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

 /*
  * Copyright (c) 2017, Intel Corporation
  *
  * SPDX-License-Identifier: Apache 2.0
  */


 #ifndef _ZEPHYR_SYSCALL_HANDLER_H_
 #define _ZEPHYR_SYSCALL_HANDLER_H_

 #ifdef CONFIG_USERSPACE

 #ifndef _ASMLANGUAGE
 #include <kernel.h>
 #include <misc/printk.h>
 #include <nano_internal.h>

 extern const _k_syscall_handler_t _k_syscall_table[K_SYSCALL_LIMIT];

 /**
  * Ensure a system object is a valid object of the expected type
  *
  * Searches for the object and ensures that it is indeed an object
  * of the expected type, that the caller has the right permissions on it,
  * and that the object has been initialized.
  *
  * This function is intended to be called on the kernel-side system
  * call handlers to validate kernel object pointers passed in from
  * userspace.
  *
  * @param ko Kernel object metadata pointer, or NULL
  * @param otype Expected type of the kernel object, or K_OBJ_ANY if type
  *	  doesn't matter
  * @param init If true, this is for an init function and we will not error
  *	   out if the object is not initialized
  * @return 0 If the object is valid
  *         -EBADF if not a valid object of the specified type
  *         -EPERM If the caller does not have permissions
  *         -EINVAL Object is not initialized
  */
 int _k_object_validate(struct _k_object *ko, enum k_objects otype, int init);

 /**
  * Dump out error information on failed _k_object_validate() call
  *
  * @param retval Return value from _k_object_validate()
  * @param obj Kernel object we were trying to verify
  * @param ko If retval=-EPERM, struct _k_object * that was looked up, or NULL
  * @param otype Expected type of the kernel object
  */
 extern void _dump_object_error(int retval, void *obj, struct _k_object *ko,
 			enum k_objects otype);

 /**
  * Kernel object validation function
  *
  * Retrieve metadata for a kernel object. This function is implemented in
  * the gperf script footer, see gen_kobject_list.py
  *
  * @param obj Address of kernel object to get metadata
  * @return Kernel object's metadata, or NULL if the parameter wasn't the
  * memory address of a kernel object
  */
 extern struct _k_object *_k_object_find(void *obj);

 /**
  * Grant a thread permission to a kernel object
  *
  * @param ko Kernel object metadata to update
  * @param thread The thread to grant permission
  */
 extern void _thread_perms_set(struct _k_object *ko, struct k_thread *thread);

 /**
  * Grant all current and future threads access to a kernel object
  *
  * @param ko Kernel object metadata to update
  */
 extern void _thread_perms_all_set(struct _k_object *ko);

 /**
  * @brief Runtime expression check for system call arguments
  *
  * Used in handler functions to perform various runtime checks on arguments,
  * and generate a kernel oops if anything is not expected, printing a custom
  * message.
  *
  * @param expr Boolean expression to verify, a false result will trigger an
  *             oops
  * @param fmt Printf-style format string (followed by appropriate variadic
  *            arguments) to print on verification failure
  */
 #define _SYSCALL_VERIFY_MSG(expr, fmt, ...) \
 	do { \
 		if (!(expr)) { \
 			printk("FATAL: syscall %s failed check: " fmt "\n", \
 			       __func__, ##__VA_ARGS__); \
 			_arch_syscall_oops(ssf); \
 		} \
 	} while (0)

 /**
  * @brief Runtime expression check for system call arguments
  *
  * Used in handler functions to perform various runtime checks on arguments,
  * and generate a kernel oops if anything is not expected.
  *
  * @param expr Boolean expression to verify, a false result will trigger an
  *             oops. A stringified version of this expression will be printed.
  */
 #define _SYSCALL_VERIFY(expr) _SYSCALL_VERIFY_MSG(expr, #expr)

 #define _SYSCALL_MEMORY(ptr, size, write) \
 	_SYSCALL_VERIFY_MSG(!_arch_buffer_validate((void *)ptr, size, write), \
 			    "Memory region %p (size %u) %s access denied", \
 			    (void *)(ptr), (u32_t)(size), \
 			    write ? "write" : "read")

 /**
  * @brief Runtime check that a user thread has read permission to a memory area
  *
  * Checks that the particular memory area is readable by the currently running
  * thread if the CPU was in user mode, and generates a kernel oops if it
  * wasn't. Prevents userspace from getting the kernel to read memory the thread
  * does not have access to, or passing in garbage pointers that would
  * crash/pagefault the kernel if dereferenced.
  *
  * @param ptr Memory area to examine
  * @param size Size of the memory area
  * @param write If the thread should be able to write to this memory, not just
  *		read it
  */
 #define _SYSCALL_MEMORY_READ(ptr, size) \
 	_SYSCALL_MEMORY(ptr, size, 0)

 /**
  * @brief Runtime check that a user thread has write permission to a memory area
  *
  * Checks that the particular memory area is readable and writable by the
  * currently running thread if the CPU was in user mode, and generates a kernel
  * oops if it wasn't. Prevents userspace from getting the kernel to read or
  * modify memory the thread does not have access to, or passing in garbage
  * pointers that would crash/pagefault the kernel if dereferenced.
  *
  * @param ptr Memory area to examine
  * @param size Size of the memory area
  * @param write If the thread should be able to write to this memory, not just
  *		read it
  */
 #define _SYSCALL_MEMORY_WRITE(ptr, size) \
 	_SYSCALL_MEMORY(ptr, size, 1)

 #define _SYSCALL_MEMORY_ARRAY(ptr, nmemb, size, write) \
 	do { \
 		u32_t product; \
 		_SYSCALL_VERIFY_MSG(!__builtin_umul_overflow((u32_t)(nmemb), \
 							     (u32_t)(size), \
 							     &product), \
 				    "%ux%u array is too large", \
 				    (u32_t)(nmemb), (u32_t)(size)); \
 		_SYSCALL_MEMORY(ptr, product, write); \
 	} while (0)

 /**
  * @brief Validate user thread has read permission for sized array
  *
  * Used when the memory region is expressed in terms of number of elements and
  * each element size, handles any overflow issues with computing the total
  * array bounds. Otherwise see _SYSCALL_MEMORY_READ.
  *
  * @param ptr Memory area to examine
  * @param nmemb Number of elements in the array
  * @param size Size of each array element
  */
 #define _SYSCALL_MEMORY_ARRAY_READ(ptr, nmemb, size) \
 	_SYSCALL_MEMORY_ARRAY(ptr, nmemb, size, 0)

 /**
  * @brief Validate user thread has read/write permission for sized array
  *
  * Used when the memory region is expressed in terms of number of elements and
  * each element size, handles any overflow issues with computing the total
  * array bounds. Otherwise see _SYSCALL_MEMORY_WRITE.
  *
  * @param ptr Memory area to examine
  * @param nmemb Number of elements in the array
  * @param size Size of each array element
  */
 #define _SYSCALL_MEMORY_ARRAY_WRITE(ptr, nmemb, size) \
 	_SYSCALL_MEMORY_ARRAY(ptr, nmemb, size, 1)

 static inline int _obj_validation_check(void *obj, enum k_objects otype,
 					int init)
 {
 	struct _k_object *ko;
 	int ret;

 	ko = _k_object_find(obj);
 	ret = _k_object_validate(ko, otype, init);

 #ifdef CONFIG_PRINTK
 	if (ret) {
 		_dump_object_error(ret, obj, ko, otype);
 	}
 #endif

 	return ret;
 }

 #define _SYSCALL_IS_OBJ(ptr, type, init) \
 	_SYSCALL_VERIFY_MSG(!_obj_validation_check((void *)ptr, type, init), \
 			    "object %p access denied", (void *)(ptr))

 /**
  * @brief Runtime check kernel object pointer for non-init functions
  *
  * Calls _k_object_validate and triggers a kernel oops if the check files.
  * For use in system call handlers which are not init functions; a check
  * enforcing that an object is initialized* will not occur.
  *
  * @param ptr Untrusted kernel object pointer
  * @param type Expected kernel object type
  */
 #define _SYSCALL_OBJ(ptr, type) \
 	_SYSCALL_IS_OBJ(ptr, type, 0)

 /**
  * @brief Runtime check kernel object pointer for non-init functions
  *
  * See description of _SYSCALL_IS_OBJ. For use in system call handlers which
  * are not init functions; a check enforcing that an object is initialized
  * will not occur.
  *
  * @param ptr Untrusted kernel object pointer
  * @param type Expected kernel object type
  */

 #define _SYSCALL_OBJ_INIT(ptr, type) \
 	_SYSCALL_IS_OBJ(ptr, type, 1)

 /*
  * Handler definition macros
  *
  * All handlers have the same prototype:
  *
  * u32_t _handler_APINAME(u32_t arg1, u32_t arg2, u32_t arg3,
  *			  u32_t arg4, u32_t arg5, u32_t arg6, void *ssf);
  *
  * These make it much simpler to define handlers instead of typing out
  * the bolierplate. The macros ensure that the seventh argument is named
  * "ssf" as this is now referenced by various other _SYSCALL macros.
  *
  * The different variants here simply depend on how many of the 6 arguments
  * passed in are really used.
  */

 #define _SYSCALL_HANDLER0(name_) \
 	u32_t _handler_ ## name_(u32_t arg1 __unused, \
 				 u32_t arg2 __unused, \
 				 u32_t arg3 __unused, \
 				 u32_t arg4 __unused, \
 				 u32_t arg5 __unused, \
 				 u32_t arg6 __unused, \
 				 void *ssf)

 #define _SYSCALL_HANDLER1(name_, arg1_) \
 	u32_t _handler_ ## name_(u32_t arg1_, \
 				 u32_t arg2 __unused, \
 				 u32_t arg3 __unused, \
 				 u32_t arg4 __unused, \
 				 u32_t arg5 __unused, \
 				 u32_t arg6 __unused, \
 				 void *ssf)

 #define _SYSCALL_HANDLER2(name_, arg1_, arg2_) \
 	u32_t _handler_ ## name_(u32_t arg1_, \
 				 u32_t arg2_, \
 				 u32_t arg3 __unused, \
 				 u32_t arg4 __unused, \
 				 u32_t arg5 __unused, \
 				 u32_t arg6 __unused, \
 				 void *ssf)

 #define _SYSCALL_HANDLER3(name_, arg1_, arg2_, arg3_) \
 	u32_t _handler_ ## name_(u32_t arg1_, \
 				 u32_t arg2_, \
 				 u32_t arg3_, \
 				 u32_t arg4 __unused, \
 				 u32_t arg5 __unused, \
 				 u32_t arg6 __unused, \
 				 void *ssf)

 #define _SYSCALL_HANDLER4(name_, arg1_, arg2_, arg3_, arg4_) \
 	u32_t _handler_ ## name_(u32_t arg1_, \
 				 u32_t arg2_, \
 				 u32_t arg3_, \
 				 u32_t arg4_, \
 				 u32_t arg5 __unused, \
 				 u32_t arg6 __unused, \
 				 void *ssf)

 #define _SYSCALL_HANDLER5(name_, arg1_, arg2_, arg3_, arg4_, arg5_) \
 	u32_t _handler_ ## name_(u32_t arg1_, \
 				 u32_t arg2_, \
 				 u32_t arg3_, \
 				 u32_t arg4_, \
 				 u32_t arg5_, \
 				 u32_t arg6 __unused, \
 				 void *ssf)

 #define _SYSCALL_HANDLER6(name_, arg1_, arg2_, arg3_, arg4_, arg5_, arg6_) \
 	u32_t _handler_ ## name_(u32_t arg1_, \
 				 u32_t arg2_, \
 				 u32_t arg3_, \
 				 u32_t arg4_, \
 				 u32_t arg5_, \
 				 u32_t arg6_, \
 				 void *ssf)

 /*
  * Helper macros for a very common case: calls which just take one argument
  * which is an initialized kernel object of a specific type. Verify the object
  * and call the implementation.
  */

 #define _SYSCALL_HANDLER1_SIMPLE(name_, obj_enum_, obj_type_) \
 	_SYSCALL_HANDLER1(name_, arg1) { \
 		_SYSCALL_OBJ(arg1, obj_enum_); \
 		return (u32_t)_impl_ ## name_((obj_type_)arg1); \
 	}

 #define _SYSCALL_HANDLER1_SIMPLE_VOID(name_, obj_enum_, obj_type_) \
 	_SYSCALL_HANDLER1(name_, arg1) { \
 		_SYSCALL_OBJ(arg1, obj_enum_); \
 		_impl_ ## name_((obj_type_)arg1); \
 		return 0; \
 	}

 #define _SYSCALL_HANDLER0_SIMPLE(name_) \
 	_SYSCALL_HANDLER0(name_) { \
 		return (u32_t)_impl_ ## name_(); \
 	}

 #define _SYSCALL_HANDLER0_SIMPLE_VOID(name_) \
 	_SYSCALL_HANDLER0(name_) { \
 		_impl_ ## name_(); \
 		return 0; \
 	}

 #endif /* _ASMLANGUAGE */

 #endif /* CONFIG_USERSPACE */

 #endif /* _ZEPHYR_SYSCALL_H_ */
	/*
	* Copyright (c) 2017, Intel Corporation
	*
	* SPDX-License-Identifier: Apache 2.0
	*/


	#ifndef _ZEPHYR_SYSCALL_HANDLER_H_
	#define _ZEPHYR_SYSCALL_HANDLER_H_

	#ifdef CONFIG_USERSPACE

	#ifndef _ASMLANGUAGE
	#include <kernel.h>
	#include <misc/printk.h>
	#include <nano_internal.h>

	extern const _k_syscall_handler_t _k_syscall_table[K_SYSCALL_LIMIT];

	/**
	* Ensure a system object is a valid object of the expected type
	*
	* Searches for the object and ensures that it is indeed an object
	* of the expected type, that the caller has the right permissions on it,
	* and that the object has been initialized.
	*
	* This function is intended to be called on the kernel-side system
	* call handlers to validate kernel object pointers passed in from
	* userspace.
	*
	* @param ko Kernel object metadata pointer, or NULL
	* @param otype Expected type of the kernel object, or K_OBJ_ANY if type
	* doesn't matter
	* @param init If true, this is for an init function and we will not error
	* out if the object is not initialized
	* @return 0 If the object is valid
	* -EBADF if not a valid object of the specified type
	* -EPERM If the caller does not have permissions
	* -EINVAL Object is not initialized
	*/
	int _k_object_validate(struct _k_object *ko, enum k_objects otype, int init);

	/**
	* Dump out error information on failed _k_object_validate() call
	*
	* @param retval Return value from _k_object_validate()
	* @param obj Kernel object we were trying to verify
	* @param ko If retval=-EPERM, struct _k_object * that was looked up, or NULL
	* @param otype Expected type of the kernel object
	*/
	extern void _dump_object_error(int retval, void obj, struct _k_object ko,
	enum k_objects otype);

	/**
	* Kernel object validation function
	*
	* Retrieve metadata for a kernel object. This function is implemented in
	* the gperf script footer, see gen_kobject_list.py
	*
	* @param obj Address of kernel object to get metadata
	* @return Kernel object's metadata, or NULL if the parameter wasn't the
	* memory address of a kernel object
	*/
	extern struct _k_object _k_object_find(void obj);

	/**
	* Grant a thread permission to a kernel object
	*
	* @param ko Kernel object metadata to update
	* @param thread The thread to grant permission
	*/
	extern void _thread_perms_set(struct _k_object ko, struct k_thread thread);

	/**
	* Grant all current and future threads access to a kernel object
	*
	* @param ko Kernel object metadata to update
	*/
	extern void _thread_perms_all_set(struct _k_object *ko);

	/**
	* @brief Runtime expression check for system call arguments
	*
	* Used in handler functions to perform various runtime checks on arguments,
	* and generate a kernel oops if anything is not expected, printing a custom
	* message.
	*
	* @param expr Boolean expression to verify, a false result will trigger an
	* oops
	* @param fmt Printf-style format string (followed by appropriate variadic
	* arguments) to print on verification failure
	*/
	#define _SYSCALL_VERIFY_MSG(expr, fmt, ...) \
	do { \
	if (!(expr)) { \
	printk("FATAL: syscall %s failed check: " fmt "\n", \
	__func__, ##__VA_ARGS__); \
	_arch_syscall_oops(ssf); \
	} \
	} while (0)

	/**
	* @brief Runtime expression check for system call arguments
	*
	* Used in handler functions to perform various runtime checks on arguments,
	* and generate a kernel oops if anything is not expected.
	*
	* @param expr Boolean expression to verify, a false result will trigger an
	* oops. A stringified version of this expression will be printed.
	*/
	#define _SYSCALL_VERIFY(expr) _SYSCALL_VERIFY_MSG(expr, #expr)

	#define _SYSCALL_MEMORY(ptr, size, write) \
	_SYSCALL_VERIFY_MSG(!_arch_buffer_validate((void *)ptr, size, write), \
	"Memory region %p (size %u) %s access denied", \
	(void *)(ptr), (u32_t)(size), \
	write ? "write" : "read")

	/**
	* @brief Runtime check that a user thread has read permission to a memory area
	*
	* Checks that the particular memory area is readable by the currently running
	* thread if the CPU was in user mode, and generates a kernel oops if it
	* wasn't. Prevents userspace from getting the kernel to read memory the thread
	* does not have access to, or passing in garbage pointers that would
	* crash/pagefault the kernel if dereferenced.
	*
	* @param ptr Memory area to examine
	* @param size Size of the memory area
	* @param write If the thread should be able to write to this memory, not just
	* read it
	*/
	#define _SYSCALL_MEMORY_READ(ptr, size) \
	_SYSCALL_MEMORY(ptr, size, 0)

	/**
	* @brief Runtime check that a user thread has write permission to a memory area
	*
	* Checks that the particular memory area is readable and writable by the
	* currently running thread if the CPU was in user mode, and generates a kernel
	* oops if it wasn't. Prevents userspace from getting the kernel to read or
	* modify memory the thread does not have access to, or passing in garbage
	* pointers that would crash/pagefault the kernel if dereferenced.
	*
	* @param ptr Memory area to examine
	* @param size Size of the memory area
	* @param write If the thread should be able to write to this memory, not just
	* read it
	*/
	#define _SYSCALL_MEMORY_WRITE(ptr, size) \
	_SYSCALL_MEMORY(ptr, size, 1)

	#define _SYSCALL_MEMORY_ARRAY(ptr, nmemb, size, write) \
	do { \
	u32_t product; \
	_SYSCALL_VERIFY_MSG(!__builtin_umul_overflow((u32_t)(nmemb), \
	(u32_t)(size), \
	&product), \
	"%ux%u array is too large", \
	(u32_t)(nmemb), (u32_t)(size)); \
	_SYSCALL_MEMORY(ptr, product, write); \
	} while (0)

	/**
	* @brief Validate user thread has read permission for sized array
	*
	* Used when the memory region is expressed in terms of number of elements and
	* each element size, handles any overflow issues with computing the total
	* array bounds. Otherwise see _SYSCALL_MEMORY_READ.
	*
	* @param ptr Memory area to examine
	* @param nmemb Number of elements in the array
	* @param size Size of each array element
	*/
	#define _SYSCALL_MEMORY_ARRAY_READ(ptr, nmemb, size) \
	_SYSCALL_MEMORY_ARRAY(ptr, nmemb, size, 0)

	/**
	* @brief Validate user thread has read/write permission for sized array
	*
	* Used when the memory region is expressed in terms of number of elements and
	* each element size, handles any overflow issues with computing the total
	* array bounds. Otherwise see _SYSCALL_MEMORY_WRITE.
	*
	* @param ptr Memory area to examine
	* @param nmemb Number of elements in the array
	* @param size Size of each array element
	*/
	#define _SYSCALL_MEMORY_ARRAY_WRITE(ptr, nmemb, size) \
	_SYSCALL_MEMORY_ARRAY(ptr, nmemb, size, 1)

	static inline int _obj_validation_check(void *obj, enum k_objects otype,
	int init)
	{
	struct _k_object *ko;
	int ret;

	ko = _k_object_find(obj);
	ret = _k_object_validate(ko, otype, init);

	#ifdef CONFIG_PRINTK
	if (ret) {
	_dump_object_error(ret, obj, ko, otype);
	}
	#endif

	return ret;
	}

	#define _SYSCALL_IS_OBJ(ptr, type, init) \
	_SYSCALL_VERIFY_MSG(!_obj_validation_check((void *)ptr, type, init), \
	"object %p access denied", (void *)(ptr))

	/**
	* @brief Runtime check kernel object pointer for non-init functions
	*
	* Calls _k_object_validate and triggers a kernel oops if the check files.
	* For use in system call handlers which are not init functions; a check
	* enforcing that an object is initialized* will not occur.
	*
	* @param ptr Untrusted kernel object pointer
	* @param type Expected kernel object type
	*/
	#define _SYSCALL_OBJ(ptr, type) \
	_SYSCALL_IS_OBJ(ptr, type, 0)

	/**
	* @brief Runtime check kernel object pointer for non-init functions
	*
	* See description of _SYSCALL_IS_OBJ. For use in system call handlers which
	* are not init functions; a check enforcing that an object is initialized
	* will not occur.
	*
	* @param ptr Untrusted kernel object pointer
	* @param type Expected kernel object type
	*/

	#define _SYSCALL_OBJ_INIT(ptr, type) \
	_SYSCALL_IS_OBJ(ptr, type, 1)

	/*
	* Handler definition macros
	*
	* All handlers have the same prototype:
	*
	* u32_t _handler_APINAME(u32_t arg1, u32_t arg2, u32_t arg3,
	* u32_t arg4, u32_t arg5, u32_t arg6, void *ssf);
	*
	* These make it much simpler to define handlers instead of typing out
	* the bolierplate. The macros ensure that the seventh argument is named
	* "ssf" as this is now referenced by various other _SYSCALL macros.
	*
	* The different variants here simply depend on how many of the 6 arguments
	* passed in are really used.
	*/

	#define _SYSCALL_HANDLER0(name_) \
	u32_t _handler_ ## name_(u32_t arg1 __unused, \
	u32_t arg2 __unused, \
	u32_t arg3 __unused, \
	u32_t arg4 __unused, \
	u32_t arg5 __unused, \
	u32_t arg6 __unused, \
	void *ssf)

	#define _SYSCALL_HANDLER1(name_, arg1_) \
	u32_t _handler_ ## name_(u32_t arg1_, \
	u32_t arg2 __unused, \
	u32_t arg3 __unused, \
	u32_t arg4 __unused, \
	u32_t arg5 __unused, \
	u32_t arg6 __unused, \
	void *ssf)

	#define _SYSCALL_HANDLER2(name_, arg1_, arg2_) \
	u32_t _handler_ ## name_(u32_t arg1_, \
	u32_t arg2_, \
	u32_t arg3 __unused, \
	u32_t arg4 __unused, \
	u32_t arg5 __unused, \
	u32_t arg6 __unused, \
	void *ssf)

	#define _SYSCALL_HANDLER3(name_, arg1_, arg2_, arg3_) \
	u32_t _handler_ ## name_(u32_t arg1_, \
	u32_t arg2_, \
	u32_t arg3_, \
	u32_t arg4 __unused, \
	u32_t arg5 __unused, \
	u32_t arg6 __unused, \
	void *ssf)

	#define _SYSCALL_HANDLER4(name_, arg1_, arg2_, arg3_, arg4_) \
	u32_t _handler_ ## name_(u32_t arg1_, \
	u32_t arg2_, \
	u32_t arg3_, \
	u32_t arg4_, \
	u32_t arg5 __unused, \
	u32_t arg6 __unused, \
	void *ssf)

	#define _SYSCALL_HANDLER5(name_, arg1_, arg2_, arg3_, arg4_, arg5_) \
	u32_t _handler_ ## name_(u32_t arg1_, \
	u32_t arg2_, \
	u32_t arg3_, \
	u32_t arg4_, \
	u32_t arg5_, \
	u32_t arg6 __unused, \
	void *ssf)

	#define _SYSCALL_HANDLER6(name_, arg1_, arg2_, arg3_, arg4_, arg5_, arg6_) \
	u32_t _handler_ ## name_(u32_t arg1_, \
	u32_t arg2_, \
	u32_t arg3_, \
	u32_t arg4_, \
	u32_t arg5_, \
	u32_t arg6_, \
	void *ssf)

	/*
	* Helper macros for a very common case: calls which just take one argument
	* which is an initialized kernel object of a specific type. Verify the object
	* and call the implementation.
	*/

	#define _SYSCALL_HANDLER1_SIMPLE(name_, obj_enum_, obj_type_) \
	_SYSCALL_HANDLER1(name_, arg1) { \
	_SYSCALL_OBJ(arg1, obj_enum_); \
	return (u32_t)_impl_ ## name_((obj_type_)arg1); \
	}

	#define _SYSCALL_HANDLER1_SIMPLE_VOID(name_, obj_enum_, obj_type_) \
	_SYSCALL_HANDLER1(name_, arg1) { \
	_SYSCALL_OBJ(arg1, obj_enum_); \
	_impl_ ## name_((obj_type_)arg1); \
	return 0; \
	}

	#define _SYSCALL_HANDLER0_SIMPLE(name_) \
	_SYSCALL_HANDLER0(name_) { \
	return (u32_t)_impl_ ## name_(); \
	}

	#define _SYSCALL_HANDLER0_SIMPLE_VOID(name_) \
	_SYSCALL_HANDLER0(name_) { \
	_impl_ ## name_(); \
	return 0; \
	}

	#endif /* _ASMLANGUAGE */

	#endif /* CONFIG_USERSPACE */

	#endif /* _ZEPHYR_SYSCALL_H_ */