tools/testing/selftests/bpf/bpf_experimental.h - linux - Git at Google

 #ifndef __BPF_EXPERIMENTAL__
 #define __BPF_EXPERIMENTAL__

 #include <vmlinux.h>
 #include <bpf/bpf_tracing.h>
 #include <bpf/bpf_helpers.h>
 #include <bpf/bpf_core_read.h>

 #define __contains(name, node) __attribute__((btf_decl_tag("contains:" #name ":" #node)))

 /* Description
  *	Allocates an object of the type represented by 'local_type_id' in
  *	program BTF. User may use the bpf_core_type_id_local macro to pass the
  *	type ID of a struct in program BTF.
  *
  *	The 'local_type_id' parameter must be a known constant.
  *	The 'meta' parameter is rewritten by the verifier, no need for BPF
  *	program to set it.
  * Returns
  *	A pointer to an object of the type corresponding to the passed in
  *	'local_type_id', or NULL on failure.
  */
 extern void *bpf_obj_new_impl(__u64 local_type_id, void *meta) __ksym;

 /* Convenience macro to wrap over bpf_obj_new_impl */
 #define bpf_obj_new(type) ((type *)bpf_obj_new_impl(bpf_core_type_id_local(type), NULL))

 /* Description
  *	Free an allocated object. All fields of the object that require
  *	destruction will be destructed before the storage is freed.
  *
  *	The 'meta' parameter is rewritten by the verifier, no need for BPF
  *	program to set it.
  * Returns
  *	Void.
  */
 extern void bpf_obj_drop_impl(void *kptr, void *meta) __ksym;

 /* Convenience macro to wrap over bpf_obj_drop_impl */
 #define bpf_obj_drop(kptr) bpf_obj_drop_impl(kptr, NULL)

 /* Description
  *	Increment the refcount on a refcounted local kptr, turning the
  *	non-owning reference input into an owning reference in the process.
  *
  *	The 'meta' parameter is rewritten by the verifier, no need for BPF
  *	program to set it.
  * Returns
  *	An owning reference to the object pointed to by 'kptr'
  */
 extern void *bpf_refcount_acquire_impl(void *kptr, void *meta) __ksym;

 /* Convenience macro to wrap over bpf_refcount_acquire_impl */
 #define bpf_refcount_acquire(kptr) bpf_refcount_acquire_impl(kptr, NULL)

 /* Description
  *	Add a new entry to the beginning of the BPF linked list.
  *
  *	The 'meta' and 'off' parameters are rewritten by the verifier, no need
  *	for BPF programs to set them
  * Returns
  *	0 if the node was successfully added
  *	-EINVAL if the node wasn't added because it's already in a list
  */
 extern int bpf_list_push_front_impl(struct bpf_list_head *head,
 				    struct bpf_list_node *node,
 				    void *meta, __u64 off) __ksym;

 /* Convenience macro to wrap over bpf_list_push_front_impl */
 #define bpf_list_push_front(head, node) bpf_list_push_front_impl(head, node, NULL, 0)

 /* Description
  *	Add a new entry to the end of the BPF linked list.
  *
  *	The 'meta' and 'off' parameters are rewritten by the verifier, no need
  *	for BPF programs to set them
  * Returns
  *	0 if the node was successfully added
  *	-EINVAL if the node wasn't added because it's already in a list
  */
 extern int bpf_list_push_back_impl(struct bpf_list_head *head,
 				   struct bpf_list_node *node,
 				   void *meta, __u64 off) __ksym;

 /* Convenience macro to wrap over bpf_list_push_back_impl */
 #define bpf_list_push_back(head, node) bpf_list_push_back_impl(head, node, NULL, 0)

 /* Description
  *	Remove the entry at the beginning of the BPF linked list.
  * Returns
  *	Pointer to bpf_list_node of deleted entry, or NULL if list is empty.
  */
 extern struct bpf_list_node *bpf_list_pop_front(struct bpf_list_head *head) __ksym;

 /* Description
  *	Remove the entry at the end of the BPF linked list.
  * Returns
  *	Pointer to bpf_list_node of deleted entry, or NULL if list is empty.
  */
 extern struct bpf_list_node *bpf_list_pop_back(struct bpf_list_head *head) __ksym;

 /* Description
  *	Remove 'node' from rbtree with root 'root'
  * Returns
  * 	Pointer to the removed node, or NULL if 'root' didn't contain 'node'
  */
 extern struct bpf_rb_node *bpf_rbtree_remove(struct bpf_rb_root *root,
 					     struct bpf_rb_node *node) __ksym;

 /* Description
  *	Add 'node' to rbtree with root 'root' using comparator 'less'
  *
  *	The 'meta' and 'off' parameters are rewritten by the verifier, no need
  *	for BPF programs to set them
  * Returns
  *	0 if the node was successfully added
  *	-EINVAL if the node wasn't added because it's already in a tree
  */
 extern int bpf_rbtree_add_impl(struct bpf_rb_root *root, struct bpf_rb_node *node,
 			       bool (less)(struct bpf_rb_node *a, const struct bpf_rb_node *b),
 			       void *meta, __u64 off) __ksym;

 /* Convenience macro to wrap over bpf_rbtree_add_impl */
 #define bpf_rbtree_add(head, node, less) bpf_rbtree_add_impl(head, node, less, NULL, 0)

 /* Description
  *	Return the first (leftmost) node in input tree
  * Returns
  *	Pointer to the node, which is _not_ removed from the tree. If the tree
  *	contains no nodes, returns NULL.
  */
 extern struct bpf_rb_node *bpf_rbtree_first(struct bpf_rb_root *root) __ksym;

 /* Description
  *	Allocates a percpu object of the type represented by 'local_type_id' in
  *	program BTF. User may use the bpf_core_type_id_local macro to pass the
  *	type ID of a struct in program BTF.
  *
  *	The 'local_type_id' parameter must be a known constant.
  *	The 'meta' parameter is rewritten by the verifier, no need for BPF
  *	program to set it.
  * Returns
  *	A pointer to a percpu object of the type corresponding to the passed in
  *	'local_type_id', or NULL on failure.
  */
 extern void *bpf_percpu_obj_new_impl(__u64 local_type_id, void *meta) __ksym;

 /* Convenience macro to wrap over bpf_percpu_obj_new_impl */
 #define bpf_percpu_obj_new(type) ((type __percpu_kptr *)bpf_percpu_obj_new_impl(bpf_core_type_id_local(type), NULL))

 /* Description
  *	Free an allocated percpu object. All fields of the object that require
  *	destruction will be destructed before the storage is freed.
  *
  *	The 'meta' parameter is rewritten by the verifier, no need for BPF
  *	program to set it.
  * Returns
  *	Void.
  */
 extern void bpf_percpu_obj_drop_impl(void *kptr, void *meta) __ksym;

 struct bpf_iter_task_vma;

 extern int bpf_iter_task_vma_new(struct bpf_iter_task_vma *it,
 				 struct task_struct *task,
 				 unsigned long addr) __ksym;
 extern struct vm_area_struct *bpf_iter_task_vma_next(struct bpf_iter_task_vma *it) __ksym;
 extern void bpf_iter_task_vma_destroy(struct bpf_iter_task_vma *it) __ksym;

 /* Convenience macro to wrap over bpf_obj_drop_impl */
 #define bpf_percpu_obj_drop(kptr) bpf_percpu_obj_drop_impl(kptr, NULL)

 /* Description
  *	Throw a BPF exception from the program, immediately terminating its
  *	execution and unwinding the stack. The supplied 'cookie' parameter
  *	will be the return value of the program when an exception is thrown,
  *	and the default exception callback is used. Otherwise, if an exception
  *	callback is set using the '__exception_cb(callback)' declaration tag
  *	on the main program, the 'cookie' parameter will be the callback's only
  *	input argument.
  *
  *	Thus, in case of default exception callback, 'cookie' is subjected to
  *	constraints on the program's return value (as with R0 on exit).
  *	Otherwise, the return value of the marked exception callback will be
  *	subjected to the same checks.
  *
  *	Note that throwing an exception with lingering resources (locks,
  *	references, etc.) will lead to a verification error.
  *
  *	Note that callbacks *cannot* call this helper.
  * Returns
  *	Never.
  * Throws
  *	An exception with the specified 'cookie' value.
  */
 extern void bpf_throw(u64 cookie) __ksym;

 /* This macro must be used to mark the exception callback corresponding to the
  * main program. For example:
  *
  * int exception_cb(u64 cookie) {
  *	return cookie;
  * }
  *
  * SEC("tc")
  * __exception_cb(exception_cb)
  * int main_prog(struct __sk_buff *ctx) {
  *	...
  *	return TC_ACT_OK;
  * }
  *
  * Here, exception callback for the main program will be 'exception_cb'. Note
  * that this attribute can only be used once, and multiple exception callbacks
  * specified for the main program will lead to verification error.
  */
 #define __exception_cb(name) __attribute__((btf_decl_tag("exception_callback:" #name)))

 #define __bpf_assert_signed(x) _Generic((x), \
     unsigned long: 0,       \
     unsigned long long: 0,  \
     signed long: 1,         \
     signed long long: 1     \
 )

 #define __bpf_assert_check(LHS, op, RHS)								 \
 	_Static_assert(sizeof(&(LHS)), "1st argument must be an lvalue expression");			 \
 	_Static_assert(sizeof(LHS) == 8, "Only 8-byte integers are supported\n");			 \
 	_Static_assert(__builtin_constant_p(__bpf_assert_signed(LHS)), "internal static assert");	 \
 	_Static_assert(__builtin_constant_p((RHS)), "2nd argument must be a constant expression")

 #define __bpf_assert(LHS, op, cons, RHS, VAL)							\
 	({											\
 		(void)bpf_throw;								\
 		asm volatile ("if %[lhs] " op " %[rhs] goto +2; r1 = %[value]; call bpf_throw"	\
 			       : : [lhs] "r"(LHS), [rhs] cons(RHS), [value] "ri"(VAL) : );	\
 	})

 #define __bpf_assert_op_sign(LHS, op, cons, RHS, VAL, supp_sign)			\
 	({										\
 		__bpf_assert_check(LHS, op, RHS);					\
 		if (__bpf_assert_signed(LHS) && !(supp_sign))				\
 			__bpf_assert(LHS, "s" #op, cons, RHS, VAL);			\
 		else									\
 			__bpf_assert(LHS, #op, cons, RHS, VAL);				\
 	 })

 #define __bpf_assert_op(LHS, op, RHS, VAL, supp_sign)					\
 	({										\
 		if (sizeof(typeof(RHS)) == 8) {						\
 			const typeof(RHS) rhs_var = (RHS);				\
 			__bpf_assert_op_sign(LHS, op, "r", rhs_var, VAL, supp_sign);	\
 		} else {								\
 			__bpf_assert_op_sign(LHS, op, "i", RHS, VAL, supp_sign);	\
 		}									\
 	 })

 #define __cmp_cannot_be_signed(x) \
 	__builtin_strcmp(#x, "==") == 0 || __builtin_strcmp(#x, "!=") == 0 || \
 	__builtin_strcmp(#x, "&") == 0

 #define __is_signed_type(type) (((type)(-1)) < (type)1)

 #define __bpf_cmp(LHS, OP, PRED, RHS, DEFAULT)						\
 	({											\
 		__label__ l_true;								\
 		bool ret = DEFAULT;								\
 		asm volatile goto("if %[lhs] " OP " %[rhs] goto %l[l_true]"		\
 				  :: [lhs] "r"((short)LHS), [rhs] PRED (RHS) :: l_true);	\
 		ret = !DEFAULT;									\
 l_true:												\
 		ret;										\
        })

 /* C type conversions coupled with comparison operator are tricky.
  * Make sure BPF program is compiled with -Wsign-compare then
  * __lhs OP __rhs below will catch the mistake.
  * Be aware that we check only __lhs to figure out the sign of compare.
  */
 #define _bpf_cmp(LHS, OP, RHS, UNLIKELY)								\
 	({											\
 		typeof(LHS) __lhs = (LHS);							\
 		typeof(RHS) __rhs = (RHS);							\
 		bool ret;									\
 		_Static_assert(sizeof(&(LHS)), "1st argument must be an lvalue expression");	\
 		(void)(__lhs OP __rhs);								\
 		if (__cmp_cannot_be_signed(OP) || !__is_signed_type(typeof(__lhs))) {		\
 			if (sizeof(__rhs) == 8)							\
 				/* "i" will truncate 64-bit constant into s32,			\
 				 * so we have to use extra register via "r".			\
 				 */								\
 				ret = __bpf_cmp(__lhs, #OP, "r", __rhs, UNLIKELY);		\
 			else									\
 				ret = __bpf_cmp(__lhs, #OP, "ri", __rhs, UNLIKELY);		\
 		} else {									\
 			if (sizeof(__rhs) == 8)							\
 				ret = __bpf_cmp(__lhs, "s"#OP, "r", __rhs, UNLIKELY);		\
 			else									\
 				ret = __bpf_cmp(__lhs, "s"#OP, "ri", __rhs, UNLIKELY);		\
 		}										\
 		ret;										\
        })

 #ifndef bpf_cmp_unlikely
 #define bpf_cmp_unlikely(LHS, OP, RHS) _bpf_cmp(LHS, OP, RHS, true)
 #endif

 #ifndef bpf_cmp_likely
 #define bpf_cmp_likely(LHS, OP, RHS)								\
 	({											\
 		bool ret = 0;									\
 		if (__builtin_strcmp(#OP, "==") == 0)						\
 			ret = _bpf_cmp(LHS, !=, RHS, false);					\
 		else if (__builtin_strcmp(#OP, "!=") == 0)					\
 			ret = _bpf_cmp(LHS, ==, RHS, false);					\
 		else if (__builtin_strcmp(#OP, "<=") == 0)					\
 			ret = _bpf_cmp(LHS, >, RHS, false);					\
 		else if (__builtin_strcmp(#OP, "<") == 0)					\
 			ret = _bpf_cmp(LHS, >=, RHS, false);					\
 		else if (__builtin_strcmp(#OP, ">") == 0)					\
 			ret = _bpf_cmp(LHS, <=, RHS, false);					\
 		else if (__builtin_strcmp(#OP, ">=") == 0)					\
 			ret = _bpf_cmp(LHS, <, RHS, false);					\
 		else										\
 			asm volatile("r0 " #OP " invalid compare");				\
 		ret;										\
        })
 #endif

 #define cond_break					\
 	({ __label__ l_break, l_continue;		\
 	 asm volatile goto("1:.byte 0xe5;			\
 		      .byte 0;				\
 		      .long ((%l[l_break] - 1b - 8) / 8) & 0xffff;	\
 		      .short 0"				\
 		      :::: l_break);			\
 	goto l_continue;				\
 	l_break: break;					\
 	l_continue:;					\
 	})

 #ifndef bpf_nop_mov
 #define bpf_nop_mov(var) \
 	asm volatile("%[reg]=%[reg]"::[reg]"r"((short)var))
 #endif

 /* emit instruction:
  * rX = rX .off = BPF_ADDR_SPACE_CAST .imm32 = (dst_as << 16) | src_as
  */
 #ifndef bpf_addr_space_cast
 #define bpf_addr_space_cast(var, dst_as, src_as)\
 	asm volatile(".byte 0xBF;		\
 		     .ifc %[reg], r0;		\
 		     .byte 0x00;		\
 		     .endif;			\
 		     .ifc %[reg], r1;		\
 		     .byte 0x11;		\
 		     .endif;			\
 		     .ifc %[reg], r2;		\
 		     .byte 0x22;		\
 		     .endif;			\
 		     .ifc %[reg], r3;		\
 		     .byte 0x33;		\
 		     .endif;			\
 		     .ifc %[reg], r4;		\
 		     .byte 0x44;		\
 		     .endif;			\
 		     .ifc %[reg], r5;		\
 		     .byte 0x55;		\
 		     .endif;			\
 		     .ifc %[reg], r6;		\
 		     .byte 0x66;		\
 		     .endif;			\
 		     .ifc %[reg], r7;		\
 		     .byte 0x77;		\
 		     .endif;			\
 		     .ifc %[reg], r8;		\
 		     .byte 0x88;		\
 		     .endif;			\
 		     .ifc %[reg], r9;		\
 		     .byte 0x99;		\
 		     .endif;			\
 		     .short %[off];		\
 		     .long %[as]"		\
 		     : [reg]"+r"(var)		\
 		     : [off]"i"(BPF_ADDR_SPACE_CAST) \
 		     , [as]"i"((dst_as << 16) | src_as));
 #endif

 /* Description
  *	Assert that a conditional expression is true.
  * Returns
  *	Void.
  * Throws
  *	An exception with the value zero when the assertion fails.
  */
 #define bpf_assert(cond) if (!(cond)) bpf_throw(0);

 /* Description
  *	Assert that a conditional expression is true.
  * Returns
  *	Void.
  * Throws
  *	An exception with the specified value when the assertion fails.
  */
 #define bpf_assert_with(cond, value) if (!(cond)) bpf_throw(value);

 /* Description
  *	Assert that LHS is in the range [BEG, END] (inclusive of both). This
  *	statement updates the known bounds of LHS during verification. Note
  *	that both BEG and END must be constant values, and must fit within the
  *	data type of LHS.
  * Returns
  *	Void.
  * Throws
  *	An exception with the value zero when the assertion fails.
  */
 #define bpf_assert_range(LHS, BEG, END)					\
 	({								\
 		_Static_assert(BEG <= END, "BEG must be <= END");	\
 		barrier_var(LHS);					\
 		__bpf_assert_op(LHS, >=, BEG, 0, false);		\
 		__bpf_assert_op(LHS, <=, END, 0, false);		\
 	})

 /* Description
  *	Assert that LHS is in the range [BEG, END] (inclusive of both). This
  *	statement updates the known bounds of LHS during verification. Note
  *	that both BEG and END must be constant values, and must fit within the
  *	data type of LHS.
  * Returns
  *	Void.
  * Throws
  *	An exception with the specified value when the assertion fails.
  */
 #define bpf_assert_range_with(LHS, BEG, END, value)			\
 	({								\
 		_Static_assert(BEG <= END, "BEG must be <= END");	\
 		barrier_var(LHS);					\
 		__bpf_assert_op(LHS, >=, BEG, value, false);		\
 		__bpf_assert_op(LHS, <=, END, value, false);		\
 	})

 struct bpf_iter_css_task;
 struct cgroup_subsys_state;
 extern int bpf_iter_css_task_new(struct bpf_iter_css_task *it,
 		struct cgroup_subsys_state *css, unsigned int flags) __weak __ksym;
 extern struct task_struct *bpf_iter_css_task_next(struct bpf_iter_css_task *it) __weak __ksym;
 extern void bpf_iter_css_task_destroy(struct bpf_iter_css_task *it) __weak __ksym;

 struct bpf_iter_task;
 extern int bpf_iter_task_new(struct bpf_iter_task *it,
 		struct task_struct *task, unsigned int flags) __weak __ksym;
 extern struct task_struct *bpf_iter_task_next(struct bpf_iter_task *it) __weak __ksym;
 extern void bpf_iter_task_destroy(struct bpf_iter_task *it) __weak __ksym;

 struct bpf_iter_css;
 extern int bpf_iter_css_new(struct bpf_iter_css *it,
 				struct cgroup_subsys_state *start, unsigned int flags) __weak __ksym;
 extern struct cgroup_subsys_state *bpf_iter_css_next(struct bpf_iter_css *it) __weak __ksym;
 extern void bpf_iter_css_destroy(struct bpf_iter_css *it) __weak __ksym;

 #endif
	#ifndef __BPF_EXPERIMENTAL__
	#define __BPF_EXPERIMENTAL__

	#include <vmlinux.h>
	#include <bpf/bpf_tracing.h>
	#include <bpf/bpf_helpers.h>
	#include <bpf/bpf_core_read.h>

	#define __contains(name, node) __attribute__((btf_decl_tag("contains:" #name ":" #node)))

	/* Description
	* Allocates an object of the type represented by 'local_type_id' in
	* program BTF. User may use the bpf_core_type_id_local macro to pass the
	* type ID of a struct in program BTF.
	*
	* The 'local_type_id' parameter must be a known constant.
	* The 'meta' parameter is rewritten by the verifier, no need for BPF
	* program to set it.
	* Returns
	* A pointer to an object of the type corresponding to the passed in
	* 'local_type_id', or NULL on failure.
	*/
	extern void bpf_obj_new_impl(__u64 local_type_id, void meta) __ksym;

	/* Convenience macro to wrap over bpf_obj_new_impl */
	#define bpf_obj_new(type) ((type *)bpf_obj_new_impl(bpf_core_type_id_local(type), NULL))

	/* Description
	* Free an allocated object. All fields of the object that require
	* destruction will be destructed before the storage is freed.
	*
	* The 'meta' parameter is rewritten by the verifier, no need for BPF
	* program to set it.
	* Returns
	* Void.
	*/
	extern void bpf_obj_drop_impl(void kptr, void meta) __ksym;

	/* Convenience macro to wrap over bpf_obj_drop_impl */
	#define bpf_obj_drop(kptr) bpf_obj_drop_impl(kptr, NULL)

	/* Description
	* Increment the refcount on a refcounted local kptr, turning the
	* non-owning reference input into an owning reference in the process.
	*
	* The 'meta' parameter is rewritten by the verifier, no need for BPF
	* program to set it.
	* Returns
	* An owning reference to the object pointed to by 'kptr'
	*/
	extern void bpf_refcount_acquire_impl(void kptr, void *meta) __ksym;

	/* Convenience macro to wrap over bpf_refcount_acquire_impl */
	#define bpf_refcount_acquire(kptr) bpf_refcount_acquire_impl(kptr, NULL)

	/* Description
	* Add a new entry to the beginning of the BPF linked list.
	*
	* The 'meta' and 'off' parameters are rewritten by the verifier, no need
	* for BPF programs to set them
	* Returns
	* 0 if the node was successfully added
	* -EINVAL if the node wasn't added because it's already in a list
	*/
	extern int bpf_list_push_front_impl(struct bpf_list_head *head,
	struct bpf_list_node *node,
	void *meta, __u64 off) __ksym;

	/* Convenience macro to wrap over bpf_list_push_front_impl */
	#define bpf_list_push_front(head, node) bpf_list_push_front_impl(head, node, NULL, 0)

	/* Description
	* Add a new entry to the end of the BPF linked list.
	*
	* The 'meta' and 'off' parameters are rewritten by the verifier, no need
	* for BPF programs to set them
	* Returns
	* 0 if the node was successfully added
	* -EINVAL if the node wasn't added because it's already in a list
	*/
	extern int bpf_list_push_back_impl(struct bpf_list_head *head,
	struct bpf_list_node *node,
	void *meta, __u64 off) __ksym;

	/* Convenience macro to wrap over bpf_list_push_back_impl */
	#define bpf_list_push_back(head, node) bpf_list_push_back_impl(head, node, NULL, 0)

	/* Description
	* Remove the entry at the beginning of the BPF linked list.
	* Returns
	* Pointer to bpf_list_node of deleted entry, or NULL if list is empty.
	*/
	extern struct bpf_list_node bpf_list_pop_front(struct bpf_list_head head) __ksym;

	/* Description
	* Remove the entry at the end of the BPF linked list.
	* Returns
	* Pointer to bpf_list_node of deleted entry, or NULL if list is empty.
	*/
	extern struct bpf_list_node bpf_list_pop_back(struct bpf_list_head head) __ksym;

	/* Description
	* Remove 'node' from rbtree with root 'root'
	* Returns
	* Pointer to the removed node, or NULL if 'root' didn't contain 'node'
	*/
	extern struct bpf_rb_node bpf_rbtree_remove(struct bpf_rb_root root,
	struct bpf_rb_node *node) __ksym;

	/* Description
	* Add 'node' to rbtree with root 'root' using comparator 'less'
	*
	* The 'meta' and 'off' parameters are rewritten by the verifier, no need
	* for BPF programs to set them
	* Returns
	* 0 if the node was successfully added
	* -EINVAL if the node wasn't added because it's already in a tree
	*/
	extern int bpf_rbtree_add_impl(struct bpf_rb_root root, struct bpf_rb_node node,
	bool (less)(struct bpf_rb_node a, const struct bpf_rb_node b),
	void *meta, __u64 off) __ksym;

	/* Convenience macro to wrap over bpf_rbtree_add_impl */
	#define bpf_rbtree_add(head, node, less) bpf_rbtree_add_impl(head, node, less, NULL, 0)

	/* Description
	* Return the first (leftmost) node in input tree
	* Returns
	* Pointer to the node, which is _not_ removed from the tree. If the tree
	* contains no nodes, returns NULL.
	*/
	extern struct bpf_rb_node bpf_rbtree_first(struct bpf_rb_root root) __ksym;

	/* Description
	* Allocates a percpu object of the type represented by 'local_type_id' in
	* program BTF. User may use the bpf_core_type_id_local macro to pass the
	* type ID of a struct in program BTF.
	*
	* The 'local_type_id' parameter must be a known constant.
	* The 'meta' parameter is rewritten by the verifier, no need for BPF
	* program to set it.
	* Returns
	* A pointer to a percpu object of the type corresponding to the passed in
	* 'local_type_id', or NULL on failure.
	*/
	extern void bpf_percpu_obj_new_impl(__u64 local_type_id, void meta) __ksym;

	/* Convenience macro to wrap over bpf_percpu_obj_new_impl */
	#define bpf_percpu_obj_new(type) ((type __percpu_kptr *)bpf_percpu_obj_new_impl(bpf_core_type_id_local(type), NULL))

	/* Description
	* Free an allocated percpu object. All fields of the object that require
	* destruction will be destructed before the storage is freed.
	*
	* The 'meta' parameter is rewritten by the verifier, no need for BPF
	* program to set it.
	* Returns
	* Void.
	*/
	extern void bpf_percpu_obj_drop_impl(void kptr, void meta) __ksym;

	struct bpf_iter_task_vma;

	extern int bpf_iter_task_vma_new(struct bpf_iter_task_vma *it,
	struct task_struct *task,
	unsigned long addr) __ksym;
	extern struct vm_area_struct bpf_iter_task_vma_next(struct bpf_iter_task_vma it) __ksym;
	extern void bpf_iter_task_vma_destroy(struct bpf_iter_task_vma *it) __ksym;

	/* Convenience macro to wrap over bpf_obj_drop_impl */
	#define bpf_percpu_obj_drop(kptr) bpf_percpu_obj_drop_impl(kptr, NULL)

	/* Description
	* Throw a BPF exception from the program, immediately terminating its
	* execution and unwinding the stack. The supplied 'cookie' parameter
	* will be the return value of the program when an exception is thrown,
	* and the default exception callback is used. Otherwise, if an exception
	* callback is set using the '__exception_cb(callback)' declaration tag
	* on the main program, the 'cookie' parameter will be the callback's only
	* input argument.
	*
	* Thus, in case of default exception callback, 'cookie' is subjected to
	* constraints on the program's return value (as with R0 on exit).
	* Otherwise, the return value of the marked exception callback will be
	* subjected to the same checks.
	*
	* Note that throwing an exception with lingering resources (locks,
	* references, etc.) will lead to a verification error.
	*
	* Note that callbacks cannot call this helper.
	* Returns
	* Never.
	* Throws
	* An exception with the specified 'cookie' value.
	*/
	extern void bpf_throw(u64 cookie) __ksym;

	/* This macro must be used to mark the exception callback corresponding to the
	* main program. For example:
	*
	* int exception_cb(u64 cookie) {
	* return cookie;
	* }
	*
	* SEC("tc")
	* __exception_cb(exception_cb)
	* int main_prog(struct __sk_buff *ctx) {
	* ...
	* return TC_ACT_OK;
	* }
	*
	* Here, exception callback for the main program will be 'exception_cb'. Note
	* that this attribute can only be used once, and multiple exception callbacks
	* specified for the main program will lead to verification error.
	*/
	#define __exception_cb(name) __attribute__((btf_decl_tag("exception_callback:" #name)))

	#define __bpf_assert_signed(x) _Generic((x), \
	unsigned long: 0, \
	unsigned long long: 0, \
	signed long: 1, \
	signed long long: 1 \
	)

	#define __bpf_assert_check(LHS, op, RHS) \
	_Static_assert(sizeof(&(LHS)), "1st argument must be an lvalue expression"); \
	_Static_assert(sizeof(LHS) == 8, "Only 8-byte integers are supported\n"); \
	_Static_assert(__builtin_constant_p(__bpf_assert_signed(LHS)), "internal static assert"); \
	_Static_assert(__builtin_constant_p((RHS)), "2nd argument must be a constant expression")

	#define __bpf_assert(LHS, op, cons, RHS, VAL) \
	({ \
	(void)bpf_throw; \
	asm volatile ("if %[lhs] " op " %[rhs] goto +2; r1 = %[value]; call bpf_throw" \
	: : [lhs] "r"(LHS), [rhs] cons(RHS), [value] "ri"(VAL) : ); \
	})

	#define __bpf_assert_op_sign(LHS, op, cons, RHS, VAL, supp_sign) \
	({ \
	__bpf_assert_check(LHS, op, RHS); \
	if (__bpf_assert_signed(LHS) && !(supp_sign)) \
	__bpf_assert(LHS, "s" #op, cons, RHS, VAL); \
	else \
	__bpf_assert(LHS, #op, cons, RHS, VAL); \
	})

	#define __bpf_assert_op(LHS, op, RHS, VAL, supp_sign) \
	({ \
	if (sizeof(typeof(RHS)) == 8) { \
	const typeof(RHS) rhs_var = (RHS); \
	__bpf_assert_op_sign(LHS, op, "r", rhs_var, VAL, supp_sign); \
	} else { \
	__bpf_assert_op_sign(LHS, op, "i", RHS, VAL, supp_sign); \
	} \
	})

	#define __cmp_cannot_be_signed(x) \
	__builtin_strcmp(#x, "==") == 0 \|\| __builtin_strcmp(#x, "!=") == 0 \|\| \
	__builtin_strcmp(#x, "&") == 0

	#define __is_signed_type(type) (((type)(-1)) < (type)1)

	#define __bpf_cmp(LHS, OP, PRED, RHS, DEFAULT) \
	({ \
	__label__ l_true; \
	bool ret = DEFAULT; \
	asm volatile goto("if %[lhs] " OP " %[rhs] goto %l[l_true]" \
	:: [lhs] "r"((short)LHS), [rhs] PRED (RHS) :: l_true); \
	ret = !DEFAULT; \
	l_true: \
	ret; \
	})

	/* C type conversions coupled with comparison operator are tricky.
	* Make sure BPF program is compiled with -Wsign-compare then
	* __lhs OP __rhs below will catch the mistake.
	* Be aware that we check only __lhs to figure out the sign of compare.
	*/
	#define _bpf_cmp(LHS, OP, RHS, UNLIKELY) \
	({ \
	typeof(LHS) __lhs = (LHS); \
	typeof(RHS) __rhs = (RHS); \
	bool ret; \
	_Static_assert(sizeof(&(LHS)), "1st argument must be an lvalue expression"); \
	(void)(__lhs OP __rhs); \
	if (__cmp_cannot_be_signed(OP) \|\| !__is_signed_type(typeof(__lhs))) { \
	if (sizeof(__rhs) == 8) \
	/* "i" will truncate 64-bit constant into s32, \
	* so we have to use extra register via "r". \
	*/ \
	ret = __bpf_cmp(__lhs, #OP, "r", __rhs, UNLIKELY); \
	else \
	ret = __bpf_cmp(__lhs, #OP, "ri", __rhs, UNLIKELY); \
	} else { \
	if (sizeof(__rhs) == 8) \
	ret = __bpf_cmp(__lhs, "s"#OP, "r", __rhs, UNLIKELY); \
	else \
	ret = __bpf_cmp(__lhs, "s"#OP, "ri", __rhs, UNLIKELY); \
	} \
	ret; \
	})

	#ifndef bpf_cmp_unlikely
	#define bpf_cmp_unlikely(LHS, OP, RHS) _bpf_cmp(LHS, OP, RHS, true)
	#endif

	#ifndef bpf_cmp_likely
	#define bpf_cmp_likely(LHS, OP, RHS) \
	({ \
	bool ret = 0; \
	if (__builtin_strcmp(#OP, "==") == 0) \
	ret = _bpf_cmp(LHS, !=, RHS, false); \
	else if (__builtin_strcmp(#OP, "!=") == 0) \
	ret = _bpf_cmp(LHS, ==, RHS, false); \
	else if (__builtin_strcmp(#OP, "<=") == 0) \
	ret = _bpf_cmp(LHS, >, RHS, false); \
	else if (__builtin_strcmp(#OP, "<") == 0) \
	ret = _bpf_cmp(LHS, >=, RHS, false); \
	else if (__builtin_strcmp(#OP, ">") == 0) \
	ret = _bpf_cmp(LHS, <=, RHS, false); \
	else if (__builtin_strcmp(#OP, ">=") == 0) \
	ret = _bpf_cmp(LHS, <, RHS, false); \
	else \
	asm volatile("r0 " #OP " invalid compare"); \
	ret; \
	})
	#endif

	#define cond_break \
	({ __label__ l_break, l_continue; \
	asm volatile goto("1:.byte 0xe5; \
	.byte 0; \
	.long ((%l[l_break] - 1b - 8) / 8) & 0xffff; \
	.short 0" \
	:::: l_break); \
	goto l_continue; \
	l_break: break; \
	l_continue:; \
	})

	#ifndef bpf_nop_mov
	#define bpf_nop_mov(var) \
	asm volatile("%[reg]=%[reg]"::[reg]"r"((short)var))
	#endif

	/* emit instruction:
	* rX = rX .off = BPF_ADDR_SPACE_CAST .imm32 = (dst_as << 16) \| src_as
	*/
	#ifndef bpf_addr_space_cast
	#define bpf_addr_space_cast(var, dst_as, src_as)\
	asm volatile(".byte 0xBF; \
	.ifc %[reg], r0; \
	.byte 0x00; \
	.endif; \
	.ifc %[reg], r1; \
	.byte 0x11; \
	.endif; \
	.ifc %[reg], r2; \
	.byte 0x22; \
	.endif; \
	.ifc %[reg], r3; \
	.byte 0x33; \
	.endif; \
	.ifc %[reg], r4; \
	.byte 0x44; \
	.endif; \
	.ifc %[reg], r5; \
	.byte 0x55; \
	.endif; \
	.ifc %[reg], r6; \
	.byte 0x66; \
	.endif; \
	.ifc %[reg], r7; \
	.byte 0x77; \
	.endif; \
	.ifc %[reg], r8; \
	.byte 0x88; \
	.endif; \
	.ifc %[reg], r9; \
	.byte 0x99; \
	.endif; \
	.short %[off]; \
	.long %[as]" \
	: [reg]"+r"(var) \
	: [off]"i"(BPF_ADDR_SPACE_CAST) \
	, [as]"i"((dst_as << 16) \| src_as));
	#endif

	/* Description
	* Assert that a conditional expression is true.
	* Returns
	* Void.
	* Throws
	* An exception with the value zero when the assertion fails.
	*/
	#define bpf_assert(cond) if (!(cond)) bpf_throw(0);

	/* Description
	* Assert that a conditional expression is true.
	* Returns
	* Void.
	* Throws
	* An exception with the specified value when the assertion fails.
	*/
	#define bpf_assert_with(cond, value) if (!(cond)) bpf_throw(value);

	/* Description
	* Assert that LHS is in the range [BEG, END] (inclusive of both). This
	* statement updates the known bounds of LHS during verification. Note
	* that both BEG and END must be constant values, and must fit within the
	* data type of LHS.
	* Returns
	* Void.
	* Throws
	* An exception with the value zero when the assertion fails.
	*/
	#define bpf_assert_range(LHS, BEG, END) \
	({ \
	_Static_assert(BEG <= END, "BEG must be <= END"); \
	barrier_var(LHS); \
	__bpf_assert_op(LHS, >=, BEG, 0, false); \
	__bpf_assert_op(LHS, <=, END, 0, false); \
	})

	/* Description
	* Assert that LHS is in the range [BEG, END] (inclusive of both). This
	* statement updates the known bounds of LHS during verification. Note
	* that both BEG and END must be constant values, and must fit within the
	* data type of LHS.
	* Returns
	* Void.
	* Throws
	* An exception with the specified value when the assertion fails.
	*/
	#define bpf_assert_range_with(LHS, BEG, END, value) \
	({ \
	_Static_assert(BEG <= END, "BEG must be <= END"); \
	barrier_var(LHS); \
	__bpf_assert_op(LHS, >=, BEG, value, false); \
	__bpf_assert_op(LHS, <=, END, value, false); \
	})

	struct bpf_iter_css_task;
	struct cgroup_subsys_state;
	extern int bpf_iter_css_task_new(struct bpf_iter_css_task *it,
	struct cgroup_subsys_state *css, unsigned int flags) __weak __ksym;
	extern struct task_struct bpf_iter_css_task_next(struct bpf_iter_css_task it) __weak __ksym;
	extern void bpf_iter_css_task_destroy(struct bpf_iter_css_task *it) __weak __ksym;

	struct bpf_iter_task;
	extern int bpf_iter_task_new(struct bpf_iter_task *it,
	struct task_struct *task, unsigned int flags) __weak __ksym;
	extern struct task_struct bpf_iter_task_next(struct bpf_iter_task it) __weak __ksym;
	extern void bpf_iter_task_destroy(struct bpf_iter_task *it) __weak __ksym;

	struct bpf_iter_css;
	extern int bpf_iter_css_new(struct bpf_iter_css *it,
	struct cgroup_subsys_state *start, unsigned int flags) __weak __ksym;
	extern struct cgroup_subsys_state bpf_iter_css_next(struct bpf_iter_css it) __weak __ksym;
	extern void bpf_iter_css_destroy(struct bpf_iter_css *it) __weak __ksym;

	#endif