| ; RUN: llc -march=mips -relocation-model=static < %s | FileCheck --check-prefixes=ALL,SYM32,O32,O32BE %s |
| ; RUN: llc -march=mipsel -relocation-model=static < %s | FileCheck --check-prefixes=ALL,SYM32,O32,O32LE %s |
| |
| ; RUN-TODO: llc -march=mips64 -relocation-model=static -target-abi o32 < %s | FileCheck --check-prefixes=ALL,SYM32,O32 %s |
| ; RUN-TODO: llc -march=mips64el -relocation-model=static -target-abi o32 < %s | FileCheck --check-prefixes=ALL,SYM32,O32 %s |
| |
| ; RUN: llc -march=mips64 -relocation-model=static -target-abi n32 < %s | FileCheck --check-prefixes=ALL,SYM32,NEW %s |
| ; RUN: llc -march=mips64el -relocation-model=static -target-abi n32 < %s | FileCheck --check-prefixes=ALL,SYM32,NEW %s |
| |
| ; RUN: llc -march=mips64 -relocation-model=static -target-abi n64 < %s | FileCheck --check-prefixes=ALL,SYM64,NEW %s |
| ; RUN: llc -march=mips64el -relocation-model=static -target-abi n64 < %s | FileCheck --check-prefixes=ALL,SYM64,NEW %s |
| |
| ; Test the floating point arguments for all ABI's and byte orders as specified |
| ; by section 5 of MD00305 (MIPS ABIs Described). |
| ; |
| ; N32/N64 are identical in this area so their checks have been combined into |
| ; the 'NEW' prefix (the N stands for New). |
| |
| @bytes = global [11 x i8] zeroinitializer |
| @dwords = global [11 x i64] zeroinitializer |
| @floats = global [11 x float] zeroinitializer |
| @doubles = global [11 x double] zeroinitializer |
| |
| define void @double_args(double %a, double %b, double %c, double %d, double %e, |
| double %f, double %g, double %h, double %i) nounwind { |
| entry: |
| %0 = getelementptr [11 x double], [11 x double]* @doubles, i32 0, i32 1 |
| store volatile double %a, double* %0 |
| %1 = getelementptr [11 x double], [11 x double]* @doubles, i32 0, i32 2 |
| store volatile double %b, double* %1 |
| %2 = getelementptr [11 x double], [11 x double]* @doubles, i32 0, i32 3 |
| store volatile double %c, double* %2 |
| %3 = getelementptr [11 x double], [11 x double]* @doubles, i32 0, i32 4 |
| store volatile double %d, double* %3 |
| %4 = getelementptr [11 x double], [11 x double]* @doubles, i32 0, i32 5 |
| store volatile double %e, double* %4 |
| %5 = getelementptr [11 x double], [11 x double]* @doubles, i32 0, i32 6 |
| store volatile double %f, double* %5 |
| %6 = getelementptr [11 x double], [11 x double]* @doubles, i32 0, i32 7 |
| store volatile double %g, double* %6 |
| %7 = getelementptr [11 x double], [11 x double]* @doubles, i32 0, i32 8 |
| store volatile double %h, double* %7 |
| %8 = getelementptr [11 x double], [11 x double]* @doubles, i32 0, i32 9 |
| store volatile double %i, double* %8 |
| ret void |
| } |
| |
| ; ALL-LABEL: double_args: |
| ; We won't test the way the global address is calculated in this test. This is |
| ; just to get the register number for the other checks. |
| ; SYM32-DAG: addiu [[R2:\$[0-9]+]], ${{[0-9]+}}, %lo(doubles) |
| ; SYM64-DAG: daddiu [[R2:\$[0-9]]], ${{[0-9]+}}, %lo(doubles) |
| |
| ; The first argument is floating point so floating point registers are used. |
| ; The first argument is the same for O32/N32/N64 but the second argument differs |
| ; by register |
| ; ALL-DAG: sdc1 $f12, 8([[R2]]) |
| ; O32-DAG: sdc1 $f14, 16([[R2]]) |
| ; NEW-DAG: sdc1 $f13, 16([[R2]]) |
| |
| ; O32 has run out of argument registers and starts using the stack |
| ; O32-DAG: ldc1 [[F1:\$f[0-9]+]], 16($sp) |
| ; O32-DAG: sdc1 [[F1]], 24([[R2]]) |
| ; NEW-DAG: sdc1 $f14, 24([[R2]]) |
| ; O32-DAG: ldc1 [[F1:\$f[0-9]+]], 24($sp) |
| ; O32-DAG: sdc1 [[F1]], 32([[R2]]) |
| ; NEW-DAG: sdc1 $f15, 32([[R2]]) |
| ; O32-DAG: ldc1 [[F1:\$f[0-9]+]], 32($sp) |
| ; O32-DAG: sdc1 [[F1]], 40([[R2]]) |
| ; NEW-DAG: sdc1 $f16, 40([[R2]]) |
| ; O32-DAG: ldc1 [[F1:\$f[0-9]+]], 40($sp) |
| ; O32-DAG: sdc1 [[F1]], 48([[R2]]) |
| ; NEW-DAG: sdc1 $f17, 48([[R2]]) |
| ; O32-DAG: ldc1 [[F1:\$f[0-9]+]], 48($sp) |
| ; O32-DAG: sdc1 [[F1]], 56([[R2]]) |
| ; NEW-DAG: sdc1 $f18, 56([[R2]]) |
| ; O32-DAG: ldc1 [[F1:\$f[0-9]+]], 56($sp) |
| ; O32-DAG: sdc1 [[F1]], 64([[R2]]) |
| ; NEW-DAG: sdc1 $f19, 64([[R2]]) |
| |
| ; N32/N64 have run out of registers and start using the stack too |
| ; O32-DAG: ldc1 [[F1:\$f[0-9]+]], 64($sp) |
| ; O32-DAG: sdc1 [[F1]], 72([[R2]]) |
| ; NEW-DAG: ldc1 [[F1:\$f[0-9]+]], 0($sp) |
| ; NEW-DAG: sdc1 [[F1]], 72([[R2]]) |
| |
| define void @float_args(float %a, float %b, float %c, float %d, float %e, |
| float %f, float %g, float %h, float %i) nounwind { |
| entry: |
| %0 = getelementptr [11 x float], [11 x float]* @floats, i32 0, i32 1 |
| store volatile float %a, float* %0 |
| %1 = getelementptr [11 x float], [11 x float]* @floats, i32 0, i32 2 |
| store volatile float %b, float* %1 |
| %2 = getelementptr [11 x float], [11 x float]* @floats, i32 0, i32 3 |
| store volatile float %c, float* %2 |
| %3 = getelementptr [11 x float], [11 x float]* @floats, i32 0, i32 4 |
| store volatile float %d, float* %3 |
| %4 = getelementptr [11 x float], [11 x float]* @floats, i32 0, i32 5 |
| store volatile float %e, float* %4 |
| %5 = getelementptr [11 x float], [11 x float]* @floats, i32 0, i32 6 |
| store volatile float %f, float* %5 |
| %6 = getelementptr [11 x float], [11 x float]* @floats, i32 0, i32 7 |
| store volatile float %g, float* %6 |
| %7 = getelementptr [11 x float], [11 x float]* @floats, i32 0, i32 8 |
| store volatile float %h, float* %7 |
| %8 = getelementptr [11 x float], [11 x float]* @floats, i32 0, i32 9 |
| store volatile float %i, float* %8 |
| ret void |
| } |
| |
| ; ALL-LABEL: float_args: |
| ; We won't test the way the global address is calculated in this test. This is |
| ; just to get the register number for the other checks. |
| ; SYM32-DAG: addiu [[R1:\$[0-9]+]], ${{[0-9]+}}, %lo(floats) |
| ; SYM64-DAG: daddiu [[R1:\$[0-9]]], ${{[0-9]+}}, %lo(floats) |
| |
| ; The first argument is floating point so floating point registers are used. |
| ; The first argument is the same for O32/N32/N64 but the second argument differs |
| ; by register |
| ; ALL-DAG: swc1 $f12, 4([[R1]]) |
| ; O32-DAG: swc1 $f14, 8([[R1]]) |
| ; NEW-DAG: swc1 $f13, 8([[R1]]) |
| |
| ; O32 has run out of argument registers and (in theory) starts using the stack |
| ; I've yet to find a reference in the documentation about this but GCC uses up |
| ; the remaining two argument slots in the GPR's first. We'll do the same for |
| ; compatibility. |
| ; O32-DAG: sw $6, 12([[R1]]) |
| ; NEW-DAG: swc1 $f14, 12([[R1]]) |
| ; O32-DAG: sw $7, 16([[R1]]) |
| ; NEW-DAG: swc1 $f15, 16([[R1]]) |
| |
| ; O32 is definitely out of registers now and switches to the stack. |
| ; O32-DAG: lwc1 [[F1:\$f[0-9]+]], 16($sp) |
| ; O32-DAG: swc1 [[F1]], 20([[R1]]) |
| ; NEW-DAG: swc1 $f16, 20([[R1]]) |
| ; O32-DAG: lwc1 [[F1:\$f[0-9]+]], 20($sp) |
| ; O32-DAG: swc1 [[F1]], 24([[R1]]) |
| ; NEW-DAG: swc1 $f17, 24([[R1]]) |
| ; O32-DAG: lwc1 [[F1:\$f[0-9]+]], 24($sp) |
| ; O32-DAG: swc1 [[F1]], 28([[R1]]) |
| ; NEW-DAG: swc1 $f18, 28([[R1]]) |
| ; O32-DAG: lwc1 [[F1:\$f[0-9]+]], 28($sp) |
| ; O32-DAG: swc1 [[F1]], 32([[R1]]) |
| ; NEW-DAG: swc1 $f19, 32([[R1]]) |
| |
| ; N32/N64 have run out of registers and start using the stack too |
| ; O32-DAG: lwc1 [[F1:\$f[0-9]+]], 32($sp) |
| ; O32-DAG: swc1 [[F1]], 36([[R1]]) |
| ; NEW-DAG: lwc1 [[F1:\$f[0-9]+]], 0($sp) |
| ; NEW-DAG: swc1 [[F1]], 36([[R1]]) |
| |
| |
| define void @double_arg2(i8 %a, double %b) nounwind { |
| entry: |
| %0 = getelementptr [11 x i8], [11 x i8]* @bytes, i32 0, i32 1 |
| store volatile i8 %a, i8* %0 |
| %1 = getelementptr [11 x double], [11 x double]* @doubles, i32 0, i32 1 |
| store volatile double %b, double* %1 |
| ret void |
| } |
| |
| ; ALL-LABEL: double_arg2: |
| ; We won't test the way the global address is calculated in this test. This is |
| ; just to get the register number for the other checks. |
| ; SYM32-DAG: addiu [[R1:\$[0-9]+]], ${{[0-9]+}}, %lo(bytes) |
| ; SYM64-DAG: daddiu [[R1:\$[0-9]]], ${{[0-9]+}}, %lo(bytes) |
| ; SYM32-DAG: addiu [[R2:\$[0-9]+]], ${{[0-9]+}}, %lo(doubles) |
| ; SYM64-DAG: daddiu [[R2:\$[0-9]]], ${{[0-9]+}}, %lo(doubles) |
| |
| ; The first argument is the same in O32/N32/N64. |
| ; ALL-DAG: sb $4, 1([[R1]]) |
| |
| ; The first argument isn't floating point so floating point registers are not |
| ; used in O32, but N32/N64 will still use them. |
| ; The second slot is insufficiently aligned for double on O32 so it is skipped. |
| ; Also, double occupies two slots on O32 and only one for N32/N64. |
| ; O32LE-DAG: mtc1 $6, [[F1:\$f[0-9]*[02468]+]] |
| ; O32LE-DAG: mtc1 $7, [[F2:\$f[0-9]*[13579]+]] |
| ; O32BE-DAG: mtc1 $6, [[F2:\$f[0-9]*[13579]+]] |
| ; O32BE-DAG: mtc1 $7, [[F1:\$f[0-9]*[02468]+]] |
| ; O32-DAG: sdc1 [[F1]], 8([[R2]]) |
| ; NEW-DAG: sdc1 $f13, 8([[R2]]) |
| |
| define void @float_arg2(i8 %a, float %b) nounwind { |
| entry: |
| %0 = getelementptr [11 x i8], [11 x i8]* @bytes, i32 0, i32 1 |
| store volatile i8 %a, i8* %0 |
| %1 = getelementptr [11 x float], [11 x float]* @floats, i32 0, i32 1 |
| store volatile float %b, float* %1 |
| ret void |
| } |
| |
| ; ALL-LABEL: float_arg2: |
| ; We won't test the way the global address is calculated in this test. This is |
| ; just to get the register number for the other checks. |
| ; SYM32-DAG: addiu [[R1:\$[0-9]+]], ${{[0-9]+}}, %lo(bytes) |
| ; SYM64-DAG: daddiu [[R1:\$[0-9]]], ${{[0-9]+}}, %lo(bytes) |
| ; SYM32-DAG: addiu [[R2:\$[0-9]+]], ${{[0-9]+}}, %lo(floats) |
| ; SYM64-DAG: daddiu [[R2:\$[0-9]]], ${{[0-9]+}}, %lo(floats) |
| |
| ; The first argument is the same in O32/N32/N64. |
| ; ALL-DAG: sb $4, 1([[R1]]) |
| |
| ; The first argument isn't floating point so floating point registers are not |
| ; used in O32, but N32/N64 will still use them. |
| ; MD00305 and GCC disagree on this one. MD00305 says that floats are treated |
| ; as 8-byte aligned and occupy two slots on O32. GCC is treating them as 4-byte |
| ; aligned and occupying one slot. We'll use GCC's definition. |
| ; O32-DAG: sw $5, 4([[R2]]) |
| ; NEW-DAG: swc1 $f13, 4([[R2]]) |