; NOTE: Assertions have been autogenerated by utils/update_test_checks.py ; RUN: opt < %s -passes=instcombine -S | FileCheck %s ; Check the libcall and the intrinsic for each case with differing FMF. ; The transform to sqrt is not allowed if we risk setting errno due to -INF. define double @pow_libcall_half_no_FMF(double %x) { ; CHECK-LABEL: @pow_libcall_half_no_FMF( ; CHECK-NEXT: [[POW:%.*]] = call double @pow(double [[X:%.*]], double 5.000000e-01) ; CHECK-NEXT: ret double [[POW]] ; %pow = call double @pow(double %x, double 5.0e-01) ret double %pow } ; The transform to (non-errno setting) sqrt is allowed as long as we deal with -0.0 and -INF. define double @pow_intrinsic_half_no_FMF(double %x) { ; CHECK-LABEL: @pow_intrinsic_half_no_FMF( ; CHECK-NEXT: [[SQRT:%.*]] = call double @llvm.sqrt.f64(double [[X:%.*]]) ; CHECK-NEXT: [[ABS:%.*]] = call double @llvm.fabs.f64(double [[SQRT]]) ; CHECK-NEXT: [[ISINF:%.*]] = fcmp oeq double [[X]], 0xFFF0000000000000 ; CHECK-NEXT: [[TMP1:%.*]] = select i1 [[ISINF]], double 0x7FF0000000000000, double [[ABS]] ; CHECK-NEXT: ret double [[TMP1]] ; %pow = call double @llvm.pow.f64(double %x, double 5.0e-01) ret double %pow } ; `afn` makes no difference, but FMF are propagated/retained. ; (As above) the transform to sqrt may generate EDOM due to -INF. Generally, EDOM implies ; formation of a NaN (which then propagates). `afn` may justify returning NaN (along with ; setting EDOM); however, the conservatively correct approach is to avoid both the NaN and ; the EDOM. define double @pow_libcall_half_approx(double %x) { ; CHECK-LABEL: @pow_libcall_half_approx( ; CHECK-NEXT: [[POW:%.*]] = call afn double @pow(double [[X:%.*]], double 5.000000e-01) ; CHECK-NEXT: ret double [[POW]] ; %pow = call afn double @pow(double %x, double 5.0e-01) ret double %pow } ; (As above) the transform to (non-errno setting) sqrt is allowed as long as we deal with -0.0 ; and -INF. define <2 x double> @pow_intrinsic_half_approx(<2 x double> %x) { ; CHECK-LABEL: @pow_intrinsic_half_approx( ; CHECK-NEXT: [[SQRT:%.*]] = call afn <2 x double> @llvm.sqrt.v2f64(<2 x double> [[X:%.*]]) ; CHECK-NEXT: [[ABS:%.*]] = call afn <2 x double> @llvm.fabs.v2f64(<2 x double> [[SQRT]]) ; CHECK-NEXT: [[ISINF:%.*]] = fcmp afn oeq <2 x double> [[X]], <double 0xFFF0000000000000, double 0xFFF0000000000000> ; CHECK-NEXT: [[TMP1:%.*]] = select afn <2 x i1> [[ISINF]], <2 x double> <double 0x7FF0000000000000, double 0x7FF0000000000000>, <2 x double> [[ABS]] ; CHECK-NEXT: ret <2 x double> [[TMP1]] ; %pow = call afn <2 x double> @llvm.pow.v2f64(<2 x double> %x, <2 x double> <double 5.0e-01, double 5.0e-01>) ret <2 x double> %pow } define float @powf_intrinsic_half_fast(float %x) { ; CHECK-LABEL: @powf_intrinsic_half_fast( ; CHECK-NEXT: [[SQRT:%.*]] = call fast float @llvm.sqrt.f32(float [[X:%.*]]) ; CHECK-NEXT: ret float [[SQRT]] ; %pow = call fast float @llvm.pow.f32(float %x, float 5.0e-01) ret float %pow } ; If we can disregard INFs, no need for a select. define double @pow_libcall_half_no_FMF_base_ninf(i32 %x) { ; CHECK-LABEL: @pow_libcall_half_no_FMF_base_ninf( ; CHECK-NEXT: [[CONV:%.*]] = uitofp i32 [[X:%.*]] to double ; CHECK-NEXT: [[SQRT:%.*]] = call double @sqrt(double [[CONV]]) ; CHECK-NEXT: [[ABS:%.*]] = call double @llvm.fabs.f64(double [[SQRT]]) ; CHECK-NEXT: ret double [[ABS]] ; %conv = uitofp i32 %x to double %pow = call double @pow(double %conv, double 5.0e-01) ret double %pow } define double @pow_libcall_half_ninf(double %x) { ; CHECK-LABEL: @pow_libcall_half_ninf( ; CHECK-NEXT: [[SQRT:%.*]] = call ninf double @sqrt(double [[X:%.*]]) ; CHECK-NEXT: [[ABS:%.*]] = call ninf double @llvm.fabs.f64(double [[SQRT]]) ; CHECK-NEXT: ret double [[ABS]] ; %pow = call ninf double @pow(double %x, double 5.0e-01) ret double %pow } define <2 x double> @pow_intrinsic_half_ninf(<2 x double> %x) { ; CHECK-LABEL: @pow_intrinsic_half_ninf( ; CHECK-NEXT: [[SQRT:%.*]] = call ninf <2 x double> @llvm.sqrt.v2f64(<2 x double> [[X:%.*]]) ; CHECK-NEXT: [[ABS:%.*]] = call ninf <2 x double> @llvm.fabs.v2f64(<2 x double> [[SQRT]]) ; CHECK-NEXT: ret <2 x double> [[ABS]] ; %pow = call ninf <2 x double> @llvm.pow.v2f64(<2 x double> %x, <2 x double> <double 5.0e-01, double 5.0e-01>) ret <2 x double> %pow } ; If we can disregard -0.0, no need for fabs, but still (because of -INF) cannot use library sqrt. define double @pow_libcall_half_nsz(double %x) { ; CHECK-LABEL: @pow_libcall_half_nsz( ; CHECK-NEXT: [[POW:%.*]] = call nsz double @pow(double [[X:%.*]], double 5.000000e-01) ; CHECK-NEXT: ret double [[POW]] ; %pow = call nsz double @pow(double %x, double 5.0e-01) ret double %pow } define double @pow_intrinsic_half_nsz(double %x) { ; CHECK-LABEL: @pow_intrinsic_half_nsz( ; CHECK-NEXT: [[SQRT:%.*]] = call nsz double @llvm.sqrt.f64(double [[X:%.*]]) ; CHECK-NEXT: [[ISINF:%.*]] = fcmp nsz oeq double [[X]], 0xFFF0000000000000 ; CHECK-NEXT: [[TMP1:%.*]] = select nsz i1 [[ISINF]], double 0x7FF0000000000000, double [[SQRT]] ; CHECK-NEXT: ret double [[TMP1]] ; %pow = call nsz double @llvm.pow.f64(double %x, double 5.0e-01) ret double %pow } ; This is just sqrt. define float @pow_libcall_half_ninf_nsz(float %x) { ; CHECK-LABEL: @pow_libcall_half_ninf_nsz( ; CHECK-NEXT: [[SQRTF:%.*]] = call ninf nsz float @sqrtf(float [[X:%.*]]) ; CHECK-NEXT: ret float [[SQRTF]] ; %pow = call ninf nsz float @powf(float %x, float 5.0e-01) ret float %pow } define double @pow_intrinsic_half_ninf_nsz(double %x) { ; CHECK-LABEL: @pow_intrinsic_half_ninf_nsz( ; CHECK-NEXT: [[SQRT:%.*]] = call ninf nsz double @llvm.sqrt.f64(double [[X:%.*]]) ; CHECK-NEXT: ret double [[SQRT]] ; %pow = call ninf nsz double @llvm.pow.f64(double %x, double 5.0e-01) ret double %pow } ; Overspecified FMF to test propagation to the new op(s). define float @pow_libcall_half_fast(float %x) { ; CHECK-LABEL: @pow_libcall_half_fast( ; CHECK-NEXT: [[SQRTF:%.*]] = call fast float @sqrtf(float [[X:%.*]]) ; CHECK-NEXT: ret float [[SQRTF]] ; %pow = call fast float @powf(float %x, float 5.0e-01) ret float %pow } define double @pow_intrinsic_half_fast(double %x) { ; CHECK-LABEL: @pow_intrinsic_half_fast( ; CHECK-NEXT: [[SQRT:%.*]] = call fast double @llvm.sqrt.f64(double [[X:%.*]]) ; CHECK-NEXT: ret double [[SQRT]] ; %pow = call fast double @llvm.pow.f64(double %x, double 5.0e-01) ret double %pow } ; This should not be transformed without some kind of FMF. ; -0.5 means take the reciprocal. define float @pow_libcall_neghalf_no_FMF(float %x) { ; CHECK-LABEL: @pow_libcall_neghalf_no_FMF( ; CHECK-NEXT: [[POW:%.*]] = call float @powf(float [[X:%.*]], float -5.000000e-01) ; CHECK-NEXT: ret float [[POW]] ; %pow = call float @powf(float %x, float -5.0e-01) ret float %pow } ; If we can disregard INFs, a call to a library sqrt is okay. ; Transform to sqrt+fdiv because 'reassoc' allows an extra rounding step. ; Use 'fabs' to handle -0.0 correctly. define float @pow_libcall_neghalf_reassoc_ninf(float %x) { ; CHECK-LABEL: @pow_libcall_neghalf_reassoc_ninf( ; CHECK-NEXT: [[SQRTF:%.*]] = call reassoc ninf float @sqrtf(float [[X:%.*]]) ; CHECK-NEXT: [[ABS:%.*]] = call reassoc ninf float @llvm.fabs.f32(float [[SQRTF]]) ; CHECK-NEXT: [[RECIPROCAL:%.*]] = fdiv reassoc ninf float 1.000000e+00, [[ABS]] ; CHECK-NEXT: ret float [[RECIPROCAL]] ; %pow = call reassoc ninf float @powf(float %x, float -5.0e-01) ret float %pow } ; If we cannot disregard INFs, a call to a library sqrt is not okay. define float @pow_libcall_neghalf_afn(float %x) { ; CHECK-LABEL: @pow_libcall_neghalf_afn( ; CHECK-NEXT: [[POW:%.*]] = call afn float @powf(float [[X:%.*]], float -5.000000e-01) ; CHECK-NEXT: ret float [[POW]] ; %pow = call afn float @powf(float %x, float -5.0e-01) ret float %pow } ; This should not be transformed without some kind of FMF. define <2 x double> @pow_intrinsic_neghalf_no_FMF(<2 x double> %x) { ; CHECK-LABEL: @pow_intrinsic_neghalf_no_FMF( ; CHECK-NEXT: [[POW:%.*]] = call <2 x double> @llvm.pow.v2f64(<2 x double> [[X:%.*]], <2 x double> <double -5.000000e-01, double -5.000000e-01>) ; CHECK-NEXT: ret <2 x double> [[POW]] ; %pow = call <2 x double> @llvm.pow.v2f64(<2 x double> %x, <2 x double> <double -5.0e-01, double -5.0e-01>) ret <2 x double> %pow } ; Transform to sqrt+fdiv because 'reassoc' allows an extra rounding step. ; Use 'fabs' to handle -0.0 correctly. ; Use 'select' to handle -INF correctly. define <2 x double> @pow_intrinsic_neghalf_reassoc(<2 x double> %x) { ; CHECK-LABEL: @pow_intrinsic_neghalf_reassoc( ; CHECK-NEXT: [[SQRT:%.*]] = call reassoc <2 x double> @llvm.sqrt.v2f64(<2 x double> [[X:%.*]]) ; CHECK-NEXT: [[ABS:%.*]] = call reassoc <2 x double> @llvm.fabs.v2f64(<2 x double> [[SQRT]]) ; CHECK-NEXT: [[ISINF:%.*]] = fcmp reassoc oeq <2 x double> [[X]], <double 0xFFF0000000000000, double 0xFFF0000000000000> ; CHECK-NEXT: [[ABS_OP:%.*]] = fdiv reassoc <2 x double> <double 1.000000e+00, double 1.000000e+00>, [[ABS]] ; CHECK-NEXT: [[RECIPROCAL:%.*]] = select <2 x i1> [[ISINF]], <2 x double> zeroinitializer, <2 x double> [[ABS_OP]] ; CHECK-NEXT: ret <2 x double> [[RECIPROCAL]] ; %pow = call reassoc <2 x double> @llvm.pow.v2f64(<2 x double> %x, <2 x double> <double -5.0e-01, double -5.0e-01>) ret <2 x double> %pow } ; Transform to sqrt+fdiv because 'afn' allows an extra rounding step. ; Use 'fabs' to handle -0.0 correctly. ; Use 'select' to handle -INF correctly. define <2 x double> @pow_intrinsic_neghalf_afn(<2 x double> %x) { ; CHECK-LABEL: @pow_intrinsic_neghalf_afn( ; CHECK-NEXT: [[SQRT:%.*]] = call afn <2 x double> @llvm.sqrt.v2f64(<2 x double> [[X:%.*]]) ; CHECK-NEXT: [[ABS:%.*]] = call afn <2 x double> @llvm.fabs.v2f64(<2 x double> [[SQRT]]) ; CHECK-NEXT: [[ISINF:%.*]] = fcmp afn oeq <2 x double> [[X]], <double 0xFFF0000000000000, double 0xFFF0000000000000> ; CHECK-NEXT: [[ABS_OP:%.*]] = fdiv afn <2 x double> <double 1.000000e+00, double 1.000000e+00>, [[ABS]] ; CHECK-NEXT: [[RECIPROCAL:%.*]] = select <2 x i1> [[ISINF]], <2 x double> zeroinitializer, <2 x double> [[ABS_OP]] ; CHECK-NEXT: ret <2 x double> [[RECIPROCAL]] ; %pow = call afn <2 x double> @llvm.pow.v2f64(<2 x double> %x, <2 x double> <double -5.0e-01, double -5.0e-01>) ret <2 x double> %pow } ; If we can disregard INFs, no need for a select. define double @pow_libcall_neghalf_ninf(double %x) { ; CHECK-LABEL: @pow_libcall_neghalf_ninf( ; CHECK-NEXT: [[SQRT:%.*]] = call ninf afn double @sqrt(double [[X:%.*]]) ; CHECK-NEXT: [[ABS:%.*]] = call ninf afn double @llvm.fabs.f64(double [[SQRT]]) ; CHECK-NEXT: [[RECIPROCAL:%.*]] = fdiv ninf afn double 1.000000e+00, [[ABS]] ; CHECK-NEXT: ret double [[RECIPROCAL]] ; %pow = call afn ninf double @pow(double %x, double -5.0e-01) ret double %pow } define <2 x double> @pow_intrinsic_neghalf_ninf(<2 x double> %x) { ; CHECK-LABEL: @pow_intrinsic_neghalf_ninf( ; CHECK-NEXT: [[SQRT:%.*]] = call ninf afn <2 x double> @llvm.sqrt.v2f64(<2 x double> [[X:%.*]]) ; CHECK-NEXT: [[ABS:%.*]] = call ninf afn <2 x double> @llvm.fabs.v2f64(<2 x double> [[SQRT]]) ; CHECK-NEXT: [[RECIPROCAL:%.*]] = fdiv ninf afn <2 x double> <double 1.000000e+00, double 1.000000e+00>, [[ABS]] ; CHECK-NEXT: ret <2 x double> [[RECIPROCAL]] ; %pow = call afn ninf <2 x double> @llvm.pow.v2f64(<2 x double> %x, <2 x double> <double -5.0e-01, double -5.0e-01>) ret <2 x double> %pow } ; If we can disregard -0.0, no need for fabs, but still (because of -INF) cannot use library sqrt. define double @pow_libcall_neghalf_nsz(double %x) { ; CHECK-LABEL: @pow_libcall_neghalf_nsz( ; CHECK-NEXT: [[POW:%.*]] = call nsz afn double @pow(double [[X:%.*]], double -5.000000e-01) ; CHECK-NEXT: ret double [[POW]] ; %pow = call afn nsz double @pow(double %x, double -5.0e-01) ret double %pow } define double @pow_intrinsic_neghalf_nsz(double %x) { ; CHECK-LABEL: @pow_intrinsic_neghalf_nsz( ; CHECK-NEXT: [[SQRT:%.*]] = call nsz afn double @llvm.sqrt.f64(double [[X:%.*]]) ; CHECK-NEXT: [[ISINF:%.*]] = fcmp nsz afn oeq double [[X]], 0xFFF0000000000000 ; CHECK-NEXT: [[SQRT_OP:%.*]] = fdiv nsz afn double 1.000000e+00, [[SQRT]] ; CHECK-NEXT: [[RECIPROCAL:%.*]] = select i1 [[ISINF]], double 0.000000e+00, double [[SQRT_OP]] ; CHECK-NEXT: ret double [[RECIPROCAL]] ; %pow = call afn nsz double @llvm.pow.f64(double %x, double -5.0e-01) ret double %pow } ; This is just recip-sqrt. define double @pow_intrinsic_neghalf_ninf_nsz(double %x) { ; CHECK-LABEL: @pow_intrinsic_neghalf_ninf_nsz( ; CHECK-NEXT: [[SQRT:%.*]] = call ninf nsz afn double @llvm.sqrt.f64(double [[X:%.*]]) ; CHECK-NEXT: [[RECIPROCAL:%.*]] = fdiv ninf nsz afn double 1.000000e+00, [[SQRT]] ; CHECK-NEXT: ret double [[RECIPROCAL]] ; %pow = call afn ninf nsz double @llvm.pow.f64(double %x, double -5.0e-01) ret double %pow } define float @pow_libcall_neghalf_ninf_nsz(float %x) { ; CHECK-LABEL: @pow_libcall_neghalf_ninf_nsz( ; CHECK-NEXT: [[SQRTF:%.*]] = call ninf nsz afn float @sqrtf(float [[X:%.*]]) ; CHECK-NEXT: [[RECIPROCAL:%.*]] = fdiv ninf nsz afn float 1.000000e+00, [[SQRTF]] ; CHECK-NEXT: ret float [[RECIPROCAL]] ; %pow = call afn ninf nsz float @powf(float %x, float -5.0e-01) ret float %pow } ; Overspecified FMF to test propagation to the new op(s). define float @pow_libcall_neghalf_fast(float %x) { ; CHECK-LABEL: @pow_libcall_neghalf_fast( ; CHECK-NEXT: [[SQRTF:%.*]] = call fast float @sqrtf(float [[X:%.*]]) ; CHECK-NEXT: [[RECIPROCAL:%.*]] = fdiv fast float 1.000000e+00, [[SQRTF]] ; CHECK-NEXT: ret float [[RECIPROCAL]] ; %pow = call fast float @powf(float %x, float -5.0e-01) ret float %pow } define double @pow_intrinsic_neghalf_fast(double %x) { ; CHECK-LABEL: @pow_intrinsic_neghalf_fast( ; CHECK-NEXT: [[SQRT:%.*]] = call fast double @llvm.sqrt.f64(double [[X:%.*]]) ; CHECK-NEXT: [[RECIPROCAL:%.*]] = fdiv fast double 1.000000e+00, [[SQRT]] ; CHECK-NEXT: ret double [[RECIPROCAL]] ; %pow = call fast double @llvm.pow.f64(double %x, double -5.0e-01) ret double %pow } declare double @llvm.pow.f64(double, double) #0 declare float @llvm.pow.f32(float, float) #0 declare <2 x double> @llvm.pow.v2f64(<2 x double>, <2 x double>) #0 declare <2 x float> @llvm.pow.v2f32(<2 x float>, <2 x float>) #0 declare <4 x float> @llvm.pow.v4f32(<4 x float>, <4 x float>) #0 declare double @pow(double, double) declare float @powf(float, float) attributes #0 = { nounwind readnone speculatable } attributes #1 = { nounwind readnone }