llvm-project/llvm/test/CodeGen/AMDGPU/llvm.amdgcn.image.sample.di...

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; RUN: llc -march=amdgcn -mcpu=verde -verify-machineinstrs < %s | FileCheck -check-prefixes=GCN,GFX6789 %s
; RUN: llc -march=amdgcn -mcpu=gfx900 -verify-machineinstrs < %s | FileCheck -check-prefixes=GCN,GFX6789 %s
; RUN: llc -march=amdgcn -mcpu=gfx1010 -verify-machineinstrs -show-mc-encoding < %s | FileCheck -check-prefixes=GCN,GFX10 %s
; GCN-LABEL: {{^}}sample_1d:
; GFX6789: image_sample v[0:3], v0, s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample v[0:3], v0, s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.1d.v4f32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
; GCN-LABEL: {{^}}sample_1d_tfe:
; GCN: v_mov_b32_e32 v0, 0
; GCN: v_mov_b32_e32 v1, v0
; GCN: v_mov_b32_e32 v2, v0
; GCN: v_mov_b32_e32 v3, v0
; GCN: v_mov_b32_e32 v4, v0
; GFX6789: image_sample v[0:4], v5, s[0:7], s[8:11] dmask:0xf tfe{{$}}
; GFX10: image_sample v[0:4], v5, s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D tfe ;
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
define amdgpu_ps <4 x float> @sample_1d_tfe(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, i32 addrspace(1)* inreg %out, float %s) {
main_body:
%v = call {<4 x float>,i32} @llvm.amdgcn.image.sample.1d.v4f32i32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 1, i32 0)
%v.vec = extractvalue {<4 x float>, i32} %v, 0
%v.err = extractvalue {<4 x float>, i32} %v, 1
store i32 %v.err, i32 addrspace(1)* %out, align 4
ret <4 x float> %v.vec
}
; GCN-LABEL: {{^}}sample_1d_tfe_adjust_writemask_1:
; GCN: v_mov_b32_e32 v0, 0
; GCN: v_mov_b32_e32 v1, v0
; GFX6789: image_sample v[0:1], v2, s[0:7], s[8:11] dmask:0x1 tfe{{$}}
; GFX10: image_sample v[0:1], v2, s[0:7], s[8:11] dmask:0x1 dim:SQ_RSRC_IMG_1D tfe ;
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
define amdgpu_ps <2 x float> @sample_1d_tfe_adjust_writemask_1(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, i32 addrspace(1)* inreg %out, float %s) {
main_body:
%v = call {<4 x float>,i32} @llvm.amdgcn.image.sample.1d.v4f32i32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 1, i32 0)
%res.vec = extractvalue {<4 x float>,i32} %v, 0
%res.f = extractelement <4 x float> %res.vec, i32 0
%res.err = extractvalue {<4 x float>,i32} %v, 1
%res.errf = bitcast i32 %res.err to float
%res.tmp = insertelement <2 x float> undef, float %res.f, i32 0
%res = insertelement <2 x float> %res.tmp, float %res.errf, i32 1
ret <2 x float> %res
}
; GCN-LABEL: {{^}}sample_1d_tfe_adjust_writemask_2:
; GCN: v_mov_b32_e32 v0, 0
; GCN: v_mov_b32_e32 v1, v0
; GFX6789: image_sample v[0:1], v2, s[0:7], s[8:11] dmask:0x2 tfe{{$}}
; GFX10: image_sample v[0:1], v2, s[0:7], s[8:11] dmask:0x2 dim:SQ_RSRC_IMG_1D tfe ;
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
define amdgpu_ps <2 x float> @sample_1d_tfe_adjust_writemask_2(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%v = call {<4 x float>,i32} @llvm.amdgcn.image.sample.1d.v4f32i32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 1, i32 0)
%res.vec = extractvalue {<4 x float>,i32} %v, 0
%res.f = extractelement <4 x float> %res.vec, i32 1
%res.err = extractvalue {<4 x float>,i32} %v, 1
%res.errf = bitcast i32 %res.err to float
%res.tmp = insertelement <2 x float> undef, float %res.f, i32 0
%res = insertelement <2 x float> %res.tmp, float %res.errf, i32 1
ret <2 x float> %res
}
; GCN-LABEL: {{^}}sample_1d_tfe_adjust_writemask_3:
; GCN: v_mov_b32_e32 v0, 0
; GCN: v_mov_b32_e32 v1, v0
; GFX6789: image_sample v[0:1], v2, s[0:7], s[8:11] dmask:0x4 tfe{{$}}
; GFX10: image_sample v[0:1], v2, s[0:7], s[8:11] dmask:0x4 dim:SQ_RSRC_IMG_1D tfe ;
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
define amdgpu_ps <2 x float> @sample_1d_tfe_adjust_writemask_3(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%v = call {<4 x float>,i32} @llvm.amdgcn.image.sample.1d.v4f32i32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 1, i32 0)
%res.vec = extractvalue {<4 x float>,i32} %v, 0
%res.f = extractelement <4 x float> %res.vec, i32 2
%res.err = extractvalue {<4 x float>,i32} %v, 1
%res.errf = bitcast i32 %res.err to float
%res.tmp = insertelement <2 x float> undef, float %res.f, i32 0
%res = insertelement <2 x float> %res.tmp, float %res.errf, i32 1
ret <2 x float> %res
}
; GCN-LABEL: {{^}}sample_1d_tfe_adjust_writemask_4:
; GCN: v_mov_b32_e32 v0, 0
; GCN: v_mov_b32_e32 v1, v0
; GFX6789: image_sample v[0:1], v2, s[0:7], s[8:11] dmask:0x8 tfe{{$}}
; GFX10: image_sample v[0:1], v2, s[0:7], s[8:11] dmask:0x8 dim:SQ_RSRC_IMG_1D tfe ;
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
define amdgpu_ps <2 x float> @sample_1d_tfe_adjust_writemask_4(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%v = call {<4 x float>,i32} @llvm.amdgcn.image.sample.1d.v4f32i32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 1, i32 0)
%res.vec = extractvalue {<4 x float>,i32} %v, 0
%res.f = extractelement <4 x float> %res.vec, i32 3
%res.err = extractvalue {<4 x float>,i32} %v, 1
%res.errf = bitcast i32 %res.err to float
%res.tmp = insertelement <2 x float> undef, float %res.f, i32 0
%res = insertelement <2 x float> %res.tmp, float %res.errf, i32 1
ret <2 x float> %res
}
; GCN-LABEL: {{^}}sample_1d_tfe_adjust_writemask_12:
; GCN: v_mov_b32_e32 v0, 0
; GCN: v_mov_b32_e32 v1, v0
; GCN: v_mov_b32_e32 v2, v0
; GFX6789: image_sample v[0:2], v3, s[0:7], s[8:11] dmask:0x3 tfe{{$}}
; GFX10: image_sample v[0:2], v3, s[0:7], s[8:11] dmask:0x3 dim:SQ_RSRC_IMG_1D tfe ;
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
define amdgpu_ps <4 x float> @sample_1d_tfe_adjust_writemask_12(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%v = call {<4 x float>,i32} @llvm.amdgcn.image.sample.1d.v4f32i32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 1, i32 0)
%res.vec = extractvalue {<4 x float>,i32} %v, 0
%res.f1 = extractelement <4 x float> %res.vec, i32 0
%res.f2 = extractelement <4 x float> %res.vec, i32 1
%res.err = extractvalue {<4 x float>,i32} %v, 1
%res.errf = bitcast i32 %res.err to float
%res.tmp1 = insertelement <4 x float> undef, float %res.f1, i32 0
%res.tmp2 = insertelement <4 x float> %res.tmp1, float %res.f2, i32 1
%res = insertelement <4 x float> %res.tmp2, float %res.errf, i32 2
ret <4 x float> %res
}
; GCN-LABEL: {{^}}sample_1d_tfe_adjust_writemask_24:
; GCN: v_mov_b32_e32 v0, 0
; GCN: v_mov_b32_e32 v1, v0
; GCN: v_mov_b32_e32 v2, v0
; GFX6789: image_sample v[0:2], v3, s[0:7], s[8:11] dmask:0xa tfe{{$}}
; GFX10: image_sample v[0:2], v3, s[0:7], s[8:11] dmask:0xa dim:SQ_RSRC_IMG_1D tfe ;
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
define amdgpu_ps <4 x float> @sample_1d_tfe_adjust_writemask_24(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%v = call {<4 x float>,i32} @llvm.amdgcn.image.sample.1d.v4f32i32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 1, i32 0)
%res.vec = extractvalue {<4 x float>,i32} %v, 0
%res.f1 = extractelement <4 x float> %res.vec, i32 1
%res.f2 = extractelement <4 x float> %res.vec, i32 3
%res.err = extractvalue {<4 x float>,i32} %v, 1
%res.errf = bitcast i32 %res.err to float
%res.tmp1 = insertelement <4 x float> undef, float %res.f1, i32 0
%res.tmp2 = insertelement <4 x float> %res.tmp1, float %res.f2, i32 1
%res = insertelement <4 x float> %res.tmp2, float %res.errf, i32 2
ret <4 x float> %res
}
; GCN-LABEL: {{^}}sample_1d_tfe_adjust_writemask_134:
; GCN: v_mov_b32_e32 v0, 0
; GCN: v_mov_b32_e32 v1, v0
; GCN: v_mov_b32_e32 v2, v0
; GCN: v_mov_b32_e32 v3, v0
; GFX6789: image_sample v[0:3], v4, s[0:7], s[8:11] dmask:0xd tfe{{$}}
; GFX10: image_sample v[0:3], v4, s[0:7], s[8:11] dmask:0xd dim:SQ_RSRC_IMG_1D tfe ;
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
define amdgpu_ps <4 x float> @sample_1d_tfe_adjust_writemask_134(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%v = call {<4 x float>,i32} @llvm.amdgcn.image.sample.1d.v4f32i32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 1, i32 0)
%res.vec = extractvalue {<4 x float>,i32} %v, 0
%res.f1 = extractelement <4 x float> %res.vec, i32 0
%res.f2 = extractelement <4 x float> %res.vec, i32 2
%res.f3 = extractelement <4 x float> %res.vec, i32 3
%res.err = extractvalue {<4 x float>,i32} %v, 1
%res.errf = bitcast i32 %res.err to float
%res.tmp1 = insertelement <4 x float> undef, float %res.f1, i32 0
%res.tmp2 = insertelement <4 x float> %res.tmp1, float %res.f2, i32 1
%res.tmp3 = insertelement <4 x float> %res.tmp2, float %res.f3, i32 2
%res = insertelement <4 x float> %res.tmp3, float %res.errf, i32 3
ret <4 x float> %res
}
; GCN-LABEL: {{^}}sample_1d_lwe:
; GCN: v_mov_b32_e32 v0, 0
; GCN: v_mov_b32_e32 v1, v0
; GCN: v_mov_b32_e32 v2, v0
; GCN: v_mov_b32_e32 v3, v0
; GCN: v_mov_b32_e32 v4, v0
; GFX6789: image_sample v[0:4], v5, s[0:7], s[8:11] dmask:0xf lwe{{$}}
; GFX10: image_sample v[0:4], v5, s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D lwe ;
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
define amdgpu_ps <4 x float> @sample_1d_lwe(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, i32 addrspace(1)* inreg %out, float %s) {
main_body:
%v = call {<4 x float>,i32} @llvm.amdgcn.image.sample.1d.v4f32i32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 2, i32 0)
%v.vec = extractvalue {<4 x float>, i32} %v, 0
%v.err = extractvalue {<4 x float>, i32} %v, 1
store i32 %v.err, i32 addrspace(1)* %out, align 4
ret <4 x float> %v.vec
}
; GCN-LABEL: {{^}}sample_2d:
; GFX6789: image_sample v[0:3], v[0:1], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample v[0:3], v[0:1], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s, float %t) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.2d.v4f32.f32(i32 15, float %s, float %t, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_3d:
; GFX6789: image_sample v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample v[0:3], v[0:2], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_3D ;
define amdgpu_ps <4 x float> @sample_3d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s, float %t, float %r) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.3d.v4f32.f32(i32 15, float %s, float %t, float %r, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_cube:
; GFX6789: image_sample v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf da{{$}}
; GFX10: image_sample v[0:3], v[0:2], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_CUBE ;
define amdgpu_ps <4 x float> @sample_cube(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s, float %t, float %face) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.cube.v4f32.f32(i32 15, float %s, float %t, float %face, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_1darray:
; GFX6789: image_sample v[0:3], v[0:1], s[0:7], s[8:11] dmask:0xf da{{$}}
; GFX10: image_sample v[0:3], v[0:1], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D_ARRAY ;
define amdgpu_ps <4 x float> @sample_1darray(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s, float %slice) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.1darray.v4f32.f32(i32 15, float %s, float %slice, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_2darray:
; GFX6789: image_sample v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf da{{$}}
; GFX10: image_sample v[0:3], v[0:2], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D_ARRAY ;
define amdgpu_ps <4 x float> @sample_2darray(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s, float %t, float %slice) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.2darray.v4f32.f32(i32 15, float %s, float %t, float %slice, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_1d:
; GFX6789: image_sample_c v[0:3], v[0:1], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c v[0:3], v[0:1], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_c_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %zcompare, float %s) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.1d.v4f32.f32(i32 15, float %zcompare, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_2d:
; GFX6789: image_sample_c v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c v[0:3], v[0:2], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_c_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %zcompare, float %s, float %t) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.2d.v4f32.f32(i32 15, float %zcompare, float %s, float %t, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_cl_1d:
; GFX6789: image_sample_cl v[0:3], v[0:1], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_cl v[0:3], v[0:1], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_cl_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s, float %clamp) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.cl.1d.v4f32.f32(i32 15, float %s, float %clamp, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_cl_2d:
; GFX6789: image_sample_cl v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_cl v[0:3], v[0:2], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_cl_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s, float %t, float %clamp) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.cl.2d.v4f32.f32(i32 15, float %s, float %t, float %clamp, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_cl_1d:
; GFX6789: image_sample_c_cl v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_cl v[0:3], v[0:2], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_c_cl_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %zcompare, float %s, float %clamp) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.cl.1d.v4f32.f32(i32 15, float %zcompare, float %s, float %clamp, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_cl_2d:
; GFX6789: image_sample_c_cl v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_cl v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_c_cl_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %zcompare, float %s, float %t, float %clamp) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.cl.2d.v4f32.f32(i32 15, float %zcompare, float %s, float %t, float %clamp, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_b_1d:
; GFX6789: image_sample_b v[0:3], v[0:1], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_b v[0:3], v[0:1], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_b_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %bias, float %s) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.b.1d.v4f32.f32.f32(i32 15, float %bias, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_b_2d:
; GFX6789: image_sample_b v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_b v[0:3], v[0:2], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_b_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %bias, float %s, float %t) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.b.2d.v4f32.f32.f32(i32 15, float %bias, float %s, float %t, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_b_1d:
; GFX6789: image_sample_c_b v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_b v[0:3], v[0:2], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_c_b_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %bias, float %zcompare, float %s) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.b.1d.v4f32.f32.f32(i32 15, float %bias, float %zcompare, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_b_2d:
; GFX6789: image_sample_c_b v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_b v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_c_b_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %bias, float %zcompare, float %s, float %t) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.b.2d.v4f32.f32.f32(i32 15, float %bias, float %zcompare, float %s, float %t, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_b_cl_1d:
; GFX6789: image_sample_b_cl v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_b_cl v[0:3], v[0:2], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_b_cl_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %bias, float %s, float %clamp) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.b.cl.1d.v4f32.f32.f32(i32 15, float %bias, float %s, float %clamp, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_b_cl_2d:
; GFX6789: image_sample_b_cl v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_b_cl v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_b_cl_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %bias, float %s, float %t, float %clamp) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.b.cl.2d.v4f32.f32.f32(i32 15, float %bias, float %s, float %t, float %clamp, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_b_cl_1d:
; GFX6789: image_sample_c_b_cl v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_b_cl v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_c_b_cl_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %bias, float %zcompare, float %s, float %clamp) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.b.cl.1d.v4f32.f32.f32(i32 15, float %bias, float %zcompare, float %s, float %clamp, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_b_cl_2d:
; GFX6789: image_sample_c_b_cl v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_b_cl v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_c_b_cl_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %bias, float %zcompare, float %s, float %t, float %clamp) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.b.cl.2d.v4f32.f32.f32(i32 15, float %bias, float %zcompare, float %s, float %t, float %clamp, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_d_1d:
; GFX6789: image_sample_d v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_d v[0:3], v[0:2], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_d_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %dsdh, float %dsdv, float %s) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.d.1d.v4f32.f32.f32(i32 15, float %dsdh, float %dsdv, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_d_2d:
; GFX6789: image_sample_d v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_d v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_d_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.d.2d.v4f32.f32.f32(i32 15, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_d_1d:
; GFX6789: image_sample_c_d v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_d v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_c_d_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %zcompare, float %dsdh, float %dsdv, float %s) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.d.1d.v4f32.f32.f32(i32 15, float %zcompare, float %dsdh, float %dsdv, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_d_2d:
; GFX6789: image_sample_c_d v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_d v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_c_d_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %zcompare, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.d.2d.v4f32.f32.f32(i32 15, float %zcompare, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_d_cl_1d:
; GFX6789: image_sample_d_cl v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_d_cl v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_d_cl_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %dsdh, float %dsdv, float %s, float %clamp) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.d.cl.1d.v4f32.f32.f32(i32 15, float %dsdh, float %dsdv, float %s, float %clamp, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_d_cl_2d:
; GFX6789: image_sample_d_cl v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_d_cl v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_d_cl_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, float %clamp) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.d.cl.2d.v4f32.f32.f32(i32 15, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, float %clamp, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_d_cl_1d:
; GFX6789: image_sample_c_d_cl v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_d_cl v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_c_d_cl_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %zcompare, float %dsdh, float %dsdv, float %s, float %clamp) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.d.cl.1d.v4f32.f32.f32(i32 15, float %zcompare, float %dsdh, float %dsdv, float %s, float %clamp, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_d_cl_2d:
; GFX6789: image_sample_c_d_cl v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_d_cl v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_c_d_cl_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %zcompare, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, float %clamp) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.d.cl.2d.v4f32.f32.f32(i32 15, float %zcompare, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, float %clamp, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_cd_1d:
; GFX6789: image_sample_cd v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_cd v[0:3], v[0:2], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_cd_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %dsdh, float %dsdv, float %s) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.cd.1d.v4f32.f32.f32(i32 15, float %dsdh, float %dsdv, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_cd_2d:
; GFX6789: image_sample_cd v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_cd v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_cd_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.cd.2d.v4f32.f32.f32(i32 15, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_cd_1d:
; GFX6789: image_sample_c_cd v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_cd v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_c_cd_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %zcompare, float %dsdh, float %dsdv, float %s) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.cd.1d.v4f32.f32.f32(i32 15, float %zcompare, float %dsdh, float %dsdv, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_cd_2d:
; GFX6789: image_sample_c_cd v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_cd v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_c_cd_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %zcompare, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.cd.2d.v4f32.f32.f32(i32 15, float %zcompare, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_cd_cl_1d:
; GFX6789: image_sample_cd_cl v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_cd_cl v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_cd_cl_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %dsdh, float %dsdv, float %s, float %clamp) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.cd.cl.1d.v4f32.f32.f32(i32 15, float %dsdh, float %dsdv, float %s, float %clamp, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_cd_cl_2d:
; GFX6789: image_sample_cd_cl v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_cd_cl v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_cd_cl_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, float %clamp) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.cd.cl.2d.v4f32.f32.f32(i32 15, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, float %clamp, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_cd_cl_1d:
; GFX6789: image_sample_c_cd_cl v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_cd_cl v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_c_cd_cl_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %zcompare, float %dsdh, float %dsdv, float %s, float %clamp) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.cd.cl.1d.v4f32.f32.f32(i32 15, float %zcompare, float %dsdh, float %dsdv, float %s, float %clamp, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_cd_cl_2d:
; GFX6789: image_sample_c_cd_cl v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_cd_cl v[0:3], v[0:7], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_c_cd_cl_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %zcompare, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, float %clamp) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.cd.cl.2d.v4f32.f32.f32(i32 15, float %zcompare, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, float %clamp, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_l_1d:
; GFX6789: image_sample_l v[0:3], v[0:1], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_l v[0:3], v[0:1], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_l_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s, float %lod) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.l.1d.v4f32.f32(i32 15, float %s, float %lod, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_l_2d:
; GFX6789: image_sample_l v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_l v[0:3], v[0:2], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_l_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s, float %t, float %lod) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.l.2d.v4f32.f32(i32 15, float %s, float %t, float %lod, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_l_1d:
; GFX6789: image_sample_c_l v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_l v[0:3], v[0:2], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_c_l_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %zcompare, float %s, float %lod) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.l.1d.v4f32.f32(i32 15, float %zcompare, float %s, float %lod, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_l_2d:
; GFX6789: image_sample_c_l v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_l v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_c_l_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %zcompare, float %s, float %t, float %lod) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.l.2d.v4f32.f32(i32 15, float %zcompare, float %s, float %t, float %lod, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_lz_1d:
; GFX6789: image_sample_lz v[0:3], v0, s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_lz v[0:3], v0, s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_lz_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.lz.1d.v4f32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_lz_2d:
; GFX6789: image_sample_lz v[0:3], v[0:1], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_lz v[0:3], v[0:1], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_lz_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s, float %t) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.lz.2d.v4f32.f32(i32 15, float %s, float %t, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_lz_1d:
; GFX6789: image_sample_c_lz v[0:3], v[0:1], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_lz v[0:3], v[0:1], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D ;
define amdgpu_ps <4 x float> @sample_c_lz_1d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %zcompare, float %s) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.lz.1d.v4f32.f32(i32 15, float %zcompare, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_lz_2d:
; GFX6789: image_sample_c_lz v[0:3], v[0:3], s[0:7], s[8:11] dmask:0xf{{$}}
; GFX10: image_sample_c_lz v[0:3], v[0:2], s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_2D ;
define amdgpu_ps <4 x float> @sample_c_lz_2d(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %zcompare, float %s, float %t) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.c.lz.2d.v4f32.f32(i32 15, float %zcompare, float %s, float %t, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_c_d_o_2darray_V1:
; GFX6789: image_sample_c_d_o v0, v[0:15], s[0:7], s[8:11] dmask:0x4 da{{$}}
; GFX10: image_sample_c_d_o v0, v[0:15], s[0:7], s[8:11] dmask:0x4 dim:SQ_RSRC_IMG_2D_ARRAY ;
define amdgpu_ps float @sample_c_d_o_2darray_V1(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, i32 %offset, float %zcompare, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, float %slice) {
main_body:
%v = call float @llvm.amdgcn.image.sample.c.d.o.2darray.f32.f32.f32(i32 4, i32 %offset, float %zcompare, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, float %slice, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret float %v
}
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
; GCN-LABEL: {{^}}sample_c_d_o_2darray_V1_tfe:
; GFX6789: image_sample_c_d_o v[9:10], v[0:15], s[0:7], s[8:11] dmask:0x4 tfe da{{$}}
; GFX10: image_sample_c_d_o v[0:1], [v10, v9, v2, v3, v4, v5, v6, v7, v8], s[0:7], s[8:11] dmask:0x4 dim:SQ_RSRC_IMG_2D_ARRAY tfe ;
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
define amdgpu_ps float @sample_c_d_o_2darray_V1_tfe(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, i32 %offset, float %zcompare, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, float %slice, i32 addrspace(1)* inreg %out) {
main_body:
%v = call {float,i32} @llvm.amdgcn.image.sample.c.d.o.2darray.f32i32.f32.f32(i32 4, i32 %offset, float %zcompare, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, float %slice, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 1, i32 0)
%v.vec = extractvalue {float, i32} %v, 0
%v.err = extractvalue {float, i32} %v, 1
store i32 %v.err, i32 addrspace(1)* %out, align 4
ret float %v.vec
}
; GCN-LABEL: {{^}}sample_c_d_o_2darray_V2:
; GFX6789: image_sample_c_d_o v[0:1], v[0:15], s[0:7], s[8:11] dmask:0x6 da{{$}}
; GFX10: image_sample_c_d_o v[0:1], v[0:15], s[0:7], s[8:11] dmask:0x6 dim:SQ_RSRC_IMG_2D_ARRAY ;
define amdgpu_ps <2 x float> @sample_c_d_o_2darray_V2(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, i32 %offset, float %zcompare, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, float %slice) {
main_body:
%v = call <2 x float> @llvm.amdgcn.image.sample.c.d.o.2darray.v2f32.f32.f32(i32 6, i32 %offset, float %zcompare, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, float %slice, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <2 x float> %v
}
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
; GCN-LABEL: {{^}}sample_c_d_o_2darray_V2_tfe:
; GFX6789: image_sample_c_d_o v[9:11], v[0:15], s[0:7], s[8:11] dmask:0x6 tfe da{{$}}
; GFX10: image_sample_c_d_o v[0:2], [v11, v10, v9, v3, v4, v5, v6, v7, v8], s[0:7], s[8:11] dmask:0x6 dim:SQ_RSRC_IMG_2D_ARRAY tfe ;
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
define amdgpu_ps <4 x float> @sample_c_d_o_2darray_V2_tfe(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, i32 %offset, float %zcompare, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, float %slice) {
main_body:
%v = call {<2 x float>, i32} @llvm.amdgcn.image.sample.c.d.o.2darray.v2f32i32.f32.f32(i32 6, i32 %offset, float %zcompare, float %dsdh, float %dtdh, float %dsdv, float %dtdv, float %s, float %t, float %slice, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 1, i32 0)
%v.vec = extractvalue {<2 x float>, i32} %v, 0
%v.f1 = extractelement <2 x float> %v.vec, i32 0
%v.f2 = extractelement <2 x float> %v.vec, i32 1
%v.err = extractvalue {<2 x float>, i32} %v, 1
%v.errf = bitcast i32 %v.err to float
%res.0 = insertelement <4 x float> undef, float %v.f1, i32 0
%res.1 = insertelement <4 x float> %res.0, float %v.f2, i32 1
%res.2 = insertelement <4 x float> %res.1, float %v.errf, i32 2
ret <4 x float> %res.2
}
; GCN-LABEL: {{^}}sample_1d_unorm:
; GFX6789: image_sample v[0:3], v0, s[0:7], s[8:11] dmask:0xf unorm{{$}}
; GFX10: image_sample v[0:3], v0, s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D unorm ;
define amdgpu_ps <4 x float> @sample_1d_unorm(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.1d.v4f32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 1, i32 0, i32 0)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_1d_glc:
; GFX6789: image_sample v[0:3], v0, s[0:7], s[8:11] dmask:0xf glc{{$}}
; GFX10: image_sample v[0:3], v0, s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D glc ;
define amdgpu_ps <4 x float> @sample_1d_glc(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.1d.v4f32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 1)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_1d_slc:
; GFX6789: image_sample v[0:3], v0, s[0:7], s[8:11] dmask:0xf slc{{$}}
; GFX10: image_sample v[0:3], v0, s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D slc ;
define amdgpu_ps <4 x float> @sample_1d_slc(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.1d.v4f32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 2)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}sample_1d_glc_slc:
; GFX6789: image_sample v[0:3], v0, s[0:7], s[8:11] dmask:0xf glc slc{{$}}
; GFX10: image_sample v[0:3], v0, s[0:7], s[8:11] dmask:0xf dim:SQ_RSRC_IMG_1D glc slc ;
define amdgpu_ps <4 x float> @sample_1d_glc_slc(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%v = call <4 x float> @llvm.amdgcn.image.sample.1d.v4f32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 3)
ret <4 x float> %v
}
; GCN-LABEL: {{^}}adjust_writemask_sample_0:
; GCN: image_sample v0, v0, s[0:7], s[8:11] dmask:0x1
define amdgpu_ps float @adjust_writemask_sample_0(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%r = call <4 x float> @llvm.amdgcn.image.sample.1d.v4f32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
%elt0 = extractelement <4 x float> %r, i32 0
ret float %elt0
}
; GCN-LABEL: {{^}}adjust_writemask_sample_01
; GCN: image_sample v[0:1], v0, s[0:7], s[8:11] dmask:0x3
define amdgpu_ps <2 x float> @adjust_writemask_sample_01(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%r = call <4 x float> @llvm.amdgcn.image.sample.1d.v4f32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
%out = shufflevector <4 x float> %r, <4 x float> undef, <2 x i32> <i32 0, i32 1>
ret <2 x float> %out
}
; GCN-LABEL: {{^}}adjust_writemask_sample_012
; GCN: image_sample v[0:2], v0, s[0:7], s[8:11] dmask:0x7
define amdgpu_ps <3 x float> @adjust_writemask_sample_012(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%r = call <4 x float> @llvm.amdgcn.image.sample.1d.v4f32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
%out = shufflevector <4 x float> %r, <4 x float> undef, <3 x i32> <i32 0, i32 1, i32 2>
ret <3 x float> %out
}
; GCN-LABEL: {{^}}adjust_writemask_sample_12
; GCN: image_sample v[0:1], v0, s[0:7], s[8:11] dmask:0x6
define amdgpu_ps <2 x float> @adjust_writemask_sample_12(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%r = call <4 x float> @llvm.amdgcn.image.sample.1d.v4f32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
%out = shufflevector <4 x float> %r, <4 x float> undef, <2 x i32> <i32 1, i32 2>
ret <2 x float> %out
}
; GCN-LABEL: {{^}}adjust_writemask_sample_03
; GCN: image_sample v[0:1], v0, s[0:7], s[8:11] dmask:0x9
define amdgpu_ps <2 x float> @adjust_writemask_sample_03(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%r = call <4 x float> @llvm.amdgcn.image.sample.1d.v4f32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
%out = shufflevector <4 x float> %r, <4 x float> undef, <2 x i32> <i32 0, i32 3>
ret <2 x float> %out
}
; GCN-LABEL: {{^}}adjust_writemask_sample_13
; GCN: image_sample v[0:1], v0, s[0:7], s[8:11] dmask:0xa
define amdgpu_ps <2 x float> @adjust_writemask_sample_13(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%r = call <4 x float> @llvm.amdgcn.image.sample.1d.v4f32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
%out = shufflevector <4 x float> %r, <4 x float> undef, <2 x i32> <i32 1, i32 3>
ret <2 x float> %out
}
; GCN-LABEL: {{^}}adjust_writemask_sample_123
; GCN: image_sample v[0:2], v0, s[0:7], s[8:11] dmask:0xe
define amdgpu_ps <3 x float> @adjust_writemask_sample_123(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%r = call <4 x float> @llvm.amdgcn.image.sample.1d.v4f32.f32(i32 15, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
%out = shufflevector <4 x float> %r, <4 x float> undef, <3 x i32> <i32 1, i32 2, i32 3>
ret <3 x float> %out
}
; GCN-LABEL: {{^}}adjust_writemask_sample_none_enabled
; GCN-NOT: image
define amdgpu_ps <4 x float> @adjust_writemask_sample_none_enabled(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%r = call <4 x float> @llvm.amdgcn.image.sample.1d.v4f32.f32(i32 0, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
ret <4 x float> %r
}
; GCN-LABEL: {{^}}adjust_writemask_sample_123_to_12
; GCN: image_sample v[0:1], v0, s[0:7], s[8:11] dmask:0x6
define amdgpu_ps <2 x float> @adjust_writemask_sample_123_to_12(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%r = call <4 x float> @llvm.amdgcn.image.sample.1d.v4f32.f32(i32 14, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
%out = shufflevector <4 x float> %r, <4 x float> undef, <2 x i32> <i32 0, i32 1>
ret <2 x float> %out
}
; GCN-LABEL: {{^}}adjust_writemask_sample_013_to_13
; GCN: image_sample v[0:1], v0, s[0:7], s[8:11] dmask:0xa
define amdgpu_ps <2 x float> @adjust_writemask_sample_013_to_13(<8 x i32> inreg %rsrc, <4 x i32> inreg %samp, float %s) {
main_body:
%r = call <4 x float> @llvm.amdgcn.image.sample.1d.v4f32.f32(i32 11, float %s, <8 x i32> %rsrc, <4 x i32> %samp, i1 0, i32 0, i32 0)
%out = shufflevector <4 x float> %r, <4 x float> undef, <2 x i32> <i32 1, i32 2>
ret <2 x float> %out
}
declare <4 x float> @llvm.amdgcn.image.sample.1d.v4f32.f32(i32, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
declare {<4 x float>,i32} @llvm.amdgcn.image.sample.1d.v4f32i32.f32(i32, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.2d.v4f32.f32(i32, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.3d.v4f32.f32(i32, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.cube.v4f32.f32(i32, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.1darray.v4f32.f32(i32, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.2darray.v4f32.f32(i32, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.1d.v4f32.f32(i32, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.2d.v4f32.f32(i32, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.cl.1d.v4f32.f32(i32, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.cl.2d.v4f32.f32(i32, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.cl.1d.v4f32.f32(i32, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.cl.2d.v4f32.f32(i32, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.b.1d.v4f32.f32.f32(i32, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.b.2d.v4f32.f32.f32(i32, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.b.1d.v4f32.f32.f32(i32, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.b.2d.v4f32.f32.f32(i32, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.b.cl.1d.v4f32.f32.f32(i32, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.b.cl.2d.v4f32.f32.f32(i32, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.b.cl.1d.v4f32.f32.f32(i32, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.b.cl.2d.v4f32.f32.f32(i32, float, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.d.1d.v4f32.f32.f32(i32, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.d.2d.v4f32.f32.f32(i32, float, float, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.d.1d.v4f32.f32.f32(i32, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.d.2d.v4f32.f32.f32(i32, float, float, float, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.d.cl.1d.v4f32.f32.f32(i32, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.d.cl.2d.v4f32.f32.f32(i32, float, float, float, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.d.cl.1d.v4f32.f32.f32(i32, float, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.d.cl.2d.v4f32.f32.f32(i32, float, float, float, float, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.cd.1d.v4f32.f32.f32(i32, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.cd.2d.v4f32.f32.f32(i32, float, float, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.cd.1d.v4f32.f32.f32(i32, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.cd.2d.v4f32.f32.f32(i32, float, float, float, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.cd.cl.1d.v4f32.f32.f32(i32, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.cd.cl.2d.v4f32.f32.f32(i32, float, float, float, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.cd.cl.1d.v4f32.f32.f32(i32, float, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.cd.cl.2d.v4f32.f32.f32(i32, float, float, float, float, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.l.1d.v4f32.f32(i32, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.l.2d.v4f32.f32(i32, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.l.1d.v4f32.f32(i32, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.l.2d.v4f32.f32(i32, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.lz.1d.v4f32.f32(i32, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.lz.2d.v4f32.f32(i32, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.lz.1d.v4f32.f32(i32, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <4 x float> @llvm.amdgcn.image.sample.c.lz.2d.v4f32.f32(i32, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare float @llvm.amdgcn.image.sample.c.d.o.2darray.f32.f32.f32(i32, i32, float, float, float, float, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
declare {float, i32} @llvm.amdgcn.image.sample.c.d.o.2darray.f32i32.f32.f32(i32, i32, float, float, float, float, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
declare <2 x float> @llvm.amdgcn.image.sample.c.d.o.2darray.v2f32.f32.f32(i32, i32, float, float, float, float, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
[AMDGPU] Add support for TFE/LWE in image intrinsics. 2nd try TFE and LWE support requires extra result registers that are written in the event of a failure in order to detect that failure case. The specific use-case that initiated these changes is sparse texture support. This means that if image intrinsics are used with either option turned on, the programmer must ensure that the return type can contain all of the expected results. This can result in redundant registers since the vector size must be a power-of-2. This change takes roughly 6 parts: 1. Modify the instruction defs in tablegen to add new instruction variants that can accomodate the extra return values. 2. Updates to lowerImage in SIISelLowering.cpp to accomodate setting TFE or LWE (where the bulk of the work for these instruction types is now done) 3. Extra verification code to catch cases where intrinsics have been used but insufficient return registers are used. 4. Modification to the adjustWritemask optimisation to account for TFE/LWE being enabled (requires extra registers to be maintained for error return value). 5. An extra pass to zero initialize the error value return - this is because if the error does not occur, the register is not written and thus must be zeroed before use. Also added a new (on by default) option to ensure ALL return values are zero-initialized that is required for sparse texture support. 6. Disable the inst_combine optimization in the presence of tfe/lwe (later TODO for this to re-enable and handle correctly). There's an additional fix now to avoid a dmask=0 For an image intrinsic with tfe where all result channels except tfe were unused, I was getting an image instruction with dmask=0 and only a single vgpr result for tfe. That is incorrect because the hardware assumes there is at least one vgpr result, plus the one for tfe. Fixed by forcing dmask to 1, which gives the desired two vgpr result with tfe in the second one. The TFE or LWE result is returned from the intrinsics using an aggregate type. Look in the test code provided to see how this works, but in essence IR code to invoke the intrinsic looks as follows: %v = call {<4 x float>,i32} @llvm.amdgcn.image.load.1d.v4f32i32.i32(i32 15, i32 %s, <8 x i32> %rsrc, i32 1, i32 0) %v.vec = extractvalue {<4 x float>, i32} %v, 0 %v.err = extractvalue {<4 x float>, i32} %v, 1 This re-submit of the change also includes a slight modification in SIISelLowering.cpp to work-around a compiler bug for the powerpc_le platform that caused a buildbot failure on a previous submission. Differential revision: https://reviews.llvm.org/D48826 Change-Id: If222bc03642e76cf98059a6bef5d5bffeda38dda Work around for ppcle compiler bug Change-Id: Ie284cf24b2271215be1b9dc95b485fd15000e32b llvm-svn: 351054
2019-01-14 19:55:24 +08:00
declare {<2 x float>, i32} @llvm.amdgcn.image.sample.c.d.o.2darray.v2f32i32.f32.f32(i32, i32, float, float, float, float, float, float, float, float, <8 x i32>, <4 x i32>, i1, i32, i32) #1
attributes #0 = { nounwind }
attributes #1 = { nounwind readonly }
attributes #2 = { nounwind readnone }