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b56f4176cb
* Denested src folder to root, renamed testing to asmjit-testing
* Refactored how headers are included into <asmjit/...> form. This
is necessary as compilers would never simplify a path once a ..
appears in include directory - then paths such as ../core/../core
appeared in asserts, which was ugly
* Moved support utilities into asmjit/support/... (still included
by asmjit/core.h for convenience and compatibility)
* Added CMakePresets.json for making it easy to develop AsmJit
* Reworked CMakeLists to be shorter and use CMake option(),
etc... This simplifies it and makes it using more standard
features
* ASMJIT_EMBED now creates asmjit_embed INTERFACE library,
which is accessible via asmjit::asmjit target - this simplifies
embedding and makes it the same as library targets from a CMake
perspective
* Removed ASMJIT_DEPS - this is now provided by cmake target
aliases - 'asmjit::asmjit' so users should not need this variable
* Changed meaning of ASMJIT_LIBS - this now contains only AsmJit
dependencies without asmjit::asmjit target alias. Don't rely on
ASMJIT_LIBS anymore as it's only used internally
* Removed ASMJIT_NO_DEPRECATED option - AsmJit is not going
to provide controllable deprecations in the future
* Removed ASMJIT_NO_VALIDATION in favor of ASMJIT_NO_INTROSPECTION,
which now controls query, features, and validation API presence
* Removed ASMJIT_DIR option - it was never really needed
* Removed AMX_TRANSPOSE feature from instruction database (X86).
Intel has removed it as well, so it's a feature that won't
be siliconized
170 lines
5.5 KiB
C++
170 lines
5.5 KiB
C++
// This file is part of AsmJit project <https://asmjit.com>
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//
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// See <asmjit/core.h> or LICENSE.md for license and copyright information
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// SPDX-License-Identifier: Zlib
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// ----------------------------------------------------------------------------
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// This is a working example that demonstrates how multiple sections can be
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// used in a JIT-based code generator. It shows also the necessary tooling
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// that is expected to be done by the user when the feature is used. It's
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// important to handle the following cases:
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//
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// - Assign offsets to sections when the code generation is finished.
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// - Tell the CodeHolder to resolve unresolved fixups and check whether
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// all fixups were resolved.
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// - Relocate the code
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// - Copy the code to the destination address.
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// ----------------------------------------------------------------------------
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#include <asmjit/core.h>
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#if ASMJIT_ARCH_X86 && !defined(ASMJIT_NO_X86) && !defined(ASMJIT_NO_JIT)
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#include <asmjit/x86.h>
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#include <stdio.h>
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#include <stdlib.h>
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#include <string.h>
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using namespace asmjit;
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// The generated function is very simple, it only accesses the built-in data
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// (from .data section) at the index as provided by its first argument. This
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// data is inlined into the resulting function so we can use it this array
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// for verification that the function returns correct values.
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static const uint8_t data_array[] = { 2, 9, 4, 7, 1, 3, 8, 5, 6, 0 };
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static void fail(const char* message, Error err) {
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printf("** FAILURE: %s (%s) **\n", message, DebugUtils::error_as_string(err));
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exit(1);
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}
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int main() {
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printf("AsmJit X86 Sections Test\n\n");
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Environment env = Environment::host();
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JitAllocator allocator;
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#ifndef ASMJIT_NO_LOGGING
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FileLogger logger(stdout);
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logger.set_indentation(FormatIndentationGroup::kCode, 2);
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#endif
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CodeHolder code;
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code.init(env);
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#ifndef ASMJIT_NO_LOGGING
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code.set_logger(&logger);
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#endif
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Section* data_section;
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Error err = code.new_section(Out(data_section), ".data", SIZE_MAX, SectionFlags::kNone, 8);
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if (err != Error::kOk) {
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fail("Failed to create a .data section", err);
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}
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else {
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printf("Generating code:\n");
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x86::Assembler a(&code);
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x86::Gp idx = a.zax();
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x86::Gp addr = a.zcx();
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Label data = a.new_label();
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FuncDetail func;
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func.init(FuncSignature::build<size_t, size_t>(), code.environment());
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FuncFrame frame;
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frame.init(func);
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frame.add_dirty_regs(idx, addr);
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FuncArgsAssignment args(&func);
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args.assign_all(idx);
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args.update_func_frame(frame);
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frame.finalize();
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a.emit_prolog(frame);
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a.emit_args_assignment(frame, args);
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a.lea(addr, x86::ptr(data));
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a.movzx(idx, x86::byte_ptr(addr, idx));
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a.emit_epilog(frame);
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a.section(data_section);
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a.bind(data);
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a.embed(data_array, sizeof(data_array));
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}
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// Manually change he offsets of each section, start at 0. This code is very similar to
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// what `CodeHolder::flatten()` does, however, it's shown here how to do it explicitly.
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printf("\nCalculating section offsets:\n");
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uint64_t offset = 0;
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for (Section* section : code.sections_by_order()) {
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offset = Support::align_up(offset, section->alignment());
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section->set_offset(offset);
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offset += section->real_size();
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printf(" [0x%08X %s] {Id=%u Size=%u}\n",
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uint32_t(section->offset()),
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section->name(),
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section->section_id(),
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uint32_t(section->real_size()));
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}
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size_t code_size = size_t(offset);
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printf(" Final code size: %zu\n", code_size);
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// Resolve cross-section fixups (if any). On 32-bit X86 this is not necessary
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// as this is handled through relocations as the addressing is different.
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if (code.has_unresolved_fixups()) {
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printf("\nResolving cross-section fixups:\n");
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printf(" Before 'resolve_cross_section_fixups()': %zu\n", code.unresolved_fixup_count());
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err = code.resolve_cross_section_fixups();
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if (err != Error::kOk) {
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fail("Failed to resolve cross-section fixups", err);
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}
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printf(" After 'resolve_cross_section_fixups()': %zu\n", code.unresolved_fixup_count());
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}
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// Allocate memory for the function and relocate it there.
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JitAllocator::Span span;
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err = allocator.alloc(Out(span), code_size);
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if (err != Error::kOk)
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fail("Failed to allocate executable memory", err);
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// Relocate to the base-address of the allocated memory.
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code.relocate_to_base(uint64_t(uintptr_t(span.rx())));
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allocator.write(span, [&](JitAllocator::Span& span) noexcept -> Error {
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// Copy the flattened code into `mem.rw`. There are two ways. You can either copy
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// everything manually by iterating over all sections or use `copy_flattened_data`.
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// This code is similar to what `copy_flattened_data(p, code_size, 0)` would do:
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for (Section* section : code.sections_by_order())
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memcpy(static_cast<uint8_t*>(span.rw()) + size_t(section->offset()), section->data(), section->buffer_size());
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return Error::kOk;
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});
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// Execute the function and test whether it works.
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using Func = size_t (*)(size_t idx);
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Func fn = (Func)span.rx();
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printf("\n");
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if (fn(0) != data_array[0] ||
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fn(3) != data_array[3] ||
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fn(6) != data_array[6] ||
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fn(9) != data_array[9] ) {
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printf("** FAILURE: The generated function returned incorrect result(s) **\n");
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return 1;
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}
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printf("** SUCCESS **\n");
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return 0;
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}
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#else
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int main() {
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printf("!! This test is disabled: ASMJIT_NO_JIT or unsuitable target architecture !!\n\n");
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return 0;
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}
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#endif // ASMJIT_ARCH_X86 && !ASMJIT_NO_X86 && !ASMJIT_NO_JIT
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