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llvm-project/llvm/test/CodeGen/AMDGPU/srl.ll
Nicolai Hähnle 10cef708a7 AMDGPU: Clean up LDS-related occupancy calculations 
Occupancy is expressed as waves per SIMD. This means that we need to
take into account the number of SIMDs per "CU" or, to be more precise,
the number of SIMDs over which a workgroup may be distributed.

getOccupancyWithLocalMemSize was wrong because it didn't take SIMDs
into account at all.

At the same time, we need to take into account that WGP mode offers
access to a larger total amount of LDS, since this can affect how
non-power-of-two LDS allocations are rounded. To make this work
consistently, we distinguish between (available) local memory size and
addressable local memory size (which is always limited by 64kB on
gfx10+, even with WGP mode).

This change results in a massive amount of test churn. A lot of it is
caused by the fact that the default work group size is 1024, which means
that (due to rounding effects) the default occupancy on older hardware
is 8 instead of 10, which affects scheduling via register pressure
estimates. I've adjusted most tests by just running the UTC tools, but
in some cases I manually changed the work group size to 32 or 64 to make
sure that work group size chunkiness has no effect.

Differential Revision: https://reviews.llvm.org/D139468
2023-01-23 21:43:06 +01:00

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; NOTE: Assertions have been autogenerated by utils/update_llc_test_checks.py
; RUN: llc -amdgpu-scalarize-global-loads=false -march=amdgcn -mcpu=verde -verify-machineinstrs < %s | FileCheck %s -check-prefixes=SI
; RUN: llc -march=amdgcn -mcpu=tonga -mattr=-flat-for-global -verify-machineinstrs < %s | FileCheck %s -check-prefixes=VI
; RUN: llc -amdgpu-scalarize-global-loads=false -march=r600 -mcpu=redwood < %s | FileCheck %s -check-prefixes=EG
declare i32 @llvm.amdgcn.workitem.id.x() #0
define amdgpu_kernel void @lshr_i32(ptr addrspace(1) %out, ptr addrspace(1) %in) {
; SI-LABEL: lshr_i32:
; SI: ; %bb.0:
; SI-NEXT: s_load_dwordx4 s[0:3], s[0:1], 0x9
; SI-NEXT: s_mov_b32 s7, 0xf000
; SI-NEXT: s_mov_b32 s6, -1
; SI-NEXT: s_mov_b32 s10, s6
; SI-NEXT: s_mov_b32 s11, s7
; SI-NEXT: s_waitcnt lgkmcnt(0)
; SI-NEXT: s_mov_b32 s8, s2
; SI-NEXT: s_mov_b32 s9, s3
; SI-NEXT: buffer_load_dwordx2 v[0:1], off, s[8:11], 0
; SI-NEXT: s_mov_b32 s4, s0
; SI-NEXT: s_mov_b32 s5, s1
; SI-NEXT: s_waitcnt vmcnt(0)
; SI-NEXT: v_lshrrev_b32_e32 v0, v1, v0
; SI-NEXT: buffer_store_dword v0, off, s[4:7], 0
; SI-NEXT: s_endpgm
;
; VI-LABEL: lshr_i32:
; VI: ; %bb.0:
; VI-NEXT: s_load_dwordx4 s[0:3], s[0:1], 0x24
; VI-NEXT: s_waitcnt lgkmcnt(0)
; VI-NEXT: s_load_dwordx2 s[4:5], s[2:3], 0x0
; VI-NEXT: s_mov_b32 s3, 0xf000
; VI-NEXT: s_mov_b32 s2, -1
; VI-NEXT: s_waitcnt lgkmcnt(0)
; VI-NEXT: s_lshr_b32 s4, s4, s5
; VI-NEXT: v_mov_b32_e32 v0, s4
; VI-NEXT: buffer_store_dword v0, off, s[0:3], 0
; VI-NEXT: s_endpgm
;
; EG-LABEL: lshr_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_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: LSHR T0.X, T0.X, T0.Y,
; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.x,
; EG-NEXT: 2(2.802597e-45), 0(0.000000e+00)
%b_ptr = getelementptr i32, ptr addrspace(1) %in, i32 1
%a = load i32, ptr addrspace(1) %in
%b = load i32, ptr addrspace(1) %b_ptr
%result = lshr i32 %a, %b
store i32 %result, ptr addrspace(1) %out
ret void
}
define amdgpu_kernel void @lshr_v2i32(ptr addrspace(1) %out, ptr addrspace(1) %in) {
; SI-LABEL: lshr_v2i32:
; SI: ; %bb.0:
; SI-NEXT: s_load_dwordx4 s[0:3], s[0:1], 0x9
; SI-NEXT: s_mov_b32 s7, 0xf000
; SI-NEXT: s_mov_b32 s6, -1
; SI-NEXT: s_mov_b32 s10, s6
; SI-NEXT: s_mov_b32 s11, s7
; SI-NEXT: s_waitcnt lgkmcnt(0)
; SI-NEXT: s_mov_b32 s8, s2
; SI-NEXT: s_mov_b32 s9, s3
; SI-NEXT: buffer_load_dwordx4 v[0:3], off, s[8:11], 0
; SI-NEXT: s_mov_b32 s4, s0
; SI-NEXT: s_mov_b32 s5, s1
; SI-NEXT: s_waitcnt vmcnt(0)
; SI-NEXT: v_lshr_b32_e32 v1, v1, v3
; SI-NEXT: v_lshr_b32_e32 v0, v0, v2
; SI-NEXT: buffer_store_dwordx2 v[0:1], off, s[4:7], 0
; SI-NEXT: s_endpgm
;
; VI-LABEL: lshr_v2i32:
; VI: ; %bb.0:
; VI-NEXT: s_load_dwordx4 s[0:3], s[0:1], 0x24
; VI-NEXT: s_waitcnt lgkmcnt(0)
; VI-NEXT: s_load_dwordx4 s[4:7], s[2:3], 0x0
; VI-NEXT: s_mov_b32 s3, 0xf000
; VI-NEXT: s_mov_b32 s2, -1
; VI-NEXT: s_waitcnt lgkmcnt(0)
; VI-NEXT: s_lshr_b32 s5, s5, s7
; VI-NEXT: s_lshr_b32 s4, s4, s6
; VI-NEXT: v_mov_b32_e32 v0, s4
; VI-NEXT: v_mov_b32_e32 v1, s5
; VI-NEXT: buffer_store_dwordx2 v[0:1], off, s[0:3], 0
; VI-NEXT: s_endpgm
;
; EG-LABEL: lshr_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: LSHR * T0.Y, T0.Y, T0.W,
; EG-NEXT: LSHR 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 = lshr <2 x i32> %a, %b
store <2 x i32> %result, ptr addrspace(1) %out
ret void
}
define amdgpu_kernel void @lshr_v4i32(ptr addrspace(1) %out, ptr addrspace(1) %in) {
; SI-LABEL: lshr_v4i32:
; SI: ; %bb.0:
; SI-NEXT: s_load_dwordx4 s[0:3], s[0:1], 0x9
; SI-NEXT: s_mov_b32 s7, 0xf000
; SI-NEXT: s_mov_b32 s6, -1
; SI-NEXT: s_mov_b32 s10, s6
; SI-NEXT: s_mov_b32 s11, s7
; SI-NEXT: s_waitcnt lgkmcnt(0)
; SI-NEXT: s_mov_b32 s8, s2
; SI-NEXT: s_mov_b32 s9, s3
; SI-NEXT: buffer_load_dwordx4 v[0:3], off, s[8:11], 0
; SI-NEXT: buffer_load_dwordx4 v[4:7], off, s[8:11], 0 offset:16
; SI-NEXT: s_mov_b32 s4, s0
; SI-NEXT: s_mov_b32 s5, s1
; SI-NEXT: s_waitcnt vmcnt(0)
; SI-NEXT: v_lshr_b32_e32 v3, v3, v7
; SI-NEXT: v_lshrrev_b32_e32 v2, v6, v2
; SI-NEXT: v_lshrrev_b32_e32 v1, v5, v1
; SI-NEXT: v_lshrrev_b32_e32 v0, v4, v0
; SI-NEXT: buffer_store_dwordx4 v[0:3], off, s[4:7], 0
; SI-NEXT: s_endpgm
;
; VI-LABEL: lshr_v4i32:
; VI: ; %bb.0:
; VI-NEXT: s_load_dwordx4 s[8:11], s[0:1], 0x24
; VI-NEXT: s_waitcnt lgkmcnt(0)
; VI-NEXT: s_load_dwordx8 s[0:7], s[10:11], 0x0
; VI-NEXT: s_mov_b32 s11, 0xf000
; VI-NEXT: s_mov_b32 s10, -1
; VI-NEXT: s_waitcnt lgkmcnt(0)
; VI-NEXT: s_lshr_b32 s3, s3, s7
; VI-NEXT: s_lshr_b32 s2, s2, s6
; VI-NEXT: s_lshr_b32 s1, s1, s5
; VI-NEXT: s_lshr_b32 s0, s0, s4
; VI-NEXT: v_mov_b32_e32 v0, s0
; VI-NEXT: v_mov_b32_e32 v1, s1
; VI-NEXT: v_mov_b32_e32 v2, s2
; VI-NEXT: v_mov_b32_e32 v3, s3
; VI-NEXT: buffer_store_dwordx4 v[0:3], off, s[8:11], 0
; VI-NEXT: s_endpgm
;
; EG-LABEL: lshr_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: LSHR * T0.W, T0.W, T1.W,
; EG-NEXT: LSHR * T0.Z, T0.Z, T1.Z,
; EG-NEXT: LSHR * T0.Y, T0.Y, T1.Y,
; EG-NEXT: LSHR 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 = lshr <4 x i32> %a, %b
store <4 x i32> %result, ptr addrspace(1) %out
ret void
}
define amdgpu_kernel void @lshr_i64(ptr addrspace(1) %out, ptr addrspace(1) %in) {
; SI-LABEL: lshr_i64:
; SI: ; %bb.0:
; SI-NEXT: s_load_dwordx4 s[0:3], s[0:1], 0x9
; SI-NEXT: s_mov_b32 s7, 0xf000
; SI-NEXT: s_mov_b32 s6, -1
; SI-NEXT: s_mov_b32 s10, s6
; SI-NEXT: s_mov_b32 s11, s7
; SI-NEXT: s_waitcnt lgkmcnt(0)
; SI-NEXT: s_mov_b32 s8, s2
; SI-NEXT: s_mov_b32 s9, s3
; SI-NEXT: buffer_load_dwordx4 v[0:3], off, s[8:11], 0
; SI-NEXT: s_mov_b32 s4, s0
; SI-NEXT: s_mov_b32 s5, s1
; SI-NEXT: s_waitcnt vmcnt(0)
; SI-NEXT: v_lshr_b64 v[0:1], v[0:1], v2
; SI-NEXT: buffer_store_dwordx2 v[0:1], off, s[4:7], 0
; SI-NEXT: s_endpgm
;
; VI-LABEL: lshr_i64:
; VI: ; %bb.0:
; VI-NEXT: s_load_dwordx4 s[0:3], s[0:1], 0x24
; VI-NEXT: s_waitcnt lgkmcnt(0)
; VI-NEXT: s_load_dwordx4 s[4:7], s[2:3], 0x0
; VI-NEXT: s_mov_b32 s3, 0xf000
; VI-NEXT: s_mov_b32 s2, -1
; VI-NEXT: s_waitcnt lgkmcnt(0)
; VI-NEXT: s_lshr_b64 s[4:5], s[4:5], s6
; VI-NEXT: v_mov_b32_e32 v0, s4
; VI-NEXT: v_mov_b32_e32 v1, s5
; VI-NEXT: buffer_store_dwordx2 v[0:1], off, s[0:3], 0
; VI-NEXT: s_endpgm
;
; EG-LABEL: lshr_i64:
; EG: ; %bb.0:
; EG-NEXT: ALU 0, @8, KC0[CB0:0-32], KC1[]
; EG-NEXT: TEX 0 @6
; EG-NEXT: ALU 9, @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: AND_INT * T0.W, T0.Z, literal.x,
; EG-NEXT: 31(4.344025e-44), 0(0.000000e+00)
; EG-NEXT: LSHR T1.Z, T0.Y, PV.W,
; EG-NEXT: BIT_ALIGN_INT T0.W, T0.Y, T0.X, T0.Z,
; EG-NEXT: AND_INT * T1.W, T0.Z, literal.x,
; EG-NEXT: 32(4.484155e-44), 0(0.000000e+00)
; EG-NEXT: CNDE_INT T0.X, PS, PV.W, PV.Z,
; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.x,
; EG-NEXT: 2(2.802597e-45), 0(0.000000e+00)
; EG-NEXT: CNDE_INT * T0.Y, T1.W, T1.Z, 0.0,
%b_ptr = getelementptr i64, ptr addrspace(1) %in, i64 1
%a = load i64, ptr addrspace(1) %in
%b = load i64, ptr addrspace(1) %b_ptr
%result = lshr i64 %a, %b
store i64 %result, ptr addrspace(1) %out
ret void
}
define amdgpu_kernel void @lshr_v4i64(ptr addrspace(1) %out, ptr addrspace(1) %in) {
; SI-LABEL: lshr_v4i64:
; SI: ; %bb.0:
; SI-NEXT: s_load_dwordx4 s[4:7], s[0:1], 0x9
; SI-NEXT: s_mov_b32 s3, 0xf000
; SI-NEXT: s_mov_b32 s2, -1
; SI-NEXT: s_mov_b32 s10, s2
; SI-NEXT: s_mov_b32 s11, s3
; SI-NEXT: s_waitcnt lgkmcnt(0)
; SI-NEXT: s_mov_b32 s8, s6
; SI-NEXT: s_mov_b32 s9, s7
; SI-NEXT: buffer_load_dwordx4 v[0:3], off, s[8:11], 0
; SI-NEXT: buffer_load_dwordx4 v[4:7], off, s[8:11], 0 offset:16
; SI-NEXT: buffer_load_dwordx4 v[8:11], off, s[8:11], 0 offset:32
; SI-NEXT: buffer_load_dwordx4 v[11:14], off, s[8:11], 0 offset:48
; SI-NEXT: s_mov_b32 s0, s4
; SI-NEXT: s_mov_b32 s1, s5
; SI-NEXT: s_waitcnt vmcnt(1)
; SI-NEXT: v_lshr_b64 v[2:3], v[2:3], v10
; SI-NEXT: s_waitcnt vmcnt(0)
; SI-NEXT: v_lshr_b64 v[6:7], v[6:7], v13
; SI-NEXT: v_lshr_b64 v[4:5], v[4:5], v11
; SI-NEXT: v_lshr_b64 v[0:1], v[0:1], v8
; SI-NEXT: buffer_store_dwordx4 v[4:7], off, s[0:3], 0 offset:16
; SI-NEXT: buffer_store_dwordx4 v[0:3], off, s[0:3], 0
; SI-NEXT: s_endpgm
;
; VI-LABEL: lshr_v4i64:
; VI: ; %bb.0:
; VI-NEXT: s_load_dwordx4 s[16:19], s[0:1], 0x24
; VI-NEXT: s_waitcnt lgkmcnt(0)
; VI-NEXT: s_load_dwordx16 s[0:15], s[18:19], 0x0
; VI-NEXT: s_mov_b32 s19, 0xf000
; VI-NEXT: s_mov_b32 s18, -1
; VI-NEXT: s_waitcnt lgkmcnt(0)
; VI-NEXT: s_lshr_b64 s[6:7], s[6:7], s14
; VI-NEXT: s_lshr_b64 s[4:5], s[4:5], s12
; VI-NEXT: s_lshr_b64 s[2:3], s[2:3], s10
; VI-NEXT: s_lshr_b64 s[0:1], s[0:1], s8
; VI-NEXT: v_mov_b32_e32 v0, s4
; VI-NEXT: v_mov_b32_e32 v1, s5
; VI-NEXT: v_mov_b32_e32 v2, s6
; VI-NEXT: v_mov_b32_e32 v3, s7
; VI-NEXT: buffer_store_dwordx4 v[0:3], off, s[16:19], 0 offset:16
; VI-NEXT: s_nop 0
; VI-NEXT: v_mov_b32_e32 v0, s0
; VI-NEXT: v_mov_b32_e32 v1, s1
; VI-NEXT: v_mov_b32_e32 v2, s2
; VI-NEXT: v_mov_b32_e32 v3, s3
; VI-NEXT: buffer_store_dwordx4 v[0:3], off, s[16:19], 0
; VI-NEXT: s_endpgm
;
; EG-LABEL: lshr_v4i64:
; EG: ; %bb.0:
; EG-NEXT: ALU 0, @14, KC0[CB0:0-32], KC1[]
; EG-NEXT: TEX 3 @6
; EG-NEXT: ALU 34, @15, KC0[CB0:0-32], KC1[]
; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T1.XYZW, T3.X, 0
; EG-NEXT: MEM_RAT_CACHELESS STORE_RAW T2.XYZW, T0.X, 1
; EG-NEXT: CF_END
; EG-NEXT: Fetch clause starting at 6:
; EG-NEXT: VTX_READ_128 T1.XYZW, T0.X, 32, #1
; EG-NEXT: VTX_READ_128 T2.XYZW, T0.X, 16, #1
; EG-NEXT: VTX_READ_128 T3.XYZW, T0.X, 48, #1
; EG-NEXT: VTX_READ_128 T0.XYZW, T0.X, 0, #1
; EG-NEXT: ALU clause starting at 14:
; EG-NEXT: MOV * T0.X, KC0[2].Z,
; EG-NEXT: ALU clause starting at 15:
; EG-NEXT: AND_INT * T1.W, T1.Z, literal.x,
; EG-NEXT: 31(4.344025e-44), 0(0.000000e+00)
; EG-NEXT: LSHR T4.Z, T0.W, PV.W,
; EG-NEXT: AND_INT T1.W, T1.Z, literal.x,
; EG-NEXT: AND_INT * T3.W, T3.Z, literal.y,
; EG-NEXT: 32(4.484155e-44), 31(4.344025e-44)
; EG-NEXT: BIT_ALIGN_INT T4.X, T0.W, T0.Z, T1.Z,
; EG-NEXT: LSHR T1.Y, T2.W, PS, BS:VEC_120/SCL_212
; EG-NEXT: AND_INT * T0.Z, T3.Z, literal.x,
; EG-NEXT: 32(4.484155e-44), 0(0.000000e+00)
; EG-NEXT: BIT_ALIGN_INT T0.W, T2.W, T2.Z, T3.Z,
; EG-NEXT: AND_INT * T2.W, T3.X, literal.x,
; EG-NEXT: 31(4.344025e-44), 0(0.000000e+00)
; EG-NEXT: AND_INT T5.X, T1.X, literal.x,
; EG-NEXT: LSHR T3.Y, T2.Y, PS,
; EG-NEXT: CNDE_INT T2.Z, T0.Z, PV.W, T1.Y,
; EG-NEXT: BIT_ALIGN_INT T0.W, T2.Y, T2.X, T3.X,
; EG-NEXT: AND_INT * T3.W, T3.X, literal.y,
; EG-NEXT: 31(4.344025e-44), 32(4.484155e-44)
; EG-NEXT: CNDE_INT T2.X, PS, PV.W, PV.Y,
; EG-NEXT: LSHR T4.Y, T0.Y, PV.X,
; EG-NEXT: CNDE_INT T1.Z, T1.W, T4.X, T4.Z,
; EG-NEXT: BIT_ALIGN_INT T0.W, T0.Y, T0.X, T1.X, BS:VEC_102/SCL_221
; EG-NEXT: AND_INT * T4.W, T1.X, literal.x,
; EG-NEXT: 32(4.484155e-44), 0(0.000000e+00)
; EG-NEXT: CNDE_INT T1.X, PS, PV.W, PV.Y,
; EG-NEXT: ADD_INT T0.W, KC0[2].Y, literal.x,
; EG-NEXT: CNDE_INT * T2.W, T0.Z, T1.Y, 0.0,
; EG-NEXT: 16(2.242078e-44), 0(0.000000e+00)
; EG-NEXT: LSHR T0.X, PV.W, literal.x,
; EG-NEXT: CNDE_INT T2.Y, T3.W, T3.Y, 0.0,
; EG-NEXT: CNDE_INT T1.W, T1.W, T4.Z, 0.0, BS:VEC_120/SCL_212
; EG-NEXT: LSHR * T3.X, KC0[2].Y, literal.x,
; EG-NEXT: 2(2.802597e-45), 0(0.000000e+00)
; EG-NEXT: CNDE_INT * T1.Y, T4.W, T4.Y, 0.0,
%b_ptr = getelementptr <4 x i64>, ptr addrspace(1) %in, i64 1
%a = load <4 x i64>, ptr addrspace(1) %in
%b = load <4 x i64>, ptr addrspace(1) %b_ptr
%result = lshr <4 x i64> %a, %b
store <4 x i64> %result, ptr addrspace(1) %out
ret void
}
; Make sure load width gets reduced to i32 load.
define amdgpu_kernel void @s_lshr_32_i64(ptr addrspace(1) %out, [8 x i32], i64 %a) {
; SI-LABEL: s_lshr_32_i64:
; SI: ; %bb.0:
; SI-NEXT: s_load_dword s4, s[0:1], 0x14
; SI-NEXT: s_load_dwordx2 s[0:1], s[0:1], 0x9
; SI-NEXT: s_mov_b32 s3, 0xf000
; SI-NEXT: s_mov_b32 s2, -1
; SI-NEXT: v_mov_b32_e32 v1, 0
; SI-NEXT: s_waitcnt lgkmcnt(0)
; SI-NEXT: v_mov_b32_e32 v0, s4
; SI-NEXT: buffer_store_dwordx2 v[0:1], off, s[0:3], 0
; SI-NEXT: s_endpgm
;
; VI-LABEL: s_lshr_32_i64:
; VI: ; %bb.0:
; VI-NEXT: s_load_dword s4, s[0:1], 0x50
; VI-NEXT: s_load_dwordx2 s[0:1], s[0:1], 0x24
; VI-NEXT: s_mov_b32 s3, 0xf000
; VI-NEXT: s_mov_b32 s2, -1
; VI-NEXT: v_mov_b32_e32 v1, 0
; VI-NEXT: s_waitcnt lgkmcnt(0)
; VI-NEXT: v_mov_b32_e32 v0, s4
; VI-NEXT: buffer_store_dwordx2 v[0:1], off, s[0:3], 0
; VI-NEXT: s_endpgm
;
; EG-LABEL: s_lshr_32_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.X, KC0[5].X,
; EG-NEXT: MOV T0.Y, 0.0,
; EG-NEXT: LSHR * T1.X, KC0[2].Y, literal.x,
; EG-NEXT: 2(2.802597e-45), 0(0.000000e+00)
%result = lshr i64 %a, 32
store i64 %result, ptr addrspace(1) %out
ret void
}
define amdgpu_kernel void @v_lshr_32_i64(ptr addrspace(1) %out, ptr addrspace(1) %in) {
; SI-LABEL: v_lshr_32_i64:
; SI: ; %bb.0:
; SI-NEXT: s_load_dwordx4 s[0:3], s[0:1], 0x9
; SI-NEXT: s_mov_b32 s6, 0
; SI-NEXT: s_mov_b32 s7, 0xf000
; SI-NEXT: v_lshlrev_b32_e32 v0, 3, v0
; SI-NEXT: v_mov_b32_e32 v1, 0
; SI-NEXT: s_waitcnt lgkmcnt(0)
; SI-NEXT: s_mov_b64 s[8:9], s[2:3]
; SI-NEXT: s_mov_b64 s[10:11], s[6:7]
; SI-NEXT: buffer_load_dword v2, v[0:1], s[8:11], 0 addr64 offset:4
; SI-NEXT: s_mov_b64 s[4:5], s[0:1]
; SI-NEXT: v_mov_b32_e32 v3, v1
; SI-NEXT: s_waitcnt vmcnt(0)
; SI-NEXT: buffer_store_dwordx2 v[2:3], v[0:1], s[4:7], 0 addr64
; SI-NEXT: s_endpgm
;
; VI-LABEL: v_lshr_32_i64:
; VI: ; %bb.0:
; VI-NEXT: s_load_dwordx4 s[0:3], s[0:1], 0x24
; VI-NEXT: v_lshlrev_b32_e32 v2, 3, v0
; VI-NEXT: s_waitcnt lgkmcnt(0)
; VI-NEXT: v_mov_b32_e32 v0, s3
; VI-NEXT: v_add_u32_e32 v1, vcc, s2, v2
; VI-NEXT: v_addc_u32_e32 v3, vcc, 0, v0, vcc
; VI-NEXT: v_add_u32_e32 v0, vcc, 4, v1
; VI-NEXT: v_addc_u32_e32 v1, vcc, 0, v3, vcc
; VI-NEXT: flat_load_dword v0, v[0:1]
; VI-NEXT: v_mov_b32_e32 v3, s1
; VI-NEXT: v_add_u32_e32 v2, vcc, s0, v2
; VI-NEXT: v_mov_b32_e32 v1, 0
; VI-NEXT: v_addc_u32_e32 v3, vcc, 0, v3, vcc
; VI-NEXT: s_waitcnt vmcnt(0)
; VI-NEXT: flat_store_dwordx2 v[2:3], v[0:1]
; VI-NEXT: s_endpgm
;
; EG-LABEL: v_lshr_32_i64:
; EG: ; %bb.0:
; EG-NEXT: ALU 2, @8, KC0[CB0:0-32], KC1[]
; EG-NEXT: TEX 0 @6
; EG-NEXT: ALU 3, @11, 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, 4, #1
; EG-NEXT: ALU clause starting at 8:
; EG-NEXT: LSHL * T0.W, T0.X, literal.x,
; EG-NEXT: 3(4.203895e-45), 0(0.000000e+00)
; EG-NEXT: ADD_INT * T0.X, KC0[2].Z, PV.W,
; EG-NEXT: ALU clause starting at 11:
; EG-NEXT: MOV T0.Y, 0.0,
; EG-NEXT: ADD_INT * T0.W, KC0[2].Y, T0.W,
; EG-NEXT: LSHR * T1.X, PV.W, literal.x,
; EG-NEXT: 2(2.802597e-45), 0(0.000000e+00)
%tid = call i32 @llvm.amdgcn.workitem.id.x() #0
%gep.in = getelementptr i64, ptr addrspace(1) %in, i32 %tid
%gep.out = getelementptr i64, ptr addrspace(1) %out, i32 %tid
%a = load i64, ptr addrspace(1) %gep.in
%result = lshr i64 %a, 32
store i64 %result, ptr addrspace(1) %gep.out
ret void
}
attributes #0 = { nounwind readnone }
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