include/lib/power_management.h - TF-A/tf-a-tests - TrustedFirmware Git Browser

 /*
  * Copyright (c) 2018, Arm Limited. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #ifndef __POWER_MANAGEMENT_H__
 #define __POWER_MANAGEMENT_H__

 #include <platform_def.h>
 #include <psci.h>
 #include <spinlock.h>
 #include <stdint.h>
 #include <types.h>

 /* Set of states of an affinity node as seen by the Test Framework */
 typedef enum {
 	TFTF_AFFINITY_STATE_OFF = 0,
 	TFTF_AFFINITY_STATE_ON_PENDING,
 	TFTF_AFFINITY_STATE_ON,
 } tftf_affinity_info_t;

 /* Structure for keeping track of CPU state */
 typedef struct {
 	volatile tftf_affinity_info_t state;
 	spinlock_t lock;
 } __aligned(CACHE_WRITEBACK_GRANULE) tftf_cpu_state_t;

 /*
  * Suspend information passed to the TFTF suspend helpers.
  */
 typedef struct suspend_info {
 	/* The power state parameter to be passed to PSCI_CPU_SUSPEND */
 	unsigned int power_state;
 	/* SMC function ID of the PSCI suspend call */
 	unsigned int psci_api;
 	/* Whether the system context needs to be saved and restored */
 	unsigned int save_system_context;
 } suspend_info_t;

 /*
  * Power up a core.
  * This uses the PSCI CPU_ON API, which means it relies on the EL3 firmware's
  * runtime services capabilities.
  * The core will be boostrapped by the framework before handing it over
  * to the entry point specified as the 2nd argument.
  *
  *    target_cpu: MPID of the CPU to power up
  *    entrypoint: Address where the CPU will jump once the framework has
  *                initialized it
  *    context_id: Context identifier as defined by the PSCI specification
  *
  *    Return: Return code of the PSCI CPU_ON call
  *            (refer to the PSCI specification for details)
  */
 int32_t tftf_cpu_on(u_register_t target_cpu,
 		    uintptr_t entrypoint,
 		    u_register_t context_id);

 /*
  * Tries to power up a core.
  * This API is similar to tftf_cpu_on API with the difference being it
  * does a SMC call to EL3 firmware without checking the status of the
  * core with respect to the framework.
  *
  * A caller is expected to handle the return code given by the EL3 firmware.
  *
  *    target_cpu: MPID of the CPU to power up
  *    entrypoint: Address where the CPU will jump once the framework has
  *                initialised it
  *    context_id: Context identifier as defined by the PSCI specification
  *
  *    Return: Return code of the PSCI CPU_ON call
  *            (refer to the PSCI specification for details)
  */
 int32_t tftf_try_cpu_on(u_register_t target_cpu,
 		    uintptr_t entrypoint,
 		    u_register_t context_id);

 /*
  * Power down the calling core.
  * This uses the PSCI CPU_OFF API, which means it relies on the EL3 firmware's
  * runtime services capabilities.
  *
  *    Return: This function does not return when successful.
  *            Otherwise, return the same error code as the PSCI CPU_OFF call
  *            (refer to the PSCI specification for details)
  */
 int32_t tftf_cpu_off(void);

 /*
  * It is an Api used to enter a suspend state. It does the following:
  * - Allocates space for saving architectural and non-architectural CPU state on
  *   stack
  * - Saves architecture state of the CPU in the space allocated which consists:
  *      a. Callee registers
  *      b. System control registers. ex: MMU, SCTLR_EL1
  * - Depending on the state of `save_system_context` flag in suspend_info
  *   saves the context of system peripherals like GIC, timer etc.
  * - Sets context ID to the base of the stack allocated for saving context
  * - Calls Secure Platform Firmware to enter suspend
  * - If suspend fails, It restores the callee registers
  *     power state: PSCI power state to be sent via SMC
  *     Returns: PSCI_E_SUCCESS or PSCI_E_INVALID_PARAMS
  *
  * Note: This api might not test all use cases, as the context ID and resume
  * entrypoint is in the control of the framework.
  */
 int tftf_suspend(const suspend_info_t *info);


 /* ----------------------------------------------------------------------------
  * The above APIs might not be suitable in all test scenarios.
  * A test case could want to bypass those APIs i.e. call the PSCI APIs
  * directly. In this case, it is the responsibility of the test case to preserve
  * the state of the framework. The below APIs are provided to this end.
  * ----------------------------------------------------------------------------
  */

 /*
  * The 3 following functions are used to manipulate the reference count tracking
  * the number of CPUs participating in a test.
  */

 /*
  * Increment the reference count.
  * Return the new, incremented value.
  */
 unsigned int tftf_inc_ref_cnt(void);

 /*
  * Decrement the reference count.
  * Return the new, decremented value.
  */
 unsigned int tftf_dec_ref_cnt(void);

 /* Return the current reference count value */
 unsigned int tftf_get_ref_cnt(void);

 /*
  * Set the calling CPU online/offline. This only adjusts the view of the core
  * from the framework's point of view, it doesn't actually power up/down the
  * core.
  */
 void tftf_set_cpu_online(void);
 void tftf_init_cpus_status_map(void);
 void tftf_set_cpu_offline(void);

 /*
  * Query the state of a core.
  *   Return: 1 if the core is online, 0 otherwise.
  */
 unsigned int tftf_is_cpu_online(unsigned int mpid);

 unsigned int tftf_is_core_pos_online(unsigned int core_pos);

 /* TFTF Suspend helpers */
 static inline int tftf_cpu_suspend(unsigned int pwr_state)
 {
 	suspend_info_t info = {
 		.power_state = pwr_state,
 		.save_system_context = 0,
 		.psci_api = SMC_PSCI_CPU_SUSPEND,
 	};

 	return tftf_suspend(&info);
 }

 static inline int tftf_cpu_suspend_save_sys_ctx(unsigned int pwr_state)
 {
 	suspend_info_t info = {
 		.power_state = pwr_state,
 		.save_system_context = 1,
 		.psci_api = SMC_PSCI_CPU_SUSPEND,
 	};

 	return tftf_suspend(&info);
 }


 static inline int tftf_system_suspend(void)
 {
 	suspend_info_t info = {
 		.power_state = 0,
 		.save_system_context = 1,
 		.psci_api = SMC_PSCI_SYSTEM_SUSPEND,
 	};

 	return tftf_suspend(&info);
 }

 #endif /* __POWER_MANAGEMENT_H__ */
	/*
	* Copyright (c) 2018, Arm Limited. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#ifndef __POWER_MANAGEMENT_H__
	#define __POWER_MANAGEMENT_H__

	#include <platform_def.h>
	#include <psci.h>
	#include <spinlock.h>
	#include <stdint.h>
	#include <types.h>

	/* Set of states of an affinity node as seen by the Test Framework */
	typedef enum {
	TFTF_AFFINITY_STATE_OFF = 0,
	TFTF_AFFINITY_STATE_ON_PENDING,
	TFTF_AFFINITY_STATE_ON,
	} tftf_affinity_info_t;

	/* Structure for keeping track of CPU state */
	typedef struct {
	volatile tftf_affinity_info_t state;
	spinlock_t lock;
	} __aligned(CACHE_WRITEBACK_GRANULE) tftf_cpu_state_t;

	/*
	* Suspend information passed to the TFTF suspend helpers.
	*/
	typedef struct suspend_info {
	/* The power state parameter to be passed to PSCI_CPU_SUSPEND */
	unsigned int power_state;
	/* SMC function ID of the PSCI suspend call */
	unsigned int psci_api;
	/* Whether the system context needs to be saved and restored */
	unsigned int save_system_context;
	} suspend_info_t;

	/*
	* Power up a core.
	* This uses the PSCI CPU_ON API, which means it relies on the EL3 firmware's
	* runtime services capabilities.
	* The core will be boostrapped by the framework before handing it over
	* to the entry point specified as the 2nd argument.
	*
	* target_cpu: MPID of the CPU to power up
	* entrypoint: Address where the CPU will jump once the framework has
	* initialized it
	* context_id: Context identifier as defined by the PSCI specification
	*
	* Return: Return code of the PSCI CPU_ON call
	* (refer to the PSCI specification for details)
	*/
	int32_t tftf_cpu_on(u_register_t target_cpu,
	uintptr_t entrypoint,
	u_register_t context_id);

	/*
	* Tries to power up a core.
	* This API is similar to tftf_cpu_on API with the difference being it
	* does a SMC call to EL3 firmware without checking the status of the
	* core with respect to the framework.
	*
	* A caller is expected to handle the return code given by the EL3 firmware.
	*
	* target_cpu: MPID of the CPU to power up
	* entrypoint: Address where the CPU will jump once the framework has
	* initialised it
	* context_id: Context identifier as defined by the PSCI specification
	*
	* Return: Return code of the PSCI CPU_ON call
	* (refer to the PSCI specification for details)
	*/
	int32_t tftf_try_cpu_on(u_register_t target_cpu,
	uintptr_t entrypoint,
	u_register_t context_id);

	/*
	* Power down the calling core.
	* This uses the PSCI CPU_OFF API, which means it relies on the EL3 firmware's
	* runtime services capabilities.
	*
	* Return: This function does not return when successful.
	* Otherwise, return the same error code as the PSCI CPU_OFF call
	* (refer to the PSCI specification for details)
	*/
	int32_t tftf_cpu_off(void);

	/*
	* It is an Api used to enter a suspend state. It does the following:
	* - Allocates space for saving architectural and non-architectural CPU state on
	* stack
	* - Saves architecture state of the CPU in the space allocated which consists:
	* a. Callee registers
	* b. System control registers. ex: MMU, SCTLR_EL1
	* - Depending on the state of `save_system_context` flag in suspend_info
	* saves the context of system peripherals like GIC, timer etc.
	* - Sets context ID to the base of the stack allocated for saving context
	* - Calls Secure Platform Firmware to enter suspend
	* - If suspend fails, It restores the callee registers
	* power state: PSCI power state to be sent via SMC
	* Returns: PSCI_E_SUCCESS or PSCI_E_INVALID_PARAMS
	*
	* Note: This api might not test all use cases, as the context ID and resume
	* entrypoint is in the control of the framework.
	*/
	int tftf_suspend(const suspend_info_t *info);


	/* ----------------------------------------------------------------------------
	* The above APIs might not be suitable in all test scenarios.
	* A test case could want to bypass those APIs i.e. call the PSCI APIs
	* directly. In this case, it is the responsibility of the test case to preserve
	* the state of the framework. The below APIs are provided to this end.
	* ----------------------------------------------------------------------------
	*/

	/*
	* The 3 following functions are used to manipulate the reference count tracking
	* the number of CPUs participating in a test.
	*/

	/*
	* Increment the reference count.
	* Return the new, incremented value.
	*/
	unsigned int tftf_inc_ref_cnt(void);

	/*
	* Decrement the reference count.
	* Return the new, decremented value.
	*/
	unsigned int tftf_dec_ref_cnt(void);

	/* Return the current reference count value */
	unsigned int tftf_get_ref_cnt(void);

	/*
	* Set the calling CPU online/offline. This only adjusts the view of the core
	* from the framework's point of view, it doesn't actually power up/down the
	* core.
	*/
	void tftf_set_cpu_online(void);
	void tftf_init_cpus_status_map(void);
	void tftf_set_cpu_offline(void);

	/*
	* Query the state of a core.
	* Return: 1 if the core is online, 0 otherwise.
	*/
	unsigned int tftf_is_cpu_online(unsigned int mpid);

	unsigned int tftf_is_core_pos_online(unsigned int core_pos);

	/* TFTF Suspend helpers */
	static inline int tftf_cpu_suspend(unsigned int pwr_state)
	{
	suspend_info_t info = {
	.power_state = pwr_state,
	.save_system_context = 0,
	.psci_api = SMC_PSCI_CPU_SUSPEND,
	};

	return tftf_suspend(&info);
	}

	static inline int tftf_cpu_suspend_save_sys_ctx(unsigned int pwr_state)
	{
	suspend_info_t info = {
	.power_state = pwr_state,
	.save_system_context = 1,
	.psci_api = SMC_PSCI_CPU_SUSPEND,
	};

	return tftf_suspend(&info);
	}


	static inline int tftf_system_suspend(void)
	{
	suspend_info_t info = {
	.power_state = 0,
	.save_system_context = 1,
	.psci_api = SMC_PSCI_SYSTEM_SUSPEND,
	};

	return tftf_suspend(&info);
	}

	#endif /* __POWER_MANAGEMENT_H__ */