sim/testsuite/bpf/ldabs.s - binutils-gdb - Git at Google

 # mach: bpf
 # sim: --skb-data-offset=0x20
 # output: pass\nexit 0 (0x0)\n
 ;;; ldabs.s
 ;;; Tests for non-generic BPF load instructions in simulator.
 ;;; These instructions (ld{abs,ind}{b,h,w,dw}) are used to access
 ;;; kernel socket data from BPF programs for high performance filters.
 ;;;
 ;;; Register r6 is an implicit input holding a pointer to a struct sk_buff.
 ;;; Register r0 is an implicit output, holding the fetched data.
 ;;;
 ;;; e.g.
 ;;; ldabsw means:
 ;;; r0 = ntohl (*(u32 *) (((struct sk_buff *)r6)->data + imm32))
 ;;;
 ;;; ldindw means
 ;;; r0 = ntohl (*(u32 *) (((struct sk_buff *)r6)->data + src_reg + imm32))

     .include "testutils.inc"

     .text
     .global main
     .type main, @function
 main:
     ;; R6 holds a pointer to a struct sk_buff, which we pretend
     ;; exists at 0x1000
     mov         %r6, 0x1000

     ;; We configure skb-data-offset=0x20
     ;; This specifies offsetof(struct sk_buff, data), where the field 'data'
     ;; is a pointer a data buffer, in this case at 0x2000
     stw         [%r6+0x20], 0x2000

     ;; Write the value 0x7eadbeef into memory at 0x2004
     ;; i.e. offset 4 within the data buffer pointed to by
     ;; ((struct sk_buff *)r6)->data
     stw         [%r6+0x1004], 0xdeadbeef

     ;; Now load data[4] into r0 using the ldabsw instruction
     ldabsw      0x4

     ;; ...and compare to what we expect
     fail_ne32   %r0, 0xdeadbeef

     ;; Repeat for a half-word (2-bytes)
     sth         [%r6+0x1008], 0x1234
     ldabsh      0x8
     fail_ne32   %r0, 0x1234

     ;; Repeat for a single byte
     stb         [%r6+0x1010], 0x5a
     ldabsb      0x10
     fail_ne32   %r0, 0x5a

     ;; Repeat for a double-word (8-byte)
     ;; (note: fail_ne macro uses r0, so copy to another r1 to compare)
     lddw        %r2, 0x1234deadbeef5678
     stxdw       [%r6+0x1018], %r2
     ldabsdw     0x18
     mov         %r1, %r0
     fail_ne     %r1, 0x1234deadbeef5678

     ;; Now, we do the same for the indirect loads
     mov         %r7, 0x100
     stw         [%r6+0x1100], 0xfeedbeef

     ldindw      %r7, 0x0
     fail_ne32   %r0, 0xfeedbeef

     ;; half-word
     sth         [%r6+0x1104], 0x6789
     ldindh      %r7, 0x4
     fail_ne32   %r0, 0x6789

     ;; byte
     stb         [%r6+0x1108], 0x5f
     ldindb      %r7, 0x8
     fail_ne32   %r0, 0x5f

     ;; double-word
     lddw        %r2, 0xcafe12345678d00d
     stxdw       [%r6+0x1110], %r2
     ldinddw     %r7, 0x10
     mov         %r1, %r0
     fail_ne     %r1, 0xcafe12345678d00d

     pass
	# mach: bpf
	# sim: --skb-data-offset=0x20
	# output: pass\nexit 0 (0x0)\n
	;;; ldabs.s
	;;; Tests for non-generic BPF load instructions in simulator.
	;;; These instructions (ld{abs,ind}{b,h,w,dw}) are used to access
	;;; kernel socket data from BPF programs for high performance filters.
	;;;
	;;; Register r6 is an implicit input holding a pointer to a struct sk_buff.
	;;; Register r0 is an implicit output, holding the fetched data.
	;;;
	;;; e.g.
	;;; ldabsw means:
	;;; r0 = ntohl ((u32 ) (((struct sk_buff *)r6)->data + imm32))
	;;;
	;;; ldindw means
	;;; r0 = ntohl ((u32 ) (((struct sk_buff *)r6)->data + src_reg + imm32))

	.include "testutils.inc"

	.text
	.global main
	.type main, @function
	main:
	;; R6 holds a pointer to a struct sk_buff, which we pretend
	;; exists at 0x1000
	mov %r6, 0x1000

	;; We configure skb-data-offset=0x20
	;; This specifies offsetof(struct sk_buff, data), where the field 'data'
	;; is a pointer a data buffer, in this case at 0x2000
	stw [%r6+0x20], 0x2000

	;; Write the value 0x7eadbeef into memory at 0x2004
	;; i.e. offset 4 within the data buffer pointed to by
	;; ((struct sk_buff *)r6)->data
	stw [%r6+0x1004], 0xdeadbeef

	;; Now load data[4] into r0 using the ldabsw instruction
	ldabsw 0x4

	;; ...and compare to what we expect
	fail_ne32 %r0, 0xdeadbeef

	;; Repeat for a half-word (2-bytes)
	sth [%r6+0x1008], 0x1234
	ldabsh 0x8
	fail_ne32 %r0, 0x1234

	;; Repeat for a single byte
	stb [%r6+0x1010], 0x5a
	ldabsb 0x10
	fail_ne32 %r0, 0x5a

	;; Repeat for a double-word (8-byte)
	;; (note: fail_ne macro uses r0, so copy to another r1 to compare)
	lddw %r2, 0x1234deadbeef5678
	stxdw [%r6+0x1018], %r2
	ldabsdw 0x18
	mov %r1, %r0
	fail_ne %r1, 0x1234deadbeef5678

	;; Now, we do the same for the indirect loads
	mov %r7, 0x100
	stw [%r6+0x1100], 0xfeedbeef

	ldindw %r7, 0x0
	fail_ne32 %r0, 0xfeedbeef

	;; half-word
	sth [%r6+0x1104], 0x6789
	ldindh %r7, 0x4
	fail_ne32 %r0, 0x6789

	;; byte
	stb [%r6+0x1108], 0x5f
	ldindb %r7, 0x8
	fail_ne32 %r0, 0x5f

	;; double-word
	lddw %r2, 0xcafe12345678d00d
	stxdw [%r6+0x1110], %r2
	ldinddw %r7, 0x10
	mov %r1, %r0
	fail_ne %r1, 0xcafe12345678d00d

	pass