h2-mod/deps/asmjit/test/asmjit_test_emitters.cpp
2024-03-07 03:33:59 -05:00

326 lines
9.5 KiB
C++

// This file is part of AsmJit project <https://asmjit.com>
//
// See asmjit.h or LICENSE.md for license and copyright information
// SPDX-License-Identifier: Zlib
#include <asmjit/core.h>
static void printInfo() noexcept {
printf("AsmJit Emitters Test-Suite v%u.%u.%u\n",
unsigned((ASMJIT_LIBRARY_VERSION >> 16) ),
unsigned((ASMJIT_LIBRARY_VERSION >> 8) & 0xFF),
unsigned((ASMJIT_LIBRARY_VERSION ) & 0xFF));
}
#if !defined(ASMJIT_NO_JIT) && ( \
(ASMJIT_ARCH_X86 != 0 && !defined(ASMJIT_NO_X86 )) || \
(ASMJIT_ARCH_ARM == 64 && !defined(ASMJIT_NO_AARCH64)) )
#if ASMJIT_ARCH_X86 != 0
#include <asmjit/x86.h>
#endif
#if ASMJIT_ARCH_ARM == 64
#include <asmjit/a64.h>
#endif
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
using namespace asmjit;
// Signature of the generated function.
typedef void (*SumIntsFunc)(int* dst, const int* a, const int* b);
// X86 Backend
// -----------
#if ASMJIT_ARCH_X86 != 0
// This function works with both x86::Assembler and x86::Builder. It shows how
// `x86::Emitter` can be used to make your code more generic.
static void generateFuncWithEmitter(x86::Emitter* emitter) noexcept {
// Decide which registers will be mapped to function arguments. Try changing
// registers of `dst`, `src_a`, and `src_b` and see what happens in function's
// prolog and epilog.
x86::Gp dst = emitter->zax();
x86::Gp src_a = emitter->zcx();
x86::Gp src_b = emitter->zdx();
// Decide which vector registers to use. We use these to keep the code generic,
// you can switch to any other registers when needed.
x86::Xmm vec0 = x86::xmm0;
x86::Xmm vec1 = x86::xmm1;
// Create and initialize `FuncDetail` and `FuncFrame`.
FuncDetail func;
func.init(FuncSignature::build<void, int*, const int*, const int*>(), emitter->environment());
FuncFrame frame;
frame.init(func);
// Make or registers dirty.
frame.addDirtyRegs(vec0, vec1);
FuncArgsAssignment args(&func); // Create arguments assignment context.
args.assignAll(dst, src_a, src_b); // Assign our registers to arguments.
args.updateFuncFrame(frame); // Reflect our args in FuncFrame.
frame.finalize();
// Emit prolog and allocate arguments to registers.
emitter->emitProlog(frame);
emitter->emitArgsAssignment(frame, args);
emitter->movdqu(vec0, x86::ptr(src_a)); // Load 4 ints from [src_a] to XMM0.
emitter->movdqu(vec1, x86::ptr(src_b)); // Load 4 ints from [src_b] to XMM1.
emitter->paddd(vec0, vec1); // Add 4 ints in XMM1 to XMM0.
emitter->movdqu(x86::ptr(dst), vec0); // Store the result to [dst].
// Emit epilog and return.
emitter->emitEpilog(frame);
}
#ifndef ASMJIT_NO_COMPILER
// This function works with x86::Compiler, provided for comparison.
static void generateFuncWithCompiler(x86::Compiler* cc) noexcept {
x86::Gp dst = cc->newIntPtr("dst");
x86::Gp src_a = cc->newIntPtr("src_a");
x86::Gp src_b = cc->newIntPtr("src_b");
x86::Xmm vec0 = cc->newXmm("vec0");
x86::Xmm vec1 = cc->newXmm("vec1");
FuncNode* funcNode = cc->addFunc(FuncSignature::build<void, int*, const int*, const int*>());
funcNode->setArg(0, dst);
funcNode->setArg(1, src_a);
funcNode->setArg(2, src_b);
cc->movdqu(vec0, x86::ptr(src_a));
cc->movdqu(vec1, x86::ptr(src_b));
cc->paddd(vec0, vec1);
cc->movdqu(x86::ptr(dst), vec0);
cc->endFunc();
}
#endif
static Error generateFunc(CodeHolder& code, EmitterType emitterType) noexcept {
switch (emitterType) {
case EmitterType::kAssembler: {
printf("Using x86::Assembler:\n");
x86::Assembler a(&code);
generateFuncWithEmitter(a.as<x86::Emitter>());
return kErrorOk;
}
#ifndef ASMJIT_NO_BUILDER
case EmitterType::kBuilder: {
printf("Using x86::Builder:\n");
x86::Builder cb(&code);
generateFuncWithEmitter(cb.as<x86::Emitter>());
return cb.finalize();
}
#endif
#ifndef ASMJIT_NO_COMPILER
case EmitterType::kCompiler: {
printf("Using x86::Compiler:\n");
x86::Compiler cc(&code);
generateFuncWithCompiler(&cc);
return cc.finalize();
}
#endif
default: {
printf("** FAILURE: No emitter to use **\n");
exit(1);
}
}
}
#endif
// AArch64 Backend
// ---------------
#if ASMJIT_ARCH_ARM == 64
// This function works with both a64::Assembler and a64::Builder. It shows how
// `a64::Emitter` can be used to make your code more generic.
static void generateFuncWithEmitter(a64::Emitter* emitter) noexcept {
// Decide which registers will be mapped to function arguments. Try changing
// registers of `dst`, `src_a`, and `src_b` and see what happens in function's
// prolog and epilog.
a64::Gp dst = a64::x0;
a64::Gp src_a = a64::x1;
a64::Gp src_b = a64::x2;
// Decide which vector registers to use. We use these to keep the code generic,
// you can switch to any other registers when needed.
a64::Vec vec0 = a64::v0;
a64::Vec vec1 = a64::v1;
a64::Vec vec2 = a64::v2;
// Create and initialize `FuncDetail` and `FuncFrame`.
FuncDetail func;
func.init(FuncSignature::build<void, int*, const int*, const int*>(), emitter->environment());
FuncFrame frame;
frame.init(func);
// Make XMM0 and XMM1 dirty. VEC group includes XMM|YMM|ZMM registers.
frame.addDirtyRegs(vec0, vec1, vec2);
FuncArgsAssignment args(&func); // Create arguments assignment context.
args.assignAll(dst, src_a, src_b); // Assign our registers to arguments.
args.updateFuncFrame(frame); // Reflect our args in FuncFrame.
frame.finalize();
// Emit prolog and allocate arguments to registers.
emitter->emitProlog(frame);
emitter->emitArgsAssignment(frame, args);
emitter->ld1(vec0.b16(), a64::ptr(src_a)); // Load 4 ints from [src_a] to vec0.
emitter->ld1(vec1.b16(), a64::ptr(src_b)); // Load 4 ints from [src_b] to vec1.
emitter->add(vec2.s4(), vec0.s4(), vec1.s4()); // Add 4 ints of vec0 and vec1 and store to vec2.
emitter->st1(vec2.b16(), a64::ptr(dst)); // Store the result (vec2) to [dst].
// Emit epilog and return.
emitter->emitEpilog(frame);
}
#ifndef ASMJIT_NO_COMPILER
// This function works with x86::Compiler, provided for comparison.
static void generateFuncWithCompiler(a64::Compiler* cc) noexcept {
a64::Gp dst = cc->newIntPtr("dst");
a64::Gp src_a = cc->newIntPtr("src_a");
a64::Gp src_b = cc->newIntPtr("src_b");
a64::Vec vec0 = cc->newVecQ("vec0");
a64::Vec vec1 = cc->newVecQ("vec1");
a64::Vec vec2 = cc->newVecQ("vec2");
FuncNode* funcNode = cc->addFunc(FuncSignature::build<void, int*, const int*, const int*>());
funcNode->setArg(0, dst);
funcNode->setArg(1, src_a);
funcNode->setArg(2, src_b);
cc->ld1(vec0.b16(), a64::ptr(src_a)); // Load 4 ints from [src_a] to vec0.
cc->ld1(vec1.b16(), a64::ptr(src_b)); // Load 4 ints from [src_b] to vec1.
cc->add(vec2.s4(), vec0.s4(), vec1.s4()); // Add 4 ints of vec0 and vec1 and store to vec2.
cc->st1(vec2.b16(), a64::ptr(dst)); // Store the result (vec2) to [dst].
cc->endFunc();
}
#endif
static Error generateFunc(CodeHolder& code, EmitterType emitterType) noexcept {
switch (emitterType) {
case EmitterType::kAssembler: {
printf("Using a64::Assembler:\n");
a64::Assembler a(&code);
generateFuncWithEmitter(a.as<a64::Emitter>());
return kErrorOk;
}
#ifndef ASMJIT_NO_BUILDER
case EmitterType::kBuilder: {
printf("Using a64::Builder:\n");
a64::Builder cb(&code);
generateFuncWithEmitter(cb.as<a64::Emitter>());
return cb.finalize();
}
#endif
#ifndef ASMJIT_NO_COMPILER
case EmitterType::kCompiler: {
printf("Using a64::Compiler:\n");
a64::Compiler cc(&code);
generateFuncWithCompiler(&cc);
return cc.finalize();
}
#endif
default: {
printf("** FAILURE: No emitter to use **\n");
exit(1);
}
}
}
#endif
// Testing
// -------
static uint32_t testFunc(JitRuntime& rt, EmitterType emitterType) noexcept {
#ifndef ASMJIT_NO_LOGGING
FileLogger logger(stdout);
logger.setIndentation(FormatIndentationGroup::kCode, 2);
#endif
CodeHolder code;
code.init(rt.environment(), rt.cpuFeatures());
#ifndef ASMJIT_NO_LOGGING
code.setLogger(&logger);
#endif
Error err = generateFunc(code, emitterType);
if (err) {
printf("** FAILURE: Failed to generate a function: %s **\n", DebugUtils::errorAsString(err));
return 1;
}
// Add the code generated to the runtime.
SumIntsFunc fn;
err = rt.add(&fn, &code);
if (err) {
printf("** FAILURE: JitRuntime::add() failed: %s **\n", DebugUtils::errorAsString(err));
return 1;
}
// Execute the generated function.
static const int inA[4] = { 4, 3, 2, 1 };
static const int inB[4] = { 1, 5, 2, 8 };
int out[4] {};
fn(out, inA, inB);
// Should print {5 8 4 9}.
printf("Result = { %d %d %d %d }\n\n", out[0], out[1], out[2], out[3]);
rt.release(fn);
return out[0] == 5 && out[1] == 8 && out[2] == 4 && out[3] == 9;
}
int main() {
printInfo();
printf("\n");
JitRuntime rt;
unsigned nFailed = 0;
nFailed += !testFunc(rt, EmitterType::kAssembler);
#ifndef ASMJIT_NO_BUILDER
nFailed += !testFunc(rt, EmitterType::kBuilder);
#endif
#ifndef ASMJIT_NO_COMPILER
nFailed += !testFunc(rt, EmitterType::kCompiler);
#endif
if (!nFailed)
printf("** SUCCESS **\n");
else
printf("** FAILURE - %u %s failed ** \n", nFailed, nFailed == 1 ? "test" : "tests");
return nFailed ? 1 : 0;
}
#else
int main() {
printInfo();
printf("\nThis test is currently disabled - no JIT or no support for the target architecture\n");
return 0;
}
#endif // ASMJIT_ARCH_X86 && !ASMJIT_NO_X86 && !ASMJIT_NO_JIT