Files
clang-p2996/llvm/examples/OrcV2Examples/OrcV2CBindingsReflectProcessSymbols/OrcV2CBindingsReflectProcessSymbols.c
Lang Hames f35707047e [ORC] Break up C-API header Orc.h, and add JITEventListener support.
This patch breaks Orc.h up into Orc.h, LLJIT.h and OrcEE.h.

Orc.h contain core Orc utilities.
LLJIT.h contains LLJIT specific types and functions.
OrcEE.h contains types and functions that depend on ExecutionEngine.

The intent is that these headers should match future library divisions: Clients
who only use Orc.h should only need to link againt the Orc core libraries,
clients using LLJIT.h will also need to link against LLVM core, and clients
using OrcEE.h will also have to link against ExecutionEngine.

In addition to breaking up the Orc.h header this patch introduces functions to:
(1) Set the object linking layer creation function on LLJITBuilder.
(2) Create an RTDyldObjectLinkingLayer instance (particularly for use in (1)).
(3) Register JITEventListeners with an RTDyldObjectLinkingLayer.

Together (1), (2) and (3) can be used to force use of RTDyldObjectLinkingLayer
as the underlying JIT linker for LLJIT, rather than the platform default, and
to register event listeners with the RTDyldObjectLinkingLayer.
2020-10-19 01:59:04 -07:00

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7.2 KiB
C

//===-------- BasicOrcV2CBindings.c - Basic OrcV2 C Bindings Demo ---------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#include "llvm-c/Core.h"
#include "llvm-c/Error.h"
#include "llvm-c/Initialization.h"
#include "llvm-c/LLJIT.h"
#include "llvm-c/Support.h"
#include "llvm-c/Target.h"
#include <assert.h>
#include <stdio.h>
int handleError(LLVMErrorRef Err) {
char *ErrMsg = LLVMGetErrorMessage(Err);
fprintf(stderr, "Error: %s\n", ErrMsg);
LLVMDisposeErrorMessage(ErrMsg);
return 1;
}
int32_t add(int32_t X, int32_t Y) { return X + Y; }
int32_t mul(int32_t X, int32_t Y) { return X * Y; }
int allowedSymbols(void *Ctx, LLVMOrcSymbolStringPoolEntryRef Sym) {
assert(Ctx && "Cannot call allowedSymbols with a null context");
LLVMOrcSymbolStringPoolEntryRef *AllowList =
(LLVMOrcSymbolStringPoolEntryRef *)Ctx;
// If Sym appears in the allowed list then return true.
LLVMOrcSymbolStringPoolEntryRef *P = AllowList;
while (*P) {
if (Sym == *P)
return 1;
++P;
}
// otherwise return false.
return 0;
}
LLVMOrcThreadSafeModuleRef createDemoModule() {
// Create a new ThreadSafeContext and underlying LLVMContext.
LLVMOrcThreadSafeContextRef TSCtx = LLVMOrcCreateNewThreadSafeContext();
// Get a reference to the underlying LLVMContext.
LLVMContextRef Ctx = LLVMOrcThreadSafeContextGetContext(TSCtx);
// Create a new LLVM module.
LLVMModuleRef M = LLVMModuleCreateWithNameInContext("demo", Ctx);
// Add a "sum" function":
// - Create the function type and function instance.
LLVMTypeRef I32BinOpParamTypes[] = {LLVMInt32Type(), LLVMInt32Type()};
LLVMTypeRef I32BinOpFunctionType =
LLVMFunctionType(LLVMInt32Type(), I32BinOpParamTypes, 2, 0);
LLVMValueRef AddI32Function = LLVMAddFunction(M, "add", I32BinOpFunctionType);
LLVMValueRef MulI32Function = LLVMAddFunction(M, "mul", I32BinOpFunctionType);
LLVMTypeRef MulAddParamTypes[] = {LLVMInt32Type(), LLVMInt32Type(),
LLVMInt32Type()};
LLVMTypeRef MulAddFunctionType =
LLVMFunctionType(LLVMInt32Type(), MulAddParamTypes, 3, 0);
LLVMValueRef MulAddFunction =
LLVMAddFunction(M, "mul_add", MulAddFunctionType);
// - Add a basic block to the function.
LLVMBasicBlockRef EntryBB = LLVMAppendBasicBlock(MulAddFunction, "entry");
// - Add an IR builder and point it at the end of the basic block.
LLVMBuilderRef Builder = LLVMCreateBuilder();
LLVMPositionBuilderAtEnd(Builder, EntryBB);
// - Get the three function arguments and use them co construct calls to
// 'mul' and 'add':
//
// i32 mul_add(i32 %0, i32 %1, i32 %2) {
// %t = call i32 @mul(i32 %0, i32 %1)
// %r = call i32 @add(i32 %t, i32 %2)
// ret i32 %r
// }
LLVMValueRef SumArg0 = LLVMGetParam(MulAddFunction, 0);
LLVMValueRef SumArg1 = LLVMGetParam(MulAddFunction, 1);
LLVMValueRef SumArg2 = LLVMGetParam(MulAddFunction, 2);
LLVMValueRef MulArgs[] = {SumArg0, SumArg1};
LLVMValueRef MulResult = LLVMBuildCall2(Builder, I32BinOpFunctionType,
MulI32Function, MulArgs, 2, "t");
LLVMValueRef AddArgs[] = {MulResult, SumArg2};
LLVMValueRef AddResult = LLVMBuildCall2(Builder, I32BinOpFunctionType,
AddI32Function, AddArgs, 2, "r");
// - Build the return instruction.
LLVMBuildRet(Builder, AddResult);
// Our demo module is now complete. Wrap it and our ThreadSafeContext in a
// ThreadSafeModule.
LLVMOrcThreadSafeModuleRef TSM = LLVMOrcCreateNewThreadSafeModule(M, TSCtx);
// Dispose of our local ThreadSafeContext value. The underlying LLVMContext
// will be kept alive by our ThreadSafeModule, TSM.
LLVMOrcDisposeThreadSafeContext(TSCtx);
// Return the result.
return TSM;
}
int main(int argc, char *argv[]) {
int MainResult = 0;
// Parse command line arguments and initialize LLVM Core.
LLVMParseCommandLineOptions(argc, (const char **)argv, "");
LLVMInitializeCore(LLVMGetGlobalPassRegistry());
// Initialize native target codegen and asm printer.
LLVMInitializeNativeTarget();
LLVMInitializeNativeAsmPrinter();
// Create the JIT instance.
LLVMOrcLLJITRef J;
{
LLVMErrorRef Err;
if ((Err = LLVMOrcCreateLLJIT(&J, 0))) {
MainResult = handleError(Err);
goto llvm_shutdown;
}
}
// Build a filter to allow JIT'd code to only access allowed symbols.
// This filter is optional: If a null value is suppled for the Filter
// argument to LLVMOrcCreateDynamicLibrarySearchGeneratorForProcess then
// all process symbols will be reflected.
LLVMOrcSymbolStringPoolEntryRef AllowList[] = {
LLVMOrcLLJITMangleAndIntern(J, "mul"),
LLVMOrcLLJITMangleAndIntern(J, "add"), 0};
{
LLVMOrcDefinitionGeneratorRef ProcessSymbolsGenerator = 0;
LLVMErrorRef Err;
if ((Err = LLVMOrcCreateDynamicLibrarySearchGeneratorForProcess(
&ProcessSymbolsGenerator, LLVMOrcLLJITGetGlobalPrefix(J),
allowedSymbols, AllowList))) {
MainResult = handleError(Err);
goto jit_cleanup;
}
LLVMOrcJITDylibAddGenerator(LLVMOrcLLJITGetMainJITDylib(J),
ProcessSymbolsGenerator);
}
// Create our demo module.
LLVMOrcThreadSafeModuleRef TSM = createDemoModule();
// Add our demo module to the JIT.
{
LLVMOrcJITDylibRef MainJD = LLVMOrcLLJITGetMainJITDylib(J);
LLVMErrorRef Err;
if ((Err = LLVMOrcLLJITAddLLVMIRModule(J, MainJD, TSM))) {
// If adding the ThreadSafeModule fails then we need to clean it up
// ourselves. If adding it succeeds the JIT will manage the memory.
LLVMOrcDisposeThreadSafeModule(TSM);
MainResult = handleError(Err);
goto jit_cleanup;
}
}
// Look up the address of our demo entry point.
LLVMOrcJITTargetAddress MulAddAddr;
{
LLVMErrorRef Err;
if ((Err = LLVMOrcLLJITLookup(J, &MulAddAddr, "mul_add"))) {
MainResult = handleError(Err);
goto jit_cleanup;
}
}
// If we made it here then everything succeeded. Execute our JIT'd code.
int32_t (*MulAdd)(int32_t, int32_t, int32_t) =
(int32_t(*)(int32_t, int32_t, int32_t))MulAddAddr;
int32_t Result = MulAdd(3, 4, 5);
// Print the result.
printf("3 * 4 + 5 = %i\n", Result);
jit_cleanup:
// Release all symbol string pool entries that we have allocated. In this
// example that's just our allowed entries.
{
LLVMOrcSymbolStringPoolEntryRef *P = AllowList;
while (*P)
LLVMOrcReleaseSymbolStringPoolEntry(*P++);
}
// Destroy our JIT instance. This will clean up any memory that the JIT has
// taken ownership of. This operation is non-trivial (e.g. it may need to
// JIT static destructors) and may also fail. In that case we want to render
// the error to stderr, but not overwrite any existing return value.
{
LLVMErrorRef Err;
if ((Err = LLVMOrcDisposeLLJIT(J))) {
int NewFailureResult = handleError(Err);
if (MainResult == 0)
MainResult = NewFailureResult;
}
}
llvm_shutdown:
// Shut down LLVM.
LLVMShutdown();
return MainResult;
}