llvm-6502/tools/lli/ChildTarget/ChildTarget.cpp
Yaron Keren 536c84fb86 Silence gcc 4.9.1 warning 'xyz' is used uninitialized in this function.
In release builds this is actually possible as without asserts there is 
no testing of the actual read bytes and the variables could be partially
uninitialized.



git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@224114 91177308-0d34-0410-b5e6-96231b3b80d8
2014-12-12 11:07:51 +00:00

245 lines
5.5 KiB
C++

#include "llvm/Config/config.h"
#include "../RPCChannel.h"
#include "../RemoteTarget.h"
#include "../RemoteTargetMessage.h"
#include "llvm/Support/Memory.h"
#include <assert.h>
#include <map>
#include <stdint.h>
#include <string>
#include <vector>
using namespace llvm;
class LLIChildTarget {
public:
void initialize();
LLIMessageType waitForIncomingMessage();
void handleMessage(LLIMessageType messageType);
RemoteTarget *RT;
RPCChannel RPC;
private:
// Incoming message handlers
void handleAllocateSpace();
void handleLoadSection(bool IsCode);
void handleExecute();
// Outgoing message handlers
void sendChildActive();
void sendAllocationResult(uint64_t Addr);
void sendLoadStatus(uint32_t Status);
void sendExecutionComplete(int Result);
// OS-specific functions
void initializeConnection();
int WriteBytes(const void *Data, size_t Size) {
return RPC.WriteBytes(Data, Size) ? Size : -1;
}
int ReadBytes(void *Data, size_t Size) {
return RPC.ReadBytes(Data, Size) ? Size : -1;
}
// Communication handles (OS-specific)
void *ConnectionData;
};
int main() {
LLIChildTarget ThisChild;
ThisChild.RT = new RemoteTarget();
ThisChild.initialize();
LLIMessageType MsgType;
do {
MsgType = ThisChild.waitForIncomingMessage();
ThisChild.handleMessage(MsgType);
} while (MsgType != LLI_Terminate &&
MsgType != LLI_Error);
delete ThisChild.RT;
return 0;
}
// Public methods
void LLIChildTarget::initialize() {
RPC.createClient();
sendChildActive();
}
LLIMessageType LLIChildTarget::waitForIncomingMessage() {
int32_t MsgType = -1;
if (ReadBytes(&MsgType, 4) > 0)
return (LLIMessageType)MsgType;
return LLI_Error;
}
void LLIChildTarget::handleMessage(LLIMessageType messageType) {
switch (messageType) {
case LLI_AllocateSpace:
handleAllocateSpace();
break;
case LLI_LoadCodeSection:
handleLoadSection(true);
break;
case LLI_LoadDataSection:
handleLoadSection(false);
break;
case LLI_Execute:
handleExecute();
break;
case LLI_Terminate:
RT->stop();
break;
default:
// FIXME: Handle error!
break;
}
}
// Incoming message handlers
void LLIChildTarget::handleAllocateSpace() {
// Read and verify the message data size.
uint32_t DataSize = 0;
int rc = ReadBytes(&DataSize, 4);
(void)rc;
assert(rc == 4);
assert(DataSize == 8);
// Read the message arguments.
uint32_t Alignment = 0;
uint32_t AllocSize = 0;
rc = ReadBytes(&Alignment, 4);
assert(rc == 4);
rc = ReadBytes(&AllocSize, 4);
assert(rc == 4);
// Allocate the memory.
uint64_t Addr;
RT->allocateSpace(AllocSize, Alignment, Addr);
// Send AllocationResult message.
sendAllocationResult(Addr);
}
void LLIChildTarget::handleLoadSection(bool IsCode) {
// Read the message data size.
uint32_t DataSize = 0;
int rc = ReadBytes(&DataSize, 4);
(void)rc;
assert(rc == 4);
// Read the target load address.
uint64_t Addr = 0;
rc = ReadBytes(&Addr, 8);
assert(rc == 8);
size_t BufferSize = DataSize - 8;
if (!RT->isAllocatedMemory(Addr, BufferSize))
return sendLoadStatus(LLI_Status_NotAllocated);
// Read section data into previously allocated buffer
rc = ReadBytes((void*)Addr, BufferSize);
if (rc != (int)(BufferSize))
return sendLoadStatus(LLI_Status_IncompleteMsg);
// If IsCode, mark memory executable
if (IsCode)
sys::Memory::InvalidateInstructionCache((void *)Addr, BufferSize);
// Send MarkLoadComplete message.
sendLoadStatus(LLI_Status_Success);
}
void LLIChildTarget::handleExecute() {
// Read the message data size.
uint32_t DataSize = 0;
int rc = ReadBytes(&DataSize, 4);
(void)rc;
assert(rc == 4);
assert(DataSize == 8);
// Read the target address.
uint64_t Addr = 0;
rc = ReadBytes(&Addr, 8);
assert(rc == 8);
// Call function
int32_t Result = -1;
RT->executeCode(Addr, Result);
// Send ExecutionResult message.
sendExecutionComplete(Result);
}
// Outgoing message handlers
void LLIChildTarget::sendChildActive() {
// Write the message type.
uint32_t MsgType = (uint32_t)LLI_ChildActive;
int rc = WriteBytes(&MsgType, 4);
(void)rc;
assert(rc == 4);
// Write the data size.
uint32_t DataSize = 0;
rc = WriteBytes(&DataSize, 4);
assert(rc == 4);
}
void LLIChildTarget::sendAllocationResult(uint64_t Addr) {
// Write the message type.
uint32_t MsgType = (uint32_t)LLI_AllocationResult;
int rc = WriteBytes(&MsgType, 4);
(void)rc;
assert(rc == 4);
// Write the data size.
uint32_t DataSize = 8;
rc = WriteBytes(&DataSize, 4);
assert(rc == 4);
// Write the allocated address.
rc = WriteBytes(&Addr, 8);
assert(rc == 8);
}
void LLIChildTarget::sendLoadStatus(uint32_t Status) {
// Write the message type.
uint32_t MsgType = (uint32_t)LLI_LoadResult;
int rc = WriteBytes(&MsgType, 4);
(void)rc;
assert(rc == 4);
// Write the data size.
uint32_t DataSize = 4;
rc = WriteBytes(&DataSize, 4);
assert(rc == 4);
// Write the result.
rc = WriteBytes(&Status, 4);
assert(rc == 4);
}
void LLIChildTarget::sendExecutionComplete(int Result) {
// Write the message type.
uint32_t MsgType = (uint32_t)LLI_ExecutionResult;
int rc = WriteBytes(&MsgType, 4);
(void)rc;
assert(rc == 4);
// Write the data size.
uint32_t DataSize = 4;
rc = WriteBytes(&DataSize, 4);
assert(rc == 4);
// Write the result.
rc = WriteBytes(&Result, 4);
assert(rc == 4);
}
#ifdef LLVM_ON_UNIX
#include "../Unix/RPCChannel.inc"
#endif
#ifdef LLVM_ON_WIN32
#include "../Windows/RPCChannel.inc"
#endif