kernel/include/kernel_internal.h - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2010-2012, 2014-2015 Wind River Systems, Inc.
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 /**
  * @file
  * @brief Architecture-independent private kernel APIs
  *
  * This file contains private kernel APIs that are not architecture-specific.
  */

 #ifndef _NANO_INTERNAL__H_
 #define _NANO_INTERNAL__H_

 #include <kernel.h>

 #ifndef _ASMLANGUAGE

 #ifdef __cplusplus
 extern "C" {
 #endif

 /* Early boot functions */

 void _bss_zero(void);
 #ifdef CONFIG_XIP
 void _data_copy(void);
 #else
 static inline void _data_copy(void)
 {
 	/* Do nothing */
 }
 #endif
 FUNC_NORETURN void _Cstart(void);

 extern FUNC_NORETURN void _thread_entry(k_thread_entry_t entry,
 			  void *p1, void *p2, void *p3);

 /* Implemented by architectures. Only called from _setup_new_thread. */
 extern void _new_thread(struct k_thread *thread, k_thread_stack_t *pStack,
 			size_t stackSize, k_thread_entry_t entry,
 			void *p1, void *p2, void *p3,
 			int prio, unsigned int options);

 extern void _setup_new_thread(struct k_thread *new_thread,
 			      k_thread_stack_t *stack, size_t stack_size,
 			      k_thread_entry_t entry,
 			      void *p1, void *p2, void *p3,
 			      int prio, u32_t options);

 #ifdef CONFIG_USERSPACE
 /**
  * @brief Get the maximum number of partitions for a memory domain
  *
  * A memory domain is a container data structure containing some number of
  * memory partitions, where each partition represents a memory range with
  * access policies.
  *
  * MMU-based systems don't have a limit here, but MPU-based systems will
  * have an upper bound on how many different regions they can manage
  * simultaneously.
  *
  * @return Max number of free regions, or -1 if there is no limit
  */
 extern int _arch_mem_domain_max_partitions_get(void);

 /**
  * @brief Configure the memory domain of the thread.
  *
  * A memory domain is a container data structure containing some number of
  * memory partitions, where each partition represents a memory range with
  * access policies. This api will configure the appropriate hardware
  * registers to make it work.
  *
  * @param thread Thread which needs to be configured.
  */
 extern void _arch_mem_domain_configure(struct k_thread *thread);

 /**
  * @brief Remove a partition from the memory domain
  *
  * A memory domain contains multiple partitions and this API provides the
  * freedom to remove a particular partition while keeping others intact.
  * This API will handle any arch/HW specific changes that needs to be done.
  *
  * @param domain The memory domain structure
  * @param partition_id The partition that needs to be deleted
  */
 extern void _arch_mem_domain_partition_remove(struct k_mem_domain *domain,
 					      u32_t  partition_id);

 /**
  * @brief Remove the memory domain
  *
  * A memory domain contains multiple partitions and this API will traverse
  * all these to reset them back to default setting.
  * This API will handle any arch/HW specific changes that needs to be done.
  *
  * @param domain The memory domain structure which needs to be deleted.
  */
 extern void _arch_mem_domain_destroy(struct k_mem_domain *domain);
 #endif

 #ifdef CONFIG_USERSPACE
 /**
  * @brief Check memory region permissions
  *
  * Given a memory region, return whether the current memory management hardware
  * configuration would allow a user thread to read/write that region. Used by
  * system calls to validate buffers coming in from userspace.
  *
  * @param addr start address of the buffer
  * @param size the size of the buffer
  * @param write If nonzero, additionally check if the area is writable.
  *	  Otherwise, just check if the memory can be read.
  *
  * @return nonzero if the permissions don't match.
  */
 extern int _arch_buffer_validate(void *addr, size_t size, int write);

 /**
  * Perform a one-way transition from supervisor to kernel mode.
  *
  * Implementations of this function must do the following:
  * - Reset the thread's stack pointer to a suitable initial value. We do not
  *   need any prior context since this is a one-way operation.
  * - Set up any kernel stack region for the CPU to use during privilege
  *   elevation
  * - Put the CPU in whatever its equivalent of user mode is
  * - Transfer execution to _new_thread() passing along all the supplied
  *   arguments, in user mode.
  *
  * @param Entry point to start executing as a user thread
  * @param p1 1st parameter to user thread
  * @param p2 2nd parameter to user thread
  * @param p3 3rd parameter to user thread
  */
 extern FUNC_NORETURN
 void _arch_user_mode_enter(k_thread_entry_t user_entry, void *p1, void *p2,
 			   void *p3);


 /**
  * @brief Induce a kernel oops that appears to come from a specific location
  *
  * Normally, k_oops() generates an exception that appears to come from the
  * call site of the k_oops() itself.
  *
  * However, when validating arguments to a system call, if there are problems
  * we want the oops to appear to come from where the system call was invoked
  * and not inside the validation function.
  *
  * @param ssf System call stack frame pointer. This gets passed as an argument
  *            to _k_syscall_handler_t functions and its contents are completely
  *            architecture specific.
  */
 extern FUNC_NORETURN void _arch_syscall_oops(void *ssf);
 #endif /* CONFIG_USERSPACE */

 /**
  * @brief Allocate some memory from the current thread's resource pool
  *
  * Threads may be assigned a resource pool, which will be used to allocate
  * memory on behalf of certain kernel and driver APIs. Memory reserved
  * in this way should be freed with k_free().
  *
  * @param size Memory allocation size
  * @return A pointer to the allocated memory, or NULL if there is insufficient
  * RAM in the pool or the thread has no resource pool assigned
  */
 void *z_thread_malloc(size_t size);

 /* set and clear essential thread flag */

 extern void _thread_essential_set(void);
 extern void _thread_essential_clear(void);

 /* clean up when a thread is aborted */

 #if defined(CONFIG_THREAD_MONITOR)
 extern void _thread_monitor_exit(struct k_thread *thread);
 #else
 #define _thread_monitor_exit(thread) \
 	do {/* nothing */    \
 	} while (0)
 #endif /* CONFIG_THREAD_MONITOR */

 extern void smp_init(void);

 extern void smp_timer_init(void);

 #ifdef CONFIG_NEWLIB_LIBC
 /**
  * @brief Fetch dimentions of newlib heap area for _sbrk()
  *
  * This memory region is used for heap allocations by the newlib C library.
  * If user threads need to have access to this, the results returned can be
  * used to program memory protection hardware appropriately.
  *
  * @param base Pointer to void pointer, filled in with the heap starting
  *             address
  * @param size Pointer to a size_y, filled in with the maximum heap size
  */
 extern void z_newlib_get_heap_bounds(void **base, size_t *size);
 #endif

 #ifdef __cplusplus
 }
 #endif

 #endif /* _ASMLANGUAGE */

 #endif /* _NANO_INTERNAL__H_ */
	/*
	* Copyright (c) 2010-2012, 2014-2015 Wind River Systems, Inc.
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	/**
	* @file
	* @brief Architecture-independent private kernel APIs
	*
	* This file contains private kernel APIs that are not architecture-specific.
	*/

	#ifndef _NANO_INTERNAL__H_
	#define _NANO_INTERNAL__H_

	#include <kernel.h>

	#ifndef _ASMLANGUAGE

	#ifdef __cplusplus
	extern "C" {
	#endif

	/* Early boot functions */

	void _bss_zero(void);
	#ifdef CONFIG_XIP
	void _data_copy(void);
	#else
	static inline void _data_copy(void)
	{
	/* Do nothing */
	}
	#endif
	FUNC_NORETURN void _Cstart(void);

	extern FUNC_NORETURN void _thread_entry(k_thread_entry_t entry,
	void p1, void p2, void *p3);

	/* Implemented by architectures. Only called from _setup_new_thread. */
	extern void _new_thread(struct k_thread thread, k_thread_stack_t pStack,
	size_t stackSize, k_thread_entry_t entry,
	void p1, void p2, void *p3,
	int prio, unsigned int options);

	extern void _setup_new_thread(struct k_thread *new_thread,
	k_thread_stack_t *stack, size_t stack_size,
	k_thread_entry_t entry,
	void p1, void p2, void *p3,
	int prio, u32_t options);

	#ifdef CONFIG_USERSPACE
	/**
	* @brief Get the maximum number of partitions for a memory domain
	*
	* A memory domain is a container data structure containing some number of
	* memory partitions, where each partition represents a memory range with
	* access policies.
	*
	* MMU-based systems don't have a limit here, but MPU-based systems will
	* have an upper bound on how many different regions they can manage
	* simultaneously.
	*
	* @return Max number of free regions, or -1 if there is no limit
	*/
	extern int _arch_mem_domain_max_partitions_get(void);

	/**
	* @brief Configure the memory domain of the thread.
	*
	* A memory domain is a container data structure containing some number of
	* memory partitions, where each partition represents a memory range with
	* access policies. This api will configure the appropriate hardware
	* registers to make it work.
	*
	* @param thread Thread which needs to be configured.
	*/
	extern void _arch_mem_domain_configure(struct k_thread *thread);

	/**
	* @brief Remove a partition from the memory domain
	*
	* A memory domain contains multiple partitions and this API provides the
	* freedom to remove a particular partition while keeping others intact.
	* This API will handle any arch/HW specific changes that needs to be done.
	*
	* @param domain The memory domain structure
	* @param partition_id The partition that needs to be deleted
	*/
	extern void _arch_mem_domain_partition_remove(struct k_mem_domain *domain,
	u32_t partition_id);

	/**
	* @brief Remove the memory domain
	*
	* A memory domain contains multiple partitions and this API will traverse
	* all these to reset them back to default setting.
	* This API will handle any arch/HW specific changes that needs to be done.
	*
	* @param domain The memory domain structure which needs to be deleted.
	*/
	extern void _arch_mem_domain_destroy(struct k_mem_domain *domain);
	#endif

	#ifdef CONFIG_USERSPACE
	/**
	* @brief Check memory region permissions
	*
	* Given a memory region, return whether the current memory management hardware
	* configuration would allow a user thread to read/write that region. Used by
	* system calls to validate buffers coming in from userspace.
	*
	* @param addr start address of the buffer
	* @param size the size of the buffer
	* @param write If nonzero, additionally check if the area is writable.
	* Otherwise, just check if the memory can be read.
	*
	* @return nonzero if the permissions don't match.
	*/
	extern int _arch_buffer_validate(void *addr, size_t size, int write);

	/**
	* Perform a one-way transition from supervisor to kernel mode.
	*
	* Implementations of this function must do the following:
	* - Reset the thread's stack pointer to a suitable initial value. We do not
	* need any prior context since this is a one-way operation.
	* - Set up any kernel stack region for the CPU to use during privilege
	* elevation
	* - Put the CPU in whatever its equivalent of user mode is
	* - Transfer execution to _new_thread() passing along all the supplied
	* arguments, in user mode.
	*
	* @param Entry point to start executing as a user thread
	* @param p1 1st parameter to user thread
	* @param p2 2nd parameter to user thread
	* @param p3 3rd parameter to user thread
	*/
	extern FUNC_NORETURN
	void _arch_user_mode_enter(k_thread_entry_t user_entry, void p1, void p2,
	void *p3);


	/**
	* @brief Induce a kernel oops that appears to come from a specific location
	*
	* Normally, k_oops() generates an exception that appears to come from the
	* call site of the k_oops() itself.
	*
	* However, when validating arguments to a system call, if there are problems
	* we want the oops to appear to come from where the system call was invoked
	* and not inside the validation function.
	*
	* @param ssf System call stack frame pointer. This gets passed as an argument
	* to _k_syscall_handler_t functions and its contents are completely
	* architecture specific.
	*/
	extern FUNC_NORETURN void _arch_syscall_oops(void *ssf);
	#endif /* CONFIG_USERSPACE */

	/**
	* @brief Allocate some memory from the current thread's resource pool
	*
	* Threads may be assigned a resource pool, which will be used to allocate
	* memory on behalf of certain kernel and driver APIs. Memory reserved
	* in this way should be freed with k_free().
	*
	* @param size Memory allocation size
	* @return A pointer to the allocated memory, or NULL if there is insufficient
	* RAM in the pool or the thread has no resource pool assigned
	*/
	void *z_thread_malloc(size_t size);

	/* set and clear essential thread flag */

	extern void _thread_essential_set(void);
	extern void _thread_essential_clear(void);

	/* clean up when a thread is aborted */

	#if defined(CONFIG_THREAD_MONITOR)
	extern void _thread_monitor_exit(struct k_thread *thread);
	#else
	#define _thread_monitor_exit(thread) \
	do {/* nothing */ \
	} while (0)
	#endif /* CONFIG_THREAD_MONITOR */

	extern void smp_init(void);

	extern void smp_timer_init(void);

	#ifdef CONFIG_NEWLIB_LIBC
	/**
	* @brief Fetch dimentions of newlib heap area for _sbrk()
	*
	* This memory region is used for heap allocations by the newlib C library.
	* If user threads need to have access to this, the results returned can be
	* used to program memory protection hardware appropriately.
	*
	* @param base Pointer to void pointer, filled in with the heap starting
	* address
	* @param size Pointer to a size_y, filled in with the maximum heap size
	*/
	extern void z_newlib_get_heap_bounds(void *base, size_t size);
	#endif

	#ifdef __cplusplus
	}
	#endif

	#endif /* _ASMLANGUAGE */

	#endif /* _NANO_INTERNAL__H_ */