; NOTE: Assertions have been autogenerated by utils/update_llc_test_checks.py UTC_ARGS: --version 3 ; RUN: llc -amdgpu-scalarize-global-loads=false -mtriple=r600 -mcpu=redwood < %s | FileCheck -check-prefix=EG %s define amdgpu_kernel void @or_v2i32(ptr addrspace(1) %out, ptr addrspace(1) %in) { ; EG-LABEL: or_v2i32: ; EG: ; %bb.0: ; EG-NEXT: ALU 0, @8, KC0[CB0:0-32], KC1[] ; EG-NEXT: TEX 0 @6 ; EG-NEXT: ALU 3, @9, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.XY, T1.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: Fetch clause starting at 6: ; EG-NEXT: VTX_READ_128 T0.XYZW, T0.X, 0, #1 ; EG-NEXT: ALU clause starting at 8: ; EG-NEXT: MOV * T0.X, KC0[2].Z, ; EG-NEXT: ALU clause starting at 9: ; EG-NEXT: OR_INT * T0.Y, T0.Y, T0.W, ; EG-NEXT: OR_INT T0.X, T0.X, T0.Z, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.x, ; EG-NEXT: 2(2.802597e-45), 0(0.000000e+00) %b_ptr = getelementptr <2 x i32>, ptr addrspace(1) %in, i32 1 %a = load <2 x i32>, ptr addrspace(1) %in %b = load <2 x i32>, ptr addrspace(1) %b_ptr %result = or <2 x i32> %a, %b store <2 x i32> %result, ptr addrspace(1) %out ret void } define amdgpu_kernel void @or_v4i32(ptr addrspace(1) %out, ptr addrspace(1) %in) { ; EG-LABEL: or_v4i32: ; EG: ; %bb.0: ; EG-NEXT: ALU 0, @10, KC0[CB0:0-32], KC1[] ; EG-NEXT: TEX 1 @6 ; EG-NEXT: ALU 5, @11, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.XYZW, T1.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: Fetch clause starting at 6: ; EG-NEXT: VTX_READ_128 T1.XYZW, T0.X, 16, #1 ; EG-NEXT: VTX_READ_128 T0.XYZW, T0.X, 0, #1 ; EG-NEXT: ALU clause starting at 10: ; EG-NEXT: MOV * T0.X, KC0[2].Z, ; EG-NEXT: ALU clause starting at 11: ; EG-NEXT: OR_INT * T0.W, T0.W, T1.W, ; EG-NEXT: OR_INT * T0.Z, T0.Z, T1.Z, ; EG-NEXT: OR_INT * T0.Y, T0.Y, T1.Y, ; EG-NEXT: OR_INT T0.X, T0.X, T1.X, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.x, ; EG-NEXT: 2(2.802597e-45), 0(0.000000e+00) %b_ptr = getelementptr <4 x i32>, ptr addrspace(1) %in, i32 1 %a = load <4 x i32>, ptr addrspace(1) %in %b = load <4 x i32>, ptr addrspace(1) %b_ptr %result = or <4 x i32> %a, %b store <4 x i32> %result, ptr addrspace(1) %out ret void } define amdgpu_kernel void @scalar_or_i32(ptr addrspace(1) %out, i32 %a, i32 %b) { ; EG-LABEL: scalar_or_i32: ; EG: ; %bb.0: ; EG-NEXT: ALU 2, @4, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T1.X, T0.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: ALU clause starting at 4: ; EG-NEXT: LSHR T0.X, KC0[2].Y, literal.x, ; EG-NEXT: OR_INT * T1.X, KC0[2].Z, KC0[2].W, ; EG-NEXT: 2(2.802597e-45), 0(0.000000e+00) %or = or i32 %a, %b store i32 %or, ptr addrspace(1) %out ret void } define amdgpu_kernel void @vector_or_i32(ptr addrspace(1) %out, ptr addrspace(1) %a, i32 %b) { ; EG-LABEL: vector_or_i32: ; EG: ; %bb.0: ; EG-NEXT: ALU 0, @8, KC0[CB0:0-32], KC1[] ; EG-NEXT: TEX 0 @6 ; EG-NEXT: ALU 2, @9, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.X, T1.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: Fetch clause starting at 6: ; EG-NEXT: VTX_READ_32 T0.X, T0.X, 0, #1 ; EG-NEXT: ALU clause starting at 8: ; EG-NEXT: MOV * T0.X, KC0[2].Z, ; EG-NEXT: ALU clause starting at 9: ; EG-NEXT: OR_INT T0.X, T0.X, KC0[2].W, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.x, ; EG-NEXT: 2(2.802597e-45), 0(0.000000e+00) %loada = load i32, ptr addrspace(1) %a %or = or i32 %loada, %b store i32 %or, ptr addrspace(1) %out ret void } define amdgpu_kernel void @scalar_or_literal_i32(ptr addrspace(1) %out, i32 %a) { ; EG-LABEL: scalar_or_literal_i32: ; EG: ; %bb.0: ; EG-NEXT: ALU 2, @4, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T1.X, T0.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: ALU clause starting at 4: ; EG-NEXT: LSHR T0.X, KC0[2].Y, literal.x, ; EG-NEXT: OR_INT * T1.X, KC0[2].Z, literal.y, ; EG-NEXT: 2(2.802597e-45), 99999(1.401284e-40) %or = or i32 %a, 99999 store i32 %or, ptr addrspace(1) %out, align 4 ret void } define amdgpu_kernel void @scalar_or_literal_i64(ptr addrspace(1) %out, [8 x i32], i64 %a) { ; EG-LABEL: scalar_or_literal_i64: ; EG: ; %bb.0: ; EG-NEXT: ALU 4, @4, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.XY, T1.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: ALU clause starting at 4: ; EG-NEXT: OR_INT * T0.Y, KC0[5].X, literal.x, ; EG-NEXT: 992123(1.390260e-39), 0(0.000000e+00) ; EG-NEXT: OR_INT T0.X, KC0[4].W, literal.x, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.y, ; EG-NEXT: 12345(1.729903e-41), 2(2.802597e-45) %or = or i64 %a, 4261135838621753 store i64 %or, ptr addrspace(1) %out ret void } define amdgpu_kernel void @scalar_or_literal_multi_use_i64(ptr addrspace(1) %out, [8 x i32], i64 %a, [8 x i32], i64 %b) { ; EG-LABEL: scalar_or_literal_multi_use_i64: ; EG: ; %bb.0: ; EG-NEXT: ALU 12, @6, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T3.XY, T4.X, 0 ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T1.X, T2.X, 0 ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.X, T2.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: ALU clause starting at 6: ; EG-NEXT: ADDC_UINT * T0.W, KC0[7].Y, literal.x, ; EG-NEXT: 12345(1.729903e-41), 0(0.000000e+00) ; EG-NEXT: ADD_INT T0.X, KC0[7].Y, literal.x, ; EG-NEXT: ADD_INT * T0.W, KC0[7].Z, PV.W, ; EG-NEXT: 12345(1.729903e-41), 0(0.000000e+00) ; EG-NEXT: ADD_INT T1.X, PV.W, literal.x, ; EG-NEXT: MOV * T2.X, literal.y, ; EG-NEXT: 992123(1.390260e-39), 0(0.000000e+00) ; EG-NEXT: OR_INT * T3.Y, KC0[5].X, literal.x, ; EG-NEXT: 992123(1.390260e-39), 0(0.000000e+00) ; EG-NEXT: OR_INT T3.X, KC0[4].W, literal.x, ; EG-NEXT: LSHR * T4.X, KC0[2].Y, literal.y, ; EG-NEXT: 12345(1.729903e-41), 2(2.802597e-45) %or = or i64 %a, 4261135838621753 store i64 %or, ptr addrspace(1) %out %foo = add i64 %b, 4261135838621753 store volatile i64 %foo, ptr addrspace(1) poison ret void } define amdgpu_kernel void @scalar_or_inline_imm_i64(ptr addrspace(1) %out, [8 x i32], i64 %a) { ; EG-LABEL: scalar_or_inline_imm_i64: ; EG: ; %bb.0: ; EG-NEXT: ALU 3, @4, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.XY, T1.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: ALU clause starting at 4: ; EG-NEXT: MOV * T0.Y, KC0[5].X, ; EG-NEXT: OR_INT T0.X, KC0[4].W, literal.x, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.y, ; EG-NEXT: 63(8.828180e-44), 2(2.802597e-45) %or = or i64 %a, 63 store i64 %or, ptr addrspace(1) %out ret void } define amdgpu_kernel void @scalar_or_inline_imm_multi_use_i64(ptr addrspace(1) %out, i64 %a, i64 %b) { ; EG-LABEL: scalar_or_inline_imm_multi_use_i64: ; EG: ; %bb.0: ; EG-NEXT: ALU 9, @6, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T3.XY, T4.X, 0 ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T1.X, T2.X, 0 ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.X, T2.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: ALU clause starting at 6: ; EG-NEXT: ADD_INT T0.X, KC0[3].Y, literal.x, ; EG-NEXT: ADDC_UINT * T0.W, KC0[3].Y, literal.x, ; EG-NEXT: 63(8.828180e-44), 0(0.000000e+00) ; EG-NEXT: ADD_INT T1.X, KC0[3].Z, PV.W, ; EG-NEXT: MOV * T2.X, literal.x, ; EG-NEXT: 0(0.000000e+00), 0(0.000000e+00) ; EG-NEXT: MOV * T3.Y, KC0[3].X, ; EG-NEXT: OR_INT T3.X, KC0[2].W, literal.x, ; EG-NEXT: LSHR * T4.X, KC0[2].Y, literal.y, ; EG-NEXT: 63(8.828180e-44), 2(2.802597e-45) %or = or i64 %a, 63 store i64 %or, ptr addrspace(1) %out %foo = add i64 %b, 63 store volatile i64 %foo, ptr addrspace(1) poison ret void } define amdgpu_kernel void @scalar_or_neg_inline_imm_i64(ptr addrspace(1) %out, [8 x i32], i64 %a) { ; EG-LABEL: scalar_or_neg_inline_imm_i64: ; EG: ; %bb.0: ; EG-NEXT: ALU 4, @4, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.XY, T1.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: ALU clause starting at 4: ; EG-NEXT: OR_INT T0.X, KC0[4].W, literal.x, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.y, ; EG-NEXT: -8(nan), 2(2.802597e-45) ; EG-NEXT: MOV * T0.Y, literal.x, ; EG-NEXT: -1(nan), 0(0.000000e+00) %or = or i64 %a, -8 store i64 %or, ptr addrspace(1) %out ret void } define amdgpu_kernel void @vector_or_literal_i32(ptr addrspace(1) %out, ptr addrspace(1) %a, ptr addrspace(1) %b) { ; EG-LABEL: vector_or_literal_i32: ; EG: ; %bb.0: ; EG-NEXT: ALU 0, @8, KC0[CB0:0-32], KC1[] ; EG-NEXT: TEX 0 @6 ; EG-NEXT: ALU 2, @9, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.X, T1.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: Fetch clause starting at 6: ; EG-NEXT: VTX_READ_32 T0.X, T0.X, 0, #1 ; EG-NEXT: ALU clause starting at 8: ; EG-NEXT: MOV * T0.X, KC0[2].Z, ; EG-NEXT: ALU clause starting at 9: ; EG-NEXT: OR_INT T0.X, T0.X, literal.x, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.y, ; EG-NEXT: 65535(9.183409e-41), 2(2.802597e-45) %loada = load i32, ptr addrspace(1) %a, align 4 %or = or i32 %loada, 65535 store i32 %or, ptr addrspace(1) %out, align 4 ret void } define amdgpu_kernel void @vector_or_inline_immediate_i32(ptr addrspace(1) %out, ptr addrspace(1) %a, ptr addrspace(1) %b) { ; EG-LABEL: vector_or_inline_immediate_i32: ; EG: ; %bb.0: ; EG-NEXT: ALU 0, @8, KC0[CB0:0-32], KC1[] ; EG-NEXT: TEX 0 @6 ; EG-NEXT: ALU 2, @9, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.X, T1.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: Fetch clause starting at 6: ; EG-NEXT: VTX_READ_32 T0.X, T0.X, 0, #1 ; EG-NEXT: ALU clause starting at 8: ; EG-NEXT: MOV * T0.X, KC0[2].Z, ; EG-NEXT: ALU clause starting at 9: ; EG-NEXT: OR_INT T0.X, T0.X, literal.x, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.y, ; EG-NEXT: 4(5.605194e-45), 2(2.802597e-45) %loada = load i32, ptr addrspace(1) %a, align 4 %or = or i32 %loada, 4 store i32 %or, ptr addrspace(1) %out, align 4 ret void } define amdgpu_kernel void @scalar_or_i64(ptr addrspace(1) %out, i64 %a, i64 %b) { ; EG-LABEL: scalar_or_i64: ; EG: ; %bb.0: ; EG-NEXT: ALU 3, @4, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.XY, T1.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: ALU clause starting at 4: ; EG-NEXT: OR_INT * T0.Y, KC0[3].X, KC0[3].Z, ; EG-NEXT: OR_INT * T0.X, KC0[2].W, KC0[3].Y, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.x, ; EG-NEXT: 2(2.802597e-45), 0(0.000000e+00) %or = or i64 %a, %b store i64 %or, ptr addrspace(1) %out ret void } define amdgpu_kernel void @vector_or_i64(ptr addrspace(1) %out, ptr addrspace(1) %a, ptr addrspace(1) %b) { ; EG-LABEL: vector_or_i64: ; EG: ; %bb.0: ; EG-NEXT: ALU 1, @10, KC0[CB0:0-32], KC1[] ; EG-NEXT: TEX 1 @6 ; EG-NEXT: ALU 3, @12, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.XY, T1.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: Fetch clause starting at 6: ; EG-NEXT: VTX_READ_64 T1.XY, T1.X, 0, #1 ; EG-NEXT: VTX_READ_64 T0.XY, T0.X, 0, #1 ; EG-NEXT: ALU clause starting at 10: ; EG-NEXT: MOV T0.X, KC0[2].Z, ; EG-NEXT: MOV * T1.X, KC0[2].W, ; EG-NEXT: ALU clause starting at 12: ; EG-NEXT: OR_INT * T0.Y, T0.Y, T1.Y, ; EG-NEXT: OR_INT T0.X, T0.X, T1.X, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.x, ; EG-NEXT: 2(2.802597e-45), 0(0.000000e+00) %loada = load i64, ptr addrspace(1) %a, align 8 %loadb = load i64, ptr addrspace(1) %b, align 8 %or = or i64 %loada, %loadb store i64 %or, ptr addrspace(1) %out ret void } define amdgpu_kernel void @scalar_vector_or_i64(ptr addrspace(1) %out, ptr addrspace(1) %a, i64 %b) { ; EG-LABEL: scalar_vector_or_i64: ; EG: ; %bb.0: ; EG-NEXT: ALU 0, @8, KC0[CB0:0-32], KC1[] ; EG-NEXT: TEX 0 @6 ; EG-NEXT: ALU 3, @9, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.XY, T1.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: Fetch clause starting at 6: ; EG-NEXT: VTX_READ_64 T0.XY, T0.X, 0, #1 ; EG-NEXT: ALU clause starting at 8: ; EG-NEXT: MOV * T0.X, KC0[2].Z, ; EG-NEXT: ALU clause starting at 9: ; EG-NEXT: OR_INT * T0.Y, T0.Y, KC0[3].X, ; EG-NEXT: OR_INT T0.X, T0.X, KC0[2].W, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.x, ; EG-NEXT: 2(2.802597e-45), 0(0.000000e+00) %loada = load i64, ptr addrspace(1) %a %or = or i64 %loada, %b store i64 %or, ptr addrspace(1) %out ret void } define amdgpu_kernel void @vector_or_i64_loadimm(ptr addrspace(1) %out, ptr addrspace(1) %a, ptr addrspace(1) %b) { ; EG-LABEL: vector_or_i64_loadimm: ; EG: ; %bb.0: ; EG-NEXT: ALU 0, @8, KC0[CB0:0-32], KC1[] ; EG-NEXT: TEX 0 @6 ; EG-NEXT: ALU 4, @9, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.XY, T1.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: Fetch clause starting at 6: ; EG-NEXT: VTX_READ_64 T0.XY, T0.X, 0, #1 ; EG-NEXT: ALU clause starting at 8: ; EG-NEXT: MOV * T0.X, KC0[2].Z, ; EG-NEXT: ALU clause starting at 9: ; EG-NEXT: OR_INT * T0.Y, T0.Y, literal.x, ; EG-NEXT: 5231(7.330192e-42), 0(0.000000e+00) ; EG-NEXT: OR_INT T0.X, T0.X, literal.x, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.y, ; EG-NEXT: -545810305(-1.784115e+19), 2(2.802597e-45) %loada = load i64, ptr addrspace(1) %a, align 8 %or = or i64 %loada, 22470723082367 store i64 %or, ptr addrspace(1) %out ret void } ; FIXME: The or 0 should really be removed. define amdgpu_kernel void @vector_or_i64_imm(ptr addrspace(1) %out, ptr addrspace(1) %a, ptr addrspace(1) %b) { ; EG-LABEL: vector_or_i64_imm: ; EG: ; %bb.0: ; EG-NEXT: ALU 0, @8, KC0[CB0:0-32], KC1[] ; EG-NEXT: TEX 0 @6 ; EG-NEXT: ALU 2, @9, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.XY, T1.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: Fetch clause starting at 6: ; EG-NEXT: VTX_READ_64 T0.XY, T0.X, 0, #1 ; EG-NEXT: ALU clause starting at 8: ; EG-NEXT: MOV * T0.X, KC0[2].Z, ; EG-NEXT: ALU clause starting at 9: ; EG-NEXT: OR_INT T0.X, T0.X, literal.x, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.y, ; EG-NEXT: 8(1.121039e-44), 2(2.802597e-45) %loada = load i64, ptr addrspace(1) %a, align 8 %or = or i64 %loada, 8 store i64 %or, ptr addrspace(1) %out ret void } define amdgpu_kernel void @vector_or_i64_neg_inline_imm(ptr addrspace(1) %out, ptr addrspace(1) %a, ptr addrspace(1) %b) { ; EG-LABEL: vector_or_i64_neg_inline_imm: ; EG: ; %bb.0: ; EG-NEXT: ALU 0, @8, KC0[CB0:0-32], KC1[] ; EG-NEXT: TEX 0 @6 ; EG-NEXT: ALU 4, @9, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.XY, T1.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: Fetch clause starting at 6: ; EG-NEXT: VTX_READ_32 T0.X, T0.X, 0, #1 ; EG-NEXT: ALU clause starting at 8: ; EG-NEXT: MOV * T0.X, KC0[2].Z, ; EG-NEXT: ALU clause starting at 9: ; EG-NEXT: OR_INT T0.X, T0.X, literal.x, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.y, ; EG-NEXT: -8(nan), 2(2.802597e-45) ; EG-NEXT: MOV * T0.Y, literal.x, ; EG-NEXT: -1(nan), 0(0.000000e+00) %loada = load i64, ptr addrspace(1) %a, align 8 %or = or i64 %loada, -8 store i64 %or, ptr addrspace(1) %out ret void } define amdgpu_kernel void @vector_or_i64_neg_literal(ptr addrspace(1) %out, ptr addrspace(1) %a, ptr addrspace(1) %b) { ; EG-LABEL: vector_or_i64_neg_literal: ; EG: ; %bb.0: ; EG-NEXT: ALU 0, @8, KC0[CB0:0-32], KC1[] ; EG-NEXT: TEX 0 @6 ; EG-NEXT: ALU 4, @9, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.XY, T1.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: Fetch clause starting at 6: ; EG-NEXT: VTX_READ_32 T0.X, T0.X, 0, #1 ; EG-NEXT: ALU clause starting at 8: ; EG-NEXT: MOV * T0.X, KC0[2].Z, ; EG-NEXT: ALU clause starting at 9: ; EG-NEXT: OR_INT T0.X, T0.X, literal.x, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.y, ; EG-NEXT: -200(nan), 2(2.802597e-45) ; EG-NEXT: MOV * T0.Y, literal.x, ; EG-NEXT: -1(nan), 0(0.000000e+00) %loada = load i64, ptr addrspace(1) %a, align 8 %or = or i64 %loada, -200 store i64 %or, ptr addrspace(1) %out ret void } define amdgpu_kernel void @trunc_i64_or_to_i32(ptr addrspace(1) %out, [8 x i32], i64 %a, [8 x i32], i64 %b) { ; EG-LABEL: trunc_i64_or_to_i32: ; EG: ; %bb.0: ; EG-NEXT: ALU 2, @4, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T1.X, T0.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: ALU clause starting at 4: ; EG-NEXT: LSHR * T0.X, KC0[2].Y, literal.x, ; EG-NEXT: 2(2.802597e-45), 0(0.000000e+00) ; EG-NEXT: OR_INT * T1.X, KC0[7].Y, KC0[4].W, %add = or i64 %b, %a %trunc = trunc i64 %add to i32 store i32 %trunc, ptr addrspace(1) %out, align 8 ret void } define amdgpu_kernel void @or_i1(ptr addrspace(1) %out, ptr addrspace(1) %in0, ptr addrspace(1) %in1) { ; EG-LABEL: or_i1: ; EG: ; %bb.0: ; EG-NEXT: ALU 1, @10, KC0[CB0:0-32], KC1[] ; EG-NEXT: TEX 1 @6 ; EG-NEXT: ALU 4, @12, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T0.X, T1.X, 1 ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: Fetch clause starting at 6: ; EG-NEXT: VTX_READ_32 T1.X, T1.X, 0, #1 ; EG-NEXT: VTX_READ_32 T0.X, T0.X, 0, #1 ; EG-NEXT: ALU clause starting at 10: ; EG-NEXT: MOV T0.X, KC0[2].Z, ; EG-NEXT: MOV * T1.X, KC0[2].W, ; EG-NEXT: ALU clause starting at 12: ; EG-NEXT: MAX_DX10 * T0.W, T0.X, T1.X, ; EG-NEXT: SETGE_DX10 * T0.W, PV.W, 0.0, ; EG-NEXT: AND_INT T0.X, PV.W, 1, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.x, ; EG-NEXT: 2(2.802597e-45), 0(0.000000e+00) %a = load float, ptr addrspace(1) %in0 %b = load float, ptr addrspace(1) %in1 %acmp = fcmp oge float %a, 0.000000e+00 %bcmp = fcmp oge float %b, 0.000000e+00 %or = or i1 %acmp, %bcmp %result = zext i1 %or to i32 store i32 %result, ptr addrspace(1) %out ret void } define amdgpu_kernel void @s_or_i1(ptr addrspace(1) %out, i32 %a, i32 %b, i32 %c, i32 %d) { ; EG-LABEL: s_or_i1: ; EG: ; %bb.0: ; EG-NEXT: ALU 14, @4, KC0[CB0:0-32], KC1[] ; EG-NEXT: MEM_RAT MSKOR T0.XW, T1.X ; EG-NEXT: CF_END ; EG-NEXT: PAD ; EG-NEXT: ALU clause starting at 4: ; EG-NEXT: SETE_INT T0.W, KC0[3].X, KC0[3].Y, ; EG-NEXT: SETE_INT * T1.W, KC0[2].Z, KC0[2].W, ; EG-NEXT: AND_INT T2.W, KC0[2].Y, literal.x, ; EG-NEXT: OR_INT * T0.W, PS, PV.W, ; EG-NEXT: 3(4.203895e-45), 0(0.000000e+00) ; EG-NEXT: AND_INT T0.W, PS, 1, ; EG-NEXT: LSHL * T1.W, PV.W, literal.x, ; EG-NEXT: 3(4.203895e-45), 0(0.000000e+00) ; EG-NEXT: LSHL T0.X, PV.W, PS, ; EG-NEXT: LSHL * T0.W, literal.x, PS, ; EG-NEXT: 255(3.573311e-43), 0(0.000000e+00) ; EG-NEXT: MOV T0.Y, 0.0, ; EG-NEXT: MOV * T0.Z, 0.0, ; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.x, ; EG-NEXT: 2(2.802597e-45), 0(0.000000e+00) %cmp0 = icmp eq i32 %a, %b %cmp1 = icmp eq i32 %c, %d %or = or i1 %cmp0, %cmp1 store i1 %or, ptr addrspace(1) %out ret void }