1
0
mirror of https://github.com/RPCS3/llvm-mirror.git synced 2024-11-24 03:33:20 +01:00
llvm-mirror/test/CodeGen/R600/store.ll
Tom Stellard 2b6ff7e802 R600: Fix handling of vector kernel arguments
The SelectionDAGBuilder was promoting vector kernel arguments to legal
types, but this won't work for R600 and SI since kernel arguments are
stored in memory and can't be promoted.  In order to handle vector
arguments correctly we need to look at the original types from the LLVM IR
function.

llvm-svn: 193215
2013-10-23 00:44:32 +00:00

283 lines
9.2 KiB
LLVM

; RUN: llc < %s -march=r600 -mcpu=redwood | FileCheck --check-prefix=EG-CHECK %s
; RUN: llc < %s -march=r600 -mcpu=cayman | FileCheck --check-prefix=CM-CHECK %s
; RUN: llc < %s -march=r600 -mcpu=verde -verify-machineinstrs | FileCheck --check-prefix=SI-CHECK %s
;===------------------------------------------------------------------------===;
; Global Address Space
;===------------------------------------------------------------------------===;
; i8 store
; EG-CHECK-LABEL: @store_i8
; EG-CHECK: MEM_RAT MSKOR T[[RW_GPR:[0-9]]].XW, T{{[0-9]}}.X
; EG-CHECK: VTX_READ_8 [[VAL:T[0-9]\.X]], [[VAL]]
; IG 0: Get the byte index and truncate the value
; EG-CHECK: AND_INT T{{[0-9]}}.[[BI_CHAN:[XYZW]]], KC0[2].Y, literal.x
; EG-CHECK-NEXT: AND_INT * T{{[0-9]}}.[[TRUNC_CHAN:[XYZW]]], [[VAL]], literal.y
; EG-CHECK-NEXT: 3(4.203895e-45), 255(3.573311e-43)
; IG 1: Truncate the calculated the shift amount for the mask
; EG-CHECK: LSHL * T{{[0-9]}}.[[SHIFT_CHAN:[XYZW]]], PV.[[BI_CHAN]], literal.x
; EG-CHECK-NEXT: 3
; IG 2: Shift the value and the mask
; EG-CHECK: LSHL T[[RW_GPR]].X, T{{[0-9]}}.[[TRUNC_CHAN]], PV.[[SHIFT_CHAN]]
; EG-CHECK: LSHL * T[[RW_GPR]].W, literal.x, PV.[[SHIFT_CHAN]]
; EG-CHECK-NEXT: 255
; IG 3: Initialize the Y and Z channels to zero
; XXX: An optimal scheduler should merge this into one of the prevous IGs.
; EG-CHECK: MOV T[[RW_GPR]].Y, 0.0
; EG-CHECK: MOV * T[[RW_GPR]].Z, 0.0
; SI-CHECK-LABEL: @store_i8
; SI-CHECK: BUFFER_STORE_BYTE
define void @store_i8(i8 addrspace(1)* %out, i8 %in) {
entry:
store i8 %in, i8 addrspace(1)* %out
ret void
}
; i16 store
; EG-CHECK-LABEL: @store_i16
; EG-CHECK: MEM_RAT MSKOR T[[RW_GPR:[0-9]]].XW, T{{[0-9]}}.X
; EG-CHECK: VTX_READ_16 [[VAL:T[0-9]\.X]], [[VAL]]
; IG 0: Get the byte index and truncate the value
; EG-CHECK: AND_INT T{{[0-9]}}.[[BI_CHAN:[XYZW]]], KC0[2].Y, literal.x
; EG-CHECK: AND_INT * T{{[0-9]}}.[[TRUNC_CHAN:[XYZW]]], [[VAL]], literal.y
; EG-CHECK-NEXT: 3(4.203895e-45), 65535(9.183409e-41)
; IG 1: Truncate the calculated the shift amount for the mask
; EG-CHECK: LSHL * T{{[0-9]}}.[[SHIFT_CHAN:[XYZW]]], PV.[[BI_CHAN]], literal.x
; EG-CHECK: 3
; IG 2: Shift the value and the mask
; EG-CHECK: LSHL T[[RW_GPR]].X, T{{[0-9]}}.[[TRUNC_CHAN]], PV.[[SHIFT_CHAN]]
; EG-CHECK: LSHL * T[[RW_GPR]].W, literal.x, PV.[[SHIFT_CHAN]]
; EG-CHECK-NEXT: 65535
; IG 3: Initialize the Y and Z channels to zero
; XXX: An optimal scheduler should merge this into one of the prevous IGs.
; EG-CHECK: MOV T[[RW_GPR]].Y, 0.0
; EG-CHECK: MOV * T[[RW_GPR]].Z, 0.0
; SI-CHECK-LABEL: @store_i16
; SI-CHECK: BUFFER_STORE_SHORT
define void @store_i16(i16 addrspace(1)* %out, i16 %in) {
entry:
store i16 %in, i16 addrspace(1)* %out
ret void
}
; EG-CHECK-LABEL: @store_v2i8
; EG-CHECK: MEM_RAT MSKOR
; EG-CHECK-NOT: MEM_RAT MSKOR
; SI-CHECK-LABEL: @store_v2i8
; SI-CHECK: BUFFER_STORE_BYTE
; SI-CHECK: BUFFER_STORE_BYTE
define void @store_v2i8(<2 x i8> addrspace(1)* %out, <2 x i32> %in) {
entry:
%0 = trunc <2 x i32> %in to <2 x i8>
store <2 x i8> %0, <2 x i8> addrspace(1)* %out
ret void
}
; EG-CHECK-LABEL: @store_v2i16
; EG-CHECK: MEM_RAT_CACHELESS STORE_RAW
; CM-CHECK-LABEL: @store_v2i16
; CM-CHECK: MEM_RAT_CACHELESS STORE_DWORD
; SI-CHECK-LABEL: @store_v2i16
; SI-CHECK: BUFFER_STORE_SHORT
; SI-CHECK: BUFFER_STORE_SHORT
define void @store_v2i16(<2 x i16> addrspace(1)* %out, <2 x i32> %in) {
entry:
%0 = trunc <2 x i32> %in to <2 x i16>
store <2 x i16> %0, <2 x i16> addrspace(1)* %out
ret void
}
; EG-CHECK-LABEL: @store_v4i8
; EG-CHECK: MEM_RAT_CACHELESS STORE_RAW
; CM-CHECK-LABEL: @store_v4i8
; CM-CHECK: MEM_RAT_CACHELESS STORE_DWORD
; SI-CHECK-LABEL: @store_v4i8
; SI-CHECK: BUFFER_STORE_BYTE
; SI-CHECK: BUFFER_STORE_BYTE
; SI-CHECK: BUFFER_STORE_BYTE
; SI-CHECK: BUFFER_STORE_BYTE
define void @store_v4i8(<4 x i8> addrspace(1)* %out, <4 x i32> %in) {
entry:
%0 = trunc <4 x i32> %in to <4 x i8>
store <4 x i8> %0, <4 x i8> addrspace(1)* %out
ret void
}
; floating-point store
; EG-CHECK-LABEL: @store_f32
; EG-CHECK: MEM_RAT_CACHELESS STORE_RAW T{{[0-9]+\.X, T[0-9]+\.X}}, 1
; CM-CHECK-LABEL: @store_f32
; CM-CHECK: MEM_RAT_CACHELESS STORE_DWORD T{{[0-9]+\.X, T[0-9]+\.X}}
; SI-CHECK-LABEL: @store_f32
; SI-CHECK: BUFFER_STORE_DWORD
define void @store_f32(float addrspace(1)* %out, float %in) {
store float %in, float addrspace(1)* %out
ret void
}
; EG-CHECK-LABEL: @store_v4i16
; EG-CHECK: MEM_RAT MSKOR
; EG-CHECK: MEM_RAT MSKOR
; EG-CHECK: MEM_RAT MSKOR
; EG-CHECK: MEM_RAT MSKOR
; EG-CHECK-NOT: MEM_RAT MSKOR
; SI-CHECK-LABEL: @store_v4i16
; SI-CHECK: BUFFER_STORE_SHORT
; SI-CHECK: BUFFER_STORE_SHORT
; SI-CHECK: BUFFER_STORE_SHORT
; SI-CHECK: BUFFER_STORE_SHORT
; SI-CHECK-NOT: BUFFER_STORE_BYTE
define void @store_v4i16(<4 x i16> addrspace(1)* %out, <4 x i32> %in) {
entry:
%0 = trunc <4 x i32> %in to <4 x i16>
store <4 x i16> %0, <4 x i16> addrspace(1)* %out
ret void
}
; vec2 floating-point stores
; EG-CHECK-LABEL: @store_v2f32
; EG-CHECK: MEM_RAT_CACHELESS STORE_RAW
; CM-CHECK-LABEL: @store_v2f32
; CM-CHECK: MEM_RAT_CACHELESS STORE_DWORD
; SI-CHECK-LABEL: @store_v2f32
; SI-CHECK: BUFFER_STORE_DWORDX2
define void @store_v2f32(<2 x float> addrspace(1)* %out, float %a, float %b) {
entry:
%0 = insertelement <2 x float> <float 0.0, float 0.0>, float %a, i32 0
%1 = insertelement <2 x float> %0, float %b, i32 1
store <2 x float> %1, <2 x float> addrspace(1)* %out
ret void
}
; EG-CHECK-LABEL: @store_v4i32
; EG-CHECK: MEM_RAT_CACHELESS STORE_RAW
; EG-CHECK-NOT: MEM_RAT_CACHELESS STORE_RAW
; CM-CHECK-LABEL: @store_v4i32
; CM-CHECK: MEM_RAT_CACHELESS STORE_DWORD
; CM-CHECK-NOT: MEM_RAT_CACHELESS STORE_DWORD
; SI-CHECK-LABEL: @store_v4i32
; SI-CHECK: BUFFER_STORE_DWORDX4
define void @store_v4i32(<4 x i32> addrspace(1)* %out, <4 x i32> %in) {
entry:
store <4 x i32> %in, <4 x i32> addrspace(1)* %out
ret void
}
;===------------------------------------------------------------------------===;
; Local Address Space
;===------------------------------------------------------------------------===;
; EG-CHECK-LABEL: @store_local_i8
; EG-CHECK: LDS_BYTE_WRITE
; SI-CHECK-LABEL: @store_local_i8
; SI-CHECK: DS_WRITE_B8
define void @store_local_i8(i8 addrspace(3)* %out, i8 %in) {
store i8 %in, i8 addrspace(3)* %out
ret void
}
; EG-CHECK-LABEL: @store_local_i16
; EG-CHECK: LDS_SHORT_WRITE
; SI-CHECK-LABEL: @store_local_i16
; SI-CHECK: DS_WRITE_B16
define void @store_local_i16(i16 addrspace(3)* %out, i16 %in) {
store i16 %in, i16 addrspace(3)* %out
ret void
}
; EG-CHECK-LABEL: @store_local_v2i16
; EG-CHECK: LDS_WRITE
; CM-CHECK-LABEL: @store_local_v2i16
; CM-CHECK: LDS_WRITE
; SI-CHECK-LABEL: @store_local_v2i16
; SI-CHECK: DS_WRITE_B16
; SI-CHECK: DS_WRITE_B16
define void @store_local_v2i16(<2 x i16> addrspace(3)* %out, <2 x i16> %in) {
entry:
store <2 x i16> %in, <2 x i16> addrspace(3)* %out
ret void
}
; EG-CHECK-LABEL: @store_local_v4i8
; EG-CHECK: LDS_WRITE
; CM-CHECK-LABEL: @store_local_v4i8
; CM-CHECK: LDS_WRITE
; SI-CHECK-LABEL: @store_local_v4i8
; SI-CHECK: DS_WRITE_B8
; SI-CHECK: DS_WRITE_B8
; SI-CHECK: DS_WRITE_B8
; SI-CHECK: DS_WRITE_B8
define void @store_local_v4i8(<4 x i8> addrspace(3)* %out, <4 x i8> %in) {
entry:
store <4 x i8> %in, <4 x i8> addrspace(3)* %out
ret void
}
; EG-CHECK-LABEL: @store_local_v2i32
; EG-CHECK: LDS_WRITE
; EG-CHECK: LDS_WRITE
; CM-CHECK-LABEL: @store_local_v2i32
; CM-CHECK: LDS_WRITE
; CM-CHECK: LDS_WRITE
; SI-CHECK-LABEL: @store_local_v2i32
; SI-CHECK: DS_WRITE_B32
; SI-CHECK: DS_WRITE_B32
define void @store_local_v2i32(<2 x i32> addrspace(3)* %out, <2 x i32> %in) {
entry:
store <2 x i32> %in, <2 x i32> addrspace(3)* %out
ret void
}
; EG-CHECK-LABEL: @store_local_v4i32
; EG-CHECK: LDS_WRITE
; EG-CHECK: LDS_WRITE
; EG-CHECK: LDS_WRITE
; EG-CHECK: LDS_WRITE
; CM-CHECK-LABEL: @store_local_v4i32
; CM-CHECK: LDS_WRITE
; CM-CHECK: LDS_WRITE
; CM-CHECK: LDS_WRITE
; CM-CHECK: LDS_WRITE
; SI-CHECK-LABEL: @store_local_v4i32
; SI-CHECK: DS_WRITE_B32
; SI-CHECK: DS_WRITE_B32
; SI-CHECK: DS_WRITE_B32
; SI-CHECK: DS_WRITE_B32
define void @store_local_v4i32(<4 x i32> addrspace(3)* %out, <4 x i32> %in) {
entry:
store <4 x i32> %in, <4 x i32> addrspace(3)* %out
ret void
}
; The stores in this function are combined by the optimizer to create a
; 64-bit store with 32-bit alignment. This is legal for SI and the legalizer
; should not try to split the 64-bit store back into 2 32-bit stores.
;
; Evergreen / Northern Islands don't support 64-bit stores yet, so there should
; be two 32-bit stores.
; EG-CHECK-LABEL: @vecload2
; EG-CHECK: MEM_RAT_CACHELESS STORE_RAW
; CM-CHECK-LABEL: @vecload2
; CM-CHECK: MEM_RAT_CACHELESS STORE_DWORD
; SI-CHECK-LABEL: @vecload2
; SI-CHECK: BUFFER_STORE_DWORDX2
define void @vecload2(i32 addrspace(1)* nocapture %out, i32 addrspace(2)* nocapture %mem) #0 {
entry:
%0 = load i32 addrspace(2)* %mem, align 4
%arrayidx1.i = getelementptr inbounds i32 addrspace(2)* %mem, i64 1
%1 = load i32 addrspace(2)* %arrayidx1.i, align 4
store i32 %0, i32 addrspace(1)* %out, align 4
%arrayidx1 = getelementptr inbounds i32 addrspace(1)* %out, i64 1
store i32 %1, i32 addrspace(1)* %arrayidx1, align 4
ret void
}
attributes #0 = { nounwind "less-precise-fpmad"="false" "no-frame-pointer-elim"="false" "no-infs-fp-math"="false" "no-nans-fp-math"="false" "unsafe-fp-math"="false" "use-soft-float"="false" }