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LeafOS / LeafOS-Project / android_art / 56fe25895e91d34a0a017429468829a20bdd5ae4 / . / compiler / utils / mips / assembler_mips32r6_test.cc
blob: 49ef272fb02a8071c8b9b652cbffb4c8026c823f [file] [log] [blame]
/*
* Copyright (C) 2016 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "assembler_mips.h"
#include <map>
#include "base/stl_util.h"
#include "utils/assembler_test.h"
#define __ GetAssembler()->
namespace art {
struct MIPSCpuRegisterCompare {
bool operator()(const mips::Register& a, const mips::Register& b) const {
return a < b;
}
};
class AssemblerMIPS32r6Test : public AssemblerTest<mips::MipsAssembler,
mips::Register,
mips::FRegister,
uint32_t> {
public:
typedef AssemblerTest<mips::MipsAssembler, mips::Register, mips::FRegister, uint32_t> Base;
AssemblerMIPS32r6Test() :
instruction_set_features_(MipsInstructionSetFeatures::FromVariant("mips32r6", nullptr)) {
}
protected:
// Get the typically used name for this architecture, e.g., aarch64, x86-64, ...
std::string GetArchitectureString() OVERRIDE {
return "mips";
}
std::string GetAssemblerCmdName() OVERRIDE {
// We assemble and link for MIPS32R6. See GetAssemblerParameters() for details.
return "gcc";
}
std::string GetAssemblerParameters() OVERRIDE {
// We assemble and link for MIPS32R6. The reason is that object files produced for MIPS32R6
// (and MIPS64R6) with the GNU assembler don't have correct final offsets in PC-relative
// branches in the .text section and so they require a relocation pass (there's a relocation
// section, .rela.text, that has the needed info to fix up the branches).
// We use "-modd-spreg" so we can use odd-numbered single precision FPU registers.
// We put the code at address 0x1000000 (instead of 0) to avoid overlapping with the
// .MIPS.abiflags section (there doesn't seem to be a way to suppress its generation easily).
return " -march=mips32r6 -modd-spreg -Wa,--no-warn"
" -Wl,-Ttext=0x1000000 -Wl,-e0x1000000 -nostdlib";
}
void Pad(std::vector<uint8_t>& data) OVERRIDE {
// The GNU linker unconditionally pads the code segment with NOPs to a size that is a multiple
// of 16 and there doesn't appear to be a way to suppress this padding. Our assembler doesn't
// pad, so, in order for two assembler outputs to match, we need to match the padding as well.
// NOP is encoded as four zero bytes on MIPS.
size_t pad_size = RoundUp(data.size(), 16u) - data.size();
data.insert(data.end(), pad_size, 0);
}
std::string GetDisassembleParameters() OVERRIDE {
return " -D -bbinary -mmips:isa32r6";
}
mips::MipsAssembler* CreateAssembler(ArenaAllocator* arena) OVERRIDE {
return new (arena) mips::MipsAssembler(arena, instruction_set_features_.get());
}
void SetUpHelpers() OVERRIDE {
if (registers_.size() == 0) {
registers_.push_back(new mips::Register(mips::ZERO));
registers_.push_back(new mips::Register(mips::AT));
registers_.push_back(new mips::Register(mips::V0));
registers_.push_back(new mips::Register(mips::V1));
registers_.push_back(new mips::Register(mips::A0));
registers_.push_back(new mips::Register(mips::A1));
registers_.push_back(new mips::Register(mips::A2));
registers_.push_back(new mips::Register(mips::A3));
registers_.push_back(new mips::Register(mips::T0));
registers_.push_back(new mips::Register(mips::T1));
registers_.push_back(new mips::Register(mips::T2));
registers_.push_back(new mips::Register(mips::T3));
registers_.push_back(new mips::Register(mips::T4));
registers_.push_back(new mips::Register(mips::T5));
registers_.push_back(new mips::Register(mips::T6));
registers_.push_back(new mips::Register(mips::T7));
registers_.push_back(new mips::Register(mips::S0));
registers_.push_back(new mips::Register(mips::S1));
registers_.push_back(new mips::Register(mips::S2));
registers_.push_back(new mips::Register(mips::S3));
registers_.push_back(new mips::Register(mips::S4));
registers_.push_back(new mips::Register(mips::S5));
registers_.push_back(new mips::Register(mips::S6));
registers_.push_back(new mips::Register(mips::S7));
registers_.push_back(new mips::Register(mips::T8));
registers_.push_back(new mips::Register(mips::T9));
registers_.push_back(new mips::Register(mips::K0));
registers_.push_back(new mips::Register(mips::K1));
registers_.push_back(new mips::Register(mips::GP));
registers_.push_back(new mips::Register(mips::SP));
registers_.push_back(new mips::Register(mips::FP));
registers_.push_back(new mips::Register(mips::RA));
secondary_register_names_.emplace(mips::Register(mips::ZERO), "zero");
secondary_register_names_.emplace(mips::Register(mips::AT), "at");
secondary_register_names_.emplace(mips::Register(mips::V0), "v0");
secondary_register_names_.emplace(mips::Register(mips::V1), "v1");
secondary_register_names_.emplace(mips::Register(mips::A0), "a0");
secondary_register_names_.emplace(mips::Register(mips::A1), "a1");
secondary_register_names_.emplace(mips::Register(mips::A2), "a2");
secondary_register_names_.emplace(mips::Register(mips::A3), "a3");
secondary_register_names_.emplace(mips::Register(mips::T0), "t0");
secondary_register_names_.emplace(mips::Register(mips::T1), "t1");
secondary_register_names_.emplace(mips::Register(mips::T2), "t2");
secondary_register_names_.emplace(mips::Register(mips::T3), "t3");
secondary_register_names_.emplace(mips::Register(mips::T4), "t4");
secondary_register_names_.emplace(mips::Register(mips::T5), "t5");
secondary_register_names_.emplace(mips::Register(mips::T6), "t6");
secondary_register_names_.emplace(mips::Register(mips::T7), "t7");
secondary_register_names_.emplace(mips::Register(mips::S0), "s0");
secondary_register_names_.emplace(mips::Register(mips::S1), "s1");
secondary_register_names_.emplace(mips::Register(mips::S2), "s2");
secondary_register_names_.emplace(mips::Register(mips::S3), "s3");
secondary_register_names_.emplace(mips::Register(mips::S4), "s4");
secondary_register_names_.emplace(mips::Register(mips::S5), "s5");
secondary_register_names_.emplace(mips::Register(mips::S6), "s6");
secondary_register_names_.emplace(mips::Register(mips::S7), "s7");
secondary_register_names_.emplace(mips::Register(mips::T8), "t8");
secondary_register_names_.emplace(mips::Register(mips::T9), "t9");
secondary_register_names_.emplace(mips::Register(mips::K0), "k0");
secondary_register_names_.emplace(mips::Register(mips::K1), "k1");
secondary_register_names_.emplace(mips::Register(mips::GP), "gp");
secondary_register_names_.emplace(mips::Register(mips::SP), "sp");
secondary_register_names_.emplace(mips::Register(mips::FP), "fp");
secondary_register_names_.emplace(mips::Register(mips::RA), "ra");
fp_registers_.push_back(new mips::FRegister(mips::F0));
fp_registers_.push_back(new mips::FRegister(mips::F1));
fp_registers_.push_back(new mips::FRegister(mips::F2));
fp_registers_.push_back(new mips::FRegister(mips::F3));
fp_registers_.push_back(new mips::FRegister(mips::F4));
fp_registers_.push_back(new mips::FRegister(mips::F5));
fp_registers_.push_back(new mips::FRegister(mips::F6));
fp_registers_.push_back(new mips::FRegister(mips::F7));
fp_registers_.push_back(new mips::FRegister(mips::F8));
fp_registers_.push_back(new mips::FRegister(mips::F9));
fp_registers_.push_back(new mips::FRegister(mips::F10));
fp_registers_.push_back(new mips::FRegister(mips::F11));
fp_registers_.push_back(new mips::FRegister(mips::F12));
fp_registers_.push_back(new mips::FRegister(mips::F13));
fp_registers_.push_back(new mips::FRegister(mips::F14));
fp_registers_.push_back(new mips::FRegister(mips::F15));
fp_registers_.push_back(new mips::FRegister(mips::F16));
fp_registers_.push_back(new mips::FRegister(mips::F17));
fp_registers_.push_back(new mips::FRegister(mips::F18));
fp_registers_.push_back(new mips::FRegister(mips::F19));
fp_registers_.push_back(new mips::FRegister(mips::F20));
fp_registers_.push_back(new mips::FRegister(mips::F21));
fp_registers_.push_back(new mips::FRegister(mips::F22));
fp_registers_.push_back(new mips::FRegister(mips::F23));
fp_registers_.push_back(new mips::FRegister(mips::F24));
fp_registers_.push_back(new mips::FRegister(mips::F25));
fp_registers_.push_back(new mips::FRegister(mips::F26));
fp_registers_.push_back(new mips::FRegister(mips::F27));
fp_registers_.push_back(new mips::FRegister(mips::F28));
fp_registers_.push_back(new mips::FRegister(mips::F29));
fp_registers_.push_back(new mips::FRegister(mips::F30));
fp_registers_.push_back(new mips::FRegister(mips::F31));
}
}
void TearDown() OVERRIDE {
AssemblerTest::TearDown();
STLDeleteElements(&registers_);
STLDeleteElements(&fp_registers_);
}
std::vector<mips::Register*> GetRegisters() OVERRIDE {
return registers_;
}
std::vector<mips::FRegister*> GetFPRegisters() OVERRIDE {
return fp_registers_;
}
uint32_t CreateImmediate(int64_t imm_value) OVERRIDE {
return imm_value;
}
std::string GetSecondaryRegisterName(const mips::Register& reg) OVERRIDE {
CHECK(secondary_register_names_.find(reg) != secondary_register_names_.end());
return secondary_register_names_[reg];
}
std::string RepeatInsn(size_t count, const std::string& insn) {
std::string result;
for (; count != 0u; --count) {
result += insn;
}
return result;
}
void BranchCondTwoRegsHelper(void (mips::MipsAssembler::*f)(mips::Register,
mips::Register,
mips::MipsLabel*),
std::string instr_name) {
mips::MipsLabel label;
(Base::GetAssembler()->*f)(mips::A0, mips::A1, &label);
constexpr size_t kAdduCount1 = 63;
for (size_t i = 0; i != kAdduCount1; ++i) {
__ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
}
__ Bind(&label);
constexpr size_t kAdduCount2 = 64;
for (size_t i = 0; i != kAdduCount2; ++i) {
__ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
}
(Base::GetAssembler()->*f)(mips::A2, mips::A3, &label);
std::string expected =
".set noreorder\n" +
instr_name + " $a0, $a1, 1f\n"
"nop\n" +
RepeatInsn(kAdduCount1, "addu $zero, $zero, $zero\n") +
"1:\n" +
RepeatInsn(kAdduCount2, "addu $zero, $zero, $zero\n") +
instr_name + " $a2, $a3, 1b\n"
"nop\n";
DriverStr(expected, instr_name);
}
private:
std::vector<mips::Register*> registers_;
std::map<mips::Register, std::string, MIPSCpuRegisterCompare> secondary_register_names_;
std::vector<mips::FRegister*> fp_registers_;
std::unique_ptr<const MipsInstructionSetFeatures> instruction_set_features_;
};
TEST_F(AssemblerMIPS32r6Test, Toolchain) {
EXPECT_TRUE(CheckTools());
}
TEST_F(AssemblerMIPS32r6Test, MulR6) {
DriverStr(RepeatRRR(&mips::MipsAssembler::MulR6, "mul ${reg1}, ${reg2}, ${reg3}"), "MulR6");
}
TEST_F(AssemblerMIPS32r6Test, MuhR6) {
DriverStr(RepeatRRR(&mips::MipsAssembler::MuhR6, "muh ${reg1}, ${reg2}, ${reg3}"), "MuhR6");
}
TEST_F(AssemblerMIPS32r6Test, MuhuR6) {
DriverStr(RepeatRRR(&mips::MipsAssembler::MuhuR6, "muhu ${reg1}, ${reg2}, ${reg3}"), "MuhuR6");
}
TEST_F(AssemblerMIPS32r6Test, DivR6) {
DriverStr(RepeatRRR(&mips::MipsAssembler::DivR6, "div ${reg1}, ${reg2}, ${reg3}"), "DivR6");
}
TEST_F(AssemblerMIPS32r6Test, ModR6) {
DriverStr(RepeatRRR(&mips::MipsAssembler::ModR6, "mod ${reg1}, ${reg2}, ${reg3}"), "ModR6");
}
TEST_F(AssemblerMIPS32r6Test, DivuR6) {
DriverStr(RepeatRRR(&mips::MipsAssembler::DivuR6, "divu ${reg1}, ${reg2}, ${reg3}"), "DivuR6");
}
TEST_F(AssemblerMIPS32r6Test, ModuR6) {
DriverStr(RepeatRRR(&mips::MipsAssembler::ModuR6, "modu ${reg1}, ${reg2}, ${reg3}"), "ModuR6");
}
//////////
// MISC //
//////////
TEST_F(AssemblerMIPS32r6Test, Aui) {
DriverStr(RepeatRRIb(&mips::MipsAssembler::Aui, 16, "aui ${reg1}, ${reg2}, {imm}"), "Aui");
}
TEST_F(AssemblerMIPS32r6Test, Auipc) {
DriverStr(RepeatRIb(&mips::MipsAssembler::Auipc, 16, "auipc ${reg}, {imm}"), "Auipc");
}
TEST_F(AssemblerMIPS32r6Test, Lwpc) {
// Lwpc() takes an unsigned 19-bit immediate, while the GNU assembler needs a signed offset,
// hence the sign extension from bit 18 with `imm - ((imm & 0x40000) << 1)`.
// The GNU assembler also wants the offset to be a multiple of 4, which it will shift right
// by 2 positions when encoding, hence `<< 2` to compensate for that shift.
// We capture the value of the immediate with `.set imm, {imm}` because the value is needed
// twice for the sign extension, but `{imm}` is substituted only once.
const char* code = ".set imm, {imm}\nlw ${reg}, ((imm - ((imm & 0x40000) << 1)) << 2)($pc)";
DriverStr(RepeatRIb(&mips::MipsAssembler::Lwpc, 19, code), "Lwpc");
}
TEST_F(AssemblerMIPS32r6Test, Bitswap) {
DriverStr(RepeatRR(&mips::MipsAssembler::Bitswap, "bitswap ${reg1}, ${reg2}"), "bitswap");
}
TEST_F(AssemblerMIPS32r6Test, Seleqz) {
DriverStr(RepeatRRR(&mips::MipsAssembler::Seleqz, "seleqz ${reg1}, ${reg2}, ${reg3}"),
"seleqz");
}
TEST_F(AssemblerMIPS32r6Test, Selnez) {
DriverStr(RepeatRRR(&mips::MipsAssembler::Selnez, "selnez ${reg1}, ${reg2}, ${reg3}"),
"selnez");
}
TEST_F(AssemblerMIPS32r6Test, ClzR6) {
DriverStr(RepeatRR(&mips::MipsAssembler::ClzR6, "clz ${reg1}, ${reg2}"), "clzR6");
}
TEST_F(AssemblerMIPS32r6Test, CloR6) {
DriverStr(RepeatRR(&mips::MipsAssembler::CloR6, "clo ${reg1}, ${reg2}"), "cloR6");
}
////////////////////
// FLOATING POINT //
////////////////////
TEST_F(AssemblerMIPS32r6Test, SelS) {
DriverStr(RepeatFFF(&mips::MipsAssembler::SelS, "sel.s ${reg1}, ${reg2}, ${reg3}"), "sel.s");
}
TEST_F(AssemblerMIPS32r6Test, SelD) {
DriverStr(RepeatFFF(&mips::MipsAssembler::SelD, "sel.d ${reg1}, ${reg2}, ${reg3}"), "sel.d");
}
TEST_F(AssemblerMIPS32r6Test, ClassS) {
DriverStr(RepeatFF(&mips::MipsAssembler::ClassS, "class.s ${reg1}, ${reg2}"), "class.s");
}
TEST_F(AssemblerMIPS32r6Test, ClassD) {
DriverStr(RepeatFF(&mips::MipsAssembler::ClassD, "class.d ${reg1}, ${reg2}"), "class.d");
}
TEST_F(AssemblerMIPS32r6Test, MinS) {
DriverStr(RepeatFFF(&mips::MipsAssembler::MinS, "min.s ${reg1}, ${reg2}, ${reg3}"), "min.s");
}
TEST_F(AssemblerMIPS32r6Test, MinD) {
DriverStr(RepeatFFF(&mips::MipsAssembler::MinD, "min.d ${reg1}, ${reg2}, ${reg3}"), "min.d");
}
TEST_F(AssemblerMIPS32r6Test, MaxS) {
DriverStr(RepeatFFF(&mips::MipsAssembler::MaxS, "max.s ${reg1}, ${reg2}, ${reg3}"), "max.s");
}
TEST_F(AssemblerMIPS32r6Test, MaxD) {
DriverStr(RepeatFFF(&mips::MipsAssembler::MaxD, "max.d ${reg1}, ${reg2}, ${reg3}"), "max.d");
}
TEST_F(AssemblerMIPS32r6Test, CmpUnS) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpUnS, "cmp.un.s ${reg1}, ${reg2}, ${reg3}"),
"cmp.un.s");
}
TEST_F(AssemblerMIPS32r6Test, CmpEqS) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpEqS, "cmp.eq.s ${reg1}, ${reg2}, ${reg3}"),
"cmp.eq.s");
}
TEST_F(AssemblerMIPS32r6Test, CmpUeqS) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpUeqS, "cmp.ueq.s ${reg1}, ${reg2}, ${reg3}"),
"cmp.ueq.s");
}
TEST_F(AssemblerMIPS32r6Test, CmpLtS) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpLtS, "cmp.lt.s ${reg1}, ${reg2}, ${reg3}"),
"cmp.lt.s");
}
TEST_F(AssemblerMIPS32r6Test, CmpUltS) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpUltS, "cmp.ult.s ${reg1}, ${reg2}, ${reg3}"),
"cmp.ult.s");
}
TEST_F(AssemblerMIPS32r6Test, CmpLeS) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpLeS, "cmp.le.s ${reg1}, ${reg2}, ${reg3}"),
"cmp.le.s");
}
TEST_F(AssemblerMIPS32r6Test, CmpUleS) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpUleS, "cmp.ule.s ${reg1}, ${reg2}, ${reg3}"),
"cmp.ule.s");
}
TEST_F(AssemblerMIPS32r6Test, CmpOrS) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpOrS, "cmp.or.s ${reg1}, ${reg2}, ${reg3}"),
"cmp.or.s");
}
TEST_F(AssemblerMIPS32r6Test, CmpUneS) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpUneS, "cmp.une.s ${reg1}, ${reg2}, ${reg3}"),
"cmp.une.s");
}
TEST_F(AssemblerMIPS32r6Test, CmpNeS) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpNeS, "cmp.ne.s ${reg1}, ${reg2}, ${reg3}"),
"cmp.ne.s");
}
TEST_F(AssemblerMIPS32r6Test, CmpUnD) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpUnD, "cmp.un.d ${reg1}, ${reg2}, ${reg3}"),
"cmp.un.d");
}
TEST_F(AssemblerMIPS32r6Test, CmpEqD) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpEqD, "cmp.eq.d ${reg1}, ${reg2}, ${reg3}"),
"cmp.eq.d");
}
TEST_F(AssemblerMIPS32r6Test, CmpUeqD) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpUeqD, "cmp.ueq.d ${reg1}, ${reg2}, ${reg3}"),
"cmp.ueq.d");
}
TEST_F(AssemblerMIPS32r6Test, CmpLtD) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpLtD, "cmp.lt.d ${reg1}, ${reg2}, ${reg3}"),
"cmp.lt.d");
}
TEST_F(AssemblerMIPS32r6Test, CmpUltD) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpUltD, "cmp.ult.d ${reg1}, ${reg2}, ${reg3}"),
"cmp.ult.d");
}
TEST_F(AssemblerMIPS32r6Test, CmpLeD) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpLeD, "cmp.le.d ${reg1}, ${reg2}, ${reg3}"),
"cmp.le.d");
}
TEST_F(AssemblerMIPS32r6Test, CmpUleD) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpUleD, "cmp.ule.d ${reg1}, ${reg2}, ${reg3}"),
"cmp.ule.d");
}
TEST_F(AssemblerMIPS32r6Test, CmpOrD) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpOrD, "cmp.or.d ${reg1}, ${reg2}, ${reg3}"),
"cmp.or.d");
}
TEST_F(AssemblerMIPS32r6Test, CmpUneD) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpUneD, "cmp.une.d ${reg1}, ${reg2}, ${reg3}"),
"cmp.une.d");
}
TEST_F(AssemblerMIPS32r6Test, CmpNeD) {
DriverStr(RepeatFFF(&mips::MipsAssembler::CmpNeD, "cmp.ne.d ${reg1}, ${reg2}, ${reg3}"),
"cmp.ne.d");
}
TEST_F(AssemblerMIPS32r6Test, LoadDFromOffset) {
__ LoadDFromOffset(mips::F0, mips::A0, -0x8000);
__ LoadDFromOffset(mips::F0, mips::A0, +0);
__ LoadDFromOffset(mips::F0, mips::A0, +0x7FF8);
__ LoadDFromOffset(mips::F0, mips::A0, +0x7FFB);
__ LoadDFromOffset(mips::F0, mips::A0, +0x7FFC);
__ LoadDFromOffset(mips::F0, mips::A0, +0x7FFF);
__ LoadDFromOffset(mips::F0, mips::A0, -0xFFF0);
__ LoadDFromOffset(mips::F0, mips::A0, -0x8008);
__ LoadDFromOffset(mips::F0, mips::A0, -0x8001);
__ LoadDFromOffset(mips::F0, mips::A0, +0x8000);
__ LoadDFromOffset(mips::F0, mips::A0, +0xFFF0);
__ LoadDFromOffset(mips::F0, mips::A0, -0x17FE8);
__ LoadDFromOffset(mips::F0, mips::A0, -0x0FFF8);
__ LoadDFromOffset(mips::F0, mips::A0, -0x0FFF1);
__ LoadDFromOffset(mips::F0, mips::A0, +0x0FFF1);
__ LoadDFromOffset(mips::F0, mips::A0, +0x0FFF8);
__ LoadDFromOffset(mips::F0, mips::A0, +0x17FE8);
__ LoadDFromOffset(mips::F0, mips::A0, -0x17FF0);
__ LoadDFromOffset(mips::F0, mips::A0, -0x17FE9);
__ LoadDFromOffset(mips::F0, mips::A0, +0x17FE9);
__ LoadDFromOffset(mips::F0, mips::A0, +0x17FF0);
__ LoadDFromOffset(mips::F0, mips::A0, +0x12345678);
const char* expected =
"ldc1 $f0, -0x8000($a0)\n"
"ldc1 $f0, 0($a0)\n"
"ldc1 $f0, 0x7FF8($a0)\n"
"lwc1 $f0, 0x7FFB($a0)\n"
"lw $t8, 0x7FFF($a0)\n"
"mthc1 $t8, $f0\n"
"addiu $at, $a0, 0x7FF8\n"
"lwc1 $f0, 4($at)\n"
"lw $t8, 8($at)\n"
"mthc1 $t8, $f0\n"
"addiu $at, $a0, 0x7FF8\n"
"lwc1 $f0, 7($at)\n"
"lw $t8, 11($at)\n"
"mthc1 $t8, $f0\n"
"addiu $at, $a0, -0x7FF8\n"
"ldc1 $f0, -0x7FF8($at)\n"
"addiu $at, $a0, -0x7FF8\n"
"ldc1 $f0, -0x10($at)\n"
"addiu $at, $a0, -0x7FF8\n"
"lwc1 $f0, -9($at)\n"
"lw $t8, -5($at)\n"
"mthc1 $t8, $f0\n"
"addiu $at, $a0, 0x7FF8\n"
"ldc1 $f0, 8($at)\n"
"addiu $at, $a0, 0x7FF8\n"
"ldc1 $f0, 0x7FF8($at)\n"
"aui $at, $a0, 0xFFFF\n"
"ldc1 $f0, -0x7FE8($at)\n"
"aui $at, $a0, 0xFFFF\n"
"ldc1 $f0, 0x8($at)\n"
"aui $at, $a0, 0xFFFF\n"
"lwc1 $f0, 0xF($at)\n"
"lw $t8, 0x13($at)\n"
"mthc1 $t8, $f0\n"
"aui $at, $a0, 0x1\n"
"lwc1 $f0, -0xF($at)\n"
"lw $t8, -0xB($at)\n"
"mthc1 $t8, $f0\n"
"aui $at, $a0, 0x1\n"
"ldc1 $f0, -0x8($at)\n"
"aui $at, $a0, 0x1\n"
"ldc1 $f0, 0x7FE8($at)\n"
"aui $at, $a0, 0xFFFF\n"
"ldc1 $f0, -0x7FF0($at)\n"
"aui $at, $a0, 0xFFFF\n"
"lwc1 $f0, -0x7FE9($at)\n"
"lw $t8, -0x7FE5($at)\n"
"mthc1 $t8, $f0\n"
"aui $at, $a0, 0x1\n"
"lwc1 $f0, 0x7FE9($at)\n"
"lw $t8, 0x7FED($at)\n"
"mthc1 $t8, $f0\n"
"aui $at, $a0, 0x1\n"
"ldc1 $f0, 0x7FF0($at)\n"
"aui $at, $a0, 0x1234\n"
"ldc1 $f0, 0x5678($at)\n";
DriverStr(expected, "LoadDFromOffset");
}
TEST_F(AssemblerMIPS32r6Test, StoreDToOffset) {
__ StoreDToOffset(mips::F0, mips::A0, -0x8000);
__ StoreDToOffset(mips::F0, mips::A0, +0);
__ StoreDToOffset(mips::F0, mips::A0, +0x7FF8);
__ StoreDToOffset(mips::F0, mips::A0, +0x7FFB);
__ StoreDToOffset(mips::F0, mips::A0, +0x7FFC);
__ StoreDToOffset(mips::F0, mips::A0, +0x7FFF);
__ StoreDToOffset(mips::F0, mips::A0, -0xFFF0);
__ StoreDToOffset(mips::F0, mips::A0, -0x8008);
__ StoreDToOffset(mips::F0, mips::A0, -0x8001);
__ StoreDToOffset(mips::F0, mips::A0, +0x8000);
__ StoreDToOffset(mips::F0, mips::A0, +0xFFF0);
__ StoreDToOffset(mips::F0, mips::A0, -0x17FE8);
__ StoreDToOffset(mips::F0, mips::A0, -0x0FFF8);
__ StoreDToOffset(mips::F0, mips::A0, -0x0FFF1);
__ StoreDToOffset(mips::F0, mips::A0, +0x0FFF1);
__ StoreDToOffset(mips::F0, mips::A0, +0x0FFF8);
__ StoreDToOffset(mips::F0, mips::A0, +0x17FE8);
__ StoreDToOffset(mips::F0, mips::A0, -0x17FF0);
__ StoreDToOffset(mips::F0, mips::A0, -0x17FE9);
__ StoreDToOffset(mips::F0, mips::A0, +0x17FE9);
__ StoreDToOffset(mips::F0, mips::A0, +0x17FF0);
__ StoreDToOffset(mips::F0, mips::A0, +0x12345678);
const char* expected =
"sdc1 $f0, -0x8000($a0)\n"
"sdc1 $f0, 0($a0)\n"
"sdc1 $f0, 0x7FF8($a0)\n"
"mfhc1 $t8, $f0\n"
"swc1 $f0, 0x7FFB($a0)\n"
"sw $t8, 0x7FFF($a0)\n"
"addiu $at, $a0, 0x7FF8\n"
"mfhc1 $t8, $f0\n"
"swc1 $f0, 4($at)\n"
"sw $t8, 8($at)\n"
"addiu $at, $a0, 0x7FF8\n"
"mfhc1 $t8, $f0\n"
"swc1 $f0, 7($at)\n"
"sw $t8, 11($at)\n"
"addiu $at, $a0, -0x7FF8\n"
"sdc1 $f0, -0x7FF8($at)\n"
"addiu $at, $a0, -0x7FF8\n"
"sdc1 $f0, -0x10($at)\n"
"addiu $at, $a0, -0x7FF8\n"
"mfhc1 $t8, $f0\n"
"swc1 $f0, -9($at)\n"
"sw $t8, -5($at)\n"
"addiu $at, $a0, 0x7FF8\n"
"sdc1 $f0, 8($at)\n"
"addiu $at, $a0, 0x7FF8\n"
"sdc1 $f0, 0x7FF8($at)\n"
"aui $at, $a0, 0xFFFF\n"
"sdc1 $f0, -0x7FE8($at)\n"
"aui $at, $a0, 0xFFFF\n"
"sdc1 $f0, 0x8($at)\n"
"aui $at, $a0, 0xFFFF\n"
"mfhc1 $t8, $f0\n"
"swc1 $f0, 0xF($at)\n"
"sw $t8, 0x13($at)\n"
"aui $at, $a0, 0x1\n"
"mfhc1 $t8, $f0\n"
"swc1 $f0, -0xF($at)\n"
"sw $t8, -0xB($at)\n"
"aui $at, $a0, 0x1\n"
"sdc1 $f0, -0x8($at)\n"
"aui $at, $a0, 0x1\n"
"sdc1 $f0, 0x7FE8($at)\n"
"aui $at, $a0, 0xFFFF\n"
"sdc1 $f0, -0x7FF0($at)\n"
"aui $at, $a0, 0xFFFF\n"
"mfhc1 $t8, $f0\n"
"swc1 $f0, -0x7FE9($at)\n"
"sw $t8, -0x7FE5($at)\n"
"aui $at, $a0, 0x1\n"
"mfhc1 $t8, $f0\n"
"swc1 $f0, 0x7FE9($at)\n"
"sw $t8, 0x7FED($at)\n"
"aui $at, $a0, 0x1\n"
"sdc1 $f0, 0x7FF0($at)\n"
"aui $at, $a0, 0x1234\n"
"sdc1 $f0, 0x5678($at)\n";
DriverStr(expected, "StoreDToOffset");
}
TEST_F(AssemblerMIPS32r6Test, LoadFarthestNearLiteral) {
mips::Literal* literal = __ NewLiteral<uint32_t>(0x12345678);
__ LoadLiteral(mips::V0, mips::ZERO, literal);
constexpr size_t kAdduCount = 0x3FFDE;
for (size_t i = 0; i != kAdduCount; ++i) {
__ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
}
std::string expected =
"lwpc $v0, 1f\n" +
RepeatInsn(kAdduCount, "addu $zero, $zero, $zero\n") +
"1:\n"
".word 0x12345678\n";
DriverStr(expected, "LoadFarthestNearLiteral");
}
TEST_F(AssemblerMIPS32r6Test, LoadNearestFarLiteral) {
mips::Literal* literal = __ NewLiteral<uint32_t>(0x12345678);
__ LoadLiteral(mips::V0, mips::ZERO, literal);
constexpr size_t kAdduCount = 0x3FFDF;
for (size_t i = 0; i != kAdduCount; ++i) {
__ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
}
std::string expected =
"1:\n"
"auipc $at, %hi(2f - 1b)\n"
"lw $v0, %lo(2f - 1b)($at)\n" +
RepeatInsn(kAdduCount, "addu $zero, $zero, $zero\n") +
"2:\n"
".word 0x12345678\n";
DriverStr(expected, "LoadNearestFarLiteral");
}
//////////////
// BRANCHES //
//////////////
// TODO: MipsAssembler::Addiupc
// MipsAssembler::Bc
// MipsAssembler::Jic
// MipsAssembler::Jialc
// MipsAssembler::Bltc
// MipsAssembler::Bltzc
// MipsAssembler::Bgtzc
// MipsAssembler::Bgec
// MipsAssembler::Bgezc
// MipsAssembler::Blezc
// MipsAssembler::Bltuc
// MipsAssembler::Bgeuc
// MipsAssembler::Beqc
// MipsAssembler::Bnec
// MipsAssembler::Beqzc
// MipsAssembler::Bnezc
// MipsAssembler::Bc1eqz
// MipsAssembler::Bc1nez
// MipsAssembler::Buncond
// MipsAssembler::Bcond
// MipsAssembler::Call
// TODO: AssemblerMIPS32r6Test.B
// AssemblerMIPS32r6Test.Beq
// AssemblerMIPS32r6Test.Bne
// AssemblerMIPS32r6Test.Beqz
// AssemblerMIPS32r6Test.Bnez
// AssemblerMIPS32r6Test.Bltz
// AssemblerMIPS32r6Test.Bgez
// AssemblerMIPS32r6Test.Blez
// AssemblerMIPS32r6Test.Bgtz
// AssemblerMIPS32r6Test.Blt
// AssemblerMIPS32r6Test.Bge
// AssemblerMIPS32r6Test.Bltu
// AssemblerMIPS32r6Test.Bgeu
#undef __
} // namespace art