctx: ACPI context pointer
 */
void acpigen_write_dsm_uuid_start_cond(struct acpi_ctx *ctx, int seq);

/**
 * acpigen_write_dsm_uuid_end_cond() - Start a new condition block
 *
 * This ends generation of condition-checking code to handle a particular
 * function:
 *
 *		}
 *
 * @ctx: ACPI context pointer
 */
void acpigen_write_dsm_uuid_end_cond(struct acpi_ctx *ctx);

/**
 * acpigen_write_dsm_uuid_end() - End a UUID block
 *
 * This ends generation of code to handle a particular UUID:
 *
 *		Return (Buffer (One) { 0x0 })
 *
 * @ctx: ACPI context pointer
 */
void acpigen_write_dsm_uuid_end(struct acpi_ctx *ctx);

/**
 * acpigen_write_dsm_end() - End a _DSM method
 *
 * This ends generates of the _DSM block:
 *
 *	Return (Buffer (One) { 0x0 })
 *
 * @ctx: ACPI context pointer
 */
void acpigen_write_dsm_end(struct acpi_ctx *ctx);

/**
 * acpigen_write_processor() - Write a Processor package
 *
 * This emits a Processor package header with the required information. The
 * caller must complete the information and call acpigen_pop_len() at the end
 * Deprecated since ACPI 6.0.
 *
 * @ctx: ACPI context pointer
 * @cpuindex: CPU number
 * @pblock_addr: PBlk system IO address
 * @pblock_len: PBlk length
 */
void acpigen_write_processor(struct acpi_ctx *ctx, uint cpuindex,
			     u32 pblock_addr, uint pblock_len);

/**
 * acpigen_write_processor_device() - Write a Processor device
 *
 * Write a device with _HID ACPI0007 identifying a processor.
 * Replacement for the Processor OpCode.
 *
 * @ctx: ACPI context pointer
 * @cpuindex: CPU number
 */
void acpigen_write_processor_device(struct acpi_ctx *ctx, uint cpuindex);

/**
 * acpigen_write_processor_package() - Write a package containing the processors
 *
 * The package containins the name of each processor in the SoC
 *
 * @ctx: ACPI context pointer
 * @name: Package name (.e.g "PPKG")
 * @first_core: Number of the first core (e.g. 0)
 * @core_count: Number of cores (e.g. 4)
 */
void acpigen_write_processor_package(struct acpi_ctx *ctx, const char *name,
				     uint first_core, uint core_count);

/**
 * acpigen_write_processor_cnot() - Write a processor notification method
 *
 * This writes a method that notifies all CPU cores
 *
 * @ctx: ACPI context pointer
 * @num_cores: Number of CPU cores
 */
void acpigen_write_processor_cnot(struct acpi_ctx *ctx, const uint num_cores);

/**
 * acpigen_write_ppc() - generates a function returning max P-states
 *
 * @ctx: ACPI context pointer
 * @num_pstates: Number of pstates to return
 */
void acpigen_write_ppc(struct acpi_ctx *ctx, uint num_pstates);

/**
 * acpigen_write_ppc() - generates a function returning PPCM
 *
 * This returns the maximum number of supported P-states, as saved in the
 * variable PPCM
 *
 * @ctx: ACPI context pointer
 */
void acpigen_write_ppc_nvs(struct acpi_ctx *ctx);

/**
 * acpigen_write_tpc() - Write a _TPC method that returns the TPC limit
 *
 * @ctx: ACPI context pointer
 * @gnvs_tpc_limit: Variable that holds the TPC limit
 */
void acpigen_write_tpc(struct acpi_ctx *ctx, const char *gnvs_tpc_limit);

/**
 * acpigen_write_pss_package() - Write a PSS package
 *
 * See ACPI v6.3 section 8.4.6: Processor Performance Control
 *
 * @ctx: ACPI context pointer
 * @corefreq: CPU core frequency in MHz
 * @translat: worst-case latency in uS that the CPU is unavailable during a
 *	transition from any performance state to this performance state
 * @busmlat: worst-case latency in microseconds that Bus Masters are prevented
 *	from accessing memory during a transition from any performance state to
 *	this performance state
 * @control: Value to write to PERF_CTRL to move to this performance state
 * @status: Expected PERF_STATUS value when in this state
 */
void acpigen_write_pss_package(struct acpi_ctx *ctx, uint corefreq, uint power,
			       uint translat, uint busmlat, uint control,
			       uint status);

/**
 * acpigen_write_psd_package() - Write a PSD package
 *
 * Writes a P-State dependency package
 *
 * See ACPI v6.3 section 8.4.6.5: _PSD (P-State Dependency)
 *
 * @ctx: ACPI context pointer
 * @domain: Dependency domain number to which this P state entry belongs
 * @numprocs: Number of processors belonging to the domain for this logical
 *	processor's P-states
 * @coordtype: Coordination type
 */
void acpigen_write_psd_package(struct acpi_ctx *ctx, uint domain, uint numprocs,
			       enum psd_coord coordtype);

/**
 * acpigen_write_cst_package() - Write a _CST package
 *
 * See ACPI v6.3 section 8.4.2.1: _CST (C States)
 *
 * @ctx: ACPI context pointer
 * @entry: Array of entries
 * @nentries; Number of entries
 */
void acpigen_write_cst_package(struct acpi_ctx *ctx,
			       const struct acpi_cstate *entry, int nentries);

/**
 * acpigen_write_csd_package() - Write a _CSD Package
 *
 * See ACPI v6.3 section 8.4.2.2: _CSD (C-State Dependency)
 *
 * @ctx: ACPI context pointer
 * @domain: dependency domain number to which this C state entry belongs
 * @numprocs: number of processors belonging to the domain for the particular
 *	C-state
 * @coordtype: Co-ordination type
 * @index: Index of the C-State entry in the _CST object for which the
 *	dependency applies
 */
void acpigen_write_csd_package(struct acpi_ctx *ctx, uint domain, uint numprocs,
			       enum csd_coord coordtype, uint index);

/**
 * acpigen_write_tss_package() - Write a _TSS package
 *
 * @ctx: ACPI context pointer
 * @entry: Entries to write
 * @nentries: Number of entries to write
 */
void acpigen_write_tss_package(struct acpi_ctx *ctx,
			       struct acpi_tstate *entry, int nentries);

/**
 * acpigen_write_tsd_package() - Write a _TSD package
 *
 * See ACPI v6.3 section 8.4.5.4: _TSD (T-State Dependency)
 *
 * @ctx: ACPI context pointer
 * @domain: dependency domain number to which this T state entry belongs
 * @numprocs: Number of processors belonging to the domain for this logical
 *	processor's T-states
 * @coordtype: Coordination type
 */
void acpigen_write_tsd_package(struct acpi_ctx *ctx, uint domain, uint numprocs,
			       enum psd_coord coordtype);

#endif