test/CodeGen/Mips/msa/elm_copy.ll - llvm - Git at Google

 ; Test the MSA intrinsics that are encoded with the ELM instruction format and
 ; are element extraction operations.

 ; RUN: llc -march=mips -mattr=+msa,+fp64 -relocation-model=pic < %s | \
 ; RUN:   FileCheck %s -check-prefixes=MIPS-ANY,MIPS32
 ; RUN: llc -march=mipsel -mattr=+msa,+fp64 -relocation-model=pic < %s | \
 ; RUN:   FileCheck %s -check-prefixes=MIPS-ANY,MIPS32
 ; RUN: llc -march=mips64 -mcpu=mips64r2 -mattr=+msa,+fp64 -relocation-model=pic < %s | \
 ; RUN:   FileCheck %s -check-prefixes=MIPS-ANY,MIPS64
 ; RUN: llc -march=mips64el -mcpu=mips64r2 -mattr=+msa,+fp64 -relocation-model=pic < %s | \
 ; RUN:   FileCheck %s -check-prefixes=MIPS-ANY,MIPS64

 @llvm_mips_copy_s_b_ARG1 = global <16 x i8> <i8 0, i8 1, i8 2, i8 3, i8 4, i8 5, i8 6, i8 7, i8 8, i8 9, i8 10, i8 11, i8 12, i8 13, i8 14, i8 15>, align 16
 @llvm_mips_copy_s_b_RES  = global i32 0, align 16

 define void @llvm_mips_copy_s_b_test() nounwind {
 entry:
   %0 = load <16 x i8>, <16 x i8>* @llvm_mips_copy_s_b_ARG1
   %1 = tail call i32 @llvm.mips.copy.s.b(<16 x i8> %0, i32 1)
   store i32 %1, i32* @llvm_mips_copy_s_b_RES
   ret void
 }

 declare i32 @llvm.mips.copy.s.b(<16 x i8>, i32) nounwind

 ; MIPS-ANY: llvm_mips_copy_s_b_test:
 ; MIPS32-DAG: lw [[R1:\$[0-9]+]], %got(llvm_mips_copy_s_b_ARG1)
 ; MIPS64-DAG: ld [[R1:\$[0-9]+]], %got_disp(llvm_mips_copy_s_b_ARG1)
 ; MIPS-ANY-DAG: ld.b [[WS:\$w[0-9]+]], 0([[R1]])
 ; MIPS-ANY-DAG: copy_s.b [[RD:\$[0-9]+]], [[WS]][1]
 ; MIPS32-DAG: lw [[RES:\$[0-9]+]], %got(llvm_mips_copy_s_b_RES)
 ; MIPS64-DAG: ld [[RES:\$[0-9]+]], %got_disp(llvm_mips_copy_s_b_RES)
 ; MIPS-ANY-DAG: sw [[RD]], 0([[RES]])
 ; MIPS-ANY: .size llvm_mips_copy_s_b_test
 ;
 @llvm_mips_copy_s_h_ARG1 = global <8 x i16> <i16 0, i16 1, i16 2, i16 3, i16 4, i16 5, i16 6, i16 7>, align 16
 @llvm_mips_copy_s_h_RES  = global i32 0, align 16

 define void @llvm_mips_copy_s_h_test() nounwind {
 entry:
   %0 = load <8 x i16>, <8 x i16>* @llvm_mips_copy_s_h_ARG1
   %1 = tail call i32 @llvm.mips.copy.s.h(<8 x i16> %0, i32 1)
   store i32 %1, i32* @llvm_mips_copy_s_h_RES
   ret void
 }

 declare i32 @llvm.mips.copy.s.h(<8 x i16>, i32) nounwind

 ; MIPS-ANY: llvm_mips_copy_s_h_test:
 ; MIPS32-DAG: lw [[R1:\$[0-9]+]], %got(llvm_mips_copy_s_h_ARG1)
 ; MIPS64-DAG: ld [[R1:\$[0-9]+]], %got_disp(llvm_mips_copy_s_h_ARG1)
 ; MIPS-ANY-DAG: ld.h [[WS:\$w[0-9]+]], 0([[R1]])
 ; MIPS-ANY-DAG: copy_s.h [[RD:\$[0-9]+]], [[WS]][1]
 ; MIPS32-DAG: lw [[RES:\$[0-9]+]], %got(llvm_mips_copy_s_h_RES)
 ; MIPS64-DAG: ld [[RES:\$[0-9]+]], %got_disp(llvm_mips_copy_s_h_RES)
 ; MIPS-ANY-DAG: sw [[RD]], 0([[RES]])
 ; MIPS-ANY: .size llvm_mips_copy_s_h_test
 ;
 @llvm_mips_copy_s_w_ARG1 = global <4 x i32> <i32 0, i32 1, i32 2, i32 3>, align 16
 @llvm_mips_copy_s_w_RES  = global i32 0, align 16

 define void @llvm_mips_copy_s_w_test() nounwind {
 entry:
   %0 = load <4 x i32>, <4 x i32>* @llvm_mips_copy_s_w_ARG1
   %1 = tail call i32 @llvm.mips.copy.s.w(<4 x i32> %0, i32 1)
   store i32 %1, i32* @llvm_mips_copy_s_w_RES
   ret void
 }

 declare i32 @llvm.mips.copy.s.w(<4 x i32>, i32) nounwind

 ; MIPS-ANY: llvm_mips_copy_s_w_test:
 ; MIPS32-DAG: lw [[R1:\$[0-9]+]], %got(llvm_mips_copy_s_w_ARG1)
 ; MIPS64-DAG: ld [[R1:\$[0-9]+]], %got_disp(llvm_mips_copy_s_w_ARG1)
 ; MIPS-ANY-DAG: ld.w [[WS:\$w[0-9]+]], 0([[R1]])
 ; MIPS-ANY-DAG: copy_s.w [[RD:\$[0-9]+]], [[WS]][1]
 ; MIPS32-DAG: lw [[RES:\$[0-9]+]], %got(llvm_mips_copy_s_w_RES)
 ; MIPS64-DAG: ld [[RES:\$[0-9]+]], %got_disp(llvm_mips_copy_s_w_RES)
 ; MIPS-ANY-DAG: sw [[RD]], 0([[RES]])
 ; MIPS-ANY: .size llvm_mips_copy_s_w_test
 ;
 @llvm_mips_copy_s_d_ARG1 = global <2 x i64> <i64 0, i64 1>, align 16
 @llvm_mips_copy_s_d_RES  = global i64 0, align 16

 define void @llvm_mips_copy_s_d_test() nounwind {
 entry:
   %0 = load <2 x i64>, <2 x i64>* @llvm_mips_copy_s_d_ARG1
   %1 = tail call i64 @llvm.mips.copy.s.d(<2 x i64> %0, i32 1)
   store i64 %1, i64* @llvm_mips_copy_s_d_RES
   ret void
 }

 declare i64 @llvm.mips.copy.s.d(<2 x i64>, i32) nounwind

 ; MIPS-ANY: llvm_mips_copy_s_d_test:
 ; MIPS32-DAG: lw [[R1:\$[0-9]+]], %got(llvm_mips_copy_s_d_ARG1)
 ; MIPS64-DAG: ld [[R1:\$[0-9]+]], %got_disp(llvm_mips_copy_s_d_ARG1)
 ; MIPS32-DAG: ld.w [[WS:\$w[0-9]+]], 0([[R1]])
 ; MIPS64-DAG: ld.d [[WS:\$w[0-9]+]], 0([[R1]])
 ; MIPS32-DAG: copy_s.w [[RD1:\$[0-9]+]], [[WS]][2]
 ; MIPS32-DAG: copy_s.w [[RD2:\$[0-9]+]], [[WS]][3]
 ; MIPS64-DAG: copy_s.d [[RD:\$[0-9]+]], [[WS]][1]
 ; MIPS32-DAG: lw [[RES:\$[0-9]+]], %got(llvm_mips_copy_s_d_RES)
 ; MIPS64-DAG: ld [[RES:\$[0-9]+]], %got_disp(llvm_mips_copy_s_d_RES)
 ; MIPS32-DAG: sw [[RD1]], 0([[RES]])
 ; MIPS32-DAG: sw [[RD2]], 4([[RES]])
 ; MIPS64-DAG: sd [[RD]], 0([[RES]])
 ; MIPS-ANY: .size llvm_mips_copy_s_d_test
 ;
 @llvm_mips_copy_u_b_ARG1 = global <16 x i8> <i8 0, i8 1, i8 2, i8 3, i8 4, i8 5, i8 6, i8 7, i8 8, i8 9, i8 10, i8 11, i8 12, i8 13, i8 14, i8 15>, align 16
 @llvm_mips_copy_u_b_RES  = global i32 0, align 16

 define void @llvm_mips_copy_u_b_test() nounwind {
 entry:
   %0 = load <16 x i8>, <16 x i8>* @llvm_mips_copy_u_b_ARG1
   %1 = tail call i32 @llvm.mips.copy.u.b(<16 x i8> %0, i32 1)
   store i32 %1, i32* @llvm_mips_copy_u_b_RES
   ret void
 }

 declare i32 @llvm.mips.copy.u.b(<16 x i8>, i32) nounwind

 ; MIPS-ANY: llvm_mips_copy_u_b_test:
 ; MIPS32-DAG: lw [[R1:\$[0-9]+]], %got(llvm_mips_copy_u_b_ARG1)
 ; MIPS64-DAG: ld [[R1:\$[0-9]+]], %got_disp(llvm_mips_copy_u_b_ARG1)
 ; MIPS-ANY-DAG: ld.b [[WS:\$w[0-9]+]], 0([[R1]])
 ; MIPS-ANY-DAG: copy_u.b [[RD:\$[0-9]+]], [[WS]][1]
 ; MIPS32-DAG: lw [[RES:\$[0-9]+]], %got(llvm_mips_copy_u_b_RES)
 ; MIPS64-DAG: ld [[RES:\$[0-9]+]], %got_disp(llvm_mips_copy_u_b_RES)
 ; MIPS-ANY-DAG: sw [[RD]], 0([[RES]])
 ; MIPS-ANY: .size llvm_mips_copy_u_b_test
 ;
 @llvm_mips_copy_u_h_ARG1 = global <8 x i16> <i16 0, i16 1, i16 2, i16 3, i16 4, i16 5, i16 6, i16 7>, align 16
 @llvm_mips_copy_u_h_RES  = global i32 0, align 16

 define void @llvm_mips_copy_u_h_test() nounwind {
 entry:
   %0 = load <8 x i16>, <8 x i16>* @llvm_mips_copy_u_h_ARG1
   %1 = tail call i32 @llvm.mips.copy.u.h(<8 x i16> %0, i32 1)
   store i32 %1, i32* @llvm_mips_copy_u_h_RES
   ret void
 }

 declare i32 @llvm.mips.copy.u.h(<8 x i16>, i32) nounwind

 ; MIPS-ANY: llvm_mips_copy_u_h_test:
 ; MIPS32-DAG: lw [[R1:\$[0-9]+]], %got(llvm_mips_copy_u_h_ARG1)
 ; MIPS64-DAG: ld [[R1:\$[0-9]+]], %got_disp(llvm_mips_copy_u_h_ARG1)
 ; MIPS-ANY-DAG: ld.h [[WS:\$w[0-9]+]], 0([[R1]])
 ; MIPS-ANY-DAG: copy_u.h [[RD:\$[0-9]+]], [[WS]][1]
 ; MIPS32-DAG: lw [[RES:\$[0-9]+]], %got(llvm_mips_copy_u_h_RES)
 ; MIPS64-DAG: ld [[RES:\$[0-9]+]], %got_disp(llvm_mips_copy_u_h_RES)
 ; MIPS-ANY-DAG: sw [[RD]], 0([[RES]])
 ; MIPS-ANY: .size llvm_mips_copy_u_h_test
 ;
 @llvm_mips_copy_u_w_ARG1 = global <4 x i32> <i32 0, i32 1, i32 2, i32 3>, align 16
 @llvm_mips_copy_u_w_RES  = global i32 0, align 16

 define void @llvm_mips_copy_u_w_test() nounwind {
 entry:
   %0 = load <4 x i32>, <4 x i32>* @llvm_mips_copy_u_w_ARG1
   %1 = tail call i32 @llvm.mips.copy.u.w(<4 x i32> %0, i32 1)
   store i32 %1, i32* @llvm_mips_copy_u_w_RES
   ret void
 }

 declare i32 @llvm.mips.copy.u.w(<4 x i32>, i32) nounwind

 ; MIPS-ANY: llvm_mips_copy_u_w_test:
 ; MIPS32-DAG: lw [[R1:\$[0-9]+]], %got(llvm_mips_copy_u_w_ARG1)
 ; MIPS64-DAG: ld [[R1:\$[0-9]+]], %got_disp(llvm_mips_copy_u_w_ARG1)
 ; MIPS-ANY-DAG: ld.w [[WS:\$w[0-9]+]], 0([[R1]])
 ; MIPS32-DAG: copy_s.w [[RD:\$[0-9]+]], [[WS]][1]
 ; MIPS64-DAG: copy_u.w [[RD:\$[0-9]+]], [[WS]][1]
 ; MIPS32-DAG: lw [[RES:\$[0-9]+]], %got(llvm_mips_copy_u_w_RES)
 ; MIPS64-DAG: ld [[RES:\$[0-9]+]], %got_disp(llvm_mips_copy_u_w_RES)
 ; MIPS-ANY-DAG: sw [[RD]], 0([[RES]])
 ; MIPS-ANY: .size llvm_mips_copy_u_w_test
 ;
 @llvm_mips_copy_u_d_ARG1 = global <2 x i64> <i64 0, i64 1>, align 16
 @llvm_mips_copy_u_d_RES  = global i64 0, align 16

 define void @llvm_mips_copy_u_d_test() nounwind {
 entry:
   %0 = load <2 x i64>, <2 x i64>* @llvm_mips_copy_u_d_ARG1
   %1 = tail call i64 @llvm.mips.copy.u.d(<2 x i64> %0, i32 1)
   store i64 %1, i64* @llvm_mips_copy_u_d_RES
   ret void
 }

 declare i64 @llvm.mips.copy.u.d(<2 x i64>, i32) nounwind

 ; MIPS-ANY: llvm_mips_copy_u_d_test:
 ; MIPS32-DAG: lw [[R1:\$[0-9]+]], %got(llvm_mips_copy_u_d_ARG1)
 ; MIPS64-DAG: ld [[R1:\$[0-9]+]], %got_disp(llvm_mips_copy_u_d_ARG1)
 ; MIPS32-DAG: ld.w [[WS:\$w[0-9]+]], 0([[R1]])
 ; MIPS64-DAG: ld.d [[WS:\$w[0-9]+]], 0([[R1]])
 ; MIPS32-DAG: copy_s.w [[RD1:\$[0-9]+]], [[WS]][2]
 ; MIPS32-DAG: copy_s.w [[RD2:\$[0-9]+]], [[WS]][3]
 ; MIPS64-DAG: copy_s.d [[RD:\$[0-9]+]], [[WS]][1]
 ; MIPS32-DAG: lw [[RES:\$[0-9]+]], %got(llvm_mips_copy_u_d_RES)
 ; MIPS64-DAG: ld [[RES:\$[0-9]+]], %got_disp(llvm_mips_copy_u_d_RES)
 ; MIPS32-DAG: sw [[RD1]], 0([[RES]])
 ; MIPS32-DAG: sw [[RD2]], 4([[RES]])
 ; MIPS64-DAG: sd [[RD]], 0([[RES]])
 ; MIPS-ANY: .size llvm_mips_copy_u_d_test
 ;
	; Test the MSA intrinsics that are encoded with the ELM instruction format and
	; are element extraction operations.

	; RUN: llc -march=mips -mattr=+msa,+fp64 -relocation-model=pic < %s \| \
	; RUN: FileCheck %s -check-prefixes=MIPS-ANY,MIPS32
	; RUN: llc -march=mipsel -mattr=+msa,+fp64 -relocation-model=pic < %s \| \
	; RUN: FileCheck %s -check-prefixes=MIPS-ANY,MIPS32
	; RUN: llc -march=mips64 -mcpu=mips64r2 -mattr=+msa,+fp64 -relocation-model=pic < %s \| \
	; RUN: FileCheck %s -check-prefixes=MIPS-ANY,MIPS64
	; RUN: llc -march=mips64el -mcpu=mips64r2 -mattr=+msa,+fp64 -relocation-model=pic < %s \| \
	; RUN: FileCheck %s -check-prefixes=MIPS-ANY,MIPS64

	@llvm_mips_copy_s_b_ARG1 = global <16 x i8> <i8 0, i8 1, i8 2, i8 3, i8 4, i8 5, i8 6, i8 7, i8 8, i8 9, i8 10, i8 11, i8 12, i8 13, i8 14, i8 15>, align 16
	@llvm_mips_copy_s_b_RES = global i32 0, align 16

	define void @llvm_mips_copy_s_b_test() nounwind {
	entry:
	%0 = load <16 x i8>, <16 x i8>* @llvm_mips_copy_s_b_ARG1
	%1 = tail call i32 @llvm.mips.copy.s.b(<16 x i8> %0, i32 1)
	store i32 %1, i32* @llvm_mips_copy_s_b_RES
	ret void
	}

	declare i32 @llvm.mips.copy.s.b(<16 x i8>, i32) nounwind

	; MIPS-ANY: llvm_mips_copy_s_b_test:
	; MIPS32-DAG: lw [[R1:\$[0-9]+]], %got(llvm_mips_copy_s_b_ARG1)
	; MIPS64-DAG: ld [[R1:\$[0-9]+]], %got_disp(llvm_mips_copy_s_b_ARG1)
	; MIPS-ANY-DAG: ld.b [[WS:\$w[0-9]+]], 0([[R1]])
	; MIPS-ANY-DAG: copy_s.b [[RD:\$[0-9]+]], [[WS]][1]
	; MIPS32-DAG: lw [[RES:\$[0-9]+]], %got(llvm_mips_copy_s_b_RES)
	; MIPS64-DAG: ld [[RES:\$[0-9]+]], %got_disp(llvm_mips_copy_s_b_RES)
	; MIPS-ANY-DAG: sw [[RD]], 0([[RES]])
	; MIPS-ANY: .size llvm_mips_copy_s_b_test
	;
	@llvm_mips_copy_s_h_ARG1 = global <8 x i16> <i16 0, i16 1, i16 2, i16 3, i16 4, i16 5, i16 6, i16 7>, align 16
	@llvm_mips_copy_s_h_RES = global i32 0, align 16

	define void @llvm_mips_copy_s_h_test() nounwind {
	entry:
	%0 = load <8 x i16>, <8 x i16>* @llvm_mips_copy_s_h_ARG1
	%1 = tail call i32 @llvm.mips.copy.s.h(<8 x i16> %0, i32 1)
	store i32 %1, i32* @llvm_mips_copy_s_h_RES
	ret void
	}

	declare i32 @llvm.mips.copy.s.h(<8 x i16>, i32) nounwind

	; MIPS-ANY: llvm_mips_copy_s_h_test:
	; MIPS32-DAG: lw [[R1:\$[0-9]+]], %got(llvm_mips_copy_s_h_ARG1)
	; MIPS64-DAG: ld [[R1:\$[0-9]+]], %got_disp(llvm_mips_copy_s_h_ARG1)
	; MIPS-ANY-DAG: ld.h [[WS:\$w[0-9]+]], 0([[R1]])
	; MIPS-ANY-DAG: copy_s.h [[RD:\$[0-9]+]], [[WS]][1]
	; MIPS32-DAG: lw [[RES:\$[0-9]+]], %got(llvm_mips_copy_s_h_RES)
	; MIPS64-DAG: ld [[RES:\$[0-9]+]], %got_disp(llvm_mips_copy_s_h_RES)
	; MIPS-ANY-DAG: sw [[RD]], 0([[RES]])
	; MIPS-ANY: .size llvm_mips_copy_s_h_test
	;
	@llvm_mips_copy_s_w_ARG1 = global <4 x i32> <i32 0, i32 1, i32 2, i32 3>, align 16
	@llvm_mips_copy_s_w_RES = global i32 0, align 16

	define void @llvm_mips_copy_s_w_test() nounwind {
	entry:
	%0 = load <4 x i32>, <4 x i32>* @llvm_mips_copy_s_w_ARG1
	%1 = tail call i32 @llvm.mips.copy.s.w(<4 x i32> %0, i32 1)
	store i32 %1, i32* @llvm_mips_copy_s_w_RES
	ret void
	}

	declare i32 @llvm.mips.copy.s.w(<4 x i32>, i32) nounwind

	; MIPS-ANY: llvm_mips_copy_s_w_test:
	; MIPS32-DAG: lw [[R1:\$[0-9]+]], %got(llvm_mips_copy_s_w_ARG1)
	; MIPS64-DAG: ld [[R1:\$[0-9]+]], %got_disp(llvm_mips_copy_s_w_ARG1)
	; MIPS-ANY-DAG: ld.w [[WS:\$w[0-9]+]], 0([[R1]])
	; MIPS-ANY-DAG: copy_s.w [[RD:\$[0-9]+]], [[WS]][1]
	; MIPS32-DAG: lw [[RES:\$[0-9]+]], %got(llvm_mips_copy_s_w_RES)
	; MIPS64-DAG: ld [[RES:\$[0-9]+]], %got_disp(llvm_mips_copy_s_w_RES)
	; MIPS-ANY-DAG: sw [[RD]], 0([[RES]])
	; MIPS-ANY: .size llvm_mips_copy_s_w_test
	;
	@llvm_mips_copy_s_d_ARG1 = global <2 x i64> <i64 0, i64 1>, align 16
	@llvm_mips_copy_s_d_RES = global i64 0, align 16

	define void @llvm_mips_copy_s_d_test() nounwind {
	entry:
	%0 = load <2 x i64>, <2 x i64>* @llvm_mips_copy_s_d_ARG1
	%1 = tail call i64 @llvm.mips.copy.s.d(<2 x i64> %0, i32 1)
	store i64 %1, i64* @llvm_mips_copy_s_d_RES
	ret void
	}

	declare i64 @llvm.mips.copy.s.d(<2 x i64>, i32) nounwind

	; MIPS-ANY: llvm_mips_copy_s_d_test:
	; MIPS32-DAG: lw [[R1:\$[0-9]+]], %got(llvm_mips_copy_s_d_ARG1)
	; MIPS64-DAG: ld [[R1:\$[0-9]+]], %got_disp(llvm_mips_copy_s_d_ARG1)
	; MIPS32-DAG: ld.w [[WS:\$w[0-9]+]], 0([[R1]])
	; MIPS64-DAG: ld.d [[WS:\$w[0-9]+]], 0([[R1]])
	; MIPS32-DAG: copy_s.w [[RD1:\$[0-9]+]], [[WS]][2]
	; MIPS32-DAG: copy_s.w [[RD2:\$[0-9]+]], [[WS]][3]
	; MIPS64-DAG: copy_s.d [[RD:\$[0-9]+]], [[WS]][1]
	; MIPS32-DAG: lw [[RES:\$[0-9]+]], %got(llvm_mips_copy_s_d_RES)
	; MIPS64-DAG: ld [[RES:\$[0-9]+]], %got_disp(llvm_mips_copy_s_d_RES)
	; MIPS32-DAG: sw [[RD1]], 0([[RES]])
	; MIPS32-DAG: sw [[RD2]], 4([[RES]])
	; MIPS64-DAG: sd [[RD]], 0([[RES]])
	; MIPS-ANY: .size llvm_mips_copy_s_d_test
	;
	@llvm_mips_copy_u_b_ARG1 = global <16 x i8> <i8 0, i8 1, i8 2, i8 3, i8 4, i8 5, i8 6, i8 7, i8 8, i8 9, i8 10, i8 11, i8 12, i8 13, i8 14, i8 15>, align 16
	@llvm_mips_copy_u_b_RES = global i32 0, align 16

	define void @llvm_mips_copy_u_b_test() nounwind {
	entry:
	%0 = load <16 x i8>, <16 x i8>* @llvm_mips_copy_u_b_ARG1
	%1 = tail call i32 @llvm.mips.copy.u.b(<16 x i8> %0, i32 1)
	store i32 %1, i32* @llvm_mips_copy_u_b_RES
	ret void
	}

	declare i32 @llvm.mips.copy.u.b(<16 x i8>, i32) nounwind

	; MIPS-ANY: llvm_mips_copy_u_b_test:
	; MIPS32-DAG: lw [[R1:\$[0-9]+]], %got(llvm_mips_copy_u_b_ARG1)
	; MIPS64-DAG: ld [[R1:\$[0-9]+]], %got_disp(llvm_mips_copy_u_b_ARG1)
	; MIPS-ANY-DAG: ld.b [[WS:\$w[0-9]+]], 0([[R1]])
	; MIPS-ANY-DAG: copy_u.b [[RD:\$[0-9]+]], [[WS]][1]
	; MIPS32-DAG: lw [[RES:\$[0-9]+]], %got(llvm_mips_copy_u_b_RES)
	; MIPS64-DAG: ld [[RES:\$[0-9]+]], %got_disp(llvm_mips_copy_u_b_RES)
	; MIPS-ANY-DAG: sw [[RD]], 0([[RES]])
	; MIPS-ANY: .size llvm_mips_copy_u_b_test
	;
	@llvm_mips_copy_u_h_ARG1 = global <8 x i16> <i16 0, i16 1, i16 2, i16 3, i16 4, i16 5, i16 6, i16 7>, align 16
	@llvm_mips_copy_u_h_RES = global i32 0, align 16

	define void @llvm_mips_copy_u_h_test() nounwind {
	entry:
	%0 = load <8 x i16>, <8 x i16>* @llvm_mips_copy_u_h_ARG1
	%1 = tail call i32 @llvm.mips.copy.u.h(<8 x i16> %0, i32 1)
	store i32 %1, i32* @llvm_mips_copy_u_h_RES
	ret void
	}

	declare i32 @llvm.mips.copy.u.h(<8 x i16>, i32) nounwind

	; MIPS-ANY: llvm_mips_copy_u_h_test:
	; MIPS32-DAG: lw [[R1:\$[0-9]+]], %got(llvm_mips_copy_u_h_ARG1)
	; MIPS64-DAG: ld [[R1:\$[0-9]+]], %got_disp(llvm_mips_copy_u_h_ARG1)
	; MIPS-ANY-DAG: ld.h [[WS:\$w[0-9]+]], 0([[R1]])
	; MIPS-ANY-DAG: copy_u.h [[RD:\$[0-9]+]], [[WS]][1]
	; MIPS32-DAG: lw [[RES:\$[0-9]+]], %got(llvm_mips_copy_u_h_RES)
	; MIPS64-DAG: ld [[RES:\$[0-9]+]], %got_disp(llvm_mips_copy_u_h_RES)
	; MIPS-ANY-DAG: sw [[RD]], 0([[RES]])
	; MIPS-ANY: .size llvm_mips_copy_u_h_test
	;
	@llvm_mips_copy_u_w_ARG1 = global <4 x i32> <i32 0, i32 1, i32 2, i32 3>, align 16
	@llvm_mips_copy_u_w_RES = global i32 0, align 16

	define void @llvm_mips_copy_u_w_test() nounwind {
	entry:
	%0 = load <4 x i32>, <4 x i32>* @llvm_mips_copy_u_w_ARG1
	%1 = tail call i32 @llvm.mips.copy.u.w(<4 x i32> %0, i32 1)
	store i32 %1, i32* @llvm_mips_copy_u_w_RES
	ret void
	}

	declare i32 @llvm.mips.copy.u.w(<4 x i32>, i32) nounwind

	; MIPS-ANY: llvm_mips_copy_u_w_test:
	; MIPS32-DAG: lw [[R1:\$[0-9]+]], %got(llvm_mips_copy_u_w_ARG1)
	; MIPS64-DAG: ld [[R1:\$[0-9]+]], %got_disp(llvm_mips_copy_u_w_ARG1)
	; MIPS-ANY-DAG: ld.w [[WS:\$w[0-9]+]], 0([[R1]])
	; MIPS32-DAG: copy_s.w [[RD:\$[0-9]+]], [[WS]][1]
	; MIPS64-DAG: copy_u.w [[RD:\$[0-9]+]], [[WS]][1]
	; MIPS32-DAG: lw [[RES:\$[0-9]+]], %got(llvm_mips_copy_u_w_RES)
	; MIPS64-DAG: ld [[RES:\$[0-9]+]], %got_disp(llvm_mips_copy_u_w_RES)
	; MIPS-ANY-DAG: sw [[RD]], 0([[RES]])
	; MIPS-ANY: .size llvm_mips_copy_u_w_test
	;
	@llvm_mips_copy_u_d_ARG1 = global <2 x i64> <i64 0, i64 1>, align 16
	@llvm_mips_copy_u_d_RES = global i64 0, align 16

	define void @llvm_mips_copy_u_d_test() nounwind {
	entry:
	%0 = load <2 x i64>, <2 x i64>* @llvm_mips_copy_u_d_ARG1
	%1 = tail call i64 @llvm.mips.copy.u.d(<2 x i64> %0, i32 1)
	store i64 %1, i64* @llvm_mips_copy_u_d_RES
	ret void
	}

	declare i64 @llvm.mips.copy.u.d(<2 x i64>, i32) nounwind

	; MIPS-ANY: llvm_mips_copy_u_d_test:
	; MIPS32-DAG: lw [[R1:\$[0-9]+]], %got(llvm_mips_copy_u_d_ARG1)
	; MIPS64-DAG: ld [[R1:\$[0-9]+]], %got_disp(llvm_mips_copy_u_d_ARG1)
	; MIPS32-DAG: ld.w [[WS:\$w[0-9]+]], 0([[R1]])
	; MIPS64-DAG: ld.d [[WS:\$w[0-9]+]], 0([[R1]])
	; MIPS32-DAG: copy_s.w [[RD1:\$[0-9]+]], [[WS]][2]
	; MIPS32-DAG: copy_s.w [[RD2:\$[0-9]+]], [[WS]][3]
	; MIPS64-DAG: copy_s.d [[RD:\$[0-9]+]], [[WS]][1]
	; MIPS32-DAG: lw [[RES:\$[0-9]+]], %got(llvm_mips_copy_u_d_RES)
	; MIPS64-DAG: ld [[RES:\$[0-9]+]], %got_disp(llvm_mips_copy_u_d_RES)
	; MIPS32-DAG: sw [[RD1]], 0([[RES]])
	; MIPS32-DAG: sw [[RD2]], 4([[RES]])
	; MIPS64-DAG: sd [[RD]], 0([[RES]])
	; MIPS-ANY: .size llvm_mips_copy_u_d_test
	;