arch/x86/include/asm/mp.h - mirrors/cros/chromiumos/third_party/u-boot - Git at Google

 /* SPDX-License-Identifier: GPL-2.0 */
 /*
  * Copyright (c) 2015 Google, Inc
  *
  * Taken from coreboot file of the same name
  */

 #ifndef _X86_MP_H_
 #define _X86_MP_H_

 #include <asm/atomic.h>
 #include <asm/cache.h>
 #include <linux/bitops.h>

 struct udevice;

 enum {
 	/*
 	 * Indicates that the function should run on all CPUs. We use a large
 	 * number, above the number of real CPUs we expect to find.
 	 */
 	MP_SELECT_ALL	= BIT(16),

 	/* Run on boot CPUs */
 	MP_SELECT_BSP,

 	/* Run on non-boot CPUs */
 	MP_SELECT_APS,
 };

 typedef int (*mp_callback_t)(struct udevice *cpu, void *arg);

 /*
  * A mp_flight_record details a sequence of calls for the APs to perform
  * along with the BSP to coordinate sequencing. Each flight record either
  * provides a barrier for each AP before calling the callback or the APs
  * are allowed to perform the callback without waiting. Regardless, each
  * record has the cpus_entered field incremented for each record. When
  * the BSP observes that the cpus_entered matches the number of APs
  * the bsp_call is called with bsp_arg and upon returning releases the
  * barrier allowing the APs to make further progress.
  *
  * Note that ap_call() and bsp_call() can be NULL. In the NULL case the
  * callback will just not be called.
  *
  * @barrier: Ensures that the BSP and AP don't run the flight record at the same
  *	time
  * @cpus_entered: Counts the number of APs that have run this record
  * @ap_call: Function for the APs to call
  * @ap_arg: Argument to pass to @ap_call
  * @bsp_call: Function for the BSP to call
  * @bsp_arg: Argument to pass to @bsp_call
  */
 struct mp_flight_record {
 	atomic_t barrier;
 	atomic_t cpus_entered;
 	mp_callback_t ap_call;
 	void *ap_arg;
 	mp_callback_t bsp_call;
 	void *bsp_arg;
 } __attribute__((aligned(ARCH_DMA_MINALIGN)));

 #define MP_FLIGHT_RECORD(barrier_, ap_func_, ap_arg_, bsp_func_, bsp_arg_) \
 	{							\
 		.barrier = ATOMIC_INIT(barrier_),		\
 		.cpus_entered = ATOMIC_INIT(0),			\
 		.ap_call = ap_func_,				\
 		.ap_arg = ap_arg_,				\
 		.bsp_call = bsp_func_,				\
 		.bsp_arg = bsp_arg_,				\
 	}

 #define MP_FR_BLOCK_APS(ap_func, ap_arg, bsp_func, bsp_arg) \
 	MP_FLIGHT_RECORD(0, ap_func, ap_arg, bsp_func, bsp_arg)

 #define MP_FR_NOBLOCK_APS(ap_func, ap_arg, bsp_func, bsp_arg) \
 	MP_FLIGHT_RECORD(1, ap_func, ap_arg, bsp_func, bsp_arg)

 /*
  * mp_init() will set up the SIPI vector and bring up the APs according to
  * mp_params. Each flight record will be executed according to the plan. Note
  * that the MP infrastructure uses SMM default area without saving it. It's
  * up to the chipset or mainboard to either e820 reserve this area or save this
  * region prior to calling mp_init() and restoring it after mp_init returns.
  *
  * At the time mp_init() is called the MTRR MSRs are mirrored into APs then
  * caching is enabled before running the flight plan.
  *
  * The MP init has the following properties:
  * 1. APs are brought up in parallel.
  * 2. The ordering of cpu number and APIC ids is not deterministic.
  *    Therefore, one cannot rely on this property or the order of devices in
  *    the device tree unless the chipset or mainboard know the APIC ids
  *    a priori.
  *
  * mp_init() returns < 0 on error, 0 on success.
  */
 int mp_init(void);

 /**
  * x86_mp_init() - Set up additional CPUs
  *
  * @returns < 0 on error, 0 on success.
  */
 int x86_mp_init(void);

 /**
  * mp_run_func() - Function to call on the AP
  *
  * @arg: Argument to pass
  */
 typedef void (*mp_run_func)(void *arg);

 #if CONFIG_IS_ENABLED(SMP) && !CONFIG_IS_ENABLED(X86_64)
 /**
  * mp_run_on_cpus() - Run a function on one or all CPUs
  *
  * This does not return until all CPUs have completed the work
  *
  * Running on anything other than the boot CPU is only supported if
  * CONFIG_SMP_AP_WORK is enabled
  *
  * @cpu_select: CPU to run on (its dev_seq() value), or MP_SELECT_ALL for
  *	all, or MP_SELECT_BSP for BSP
  * @func: Function to run
  * @arg: Argument to pass to the function
  * @return 0 on success, -ve on error
  */
 int mp_run_on_cpus(int cpu_select, mp_run_func func, void *arg);

 /**
  * mp_park_aps() - Park the APs ready for the OS
  *
  * This halts all CPUs except the main one, ready for the OS to use them
  *
  * @return 0 if OK, -ve on error
  */
 int mp_park_aps(void);

 /**
  * mp_first_cpu() - Get the first CPU to process, from a selection
  *
  * This is used to iterate through selected CPUs. Call this function first, then
  * call mp_next_cpu() repeatedly (with the same @cpu_select) until it returns
  * -EFBIG.
  *
  * @cpu_select: Selected CPUs (either a CPU number or MP_SELECT_...)
  * @return next CPU number to run on (e.g. 0)
  */
 int mp_first_cpu(int cpu_select);

 /**
  * mp_next_cpu() - Get the next CPU to process, from a selection
  *
  * This is used to iterate through selected CPUs. After first calling
  * mp_first_cpu() once, call this function repeatedly until it returns -EFBIG.
  *
  * The value of @cpu_select must be the same for all calls and must match the
  * value passed to mp_first_cpu(), otherwise the behaviour is undefined.
  *
  * @cpu_select: Selected CPUs (either a CPU number or MP_SELECT_...)
  * @prev_cpu: Previous value returned by mp_first_cpu()/mp_next_cpu()
  * @return next CPU number to run on (e.g. 0)
  */
 int mp_next_cpu(int cpu_select, int prev_cpu);
 #else
 static inline int mp_run_on_cpus(int cpu_select, mp_run_func func, void *arg)
 {
 	/* There is only one CPU, so just call the function here */
 	func(arg);

 	return 0;
 }

 static inline int mp_park_aps(void)
 {
 	/* No APs to park */

 	return 0;
 }

 static inline int mp_first_cpu(int cpu_select)
 {
 	/* We cannot run on any APs, nor a selected CPU */
 	return cpu_select == MP_SELECT_APS ? -EFBIG : MP_SELECT_BSP;
 }

 static inline int mp_next_cpu(int cpu_select, int prev_cpu)
 {
 	/*
 	 * When MP is not enabled, there is only one CPU and we did it in
 	 * mp_first_cpu()
 	 */
 	return -EFBIG;
 }

 #endif

 #endif /* _X86_MP_H_ */
	/* SPDX-License-Identifier: GPL-2.0 */
	/*
	* Copyright (c) 2015 Google, Inc
	*
	* Taken from coreboot file of the same name
	*/

	#ifndef _X86_MP_H_
	#define _X86_MP_H_

	#include <asm/atomic.h>
	#include <asm/cache.h>
	#include <linux/bitops.h>

	struct udevice;

	enum {
	/*
	* Indicates that the function should run on all CPUs. We use a large
	* number, above the number of real CPUs we expect to find.
	*/
	MP_SELECT_ALL = BIT(16),

	/* Run on boot CPUs */
	MP_SELECT_BSP,

	/* Run on non-boot CPUs */
	MP_SELECT_APS,
	};

	typedef int (mp_callback_t)(struct udevice cpu, void *arg);

	/*
	* A mp_flight_record details a sequence of calls for the APs to perform
	* along with the BSP to coordinate sequencing. Each flight record either
	* provides a barrier for each AP before calling the callback or the APs
	* are allowed to perform the callback without waiting. Regardless, each
	* record has the cpus_entered field incremented for each record. When
	* the BSP observes that the cpus_entered matches the number of APs
	* the bsp_call is called with bsp_arg and upon returning releases the
	* barrier allowing the APs to make further progress.
	*
	* Note that ap_call() and bsp_call() can be NULL. In the NULL case the
	* callback will just not be called.
	*
	* @barrier: Ensures that the BSP and AP don't run the flight record at the same
	* time
	* @cpus_entered: Counts the number of APs that have run this record
	* @ap_call: Function for the APs to call
	* @ap_arg: Argument to pass to @ap_call
	* @bsp_call: Function for the BSP to call
	* @bsp_arg: Argument to pass to @bsp_call
	*/
	struct mp_flight_record {
	atomic_t barrier;
	atomic_t cpus_entered;
	mp_callback_t ap_call;
	void *ap_arg;
	mp_callback_t bsp_call;
	void *bsp_arg;
	} __attribute__((aligned(ARCH_DMA_MINALIGN)));

	#define MP_FLIGHT_RECORD(barrier_, ap_func_, ap_arg_, bsp_func_, bsp_arg_) \
	{ \
	.barrier = ATOMIC_INIT(barrier_), \
	.cpus_entered = ATOMIC_INIT(0), \
	.ap_call = ap_func_, \
	.ap_arg = ap_arg_, \
	.bsp_call = bsp_func_, \
	.bsp_arg = bsp_arg_, \
	}

	#define MP_FR_BLOCK_APS(ap_func, ap_arg, bsp_func, bsp_arg) \
	MP_FLIGHT_RECORD(0, ap_func, ap_arg, bsp_func, bsp_arg)

	#define MP_FR_NOBLOCK_APS(ap_func, ap_arg, bsp_func, bsp_arg) \
	MP_FLIGHT_RECORD(1, ap_func, ap_arg, bsp_func, bsp_arg)

	/*
	* mp_init() will set up the SIPI vector and bring up the APs according to
	* mp_params. Each flight record will be executed according to the plan. Note
	* that the MP infrastructure uses SMM default area without saving it. It's
	* up to the chipset or mainboard to either e820 reserve this area or save this
	* region prior to calling mp_init() and restoring it after mp_init returns.
	*
	* At the time mp_init() is called the MTRR MSRs are mirrored into APs then
	* caching is enabled before running the flight plan.
	*
	* The MP init has the following properties:
	* 1. APs are brought up in parallel.
	* 2. The ordering of cpu number and APIC ids is not deterministic.
	* Therefore, one cannot rely on this property or the order of devices in
	* the device tree unless the chipset or mainboard know the APIC ids
	* a priori.
	*
	* mp_init() returns < 0 on error, 0 on success.
	*/
	int mp_init(void);

	/**
	* x86_mp_init() - Set up additional CPUs
	*
	* @returns < 0 on error, 0 on success.
	*/
	int x86_mp_init(void);

	/**
	* mp_run_func() - Function to call on the AP
	*
	* @arg: Argument to pass
	*/
	typedef void (mp_run_func)(void arg);

	#if CONFIG_IS_ENABLED(SMP) && !CONFIG_IS_ENABLED(X86_64)
	/**
	* mp_run_on_cpus() - Run a function on one or all CPUs
	*
	* This does not return until all CPUs have completed the work
	*
	* Running on anything other than the boot CPU is only supported if
	* CONFIG_SMP_AP_WORK is enabled
	*
	* @cpu_select: CPU to run on (its dev_seq() value), or MP_SELECT_ALL for
	* all, or MP_SELECT_BSP for BSP
	* @func: Function to run
	* @arg: Argument to pass to the function
	* @return 0 on success, -ve on error
	*/
	int mp_run_on_cpus(int cpu_select, mp_run_func func, void *arg);

	/**
	* mp_park_aps() - Park the APs ready for the OS
	*
	* This halts all CPUs except the main one, ready for the OS to use them
	*
	* @return 0 if OK, -ve on error
	*/
	int mp_park_aps(void);

	/**
	* mp_first_cpu() - Get the first CPU to process, from a selection
	*
	* This is used to iterate through selected CPUs. Call this function first, then
	* call mp_next_cpu() repeatedly (with the same @cpu_select) until it returns
	* -EFBIG.
	*
	* @cpu_select: Selected CPUs (either a CPU number or MP_SELECT_...)
	* @return next CPU number to run on (e.g. 0)
	*/
	int mp_first_cpu(int cpu_select);

	/**
	* mp_next_cpu() - Get the next CPU to process, from a selection
	*
	* This is used to iterate through selected CPUs. After first calling
	* mp_first_cpu() once, call this function repeatedly until it returns -EFBIG.
	*
	* The value of @cpu_select must be the same for all calls and must match the
	* value passed to mp_first_cpu(), otherwise the behaviour is undefined.
	*
	* @cpu_select: Selected CPUs (either a CPU number or MP_SELECT_...)
	* @prev_cpu: Previous value returned by mp_first_cpu()/mp_next_cpu()
	* @return next CPU number to run on (e.g. 0)
	*/
	int mp_next_cpu(int cpu_select, int prev_cpu);
	#else
	static inline int mp_run_on_cpus(int cpu_select, mp_run_func func, void *arg)
	{
	/* There is only one CPU, so just call the function here */
	func(arg);

	return 0;
	}

	static inline int mp_park_aps(void)
	{
	/* No APs to park */

	return 0;
	}

	static inline int mp_first_cpu(int cpu_select)
	{
	/* We cannot run on any APs, nor a selected CPU */
	return cpu_select == MP_SELECT_APS ? -EFBIG : MP_SELECT_BSP;
	}

	static inline int mp_next_cpu(int cpu_select, int prev_cpu)
	{
	/*
	* When MP is not enabled, there is only one CPU and we did it in
	* mp_first_cpu()
	*/
	return -EFBIG;
	}

	#endif

	#endif /* _X86_MP_H_ */