Angelscript/angelscript/source/as_context.cpp

5998 lines
163 KiB
C++
Raw Normal View History

2021-04-12 18:25:02 +00:00
/*
AngelCode Scripting Library
Copyright (c) 2003-2020 Andreas Jonsson
This software is provided 'as-is', without any express or implied
warranty. In no event will the authors be held liable for any
damages arising from the use of this software.
Permission is granted to anyone to use this software for any
purpose, including commercial applications, and to alter it and
redistribute it freely, subject to the following restrictions:
1. The origin of this software must not be misrepresented; you
must not claim that you wrote the original software. If you use
this software in a product, an acknowledgment in the product
documentation would be appreciated but is not required.
2. Altered source versions must be plainly marked as such, and
must not be misrepresented as being the original software.
3. This notice may not be removed or altered from any source
distribution.
The original version of this library can be located at:
http://www.angelcode.com/angelscript/
Andreas Jonsson
andreas@angelcode.com
*/
//
// as_context.cpp
//
// This class handles the execution of the byte code
//
#include <math.h> // fmodf() pow()
#include "as_config.h"
#include "as_context.h"
#include "as_scriptengine.h"
#include "as_tokendef.h"
#include "as_texts.h"
#include "as_callfunc.h"
#include "as_generic.h"
#include "as_debug.h" // mkdir()
#include "as_bytecode.h"
#include "as_scriptobject.h"
#ifdef _MSC_VER
#pragma warning(disable:4702) // unreachable code
#endif
BEGIN_AS_NAMESPACE
// We need at least 2 PTRs reserved for exception handling
// We need at least 1 PTR reserved for calling system functions
const int RESERVE_STACK = 2*AS_PTR_SIZE;
// For each script function call we push 9 PTRs on the call stack
const int CALLSTACK_FRAME_SIZE = 9;
#if defined(AS_DEBUG)
class asCDebugStats
{
public:
asCDebugStats()
{
memset(instrCount, 0, sizeof(instrCount));
memset(instrCount2, 0, sizeof(instrCount2));
lastBC = 255;
}
~asCDebugStats()
{
// This code writes out some statistics for the VM.
// It's useful for determining what needs to be optimized.
#ifndef __MINGW32__
// _mkdir is broken on mingw
_mkdir("AS_DEBUG");
#endif
#if _MSC_VER >= 1500 && !defined(AS_MARMALADE)
FILE *f;
fopen_s(&f, "AS_DEBUG/stats.txt", "wt");
#else
FILE *f = fopen("AS_DEBUG/stats.txt", "wt");
#endif
if( f )
{
// Output instruction statistics
fprintf(f, "\nTotal count\n");
int n;
for( n = 0; n < asBC_MAXBYTECODE; n++ )
{
if( asBCInfo[n].name && instrCount[n] > 0 )
fprintf(f, "%-10.10s : %.0f\n", asBCInfo[n].name, instrCount[n]);
}
fprintf(f, "\nNever executed\n");
for( n = 0; n < asBC_MAXBYTECODE; n++ )
{
if( asBCInfo[n].name && instrCount[n] == 0 )
fprintf(f, "%-10.10s\n", asBCInfo[n].name);
}
fprintf(f, "\nSequences\n");
for( n = 0; n < 256; n++ )
{
if( asBCInfo[n].name )
{
for( int m = 0; m < 256; m++ )
{
if( instrCount2[n][m] )
fprintf(f, "%-10.10s, %-10.10s : %.0f\n", asBCInfo[n].name, asBCInfo[m].name, instrCount2[n][m]);
}
}
}
fclose(f);
}
}
void Instr(asBYTE bc)
{
++instrCount[bc];
++instrCount2[lastBC][bc];
lastBC = bc;
}
// Instruction statistics
double instrCount[256];
double instrCount2[256][256];
int lastBC;
} stats;
#endif
// interface
AS_API asIScriptContext *asGetActiveContext()
{
asCThreadLocalData *tld = asCThreadManager::GetLocalData();
// tld can be 0 if asGetActiveContext is called before any engine has been created.
// Observe! I've seen a case where an application linked with the library twice
// and thus ended up with two separate instances of the code and global variables.
// The application somehow mixed the two instances so that a function called from
// a script ended up calling asGetActiveContext from the other instance that had
// never been initialized.
if( tld == 0 || tld->activeContexts.GetLength() == 0 )
return 0;
return tld->activeContexts[tld->activeContexts.GetLength()-1];
}
// internal
asCThreadLocalData *asPushActiveContext(asIScriptContext *ctx)
{
asCThreadLocalData *tld = asCThreadManager::GetLocalData();
asASSERT( tld );
if( tld == 0 )
return 0;
tld->activeContexts.PushLast(ctx);
return tld;
}
// internal
void asPopActiveContext(asCThreadLocalData *tld, asIScriptContext *ctx)
{
UNUSED_VAR(ctx);
asASSERT(tld && tld->activeContexts[tld->activeContexts.GetLength() - 1] == ctx);
if (tld)
tld->activeContexts.PopLast();
}
asCContext::asCContext(asCScriptEngine *engine, bool holdRef)
{
m_refCount.set(1);
m_holdEngineRef = holdRef;
if( holdRef )
engine->AddRef();
m_engine = engine;
m_status = asEXECUTION_UNINITIALIZED;
m_stackBlockSize = 0;
m_originalStackPointer = 0;
m_inExceptionHandler = false;
m_isStackMemoryNotAllocated = false;
m_needToCleanupArgs = false;
m_currentFunction = 0;
m_callingSystemFunction = 0;
m_regs.objectRegister = 0;
m_initialFunction = 0;
m_lineCallback = false;
m_exceptionCallback = false;
m_regs.doProcessSuspend = false;
m_doSuspend = false;
m_userData = 0;
m_regs.ctx = this;
m_exceptionWillBeCaught = false;
}
asCContext::~asCContext()
{
DetachEngine();
}
// interface
bool asCContext::IsNested(asUINT *nestCount) const
{
if( nestCount )
*nestCount = 0;
asUINT c = GetCallstackSize();
if( c == 0 )
return false;
// Search for a marker on the call stack
// This loop starts at 2 because the 0th entry is not stored in m_callStack,
// and then we need to subtract one more to get the base of each frame
for( asUINT n = 2; n <= c; n++ )
{
const asPWORD *s = m_callStack.AddressOf() + (c - n)*CALLSTACK_FRAME_SIZE;
if( s && s[0] == 0 )
{
if( nestCount )
(*nestCount)++;
else
return true;
}
}
if( nestCount && *nestCount > 0 )
return true;
return false;
}
// interface
int asCContext::AddRef() const
{
return m_refCount.atomicInc();
}
// interface
int asCContext::Release() const
{
int r = m_refCount.atomicDec();
if( r == 0 )
{
asDELETE(const_cast<asCContext*>(this),asCContext);
return 0;
}
return r;
}
// internal
void asCContext::DetachEngine()
{
if( m_engine == 0 ) return;
// Clean up all calls, included nested ones
do
{
// Abort any execution
Abort();
// Free all resources
Unprepare();
}
while( IsNested() );
// Free the stack blocks
for( asUINT n = 0; n < m_stackBlocks.GetLength(); n++ )
{
if( m_stackBlocks[n] )
{
#ifndef WIP_16BYTE_ALIGN
asDELETEARRAY(m_stackBlocks[n]);
#else
asDELETEARRAYALIGNED(m_stackBlocks[n]);
#endif
}
}
m_stackBlocks.SetLength(0);
m_stackBlockSize = 0;
// Clean the user data
for( asUINT n = 0; n < m_userData.GetLength(); n += 2 )
{
if( m_userData[n+1] )
{
for( asUINT c = 0; c < m_engine->cleanContextFuncs.GetLength(); c++ )
if( m_engine->cleanContextFuncs[c].type == m_userData[n] )
m_engine->cleanContextFuncs[c].cleanFunc(this);
}
}
m_userData.SetLength(0);
// Clear engine pointer
if( m_holdEngineRef )
m_engine->Release();
m_engine = 0;
}
// interface
asIScriptEngine *asCContext::GetEngine() const
{
return m_engine;
}
// interface
void *asCContext::SetUserData(void *data, asPWORD type)
{
// As a thread might add a new new user data at the same time as another
// it is necessary to protect both read and write access to the userData member
ACQUIREEXCLUSIVE(m_engine->engineRWLock);
// It is not intended to store a lot of different types of userdata,
// so a more complex structure like a associative map would just have
// more overhead than a simple array.
for( asUINT n = 0; n < m_userData.GetLength(); n += 2 )
{
if( m_userData[n] == type )
{
void *oldData = reinterpret_cast<void*>(m_userData[n+1]);
m_userData[n+1] = reinterpret_cast<asPWORD>(data);
RELEASEEXCLUSIVE(m_engine->engineRWLock);
return oldData;
}
}
m_userData.PushLast(type);
m_userData.PushLast(reinterpret_cast<asPWORD>(data));
RELEASEEXCLUSIVE(m_engine->engineRWLock);
return 0;
}
// interface
void *asCContext::GetUserData(asPWORD type) const
{
// There may be multiple threads reading, but when
// setting the user data nobody must be reading.
ACQUIRESHARED(m_engine->engineRWLock);
for( asUINT n = 0; n < m_userData.GetLength(); n += 2 )
{
if( m_userData[n] == type )
{
RELEASESHARED(m_engine->engineRWLock);
return reinterpret_cast<void*>(m_userData[n+1]);
}
}
RELEASESHARED(m_engine->engineRWLock);
return 0;
}
// interface
asIScriptFunction *asCContext::GetSystemFunction()
{
return m_callingSystemFunction;
}
// interface
int asCContext::Prepare(asIScriptFunction *func)
{
if( func == 0 )
{
asCString str;
str.Format(TXT_FAILED_IN_FUNC_s_WITH_s_s_d, "Prepare", "null", errorNames[-asNO_FUNCTION], asNO_FUNCTION);
m_engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
return asNO_FUNCTION;
}
if( m_status == asEXECUTION_ACTIVE || m_status == asEXECUTION_SUSPENDED )
{
asCString str;
str.Format(TXT_FAILED_IN_FUNC_s_WITH_s_s_d, "Prepare", func->GetDeclaration(true, true), errorNames[-asCONTEXT_ACTIVE], asCONTEXT_ACTIVE);
m_engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
return asCONTEXT_ACTIVE;
}
// Clean the stack if not done before
if( m_status != asEXECUTION_FINISHED && m_status != asEXECUTION_UNINITIALIZED )
CleanStack();
// Release the returned object (if any)
CleanReturnObject();
// Release the object if it is a script object
if( m_initialFunction && m_initialFunction->objectType && (m_initialFunction->objectType->flags & asOBJ_SCRIPT_OBJECT) )
{
asCScriptObject *obj = *(asCScriptObject**)&m_regs.stackFramePointer[0];
if( obj )
obj->Release();
*(asPWORD*)&m_regs.stackFramePointer[0] = 0;
}
if( m_initialFunction && m_initialFunction == func )
{
// If the same function is executed again, we can skip a lot of the setup
m_currentFunction = m_initialFunction;
// Reset stack pointer
m_regs.stackPointer = m_originalStackPointer;
// Make sure the stack pointer is pointing to the original position,
// otherwise something is wrong with the way it is being updated
asASSERT( IsNested() || m_stackIndex > 0 || (m_regs.stackPointer == m_stackBlocks[0] + m_stackBlockSize) );
}
else
{
asASSERT( m_engine );
// Make sure the function is from the same engine as the context to avoid mixups
if( m_engine != func->GetEngine() )
{
asCString str;
str.Format(TXT_FAILED_IN_FUNC_s_WITH_s_s_d, "Prepare", func->GetDeclaration(true, true), errorNames[-asINVALID_ARG], asINVALID_ARG);
m_engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
return asINVALID_ARG;
}
if( m_initialFunction )
{
m_initialFunction->Release();
// Reset stack pointer
m_regs.stackPointer = m_originalStackPointer;
// Make sure the stack pointer is pointing to the original position,
// otherwise something is wrong with the way it is being updated
asASSERT( IsNested() || m_stackIndex > 0 || (m_regs.stackPointer == m_stackBlocks[0] + m_stackBlockSize) );
}
// We trust the application not to pass anything else but a asCScriptFunction
m_initialFunction = reinterpret_cast<asCScriptFunction *>(func);
m_initialFunction->AddRef();
m_currentFunction = m_initialFunction;
// TODO: runtime optimize: GetSpaceNeededForArguments() should be precomputed
m_argumentsSize = m_currentFunction->GetSpaceNeededForArguments() + (m_currentFunction->objectType ? AS_PTR_SIZE : 0);
// Reserve space for the arguments and return value
if( m_currentFunction->DoesReturnOnStack() )
{
m_returnValueSize = m_currentFunction->returnType.GetSizeInMemoryDWords();
m_argumentsSize += AS_PTR_SIZE;
}
else
m_returnValueSize = 0;
// Determine the minimum stack size needed
int stackSize = m_argumentsSize + m_returnValueSize;
if( m_currentFunction->scriptData )
stackSize += m_currentFunction->scriptData->stackNeeded;
// Make sure there is enough space on the stack for the arguments and return value
if( !ReserveStackSpace(stackSize) )
return asOUT_OF_MEMORY;
// Set up the call stack too
if (m_callStack.GetCapacity() < m_engine->ep.initCallStackSize)
m_callStack.AllocateNoConstruct(m_engine->ep.initCallStackSize * CALLSTACK_FRAME_SIZE, true);
}
// Reset state
// Most of the time the previous state will be asEXECUTION_FINISHED, in which case the values are already initialized
if( m_status != asEXECUTION_FINISHED )
{
m_exceptionLine = -1;
m_exceptionFunction = 0;
m_doAbort = false;
m_doSuspend = false;
m_regs.doProcessSuspend = m_lineCallback;
m_externalSuspendRequest = false;
}
m_status = asEXECUTION_PREPARED;
m_regs.programPointer = 0;
// Reserve space for the arguments and return value
m_regs.stackFramePointer = m_regs.stackPointer - m_argumentsSize - m_returnValueSize;
m_originalStackPointer = m_regs.stackPointer;
m_regs.stackPointer = m_regs.stackFramePointer;
// Set arguments to 0
memset(m_regs.stackPointer, 0, 4*m_argumentsSize);
if( m_returnValueSize )
{
// Set the address of the location where the return value should be put
asDWORD *ptr = m_regs.stackFramePointer;
if( m_currentFunction->objectType )
ptr += AS_PTR_SIZE;
*(void**)ptr = (void*)(m_regs.stackFramePointer + m_argumentsSize);
}
return asSUCCESS;
}
// Free all resources
int asCContext::Unprepare()
{
if( m_status == asEXECUTION_ACTIVE || m_status == asEXECUTION_SUSPENDED )
return asCONTEXT_ACTIVE;
// Set the context as active so that any clean up code can use access it if desired
asCThreadLocalData *tld = asPushActiveContext((asIScriptContext *)this);
asDWORD count = m_refCount.get();
UNUSED_VAR(count);
// Only clean the stack if the context was prepared but not executed until the end
if( m_status != asEXECUTION_UNINITIALIZED &&
m_status != asEXECUTION_FINISHED )
CleanStack();
asASSERT( m_needToCleanupArgs == false );
// Release the returned object (if any)
CleanReturnObject();
// TODO: Unprepare is called during destruction, so nobody
// must be allowed to keep an extra reference
asASSERT(m_refCount.get() == count);
asPopActiveContext(tld, this);
// Release the object if it is a script object
if( m_initialFunction && m_initialFunction->objectType && (m_initialFunction->objectType->flags & asOBJ_SCRIPT_OBJECT) )
{
asCScriptObject *obj = *(asCScriptObject**)&m_regs.stackFramePointer[0];
if( obj )
obj->Release();
}
// Release the initial function
if( m_initialFunction )
{
m_initialFunction->Release();
// Reset stack pointer
m_regs.stackPointer = m_originalStackPointer;
// Make sure the stack pointer is pointing to the original position,
// otherwise something is wrong with the way it is being updated
asASSERT( IsNested() || m_stackIndex > 0 || (m_regs.stackPointer == m_stackBlocks[0] + m_stackBlockSize) );
}
// Clear function pointers
m_initialFunction = 0;
m_currentFunction = 0;
m_exceptionFunction = 0;
m_regs.programPointer = 0;
// Reset status
m_status = asEXECUTION_UNINITIALIZED;
m_regs.stackFramePointer = 0;
return 0;
}
asBYTE asCContext::GetReturnByte()
{
if( m_status != asEXECUTION_FINISHED ) return 0;
asCDataType *dt = &m_initialFunction->returnType;
if( dt->IsObject() || dt->IsFuncdef() || dt->IsReference() ) return 0;
return *(asBYTE*)&m_regs.valueRegister;
}
asWORD asCContext::GetReturnWord()
{
if( m_status != asEXECUTION_FINISHED ) return 0;
asCDataType *dt = &m_initialFunction->returnType;
if( dt->IsObject() || dt->IsFuncdef() || dt->IsReference() ) return 0;
return *(asWORD*)&m_regs.valueRegister;
}
asDWORD asCContext::GetReturnDWord()
{
if( m_status != asEXECUTION_FINISHED ) return 0;
asCDataType *dt = &m_initialFunction->returnType;
if( dt->IsObject() || dt->IsFuncdef() || dt->IsReference() ) return 0;
return *(asDWORD*)&m_regs.valueRegister;
}
asQWORD asCContext::GetReturnQWord()
{
if( m_status != asEXECUTION_FINISHED ) return 0;
asCDataType *dt = &m_initialFunction->returnType;
if( dt->IsObject() || dt->IsFuncdef() || dt->IsReference() ) return 0;
return m_regs.valueRegister;
}
float asCContext::GetReturnFloat()
{
if( m_status != asEXECUTION_FINISHED ) return 0;
asCDataType *dt = &m_initialFunction->returnType;
if( dt->IsObject() || dt->IsFuncdef() || dt->IsReference() ) return 0;
return *(float*)&m_regs.valueRegister;
}
double asCContext::GetReturnDouble()
{
if( m_status != asEXECUTION_FINISHED ) return 0;
asCDataType *dt = &m_initialFunction->returnType;
if( dt->IsObject() || dt->IsFuncdef() || dt->IsReference() ) return 0;
return *(double*)&m_regs.valueRegister;
}
void *asCContext::GetReturnAddress()
{
if( m_status != asEXECUTION_FINISHED ) return 0;
asCDataType *dt = &m_initialFunction->returnType;
if( dt->IsReference() )
return *(void**)&m_regs.valueRegister;
else if( dt->IsObject() || dt->IsFuncdef() )
{
if( m_initialFunction->DoesReturnOnStack() )
{
// The address of the return value was passed as the first argument, after the object pointer
int offset = 0;
if( m_initialFunction->objectType )
offset += AS_PTR_SIZE;
return *(void**)(&m_regs.stackFramePointer[offset]);
}
return m_regs.objectRegister;
}
return 0;
}
void *asCContext::GetReturnObject()
{
if( m_status != asEXECUTION_FINISHED ) return 0;
asCDataType *dt = &m_initialFunction->returnType;
if( !dt->IsObject() && !dt->IsFuncdef() ) return 0;
if( dt->IsReference() )
return *(void**)(asPWORD)m_regs.valueRegister;
else
{
if( m_initialFunction->DoesReturnOnStack() )
{
// The address of the return value was passed as the first argument, after the object pointer
int offset = 0;
if( m_initialFunction->objectType )
offset += AS_PTR_SIZE;
return *(void**)(&m_regs.stackFramePointer[offset]);
}
return m_regs.objectRegister;
}
}
void *asCContext::GetAddressOfReturnValue()
{
if( m_status != asEXECUTION_FINISHED ) return 0;
asCDataType *dt = &m_initialFunction->returnType;
// An object is stored in the objectRegister
if( !dt->IsReference() && (dt->IsObject() || dt->IsFuncdef()) )
{
// Need to dereference objects
if( !dt->IsObjectHandle() )
{
if( m_initialFunction->DoesReturnOnStack() )
{
// The address of the return value was passed as the first argument, after the object pointer
int offset = 0;
if( m_initialFunction->objectType )
offset += AS_PTR_SIZE;
return *(void**)(&m_regs.stackFramePointer[offset]);
}
return *(void**)&m_regs.objectRegister;
}
return &m_regs.objectRegister;
}
// Primitives and references are stored in valueRegister
return &m_regs.valueRegister;
}
int asCContext::SetObject(void *obj)
{
if( m_status != asEXECUTION_PREPARED )
return asCONTEXT_NOT_PREPARED;
if( !m_initialFunction->objectType )
{
m_status = asEXECUTION_ERROR;
return asERROR;
}
asASSERT( *(asPWORD*)&m_regs.stackFramePointer[0] == 0 );
*(asPWORD*)&m_regs.stackFramePointer[0] = (asPWORD)obj;
// TODO: This should be optional by having a flag where the application can chose whether it should be done or not
// The flag could be named something like takeOwnership and have default value of true
if( obj && (m_initialFunction->objectType->flags & asOBJ_SCRIPT_OBJECT) )
reinterpret_cast<asCScriptObject*>(obj)->AddRef();
return 0;
}
int asCContext::SetArgByte(asUINT arg, asBYTE value)
{
if( m_status != asEXECUTION_PREPARED )
return asCONTEXT_NOT_PREPARED;
if( arg >= (unsigned)m_initialFunction->parameterTypes.GetLength() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_ARG;
}
// Verify the type of the argument
asCDataType *dt = &m_initialFunction->parameterTypes[arg];
if( dt->IsObject() || dt->IsFuncdef() || dt->IsReference() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_TYPE;
}
if( dt->GetSizeInMemoryBytes() != 1 )
{
m_status = asEXECUTION_ERROR;
return asINVALID_TYPE;
}
// Determine the position of the argument
int offset = 0;
if( m_initialFunction->objectType )
offset += AS_PTR_SIZE;
// If function returns object by value an extra pointer is pushed on the stack
if( m_returnValueSize )
offset += AS_PTR_SIZE;
for( asUINT n = 0; n < arg; n++ )
offset += m_initialFunction->parameterTypes[n].GetSizeOnStackDWords();
// Set the value
*(asBYTE*)&m_regs.stackFramePointer[offset] = value;
return 0;
}
int asCContext::SetArgWord(asUINT arg, asWORD value)
{
if( m_status != asEXECUTION_PREPARED )
return asCONTEXT_NOT_PREPARED;
if( arg >= m_initialFunction->parameterTypes.GetLength() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_ARG;
}
// Verify the type of the argument
asCDataType *dt = &m_initialFunction->parameterTypes[arg];
if( dt->IsObject() || dt->IsFuncdef() || dt->IsReference() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_TYPE;
}
if( dt->GetSizeInMemoryBytes() != 2 )
{
m_status = asEXECUTION_ERROR;
return asINVALID_TYPE;
}
// Determine the position of the argument
int offset = 0;
if( m_initialFunction->objectType )
offset += AS_PTR_SIZE;
// If function returns object by value an extra pointer is pushed on the stack
if( m_returnValueSize )
offset += AS_PTR_SIZE;
for( asUINT n = 0; n < arg; n++ )
offset += m_initialFunction->parameterTypes[n].GetSizeOnStackDWords();
// Set the value
*(asWORD*)&m_regs.stackFramePointer[offset] = value;
return 0;
}
int asCContext::SetArgDWord(asUINT arg, asDWORD value)
{
if( m_status != asEXECUTION_PREPARED )
return asCONTEXT_NOT_PREPARED;
if( arg >= (unsigned)m_initialFunction->parameterTypes.GetLength() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_ARG;
}
// Verify the type of the argument
asCDataType *dt = &m_initialFunction->parameterTypes[arg];
if( dt->IsObject() || dt->IsFuncdef() || dt->IsReference() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_TYPE;
}
if( dt->GetSizeInMemoryBytes() != 4 )
{
m_status = asEXECUTION_ERROR;
return asINVALID_TYPE;
}
// Determine the position of the argument
int offset = 0;
if( m_initialFunction->objectType )
offset += AS_PTR_SIZE;
// If function returns object by value an extra pointer is pushed on the stack
if( m_returnValueSize )
offset += AS_PTR_SIZE;
for( asUINT n = 0; n < arg; n++ )
offset += m_initialFunction->parameterTypes[n].GetSizeOnStackDWords();
// Set the value
*(asDWORD*)&m_regs.stackFramePointer[offset] = value;
return 0;
}
int asCContext::SetArgQWord(asUINT arg, asQWORD value)
{
if( m_status != asEXECUTION_PREPARED )
return asCONTEXT_NOT_PREPARED;
if( arg >= (unsigned)m_initialFunction->parameterTypes.GetLength() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_ARG;
}
// Verify the type of the argument
asCDataType *dt = &m_initialFunction->parameterTypes[arg];
if( dt->IsObject() || dt->IsFuncdef() || dt->IsReference() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_TYPE;
}
if( dt->GetSizeOnStackDWords() != 2 )
{
m_status = asEXECUTION_ERROR;
return asINVALID_TYPE;
}
// Determine the position of the argument
int offset = 0;
if( m_initialFunction->objectType )
offset += AS_PTR_SIZE;
// If function returns object by value an extra pointer is pushed on the stack
if( m_returnValueSize )
offset += AS_PTR_SIZE;
for( asUINT n = 0; n < arg; n++ )
offset += m_initialFunction->parameterTypes[n].GetSizeOnStackDWords();
// Set the value
*(asQWORD*)(&m_regs.stackFramePointer[offset]) = value;
return 0;
}
int asCContext::SetArgFloat(asUINT arg, float value)
{
if( m_status != asEXECUTION_PREPARED )
return asCONTEXT_NOT_PREPARED;
if( arg >= (unsigned)m_initialFunction->parameterTypes.GetLength() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_ARG;
}
// Verify the type of the argument
asCDataType *dt = &m_initialFunction->parameterTypes[arg];
if( dt->IsObject() || dt->IsFuncdef() || dt->IsReference() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_TYPE;
}
if( dt->GetSizeOnStackDWords() != 1 )
{
m_status = asEXECUTION_ERROR;
return asINVALID_TYPE;
}
// Determine the position of the argument
int offset = 0;
if( m_initialFunction->objectType )
offset += AS_PTR_SIZE;
// If function returns object by value an extra pointer is pushed on the stack
if( m_returnValueSize )
offset += AS_PTR_SIZE;
for( asUINT n = 0; n < arg; n++ )
offset += m_initialFunction->parameterTypes[n].GetSizeOnStackDWords();
// Set the value
*(float*)(&m_regs.stackFramePointer[offset]) = value;
return 0;
}
int asCContext::SetArgDouble(asUINT arg, double value)
{
if( m_status != asEXECUTION_PREPARED )
return asCONTEXT_NOT_PREPARED;
if( arg >= (unsigned)m_initialFunction->parameterTypes.GetLength() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_ARG;
}
// Verify the type of the argument
asCDataType *dt = &m_initialFunction->parameterTypes[arg];
if( dt->IsObject() || dt->IsFuncdef() || dt->IsReference() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_TYPE;
}
if( dt->GetSizeOnStackDWords() != 2 )
{
m_status = asEXECUTION_ERROR;
return asINVALID_TYPE;
}
// Determine the position of the argument
int offset = 0;
if( m_initialFunction->objectType )
offset += AS_PTR_SIZE;
// If function returns object by value an extra pointer is pushed on the stack
if( m_returnValueSize )
offset += AS_PTR_SIZE;
for( asUINT n = 0; n < arg; n++ )
offset += m_initialFunction->parameterTypes[n].GetSizeOnStackDWords();
// Set the value
*(double*)(&m_regs.stackFramePointer[offset]) = value;
return 0;
}
int asCContext::SetArgAddress(asUINT arg, void *value)
{
if( m_status != asEXECUTION_PREPARED )
return asCONTEXT_NOT_PREPARED;
if( arg >= (unsigned)m_initialFunction->parameterTypes.GetLength() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_ARG;
}
// Verify the type of the argument
asCDataType *dt = &m_initialFunction->parameterTypes[arg];
if( !dt->IsReference() && !dt->IsObjectHandle() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_TYPE;
}
// Determine the position of the argument
int offset = 0;
if( m_initialFunction->objectType )
offset += AS_PTR_SIZE;
// If function returns object by value an extra pointer is pushed on the stack
if( m_returnValueSize )
offset += AS_PTR_SIZE;
for( asUINT n = 0; n < arg; n++ )
offset += m_initialFunction->parameterTypes[n].GetSizeOnStackDWords();
// Set the value
*(asPWORD*)(&m_regs.stackFramePointer[offset]) = (asPWORD)value;
return 0;
}
int asCContext::SetArgObject(asUINT arg, void *obj)
{
if( m_status != asEXECUTION_PREPARED )
return asCONTEXT_NOT_PREPARED;
if( arg >= (unsigned)m_initialFunction->parameterTypes.GetLength() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_ARG;
}
// Verify the type of the argument
asCDataType *dt = &m_initialFunction->parameterTypes[arg];
if( !dt->IsObject() && !dt->IsFuncdef() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_TYPE;
}
// If the object should be sent by value we must make a copy of it
if( !dt->IsReference() )
{
if( dt->IsObjectHandle() )
{
// Increase the reference counter
if (obj && dt->IsFuncdef())
((asIScriptFunction*)obj)->AddRef();
else
{
asSTypeBehaviour *beh = &CastToObjectType(dt->GetTypeInfo())->beh;
if (obj && beh->addref)
m_engine->CallObjectMethod(obj, beh->addref);
}
}
else
{
obj = m_engine->CreateScriptObjectCopy(obj, dt->GetTypeInfo());
}
}
// Determine the position of the argument
int offset = 0;
if( m_initialFunction->objectType )
offset += AS_PTR_SIZE;
// If function returns object by value an extra pointer is pushed on the stack
if( m_returnValueSize )
offset += AS_PTR_SIZE;
for( asUINT n = 0; n < arg; n++ )
offset += m_initialFunction->parameterTypes[n].GetSizeOnStackDWords();
// Set the value
*(asPWORD*)(&m_regs.stackFramePointer[offset]) = (asPWORD)obj;
return 0;
}
int asCContext::SetArgVarType(asUINT arg, void *ptr, int typeId)
{
if( m_status != asEXECUTION_PREPARED )
return asCONTEXT_NOT_PREPARED;
if( arg >= (unsigned)m_initialFunction->parameterTypes.GetLength() )
{
m_status = asEXECUTION_ERROR;
return asINVALID_ARG;
}
// Verify the type of the argument
asCDataType *dt = &m_initialFunction->parameterTypes[arg];
if( dt->GetTokenType() != ttQuestion )
{
m_status = asEXECUTION_ERROR;
return asINVALID_TYPE;
}
// Determine the position of the argument
int offset = 0;
if( m_initialFunction->objectType )
offset += AS_PTR_SIZE;
// If function returns object by value an extra pointer is pushed on the stack
if( m_returnValueSize )
offset += AS_PTR_SIZE;
for( asUINT n = 0; n < arg; n++ )
offset += m_initialFunction->parameterTypes[n].GetSizeOnStackDWords();
// Set the typeId and pointer
*(asPWORD*)(&m_regs.stackFramePointer[offset]) = (asPWORD)ptr;
offset += AS_PTR_SIZE;
*(int*)(&m_regs.stackFramePointer[offset]) = typeId;
return 0;
}
// TODO: Instead of GetAddressOfArg, maybe we need a SetArgValue(int arg, void *value, bool takeOwnership) instead.
// interface
void *asCContext::GetAddressOfArg(asUINT arg)
{
if( m_status != asEXECUTION_PREPARED )
return 0;
if( arg >= (unsigned)m_initialFunction->parameterTypes.GetLength() )
return 0;
// Determine the position of the argument
int offset = 0;
if( m_initialFunction->objectType )
offset += AS_PTR_SIZE;
// If function returns object by value an extra pointer is pushed on the stack
if( m_returnValueSize )
offset += AS_PTR_SIZE;
for( asUINT n = 0; n < arg; n++ )
offset += m_initialFunction->parameterTypes[n].GetSizeOnStackDWords();
// We should return the address of the location where the argument value will be placed
// All registered types are always sent by reference, even if
// the function is declared to receive the argument by value.
return &m_regs.stackFramePointer[offset];
}
int asCContext::Abort()
{
if( m_engine == 0 ) return asERROR;
// TODO: multithread: Make thread safe. There is a chance that the status
// changes to something else after being set to ABORTED here.
if( m_status == asEXECUTION_SUSPENDED )
m_status = asEXECUTION_ABORTED;
m_doSuspend = true;
m_regs.doProcessSuspend = true;
m_externalSuspendRequest = true;
m_doAbort = true;
return 0;
}
// interface
int asCContext::Suspend()
{
// This function just sets some internal flags and is safe
// to call from a secondary thread, even if the library has
// been built without multi-thread support.
if( m_engine == 0 ) return asERROR;
m_doSuspend = true;
m_externalSuspendRequest = true;
m_regs.doProcessSuspend = true;
return 0;
}
// interface
int asCContext::Execute()
{
asASSERT( m_engine != 0 );
if( m_status != asEXECUTION_SUSPENDED && m_status != asEXECUTION_PREPARED )
{
asCString str;
str.Format(TXT_FAILED_IN_FUNC_s_s_d, "Execute", errorNames[-asCONTEXT_NOT_PREPARED], asCONTEXT_NOT_PREPARED);
m_engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
return asCONTEXT_NOT_PREPARED;
}
m_status = asEXECUTION_ACTIVE;
asCThreadLocalData *tld = asPushActiveContext((asIScriptContext *)this);
// Make sure there are not too many nested calls, as it could crash the application
// by filling up the thread call stack
if (tld->activeContexts.GetLength() > m_engine->ep.maxNestedCalls)
SetInternalException(TXT_TOO_MANY_NESTED_CALLS);
else if( m_regs.programPointer == 0 )
{
if( m_currentFunction->funcType == asFUNC_DELEGATE )
{
// Push the object pointer onto the stack
asASSERT( m_regs.stackPointer - AS_PTR_SIZE >= m_stackBlocks[m_stackIndex] );
m_regs.stackPointer -= AS_PTR_SIZE;
m_regs.stackFramePointer -= AS_PTR_SIZE;
*(asPWORD*)m_regs.stackPointer = asPWORD(m_currentFunction->objForDelegate);
// Make the call to the delegated object method
m_currentFunction = m_currentFunction->funcForDelegate;
}
if( m_currentFunction->funcType == asFUNC_VIRTUAL ||
m_currentFunction->funcType == asFUNC_INTERFACE )
{
// The currentFunction is a virtual method
// Determine the true function from the object
asCScriptObject *obj = *(asCScriptObject**)(asPWORD*)m_regs.stackFramePointer;
if( obj == 0 )
{
SetInternalException(TXT_NULL_POINTER_ACCESS);
}
else
{
asCObjectType *objType = obj->objType;
asCScriptFunction *realFunc = 0;
if( m_currentFunction->funcType == asFUNC_VIRTUAL )
{
if( objType->virtualFunctionTable.GetLength() > (asUINT)m_currentFunction->vfTableIdx )
{
realFunc = objType->virtualFunctionTable[m_currentFunction->vfTableIdx];
}
}
else
{
// Search the object type for a function that matches the interface function
for( asUINT n = 0; n < objType->methods.GetLength(); n++ )
{
asCScriptFunction *f2 = m_engine->scriptFunctions[objType->methods[n]];
if( f2->signatureId == m_currentFunction->signatureId )
{
if( f2->funcType == asFUNC_VIRTUAL )
realFunc = objType->virtualFunctionTable[f2->vfTableIdx];
else
realFunc = f2;
break;
}
}
}
if( realFunc && realFunc->signatureId == m_currentFunction->signatureId )
m_currentFunction = realFunc;
else
SetInternalException(TXT_NULL_POINTER_ACCESS);
}
}
else if( m_currentFunction->funcType == asFUNC_IMPORTED )
{
int funcId = m_engine->importedFunctions[m_currentFunction->id & ~FUNC_IMPORTED]->boundFunctionId;
if( funcId > 0 )
m_currentFunction = m_engine->scriptFunctions[funcId];
else
SetInternalException(TXT_UNBOUND_FUNCTION);
}
if( m_currentFunction->funcType == asFUNC_SCRIPT )
{
m_regs.programPointer = m_currentFunction->scriptData->byteCode.AddressOf();
// Set up the internal registers for executing the script function
PrepareScriptFunction();
}
else if( m_currentFunction->funcType == asFUNC_SYSTEM )
{
// The current function is an application registered function
// Call the function directly
CallSystemFunction(m_currentFunction->id, this);
// Was the call successful?
if( m_status == asEXECUTION_ACTIVE )
{
m_status = asEXECUTION_FINISHED;
}
}
else
{
// This shouldn't happen unless there was an error in which
// case an exception should have been raised already
asASSERT( m_status == asEXECUTION_EXCEPTION );
}
}
asUINT gcPreObjects = 0;
if( m_engine->ep.autoGarbageCollect )
m_engine->gc.GetStatistics(&gcPreObjects, 0, 0, 0, 0);
while (m_status == asEXECUTION_ACTIVE)
{
ExecuteNext();
// If an exception was raised that will be caught, then unwind the stack
// and move the program pointer to the catch block before proceeding
if (m_status == asEXECUTION_EXCEPTION && m_exceptionWillBeCaught)
CleanStack(true);
}
if( m_lineCallback )
{
// Call the line callback one last time before leaving
// so anyone listening can catch the state change
CallLineCallback();
m_regs.doProcessSuspend = true;
}
else
m_regs.doProcessSuspend = false;
m_doSuspend = false;
if( m_engine->ep.autoGarbageCollect )
{
asUINT gcPosObjects = 0;
m_engine->gc.GetStatistics(&gcPosObjects, 0, 0, 0, 0);
if( gcPosObjects > gcPreObjects )
{
// Execute as many steps as there were new objects created
m_engine->GarbageCollect(asGC_ONE_STEP | asGC_DESTROY_GARBAGE | asGC_DETECT_GARBAGE, gcPosObjects - gcPreObjects);
}
else if( gcPosObjects > 0 )
{
// Execute at least one step, even if no new objects were created
m_engine->GarbageCollect(asGC_ONE_STEP | asGC_DESTROY_GARBAGE | asGC_DETECT_GARBAGE, 1);
}
}
// Pop the active context
asPopActiveContext(tld, this);
if( m_status == asEXECUTION_FINISHED )
{
m_regs.objectType = m_initialFunction->returnType.GetTypeInfo();
return asEXECUTION_FINISHED;
}
if( m_doAbort )
{
m_doAbort = false;
m_status = asEXECUTION_ABORTED;
return asEXECUTION_ABORTED;
}
if( m_status == asEXECUTION_SUSPENDED )
return asEXECUTION_SUSPENDED;
if( m_status == asEXECUTION_EXCEPTION )
return asEXECUTION_EXCEPTION;
return asERROR;
}
int asCContext::PushState()
{
// Only allow the state to be pushed when active
// TODO: Can we support a suspended state too? So the reuse of
// the context can be done outside the Execute() call?
if( m_status != asEXECUTION_ACTIVE )
{
// TODO: Write message. Wrong usage
return asERROR;
}
// Allocate space on the callstack for at least two states
if (m_callStack.GetLength() >= m_callStack.GetCapacity() - 2*CALLSTACK_FRAME_SIZE)
{
if (m_engine->ep.maxCallStackSize > 0 && m_callStack.GetLength() >= m_engine->ep.maxCallStackSize*CALLSTACK_FRAME_SIZE)
{
// The call stack is too big to grow further
// If an error occurs, no change to the context should be done
return asOUT_OF_MEMORY;
}
// Allocate space for 10 call states at a time to save time
m_callStack.AllocateNoConstruct(m_callStack.GetLength() + 10 * CALLSTACK_FRAME_SIZE, true);
}
// Push the current script function that is calling the system function
// This cannot fail, since the memory was already allocated above
PushCallState();
// Push the system function too, which will serve both as a marker and
// informing which system function that created the nested call
m_callStack.SetLengthNoConstruct(m_callStack.GetLength() + CALLSTACK_FRAME_SIZE);
// Need to push m_initialFunction as it must be restored later
asPWORD *tmp = m_callStack.AddressOf() + m_callStack.GetLength() - CALLSTACK_FRAME_SIZE;
tmp[0] = 0;
tmp[1] = (asPWORD)m_callingSystemFunction;
tmp[2] = (asPWORD)m_initialFunction;
tmp[3] = (asPWORD)m_originalStackPointer;
tmp[4] = (asPWORD)m_argumentsSize;
// Need to push the value of registers so they can be restored
tmp[5] = (asPWORD)asDWORD(m_regs.valueRegister);
tmp[6] = (asPWORD)asDWORD(m_regs.valueRegister>>32);
tmp[7] = (asPWORD)m_regs.objectRegister;
tmp[8] = (asPWORD)m_regs.objectType;
// Decrease stackpointer to prevent the top value from being overwritten
m_regs.stackPointer -= 2;
// Clear the initial function so that Prepare() knows it must do all validations
m_initialFunction = 0;
// After this the state should appear as if uninitialized
m_callingSystemFunction = 0;
m_regs.objectRegister = 0;
m_regs.objectType = 0;
// Set the status to uninitialized as application
// should call Prepare() after this to reuse the context
m_status = asEXECUTION_UNINITIALIZED;
return asSUCCESS;
}
int asCContext::PopState()
{
if( !IsNested() )
return asERROR;
// Clean up the current execution
Unprepare();
// The topmost state must be a marker for nested call
asASSERT( m_callStack[m_callStack.GetLength() - CALLSTACK_FRAME_SIZE] == 0 );
// Restore the previous state
asPWORD *tmp = &m_callStack[m_callStack.GetLength() - CALLSTACK_FRAME_SIZE];
m_callingSystemFunction = reinterpret_cast<asCScriptFunction*>(tmp[1]);
m_callStack.SetLength(m_callStack.GetLength() - CALLSTACK_FRAME_SIZE);
// Restore the previous initial function and the associated values
m_initialFunction = reinterpret_cast<asCScriptFunction*>(tmp[2]);
m_originalStackPointer = (asDWORD*)tmp[3];
m_argumentsSize = (int)tmp[4];
m_regs.valueRegister = asQWORD(asDWORD(tmp[5]));
m_regs.valueRegister |= asQWORD(tmp[6])<<32;
m_regs.objectRegister = (void*)tmp[7];
m_regs.objectType = (asITypeInfo*)tmp[8];
// Calculate the returnValueSize
if( m_initialFunction->DoesReturnOnStack() )
m_returnValueSize = m_initialFunction->returnType.GetSizeInMemoryDWords();
else
m_returnValueSize = 0;
// Pop the current script function. This will also restore the previous stack pointer
PopCallState();
m_status = asEXECUTION_ACTIVE;
return asSUCCESS;
}
int asCContext::PushCallState()
{
if( m_callStack.GetLength() == m_callStack.GetCapacity() )
{
if (m_engine->ep.maxCallStackSize > 0 && m_callStack.GetLength() >= m_engine->ep.maxCallStackSize*CALLSTACK_FRAME_SIZE)
{
// The call stack is too big to grow further
SetInternalException(TXT_STACK_OVERFLOW);
return asERROR;
}
// Allocate space for 10 call states at a time to save time
m_callStack.AllocateNoConstruct(m_callStack.GetLength() + 10*CALLSTACK_FRAME_SIZE, true);
}
m_callStack.SetLengthNoConstruct(m_callStack.GetLength() + CALLSTACK_FRAME_SIZE);
// Separating the loads and stores limits data cache trash, and with a smart compiler
// could turn into SIMD style loading/storing if available.
// The compiler can't do this itself due to potential pointer aliasing between the pointers,
// ie writing to tmp could overwrite the data contained in registers.stackFramePointer for example
// for all the compiler knows. So introducing the local variable s, which is never referred to by
// its address we avoid this issue.
asPWORD s[5];
s[0] = (asPWORD)m_regs.stackFramePointer;
s[1] = (asPWORD)m_currentFunction;
s[2] = (asPWORD)m_regs.programPointer;
s[3] = (asPWORD)m_regs.stackPointer;
s[4] = m_stackIndex;
asPWORD *tmp = m_callStack.AddressOf() + m_callStack.GetLength() - CALLSTACK_FRAME_SIZE;
tmp[0] = s[0];
tmp[1] = s[1];
tmp[2] = s[2];
tmp[3] = s[3];
tmp[4] = s[4];
return asSUCCESS;
}
void asCContext::PopCallState()
{
// See comments in PushCallState about pointer aliasing and data cache trashing
asPWORD *tmp = m_callStack.AddressOf() + m_callStack.GetLength() - CALLSTACK_FRAME_SIZE;
asPWORD s[5];
s[0] = tmp[0];
s[1] = tmp[1];
s[2] = tmp[2];
s[3] = tmp[3];
s[4] = tmp[4];
m_regs.stackFramePointer = (asDWORD*)s[0];
m_currentFunction = (asCScriptFunction*)s[1];
m_regs.programPointer = (asDWORD*)s[2];
m_regs.stackPointer = (asDWORD*)s[3];
m_stackIndex = (int)s[4];
m_callStack.SetLength(m_callStack.GetLength() - CALLSTACK_FRAME_SIZE);
}
// interface
asUINT asCContext::GetCallstackSize() const
{
if( m_currentFunction == 0 ) return 0;
// The current function is accessed at stackLevel 0
return asUINT(1 + m_callStack.GetLength() / CALLSTACK_FRAME_SIZE);
}
// interface
asIScriptFunction *asCContext::GetFunction(asUINT stackLevel)
{
if( stackLevel >= GetCallstackSize() ) return 0;
if( stackLevel == 0 ) return m_currentFunction;
asPWORD *s = m_callStack.AddressOf() + (GetCallstackSize() - stackLevel - 1)*CALLSTACK_FRAME_SIZE;
asCScriptFunction *func = (asCScriptFunction*)s[1];
return func;
}
// interface
int asCContext::GetLineNumber(asUINT stackLevel, int *column, const char **sectionName)
{
if( stackLevel >= GetCallstackSize() ) return asINVALID_ARG;
asCScriptFunction *func;
asDWORD *bytePos;
if( stackLevel == 0 )
{
func = m_currentFunction;
if( func->scriptData == 0 ) return 0;
bytePos = m_regs.programPointer;
}
else
{
asPWORD *s = m_callStack.AddressOf() + (GetCallstackSize()-stackLevel-1)*CALLSTACK_FRAME_SIZE;
func = (asCScriptFunction*)s[1];
if( func->scriptData == 0 ) return 0;
bytePos = (asDWORD*)s[2];
// Subract 1 from the bytePos, because we want the line where
// the call was made, and not the instruction after the call
bytePos -= 1;
}
// For nested calls it is possible that func is null
if( func == 0 )
{
if( column ) *column = 0;
if( sectionName ) *sectionName = 0;
return 0;
}
int sectionIdx;
asDWORD line = func->GetLineNumber(int(bytePos - func->scriptData->byteCode.AddressOf()), &sectionIdx);
if( column ) *column = (line >> 20);
if( sectionName )
{
asASSERT( sectionIdx < int(m_engine->scriptSectionNames.GetLength()) );
if( sectionIdx >= 0 && asUINT(sectionIdx) < m_engine->scriptSectionNames.GetLength() )
*sectionName = m_engine->scriptSectionNames[sectionIdx]->AddressOf();
else
*sectionName = 0;
}
return (line & 0xFFFFF);
}
// internal
bool asCContext::ReserveStackSpace(asUINT size)
{
#ifdef WIP_16BYTE_ALIGN
// Pad size to a multiple of MAX_TYPE_ALIGNMENT.
const asUINT remainder = size % MAX_TYPE_ALIGNMENT;
if(remainder != 0)
{
size = size + (MAX_TYPE_ALIGNMENT - (size % MAX_TYPE_ALIGNMENT));
}
#endif
// Make sure the first stack block is allocated
if( m_stackBlocks.GetLength() == 0 )
{
m_stackBlockSize = m_engine->ep.initContextStackSize;
asASSERT( m_stackBlockSize > 0 );
#ifndef WIP_16BYTE_ALIGN
asDWORD *stack = asNEWARRAY(asDWORD,m_stackBlockSize);
#else
asDWORD *stack = asNEWARRAYALIGNED(asDWORD, m_stackBlockSize, MAX_TYPE_ALIGNMENT);
#endif
if( stack == 0 )
{
// Out of memory
return false;
}
#ifdef WIP_16BYTE_ALIGN
asASSERT( isAligned(stack, MAX_TYPE_ALIGNMENT) );
#endif
m_stackBlocks.PushLast(stack);
m_stackIndex = 0;
m_regs.stackPointer = m_stackBlocks[0] + m_stackBlockSize;
#ifdef WIP_16BYTE_ALIGN
// Align the stack pointer. This is necessary as the m_stackBlockSize is not necessarily evenly divisable with the max alignment
((asPWORD&)m_regs.stackPointer) &= ~(MAX_TYPE_ALIGNMENT-1);
asASSERT( isAligned(m_regs.stackPointer, MAX_TYPE_ALIGNMENT) );
#endif
}
// Check if there is enough space on the current stack block, otherwise move
// to the next one. New and larger blocks will be allocated as necessary
while( m_regs.stackPointer - (size + RESERVE_STACK) < m_stackBlocks[m_stackIndex] )
{
// Make sure we don't allocate more space than allowed
if( m_engine->ep.maximumContextStackSize )
{
// This test will only stop growth once it is on or already crossed the limit
if( m_stackBlockSize * ((1 << (m_stackIndex+1)) - 1) >= m_engine->ep.maximumContextStackSize )
{
m_isStackMemoryNotAllocated = true;
// Set the stackFramePointer, even though the stackPointer wasn't updated
m_regs.stackFramePointer = m_regs.stackPointer;
SetInternalException(TXT_STACK_OVERFLOW);
return false;
}
}
m_stackIndex++;
if( m_stackBlocks.GetLength() == m_stackIndex )
{
// Allocate the new stack block, with twice the size of the previous
#ifndef WIP_16BYTE_ALIGN
asDWORD *stack = asNEWARRAY(asDWORD, (m_stackBlockSize << m_stackIndex));
#else
asDWORD *stack = asNEWARRAYALIGNED(asDWORD, (m_stackBlockSize << m_stackIndex), MAX_TYPE_ALIGNMENT);
#endif
if( stack == 0 )
{
// Out of memory
m_isStackMemoryNotAllocated = true;
// Set the stackFramePointer, even though the stackPointer wasn't updated
m_regs.stackFramePointer = m_regs.stackPointer;
SetInternalException(TXT_STACK_OVERFLOW);
return false;
}
#ifdef WIP_16BYTE_ALIGN
asASSERT( isAligned(stack, MAX_TYPE_ALIGNMENT) );
#endif
m_stackBlocks.PushLast(stack);
}
// Update the stack pointer to point to the new block.
// Leave enough room above the stackpointer to copy the arguments from the previous stackblock
m_regs.stackPointer = m_stackBlocks[m_stackIndex] +
(m_stackBlockSize<<m_stackIndex) -
m_currentFunction->GetSpaceNeededForArguments() -
(m_currentFunction->objectType ? AS_PTR_SIZE : 0) -
(m_currentFunction->DoesReturnOnStack() ? AS_PTR_SIZE : 0);
#ifdef WIP_16BYTE_ALIGN
// Align the stack pointer
(asPWORD&)m_regs.stackPointer &= ~(MAX_TYPE_ALIGNMENT-1);
asASSERT( isAligned(m_regs.stackPointer, MAX_TYPE_ALIGNMENT) );
#endif
}
return true;
}
// internal
void asCContext::CallScriptFunction(asCScriptFunction *func)
{
asASSERT( func->scriptData );
// Push the framepointer, function id and programCounter on the stack
if (PushCallState() < 0)
return;
// Update the current function and program position before increasing the stack
// so the exception handler will know what to do if there is a stack overflow
m_currentFunction = func;
m_regs.programPointer = m_currentFunction->scriptData->byteCode.AddressOf();
PrepareScriptFunction();
}
void asCContext::PrepareScriptFunction()
{
asASSERT( m_currentFunction->scriptData );
// Make sure there is space on the stack to execute the function
asDWORD *oldStackPointer = m_regs.stackPointer;
if( !ReserveStackSpace(m_currentFunction->scriptData->stackNeeded) )
return;
// If a new stack block was allocated then we'll need to move
// over the function arguments to the new block.
if( m_regs.stackPointer != oldStackPointer )
{
int numDwords = m_currentFunction->GetSpaceNeededForArguments() +
(m_currentFunction->objectType ? AS_PTR_SIZE : 0) +
(m_currentFunction->DoesReturnOnStack() ? AS_PTR_SIZE : 0);
memcpy(m_regs.stackPointer, oldStackPointer, sizeof(asDWORD)*numDwords);
}
// Update framepointer
m_regs.stackFramePointer = m_regs.stackPointer;
// Set all object variables to 0 to guarantee that they are null before they are used
// Only variables on the heap should be cleared. The rest will be cleared by calling the constructor
asUINT n = m_currentFunction->scriptData->objVariablesOnHeap;
while( n-- > 0 )
{
int pos = m_currentFunction->scriptData->objVariablePos[n];
*(asPWORD*)&m_regs.stackFramePointer[-pos] = 0;
}
// Initialize the stack pointer with the space needed for local variables
m_regs.stackPointer -= m_currentFunction->scriptData->variableSpace;
// Call the line callback for each script function, to guarantee that infinitely recursive scripts can
// be interrupted, even if the scripts have been compiled with asEP_BUILD_WITHOUT_LINE_CUES
if( m_regs.doProcessSuspend )
{
if( m_lineCallback )
CallLineCallback();
if( m_doSuspend )
m_status = asEXECUTION_SUSPENDED;
}
}
void asCContext::CallInterfaceMethod(asCScriptFunction *func)
{
// Resolve the interface method using the current script type
asCScriptObject *obj = *(asCScriptObject**)(asPWORD*)m_regs.stackPointer;
if( obj == 0 )
{
// Tell the exception handler to clean up the arguments to this method
m_needToCleanupArgs = true;
SetInternalException(TXT_NULL_POINTER_ACCESS);
return;
}
asCObjectType *objType = obj->objType;
// Search the object type for a function that matches the interface function
asCScriptFunction *realFunc = 0;
if( func->funcType == asFUNC_INTERFACE )
{
// Find the offset for the interface's virtual function table chunk
asUINT offset = 0;
bool found = false;
asCObjectType *findInterface = func->objectType;
// TODO: runtime optimize: The list of interfaces should be ordered by the address
// Then a binary search pattern can be used.
asUINT intfCount = asUINT(objType->interfaces.GetLength());
for( asUINT n = 0; n < intfCount; n++ )
{
if( objType->interfaces[n] == findInterface )
{
offset = objType->interfaceVFTOffsets[n];
found = true;
break;
}
}
if( !found )
{
// Tell the exception handler to clean up the arguments to this method
m_needToCleanupArgs = true;
SetInternalException(TXT_NULL_POINTER_ACCESS);
return;
}
// Find the real function in the virtual table chunk with the found offset
realFunc = objType->virtualFunctionTable[func->vfTableIdx + offset];
// Since the interface was implemented by the class, it shouldn't
// be possible that the real function isn't found
asASSERT( realFunc );
asASSERT( realFunc->signatureId == func->signatureId );
}
else // if( func->funcType == asFUNC_VIRTUAL )
{
realFunc = objType->virtualFunctionTable[func->vfTableIdx];
}
// Then call the true script function
CallScriptFunction(realFunc);
}
void asCContext::ExecuteNext()
{
asDWORD *l_bc = m_regs.programPointer;
asDWORD *l_sp = m_regs.stackPointer;
asDWORD *l_fp = m_regs.stackFramePointer;
for(;;)
{
#ifdef AS_DEBUG
// Gather statistics on executed bytecode
stats.Instr(*(asBYTE*)l_bc);
// Used to verify that the size of the instructions are correct
asDWORD *old = l_bc;
#endif
// Remember to keep the cases in order and without
// gaps, because that will make the switch faster.
// It will be faster since only one lookup will be
// made to find the correct jump destination. If not
// in order, the switch will make two lookups.
switch( *(asBYTE*)l_bc )
{
//--------------
// memory access functions
case asBC_PopPtr:
// Pop a pointer from the stack
l_sp += AS_PTR_SIZE;
l_bc++;
break;
case asBC_PshGPtr:
// Replaces PGA + RDSPtr
l_sp -= AS_PTR_SIZE;
*(asPWORD*)l_sp = *(asPWORD*)asBC_PTRARG(l_bc);
l_bc += 1 + AS_PTR_SIZE;
break;
// Push a dword value on the stack
case asBC_PshC4:
--l_sp;
*l_sp = asBC_DWORDARG(l_bc);
l_bc += 2;
break;
// Push the dword value of a variable on the stack
case asBC_PshV4:
--l_sp;
*l_sp = *(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
// Push the address of a variable on the stack
case asBC_PSF:
l_sp -= AS_PTR_SIZE;
*(asPWORD*)l_sp = asPWORD(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
// Swap the top 2 pointers on the stack
case asBC_SwapPtr:
{
asPWORD p = *(asPWORD*)l_sp;
*(asPWORD*)l_sp = *(asPWORD*)(l_sp+AS_PTR_SIZE);
*(asPWORD*)(l_sp+AS_PTR_SIZE) = p;
l_bc++;
}
break;
// Do a boolean not operation, modifying the value of the variable
case asBC_NOT:
#if AS_SIZEOF_BOOL == 1
{
// Set the value to true if it is equal to 0
// We need to use volatile here to tell the compiler it cannot
// change the order of read and write operations on the pointer.
volatile asBYTE *ptr = (asBYTE*)(l_fp - asBC_SWORDARG0(l_bc));
asBYTE val = (ptr[0] == 0) ? VALUE_OF_BOOLEAN_TRUE : 0;
ptr[0] = val; // The result is stored in the lower byte
ptr[1] = 0; // Make sure the rest of the DWORD is 0
ptr[2] = 0;
ptr[3] = 0;
}
#else
*(l_fp - asBC_SWORDARG0(l_bc)) = (*(l_fp - asBC_SWORDARG0(l_bc)) == 0 ? VALUE_OF_BOOLEAN_TRUE : 0);
#endif
l_bc++;
break;
// Push the dword value of a global variable on the stack
case asBC_PshG4:
--l_sp;
*l_sp = *(asDWORD*)asBC_PTRARG(l_bc);
l_bc += 1 + AS_PTR_SIZE;
break;
// Load the address of a global variable in the register, then
// copy the value of the global variable into a local variable
case asBC_LdGRdR4:
*(void**)&m_regs.valueRegister = (void*)asBC_PTRARG(l_bc);
*(l_fp - asBC_SWORDARG0(l_bc)) = **(asDWORD**)&m_regs.valueRegister;
l_bc += 1+AS_PTR_SIZE;
break;
//----------------
// path control instructions
// Begin execution of a script function
case asBC_CALL:
{
int i = asBC_INTARG(l_bc);
l_bc += 2;
asASSERT( i >= 0 );
asASSERT( (i & FUNC_IMPORTED) == 0 );
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
CallScriptFunction(m_engine->scriptFunctions[i]);
// Extract the values from the context again
l_bc = m_regs.programPointer;
l_sp = m_regs.stackPointer;
l_fp = m_regs.stackFramePointer;
// If status isn't active anymore then we must stop
if( m_status != asEXECUTION_ACTIVE )
return;
}
break;
// Return to the caller, and remove the arguments from the stack
case asBC_RET:
{
// Return if this was the first function, or a nested execution
if( m_callStack.GetLength() == 0 ||
m_callStack[m_callStack.GetLength() - CALLSTACK_FRAME_SIZE] == 0 )
{
m_status = asEXECUTION_FINISHED;
return;
}
asWORD w = asBC_WORDARG0(l_bc);
// Read the old framepointer, functionid, and programCounter from the call stack
PopCallState();
// Extract the values from the context again
l_bc = m_regs.programPointer;
l_sp = m_regs.stackPointer;
l_fp = m_regs.stackFramePointer;
// Pop arguments from stack
l_sp += w;
}
break;
// Jump to a relative position
case asBC_JMP:
l_bc += 2 + asBC_INTARG(l_bc);
break;
//----------------
// Conditional jumps
// Jump to a relative position if the value in the register is 0
case asBC_JZ:
if( *(int*)&m_regs.valueRegister == 0 )
l_bc += asBC_INTARG(l_bc) + 2;
else
l_bc += 2;
break;
// Jump to a relative position if the value in the register is not 0
case asBC_JNZ:
if( *(int*)&m_regs.valueRegister != 0 )
l_bc += asBC_INTARG(l_bc) + 2;
else
l_bc += 2;
break;
// Jump to a relative position if the value in the register is negative
case asBC_JS:
if( *(int*)&m_regs.valueRegister < 0 )
l_bc += asBC_INTARG(l_bc) + 2;
else
l_bc += 2;
break;
// Jump to a relative position if the value in the register it not negative
case asBC_JNS:
if( *(int*)&m_regs.valueRegister >= 0 )
l_bc += asBC_INTARG(l_bc) + 2;
else
l_bc += 2;
break;
// Jump to a relative position if the value in the register is greater than 0
case asBC_JP:
if( *(int*)&m_regs.valueRegister > 0 )
l_bc += asBC_INTARG(l_bc) + 2;
else
l_bc += 2;
break;
// Jump to a relative position if the value in the register is not greater than 0
case asBC_JNP:
if( *(int*)&m_regs.valueRegister <= 0 )
l_bc += asBC_INTARG(l_bc) + 2;
else
l_bc += 2;
break;
//--------------------
// test instructions
// If the value in the register is 0, then set the register to 1, else to 0
case asBC_TZ:
#if AS_SIZEOF_BOOL == 1
{
// Set the value to true if it is equal to 0
// We need to use volatile here to tell the compiler it cannot
// change the order of read and write operations on valueRegister.
volatile int *regPtr = (int*)&m_regs.valueRegister;
volatile asBYTE *regBptr = (asBYTE*)&m_regs.valueRegister;
asBYTE val = (regPtr[0] == 0) ? VALUE_OF_BOOLEAN_TRUE : 0;
regBptr[0] = val; // The result is stored in the lower byte
regBptr[1] = 0; // Make sure the rest of the register is 0
regBptr[2] = 0;
regBptr[3] = 0;
regBptr[4] = 0;
regBptr[5] = 0;
regBptr[6] = 0;
regBptr[7] = 0;
}
#else
*(int*)&m_regs.valueRegister = (*(int*)&m_regs.valueRegister == 0 ? VALUE_OF_BOOLEAN_TRUE : 0);
#endif
l_bc++;
break;
// If the value in the register is not 0, then set the register to 1, else to 0
case asBC_TNZ:
#if AS_SIZEOF_BOOL == 1
{
// Set the value to true if it is not equal to 0
// We need to use volatile here to tell the compiler it cannot
// change the order of read and write operations on valueRegister.
volatile int *regPtr = (int*)&m_regs.valueRegister;
volatile asBYTE *regBptr = (asBYTE*)&m_regs.valueRegister;
asBYTE val = (regPtr[0] == 0) ? 0 : VALUE_OF_BOOLEAN_TRUE;
regBptr[0] = val; // The result is stored in the lower byte
regBptr[1] = 0; // Make sure the rest of the register is 0
regBptr[2] = 0;
regBptr[3] = 0;
regBptr[4] = 0;
regBptr[5] = 0;
regBptr[6] = 0;
regBptr[7] = 0;
}
#else
*(int*)&m_regs.valueRegister = (*(int*)&m_regs.valueRegister == 0 ? 0 : VALUE_OF_BOOLEAN_TRUE);
#endif
l_bc++;
break;
// If the value in the register is negative, then set the register to 1, else to 0
case asBC_TS:
#if AS_SIZEOF_BOOL == 1
{
// Set the value to true if it is less than 0
// We need to use volatile here to tell the compiler it cannot
// change the order of read and write operations on valueRegister.
volatile int *regPtr = (int*)&m_regs.valueRegister;
volatile asBYTE *regBptr = (asBYTE*)&m_regs.valueRegister;
asBYTE val = (regPtr[0] < 0) ? VALUE_OF_BOOLEAN_TRUE : 0;
regBptr[0] = val; // The result is stored in the lower byte
regBptr[1] = 0; // Make sure the rest of the register is 0
regBptr[2] = 0;
regBptr[3] = 0;
regBptr[4] = 0;
regBptr[5] = 0;
regBptr[6] = 0;
regBptr[7] = 0;
}
#else
*(int*)&m_regs.valueRegister = (*(int*)&m_regs.valueRegister < 0 ? VALUE_OF_BOOLEAN_TRUE : 0);
#endif
l_bc++;
break;
// If the value in the register is not negative, then set the register to 1, else to 0
case asBC_TNS:
#if AS_SIZEOF_BOOL == 1
{
// Set the value to true if it is not less than 0
// We need to use volatile here to tell the compiler it cannot
// change the order of read and write operations on valueRegister.
volatile int *regPtr = (int*)&m_regs.valueRegister;
volatile asBYTE *regBptr = (asBYTE*)&m_regs.valueRegister;
asBYTE val = (regPtr[0] >= 0) ? VALUE_OF_BOOLEAN_TRUE : 0;
regBptr[0] = val; // The result is stored in the lower byte
regBptr[1] = 0; // Make sure the rest of the register is 0
regBptr[2] = 0;
regBptr[3] = 0;
regBptr[4] = 0;
regBptr[5] = 0;
regBptr[6] = 0;
regBptr[7] = 0;
}
#else
*(int*)&m_regs.valueRegister = (*(int*)&m_regs.valueRegister < 0 ? 0 : VALUE_OF_BOOLEAN_TRUE);
#endif
l_bc++;
break;
// If the value in the register is greater than 0, then set the register to 1, else to 0
case asBC_TP:
#if AS_SIZEOF_BOOL == 1
{
// Set the value to true if it is greater than 0
// We need to use volatile here to tell the compiler it cannot
// change the order of read and write operations on valueRegister.
volatile int *regPtr = (int*)&m_regs.valueRegister;
volatile asBYTE *regBptr = (asBYTE*)&m_regs.valueRegister;
asBYTE val = (regPtr[0] > 0) ? VALUE_OF_BOOLEAN_TRUE : 0;
regBptr[0] = val; // The result is stored in the lower byte
regBptr[1] = 0; // Make sure the rest of the register is 0
regBptr[2] = 0;
regBptr[3] = 0;
regBptr[4] = 0;
regBptr[5] = 0;
regBptr[6] = 0;
regBptr[7] = 0;
}
#else
*(int*)&m_regs.valueRegister = (*(int*)&m_regs.valueRegister > 0 ? VALUE_OF_BOOLEAN_TRUE : 0);
#endif
l_bc++;
break;
// If the value in the register is not greater than 0, then set the register to 1, else to 0
case asBC_TNP:
#if AS_SIZEOF_BOOL == 1
{
// Set the value to true if it is not greater than 0
// We need to use volatile here to tell the compiler it cannot
// change the order of read and write operations on valueRegister.
volatile int *regPtr = (int*)&m_regs.valueRegister;
volatile asBYTE *regBptr = (asBYTE*)&m_regs.valueRegister;
asBYTE val = (regPtr[0] <= 0) ? VALUE_OF_BOOLEAN_TRUE : 0;
regBptr[0] = val; // The result is stored in the lower byte
regBptr[1] = 0; // Make sure the rest of the register is 0
regBptr[2] = 0;
regBptr[3] = 0;
regBptr[4] = 0;
regBptr[5] = 0;
regBptr[6] = 0;
regBptr[7] = 0;
}
#else
*(int*)&m_regs.valueRegister = (*(int*)&m_regs.valueRegister > 0 ? 0 : VALUE_OF_BOOLEAN_TRUE);
#endif
l_bc++;
break;
//--------------------
// negate value
// Negate the integer value in the variable
case asBC_NEGi:
*(l_fp - asBC_SWORDARG0(l_bc)) = asDWORD(-int(*(l_fp - asBC_SWORDARG0(l_bc))));
l_bc++;
break;
// Negate the float value in the variable
case asBC_NEGf:
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = -*(float*)(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
// Negate the double value in the variable
case asBC_NEGd:
*(double*)(l_fp - asBC_SWORDARG0(l_bc)) = -*(double*)(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
//-------------------------
// Increment value pointed to by address in register
// Increment the short value pointed to by the register
case asBC_INCi16:
(**(short**)&m_regs.valueRegister)++;
l_bc++;
break;
// Increment the byte value pointed to by the register
case asBC_INCi8:
(**(char**)&m_regs.valueRegister)++;
l_bc++;
break;
// Decrement the short value pointed to by the register
case asBC_DECi16:
(**(short**)&m_regs.valueRegister)--;
l_bc++;
break;
// Decrement the byte value pointed to by the register
case asBC_DECi8:
(**(char**)&m_regs.valueRegister)--;
l_bc++;
break;
// Increment the integer value pointed to by the register
case asBC_INCi:
++(**(int**)&m_regs.valueRegister);
l_bc++;
break;
// Decrement the integer value pointed to by the register
case asBC_DECi:
--(**(int**)&m_regs.valueRegister);
l_bc++;
break;
// Increment the float value pointed to by the register
case asBC_INCf:
++(**(float**)&m_regs.valueRegister);
l_bc++;
break;
// Decrement the float value pointed to by the register
case asBC_DECf:
--(**(float**)&m_regs.valueRegister);
l_bc++;
break;
// Increment the double value pointed to by the register
case asBC_INCd:
++(**(double**)&m_regs.valueRegister);
l_bc++;
break;
// Decrement the double value pointed to by the register
case asBC_DECd:
--(**(double**)&m_regs.valueRegister);
l_bc++;
break;
// Increment the local integer variable
case asBC_IncVi:
(*(int*)(l_fp - asBC_SWORDARG0(l_bc)))++;
l_bc++;
break;
// Decrement the local integer variable
case asBC_DecVi:
(*(int*)(l_fp - asBC_SWORDARG0(l_bc)))--;
l_bc++;
break;
//--------------------
// bits instructions
// Do a bitwise not on the value in the variable
case asBC_BNOT:
*(l_fp - asBC_SWORDARG0(l_bc)) = ~*(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
// Do a bitwise and of two variables and store the result in a third variable
case asBC_BAND:
*(l_fp - asBC_SWORDARG0(l_bc)) = *(l_fp - asBC_SWORDARG1(l_bc)) & *(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
// Do a bitwise or of two variables and store the result in a third variable
case asBC_BOR:
*(l_fp - asBC_SWORDARG0(l_bc)) = *(l_fp - asBC_SWORDARG1(l_bc)) | *(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
// Do a bitwise xor of two variables and store the result in a third variable
case asBC_BXOR:
*(l_fp - asBC_SWORDARG0(l_bc)) = *(l_fp - asBC_SWORDARG1(l_bc)) ^ *(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
// Do a logical shift left of two variables and store the result in a third variable
case asBC_BSLL:
*(l_fp - asBC_SWORDARG0(l_bc)) = *(l_fp - asBC_SWORDARG1(l_bc)) << *(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
// Do a logical shift right of two variables and store the result in a third variable
case asBC_BSRL:
*(l_fp - asBC_SWORDARG0(l_bc)) = *(l_fp - asBC_SWORDARG1(l_bc)) >> *(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
// Do an arithmetic shift right of two variables and store the result in a third variable
case asBC_BSRA:
*(l_fp - asBC_SWORDARG0(l_bc)) = int(*(l_fp - asBC_SWORDARG1(l_bc))) >> *(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_COPY:
{
void *d = (void*)*(asPWORD*)l_sp; l_sp += AS_PTR_SIZE;
void *s = (void*)*(asPWORD*)l_sp;
if( s == 0 || d == 0 )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_NULL_POINTER_ACCESS);
return;
}
memcpy(d, s, asBC_WORDARG0(l_bc)*4);
// replace the pointer on the stack with the lvalue
*(asPWORD**)l_sp = (asPWORD*)d;
}
l_bc += 2;
break;
case asBC_PshC8:
l_sp -= 2;
*(asQWORD*)l_sp = asBC_QWORDARG(l_bc);
l_bc += 3;
break;
case asBC_PshVPtr:
l_sp -= AS_PTR_SIZE;
*(asPWORD*)l_sp = *(asPWORD*)(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
case asBC_RDSPtr:
{
// The pointer must not be null
asPWORD a = *(asPWORD*)l_sp;
if( a == 0 )
{
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
SetInternalException(TXT_NULL_POINTER_ACCESS);
return;
}
// Pop an address from the stack, read a pointer from that address and push it on the stack
*(asPWORD*)l_sp = *(asPWORD*)a;
}
l_bc++;
break;
//----------------------------
// Comparisons
case asBC_CMPd:
{
// Do a comparison of the values, rather than a subtraction
// in order to get proper behaviour for infinity values.
double dbl1 = *(double*)(l_fp - asBC_SWORDARG0(l_bc));
double dbl2 = *(double*)(l_fp - asBC_SWORDARG1(l_bc));
if( dbl1 == dbl2 ) *(int*)&m_regs.valueRegister = 0;
else if( dbl1 < dbl2 ) *(int*)&m_regs.valueRegister = -1;
else *(int*)&m_regs.valueRegister = 1;
l_bc += 2;
}
break;
case asBC_CMPu:
{
asDWORD d1 = *(asDWORD*)(l_fp - asBC_SWORDARG0(l_bc));
asDWORD d2 = *(asDWORD*)(l_fp - asBC_SWORDARG1(l_bc));
if( d1 == d2 ) *(int*)&m_regs.valueRegister = 0;
else if( d1 < d2 ) *(int*)&m_regs.valueRegister = -1;
else *(int*)&m_regs.valueRegister = 1;
l_bc += 2;
}
break;
case asBC_CMPf:
{
// Do a comparison of the values, rather than a subtraction
// in order to get proper behaviour for infinity values.
float f1 = *(float*)(l_fp - asBC_SWORDARG0(l_bc));
float f2 = *(float*)(l_fp - asBC_SWORDARG1(l_bc));
if( f1 == f2 ) *(int*)&m_regs.valueRegister = 0;
else if( f1 < f2 ) *(int*)&m_regs.valueRegister = -1;
else *(int*)&m_regs.valueRegister = 1;
l_bc += 2;
}
break;
case asBC_CMPi:
{
int i1 = *(int*)(l_fp - asBC_SWORDARG0(l_bc));
int i2 = *(int*)(l_fp - asBC_SWORDARG1(l_bc));
if( i1 == i2 ) *(int*)&m_regs.valueRegister = 0;
else if( i1 < i2 ) *(int*)&m_regs.valueRegister = -1;
else *(int*)&m_regs.valueRegister = 1;
l_bc += 2;
}
break;
//----------------------------
// Comparisons with constant value
case asBC_CMPIi:
{
int i1 = *(int*)(l_fp - asBC_SWORDARG0(l_bc));
int i2 = asBC_INTARG(l_bc);
if( i1 == i2 ) *(int*)&m_regs.valueRegister = 0;
else if( i1 < i2 ) *(int*)&m_regs.valueRegister = -1;
else *(int*)&m_regs.valueRegister = 1;
l_bc += 2;
}
break;
case asBC_CMPIf:
{
// Do a comparison of the values, rather than a subtraction
// in order to get proper behaviour for infinity values.
float f1 = *(float*)(l_fp - asBC_SWORDARG0(l_bc));
float f2 = asBC_FLOATARG(l_bc);
if( f1 == f2 ) *(int*)&m_regs.valueRegister = 0;
else if( f1 < f2 ) *(int*)&m_regs.valueRegister = -1;
else *(int*)&m_regs.valueRegister = 1;
l_bc += 2;
}
break;
case asBC_CMPIu:
{
asDWORD d1 = *(asDWORD*)(l_fp - asBC_SWORDARG0(l_bc));
asDWORD d2 = asBC_DWORDARG(l_bc);
if( d1 == d2 ) *(int*)&m_regs.valueRegister = 0;
else if( d1 < d2 ) *(int*)&m_regs.valueRegister = -1;
else *(int*)&m_regs.valueRegister = 1;
l_bc += 2;
}
break;
case asBC_JMPP:
l_bc += 1 + (*(int*)(l_fp - asBC_SWORDARG0(l_bc)))*2;
break;
case asBC_PopRPtr:
*(asPWORD*)&m_regs.valueRegister = *(asPWORD*)l_sp;
l_sp += AS_PTR_SIZE;
l_bc++;
break;
case asBC_PshRPtr:
l_sp -= AS_PTR_SIZE;
*(asPWORD*)l_sp = *(asPWORD*)&m_regs.valueRegister;
l_bc++;
break;
case asBC_STR:
// TODO: NEWSTRING: Deprecate this instruction
asASSERT(false);
l_bc++;
break;
case asBC_CALLSYS:
{
// Get function ID from the argument
int i = asBC_INTARG(l_bc);
// Need to move the values back to the context as the called functions
// may use the debug interface to inspect the registers
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
l_sp += CallSystemFunction(i, this);
// Update the program position after the call so that line number is correct
l_bc += 2;
if( m_regs.doProcessSuspend )
{
// Should the execution be suspended?
if( m_doSuspend )
{
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
m_status = asEXECUTION_SUSPENDED;
return;
}
// An exception might have been raised
if( m_status != asEXECUTION_ACTIVE )
{
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
return;
}
}
}
break;
case asBC_CALLBND:
{
// TODO: Clean-up: This code is very similar to asBC_CallPtr. Create a shared method for them
// Get the function ID from the stack
int i = asBC_INTARG(l_bc);
asASSERT( i >= 0 );
asASSERT( i & FUNC_IMPORTED );
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
int funcId = m_engine->importedFunctions[i & ~FUNC_IMPORTED]->boundFunctionId;
if( funcId == -1 )
{
// Need to update the program pointer for the exception handler
m_regs.programPointer += 2;
// Tell the exception handler to clean up the arguments to this function
m_needToCleanupArgs = true;
SetInternalException(TXT_UNBOUND_FUNCTION);
return;
}
else
{
asCScriptFunction *func = m_engine->GetScriptFunction(funcId);
if( func->funcType == asFUNC_SCRIPT )
{
m_regs.programPointer += 2;
CallScriptFunction(func);
}
else if( func->funcType == asFUNC_DELEGATE )
{
// Push the object pointer on the stack. There is always a reserved space for this so
// we don't don't need to worry about overflowing the allocated memory buffer
asASSERT( m_regs.stackPointer - AS_PTR_SIZE >= m_stackBlocks[m_stackIndex] );
m_regs.stackPointer -= AS_PTR_SIZE;
*(asPWORD*)m_regs.stackPointer = asPWORD(func->objForDelegate);
// Call the delegated method
if( func->funcForDelegate->funcType == asFUNC_SYSTEM )
{
m_regs.stackPointer += CallSystemFunction(func->funcForDelegate->id, this);
// Update program position after the call so the line number
// is correct in case the system function queries it
m_regs.programPointer += 2;
}
else
{
m_regs.programPointer += 2;
// TODO: run-time optimize: The true method could be figured out when creating the delegate
CallInterfaceMethod(func->funcForDelegate);
}
}
else
{
asASSERT( func->funcType == asFUNC_SYSTEM );
m_regs.stackPointer += CallSystemFunction(func->id, this);
// Update program position after the call so the line number
// is correct in case the system function queries it
m_regs.programPointer += 2;
}
}
// Extract the values from the context again
l_bc = m_regs.programPointer;
l_sp = m_regs.stackPointer;
l_fp = m_regs.stackFramePointer;
// If status isn't active anymore then we must stop
if( m_status != asEXECUTION_ACTIVE )
return;
}
break;
case asBC_SUSPEND:
if( m_regs.doProcessSuspend )
{
if( m_lineCallback )
{
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
CallLineCallback();
}
if( m_doSuspend )
{
l_bc++;
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
m_status = asEXECUTION_SUSPENDED;
return;
}
}
l_bc++;
break;
case asBC_ALLOC:
{
asCObjectType *objType = (asCObjectType*)asBC_PTRARG(l_bc);
int func = asBC_INTARG(l_bc+AS_PTR_SIZE);
if( objType->flags & asOBJ_SCRIPT_OBJECT )
{
// Need to move the values back to the context as the construction
// of the script object may reuse the context for nested calls.
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Pre-allocate the memory
asDWORD *mem = (asDWORD*)m_engine->CallAlloc(objType);
// Pre-initialize the memory by calling the constructor for asCScriptObject
ScriptObject_Construct(objType, (asCScriptObject*)mem);
// Call the constructor to initalize the memory
asCScriptFunction *f = m_engine->scriptFunctions[func];
asDWORD **a = (asDWORD**)*(asPWORD*)(m_regs.stackPointer + f->GetSpaceNeededForArguments());
if( a ) *a = mem;
// Push the object pointer on the stack
m_regs.stackPointer -= AS_PTR_SIZE;
*(asPWORD*)m_regs.stackPointer = (asPWORD)mem;
m_regs.programPointer += 2+AS_PTR_SIZE;
CallScriptFunction(f);
// Extract the values from the context again
l_bc = m_regs.programPointer;
l_sp = m_regs.stackPointer;
l_fp = m_regs.stackFramePointer;
// If status isn't active anymore then we must stop
if( m_status != asEXECUTION_ACTIVE )
return;
}
else
{
// Pre-allocate the memory
asDWORD *mem = (asDWORD*)m_engine->CallAlloc(objType);
if( func )
{
// Push the object pointer on the stack (it will be popped by the function)
l_sp -= AS_PTR_SIZE;
*(asPWORD*)l_sp = (asPWORD)mem;
// Need to move the values back to the context as the called functions
// may use the debug interface to inspect the registers
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
l_sp += CallSystemFunction(func, this);
}
// Pop the variable address from the stack
asDWORD **a = (asDWORD**)*(asPWORD*)l_sp;
l_sp += AS_PTR_SIZE;
if( a ) *a = mem;
l_bc += 2+AS_PTR_SIZE;
if( m_regs.doProcessSuspend )
{
// Should the execution be suspended?
if( m_doSuspend )
{
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
m_status = asEXECUTION_SUSPENDED;
return;
}
// An exception might have been raised
if( m_status != asEXECUTION_ACTIVE )
{
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
m_engine->CallFree(mem);
*a = 0;
return;
}
}
}
}
break;
case asBC_FREE:
{
// Get the variable that holds the object handle/reference
asPWORD *a = (asPWORD*)asPWORD(l_fp - asBC_SWORDARG0(l_bc));
if( *a )
{
asCObjectType *objType = (asCObjectType*)asBC_PTRARG(l_bc);
asSTypeBehaviour *beh = &objType->beh;
// Need to move the values back to the context as the called functions
// may use the debug interface to inspect the registers
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
if( objType->flags & asOBJ_REF )
{
asASSERT( (objType->flags & asOBJ_NOCOUNT) || beh->release );
if( beh->release )
m_engine->CallObjectMethod((void*)(asPWORD)*a, beh->release);
}
else
{
if( beh->destruct )
m_engine->CallObjectMethod((void*)(asPWORD)*a, beh->destruct);
else if( objType->flags & asOBJ_LIST_PATTERN )
m_engine->DestroyList((asBYTE*)(asPWORD)*a, objType);
m_engine->CallFree((void*)(asPWORD)*a);
}
// Clear the variable
*a = 0;
}
}
l_bc += 1+AS_PTR_SIZE;
break;
case asBC_LOADOBJ:
{
// Move the object pointer from the object variable into the object register
void **a = (void**)(l_fp - asBC_SWORDARG0(l_bc));
m_regs.objectType = 0;
m_regs.objectRegister = *a;
*a = 0;
}
l_bc++;
break;
case asBC_STOREOBJ:
// Move the object pointer from the object register to the object variable
*(asPWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = asPWORD(m_regs.objectRegister);
m_regs.objectRegister = 0;
l_bc++;
break;
case asBC_GETOBJ:
{
// Read variable index from location on stack
asPWORD *a = (asPWORD*)(l_sp + asBC_WORDARG0(l_bc));
asPWORD offset = *a;
// Move pointer from variable to the same location on the stack
asPWORD *v = (asPWORD*)(l_fp - offset);
*a = *v;
// Clear variable
*v = 0;
}
l_bc++;
break;
case asBC_REFCPY:
{
asCObjectType *objType = (asCObjectType*)asBC_PTRARG(l_bc);
asSTypeBehaviour *beh = &objType->beh;
// Pop address of destination pointer from the stack
void **d = (void**)*(asPWORD*)l_sp;
l_sp += AS_PTR_SIZE;
// Read wanted pointer from the stack
void *s = (void*)*(asPWORD*)l_sp;
// Need to move the values back to the context as the called functions
// may use the debug interface to inspect the registers
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
if( !(objType->flags & asOBJ_NOCOUNT) )
{
// Release previous object held by destination pointer
if( *d != 0 && beh->release )
m_engine->CallObjectMethod(*d, beh->release);
// Increase ref counter of wanted object
if( s != 0 && beh->addref )
m_engine->CallObjectMethod(s, beh->addref);
}
// Set the new object in the destination
*d = s;
}
l_bc += 1+AS_PTR_SIZE;
break;
case asBC_CHKREF:
{
// Verify if the pointer on the stack is null
// This is used when validating a pointer that an operator will work on
asPWORD a = *(asPWORD*)l_sp;
if( a == 0 )
{
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
SetInternalException(TXT_NULL_POINTER_ACCESS);
return;
}
}
l_bc++;
break;
case asBC_GETOBJREF:
{
// Get the location on the stack where the reference will be placed
asPWORD *a = (asPWORD*)(l_sp + asBC_WORDARG0(l_bc));
// Replace the variable index with the object handle held in the variable
*(asPWORD**)a = *(asPWORD**)(l_fp - *a);
}
l_bc++;
break;
case asBC_GETREF:
{
// Get the location on the stack where the reference will be placed
asPWORD *a = (asPWORD*)(l_sp + asBC_WORDARG0(l_bc));
// Replace the variable index with the address of the variable
*(asPWORD**)a = (asPWORD*)(l_fp - (int)*a);
}
l_bc++;
break;
case asBC_PshNull:
// Push a null pointer on the stack
l_sp -= AS_PTR_SIZE;
*(asPWORD*)l_sp = 0;
l_bc++;
break;
case asBC_ClrVPtr:
// TODO: runtime optimize: Is this instruction really necessary?
// CallScriptFunction() can clear the null handles upon entry, just as is done for
// all other object variables
// Clear pointer variable
*(asPWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = 0;
l_bc++;
break;
case asBC_OBJTYPE:
// Push the object type on the stack
l_sp -= AS_PTR_SIZE;
*(asPWORD*)l_sp = asBC_PTRARG(l_bc);
l_bc += 1+AS_PTR_SIZE;
break;
case asBC_TYPEID:
// Equivalent to PshC4, but kept as separate instruction for bytecode serialization
--l_sp;
*l_sp = asBC_DWORDARG(l_bc);
l_bc += 2;
break;
case asBC_SetV4:
*(l_fp - asBC_SWORDARG0(l_bc)) = asBC_DWORDARG(l_bc);
l_bc += 2;
break;
case asBC_SetV8:
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = asBC_QWORDARG(l_bc);
l_bc += 3;
break;
case asBC_ADDSi:
{
// The pointer must not be null
asPWORD a = *(asPWORD*)l_sp;
if( a == 0 )
{
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
SetInternalException(TXT_NULL_POINTER_ACCESS);
return;
}
// Add an offset to the pointer
*(asPWORD*)l_sp = a + asBC_SWORDARG0(l_bc);
}
l_bc += 2;
break;
case asBC_CpyVtoV4:
*(l_fp - asBC_SWORDARG0(l_bc)) = *(l_fp - asBC_SWORDARG1(l_bc));
l_bc += 2;
break;
case asBC_CpyVtoV8:
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asQWORD*)(l_fp - asBC_SWORDARG1(l_bc));
l_bc += 2;
break;
case asBC_CpyVtoR4:
*(asDWORD*)&m_regs.valueRegister = *(asDWORD*)(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
case asBC_CpyVtoR8:
*(asQWORD*)&m_regs.valueRegister = *(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
case asBC_CpyVtoG4:
*(asDWORD*)asBC_PTRARG(l_bc) = *(asDWORD*)(l_fp - asBC_SWORDARG0(l_bc));
l_bc += 1 + AS_PTR_SIZE;
break;
case asBC_CpyRtoV4:
*(asDWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asDWORD*)&m_regs.valueRegister;
l_bc++;
break;
case asBC_CpyRtoV8:
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = m_regs.valueRegister;
l_bc++;
break;
case asBC_CpyGtoV4:
*(asDWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asDWORD*)asBC_PTRARG(l_bc);
l_bc += 1 + AS_PTR_SIZE;
break;
case asBC_WRTV1:
// The pointer in the register points to a byte, and *(l_fp - offset) too
**(asBYTE**)&m_regs.valueRegister = *(asBYTE*)(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
case asBC_WRTV2:
// The pointer in the register points to a word, and *(l_fp - offset) too
**(asWORD**)&m_regs.valueRegister = *(asWORD*)(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
case asBC_WRTV4:
**(asDWORD**)&m_regs.valueRegister = *(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
case asBC_WRTV8:
**(asQWORD**)&m_regs.valueRegister = *(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
case asBC_RDR1:
{
// The pointer in the register points to a byte, and *(l_fp - offset) will also point to a byte
asBYTE *bPtr = (asBYTE*)(l_fp - asBC_SWORDARG0(l_bc));
bPtr[0] = **(asBYTE**)&m_regs.valueRegister; // read the byte
bPtr[1] = 0; // 0 the rest of the DWORD
bPtr[2] = 0;
bPtr[3] = 0;
}
l_bc++;
break;
case asBC_RDR2:
{
// The pointer in the register points to a word, and *(l_fp - offset) will also point to a word
asWORD *wPtr = (asWORD*)(l_fp - asBC_SWORDARG0(l_bc));
wPtr[0] = **(asWORD**)&m_regs.valueRegister; // read the word
wPtr[1] = 0; // 0 the rest of the DWORD
}
l_bc++;
break;
case asBC_RDR4:
*(asDWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = **(asDWORD**)&m_regs.valueRegister;
l_bc++;
break;
case asBC_RDR8:
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = **(asQWORD**)&m_regs.valueRegister;
l_bc++;
break;
case asBC_LDG:
*(asPWORD*)&m_regs.valueRegister = asBC_PTRARG(l_bc);
l_bc += 1+AS_PTR_SIZE;
break;
case asBC_LDV:
*(asDWORD**)&m_regs.valueRegister = (l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
case asBC_PGA:
l_sp -= AS_PTR_SIZE;
*(asPWORD*)l_sp = asBC_PTRARG(l_bc);
l_bc += 1+AS_PTR_SIZE;
break;
case asBC_CmpPtr:
{
// TODO: runtime optimize: This instruction should really just be an equals, and return true or false.
// The instruction is only used for is and !is tests anyway.
asPWORD p1 = *(asPWORD*)(l_fp - asBC_SWORDARG0(l_bc));
asPWORD p2 = *(asPWORD*)(l_fp - asBC_SWORDARG1(l_bc));
if( p1 == p2 ) *(int*)&m_regs.valueRegister = 0;
else if( p1 < p2 ) *(int*)&m_regs.valueRegister = -1;
else *(int*)&m_regs.valueRegister = 1;
l_bc += 2;
}
break;
case asBC_VAR:
l_sp -= AS_PTR_SIZE;
*(asPWORD*)l_sp = (asPWORD)asBC_SWORDARG0(l_bc);
l_bc++;
break;
//----------------------------
// Type conversions
case asBC_iTOf:
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = float(*(int*)(l_fp - asBC_SWORDARG0(l_bc)));
l_bc++;
break;
case asBC_fTOi:
*(l_fp - asBC_SWORDARG0(l_bc)) = int(*(float*)(l_fp - asBC_SWORDARG0(l_bc)));
l_bc++;
break;
case asBC_uTOf:
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = float(*(l_fp - asBC_SWORDARG0(l_bc)));
l_bc++;
break;
case asBC_fTOu:
// We must cast to int first, because on some compilers the cast of a negative float value to uint result in 0
*(l_fp - asBC_SWORDARG0(l_bc)) = asUINT(int(*(float*)(l_fp - asBC_SWORDARG0(l_bc))));
l_bc++;
break;
case asBC_sbTOi:
// *(l_fp - offset) points to a char, and will point to an int afterwards
*(l_fp - asBC_SWORDARG0(l_bc)) = *(signed char*)(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
case asBC_swTOi:
// *(l_fp - offset) points to a short, and will point to an int afterwards
*(l_fp - asBC_SWORDARG0(l_bc)) = *(short*)(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
case asBC_ubTOi:
// (l_fp - offset) points to a byte, and will point to an int afterwards
*(l_fp - asBC_SWORDARG0(l_bc)) = *(asBYTE*)(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
case asBC_uwTOi:
// *(l_fp - offset) points to a word, and will point to an int afterwards
*(l_fp - asBC_SWORDARG0(l_bc)) = *(asWORD*)(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
case asBC_dTOi:
*(l_fp - asBC_SWORDARG0(l_bc)) = int(*(double*)(l_fp - asBC_SWORDARG1(l_bc)));
l_bc += 2;
break;
case asBC_dTOu:
// We must cast to int first, because on some compilers the cast of a negative float value to uint result in 0
*(l_fp - asBC_SWORDARG0(l_bc)) = asUINT(int(*(double*)(l_fp - asBC_SWORDARG1(l_bc))));
l_bc += 2;
break;
case asBC_dTOf:
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = float(*(double*)(l_fp - asBC_SWORDARG1(l_bc)));
l_bc += 2;
break;
case asBC_iTOd:
*(double*)(l_fp - asBC_SWORDARG0(l_bc)) = double(*(int*)(l_fp - asBC_SWORDARG1(l_bc)));
l_bc += 2;
break;
case asBC_uTOd:
*(double*)(l_fp - asBC_SWORDARG0(l_bc)) = double(*(asUINT*)(l_fp - asBC_SWORDARG1(l_bc)));
l_bc += 2;
break;
case asBC_fTOd:
*(double*)(l_fp - asBC_SWORDARG0(l_bc)) = double(*(float*)(l_fp - asBC_SWORDARG1(l_bc)));
l_bc += 2;
break;
//------------------------------
// Math operations
case asBC_ADDi:
*(int*)(l_fp - asBC_SWORDARG0(l_bc)) = *(int*)(l_fp - asBC_SWORDARG1(l_bc)) + *(int*)(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_SUBi:
*(int*)(l_fp - asBC_SWORDARG0(l_bc)) = *(int*)(l_fp - asBC_SWORDARG1(l_bc)) - *(int*)(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_MULi:
*(int*)(l_fp - asBC_SWORDARG0(l_bc)) = *(int*)(l_fp - asBC_SWORDARG1(l_bc)) * *(int*)(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_DIVi:
{
int divider = *(int*)(l_fp - asBC_SWORDARG2(l_bc));
if( divider == 0 )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_DIVIDE_BY_ZERO);
return;
}
else if( divider == -1 )
{
// Need to check if the value that is divided is 0x80000000
// as dividing it with -1 will cause an overflow exception
if( *(int*)(l_fp - asBC_SWORDARG1(l_bc)) == int(0x80000000) )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_DIVIDE_OVERFLOW);
return;
}
}
*(int*)(l_fp - asBC_SWORDARG0(l_bc)) = *(int*)(l_fp - asBC_SWORDARG1(l_bc)) / divider;
}
l_bc += 2;
break;
case asBC_MODi:
{
int divider = *(int*)(l_fp - asBC_SWORDARG2(l_bc));
if( divider == 0 )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_DIVIDE_BY_ZERO);
return;
}
else if( divider == -1 )
{
// Need to check if the value that is divided is 0x80000000
// as dividing it with -1 will cause an overflow exception
if( *(int*)(l_fp - asBC_SWORDARG1(l_bc)) == int(0x80000000) )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_DIVIDE_OVERFLOW);
return;
}
}
*(int*)(l_fp - asBC_SWORDARG0(l_bc)) = *(int*)(l_fp - asBC_SWORDARG1(l_bc)) % divider;
}
l_bc += 2;
break;
case asBC_ADDf:
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = *(float*)(l_fp - asBC_SWORDARG1(l_bc)) + *(float*)(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_SUBf:
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = *(float*)(l_fp - asBC_SWORDARG1(l_bc)) - *(float*)(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_MULf:
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = *(float*)(l_fp - asBC_SWORDARG1(l_bc)) * *(float*)(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_DIVf:
{
float divider = *(float*)(l_fp - asBC_SWORDARG2(l_bc));
if( divider == 0 )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_DIVIDE_BY_ZERO);
return;
}
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = *(float*)(l_fp - asBC_SWORDARG1(l_bc)) / divider;
}
l_bc += 2;
break;
case asBC_MODf:
{
float divider = *(float*)(l_fp - asBC_SWORDARG2(l_bc));
if( divider == 0 )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_DIVIDE_BY_ZERO);
return;
}
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = fmodf(*(float*)(l_fp - asBC_SWORDARG1(l_bc)), divider);
}
l_bc += 2;
break;
case asBC_ADDd:
*(double*)(l_fp - asBC_SWORDARG0(l_bc)) = *(double*)(l_fp - asBC_SWORDARG1(l_bc)) + *(double*)(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_SUBd:
*(double*)(l_fp - asBC_SWORDARG0(l_bc)) = *(double*)(l_fp - asBC_SWORDARG1(l_bc)) - *(double*)(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_MULd:
*(double*)(l_fp - asBC_SWORDARG0(l_bc)) = *(double*)(l_fp - asBC_SWORDARG1(l_bc)) * *(double*)(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_DIVd:
{
double divider = *(double*)(l_fp - asBC_SWORDARG2(l_bc));
if( divider == 0 )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_DIVIDE_BY_ZERO);
return;
}
*(double*)(l_fp - asBC_SWORDARG0(l_bc)) = *(double*)(l_fp - asBC_SWORDARG1(l_bc)) / divider;
l_bc += 2;
}
break;
case asBC_MODd:
{
double divider = *(double*)(l_fp - asBC_SWORDARG2(l_bc));
if( divider == 0 )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_DIVIDE_BY_ZERO);
return;
}
*(double*)(l_fp - asBC_SWORDARG0(l_bc)) = fmod(*(double*)(l_fp - asBC_SWORDARG1(l_bc)), divider);
l_bc += 2;
}
break;
//------------------------------
// Math operations with constant value
case asBC_ADDIi:
*(int*)(l_fp - asBC_SWORDARG0(l_bc)) = *(int*)(l_fp - asBC_SWORDARG1(l_bc)) + asBC_INTARG(l_bc+1);
l_bc += 3;
break;
case asBC_SUBIi:
*(int*)(l_fp - asBC_SWORDARG0(l_bc)) = *(int*)(l_fp - asBC_SWORDARG1(l_bc)) - asBC_INTARG(l_bc+1);
l_bc += 3;
break;
case asBC_MULIi:
*(int*)(l_fp - asBC_SWORDARG0(l_bc)) = *(int*)(l_fp - asBC_SWORDARG1(l_bc)) * asBC_INTARG(l_bc+1);
l_bc += 3;
break;
case asBC_ADDIf:
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = *(float*)(l_fp - asBC_SWORDARG1(l_bc)) + asBC_FLOATARG(l_bc+1);
l_bc += 3;
break;
case asBC_SUBIf:
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = *(float*)(l_fp - asBC_SWORDARG1(l_bc)) - asBC_FLOATARG(l_bc+1);
l_bc += 3;
break;
case asBC_MULIf:
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = *(float*)(l_fp - asBC_SWORDARG1(l_bc)) * asBC_FLOATARG(l_bc+1);
l_bc += 3;
break;
//-----------------------------------
case asBC_SetG4:
*(asDWORD*)asBC_PTRARG(l_bc) = asBC_DWORDARG(l_bc+AS_PTR_SIZE);
l_bc += 2 + AS_PTR_SIZE;
break;
case asBC_ChkRefS:
{
// Verify if the pointer on the stack refers to a non-null value
// This is used to validate a reference to a handle
asPWORD *a = (asPWORD*)*(asPWORD*)l_sp;
if( *a == 0 )
{
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
SetInternalException(TXT_NULL_POINTER_ACCESS);
return;
}
}
l_bc++;
break;
case asBC_ChkNullV:
{
// Verify if variable (on the stack) is not null
asDWORD *a = *(asDWORD**)(l_fp - asBC_SWORDARG0(l_bc));
if( a == 0 )
{
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
SetInternalException(TXT_NULL_POINTER_ACCESS);
return;
}
}
l_bc++;
break;
case asBC_CALLINTF:
{
int i = asBC_INTARG(l_bc);
l_bc += 2;
asASSERT( i >= 0 );
asASSERT( (i & FUNC_IMPORTED) == 0 );
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
CallInterfaceMethod(m_engine->GetScriptFunction(i));
// Extract the values from the context again
l_bc = m_regs.programPointer;
l_sp = m_regs.stackPointer;
l_fp = m_regs.stackFramePointer;
// If status isn't active anymore then we must stop
if( m_status != asEXECUTION_ACTIVE )
return;
}
break;
case asBC_iTOb:
{
// *(l_fp - offset) points to an int, and will point to a byte afterwards
// We need to use volatile here to tell the compiler not to rearrange
// read and write operations during optimizations.
volatile asDWORD val = *(l_fp - asBC_SWORDARG0(l_bc));
volatile asBYTE *bPtr = (asBYTE*)(l_fp - asBC_SWORDARG0(l_bc));
bPtr[0] = (asBYTE)val; // write the byte
bPtr[1] = 0; // 0 the rest of the DWORD
bPtr[2] = 0;
bPtr[3] = 0;
}
l_bc++;
break;
case asBC_iTOw:
{
// *(l_fp - offset) points to an int, and will point to word afterwards
// We need to use volatile here to tell the compiler not to rearrange
// read and write operations during optimizations.
volatile asDWORD val = *(l_fp - asBC_SWORDARG0(l_bc));
volatile asWORD *wPtr = (asWORD*)(l_fp - asBC_SWORDARG0(l_bc));
wPtr[0] = (asWORD)val; // write the word
wPtr[1] = 0; // 0 the rest of the DWORD
}
l_bc++;
break;
case asBC_SetV1:
// TODO: This is exactly the same as SetV4. This is a left over from the time
// when the bytecode instructions were more tightly packed. It can now
// be removed. When removing it, make sure the value is correctly converted
// on big-endian CPUs.
// The byte is already stored correctly in the argument
*(l_fp - asBC_SWORDARG0(l_bc)) = asBC_DWORDARG(l_bc);
l_bc += 2;
break;
case asBC_SetV2:
// TODO: This is exactly the same as SetV4. This is a left over from the time
// when the bytecode instructions were more tightly packed. It can now
// be removed. When removing it, make sure the value is correctly converted
// on big-endian CPUs.
// The word is already stored correctly in the argument
*(l_fp - asBC_SWORDARG0(l_bc)) = asBC_DWORDARG(l_bc);
l_bc += 2;
break;
case asBC_Cast:
// Cast the handle at the top of the stack to the type in the argument
{
asDWORD **a = (asDWORD**)*(asPWORD*)l_sp;
if( a && *a )
{
asDWORD typeId = asBC_DWORDARG(l_bc);
asCScriptObject *obj = (asCScriptObject *)* a;
asCObjectType *objType = obj->objType;
asCObjectType *to = m_engine->GetObjectTypeFromTypeId(typeId);
// This instruction can only be used with script classes and interfaces
asASSERT( objType->flags & asOBJ_SCRIPT_OBJECT );
asASSERT( to->flags & asOBJ_SCRIPT_OBJECT );
if( objType->Implements(to) || objType->DerivesFrom(to) )
{
m_regs.objectType = 0;
m_regs.objectRegister = obj;
obj->AddRef();
}
else
{
// The object register should already be null, so there
// is no need to clear it if the cast is unsuccessful
asASSERT( m_regs.objectRegister == 0 );
}
}
l_sp += AS_PTR_SIZE;
}
l_bc += 2;
break;
case asBC_i64TOi:
*(l_fp - asBC_SWORDARG0(l_bc)) = int(*(asINT64*)(l_fp - asBC_SWORDARG1(l_bc)));
l_bc += 2;
break;
case asBC_uTOi64:
*(asINT64*)(l_fp - asBC_SWORDARG0(l_bc)) = asINT64(*(asUINT*)(l_fp - asBC_SWORDARG1(l_bc)));
l_bc += 2;
break;
case asBC_iTOi64:
*(asINT64*)(l_fp - asBC_SWORDARG0(l_bc)) = asINT64(*(int*)(l_fp - asBC_SWORDARG1(l_bc)));
l_bc += 2;
break;
case asBC_fTOi64:
*(asINT64*)(l_fp - asBC_SWORDARG0(l_bc)) = asINT64(*(float*)(l_fp - asBC_SWORDARG1(l_bc)));
l_bc += 2;
break;
case asBC_dTOi64:
*(asINT64*)(l_fp - asBC_SWORDARG0(l_bc)) = asINT64(*(double*)(l_fp - asBC_SWORDARG0(l_bc)));
l_bc++;
break;
case asBC_fTOu64:
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = asQWORD(asINT64(*(float*)(l_fp - asBC_SWORDARG1(l_bc))));
l_bc += 2;
break;
case asBC_dTOu64:
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = asQWORD(asINT64(*(double*)(l_fp - asBC_SWORDARG0(l_bc))));
l_bc++;
break;
case asBC_i64TOf:
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = float(*(asINT64*)(l_fp - asBC_SWORDARG1(l_bc)));
l_bc += 2;
break;
case asBC_u64TOf:
#if defined(_MSC_VER) && _MSC_VER <= 1200 // MSVC6
{
// MSVC6 doesn't permit UINT64 to double
asINT64 v = *(asINT64*)(l_fp - asBC_SWORDARG1(l_bc));
if( v < 0 )
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = 18446744073709551615.0f+float(v);
else
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = float(v);
}
#else
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = float(*(asQWORD*)(l_fp - asBC_SWORDARG1(l_bc)));
#endif
l_bc += 2;
break;
case asBC_i64TOd:
*(double*)(l_fp - asBC_SWORDARG0(l_bc)) = double(*(asINT64*)(l_fp - asBC_SWORDARG0(l_bc)));
l_bc++;
break;
case asBC_u64TOd:
#if defined(_MSC_VER) && _MSC_VER <= 1200 // MSVC6
{
// MSVC6 doesn't permit UINT64 to double
asINT64 v = *(asINT64*)(l_fp - asBC_SWORDARG0(l_bc));
if( v < 0 )
*(double*)(l_fp - asBC_SWORDARG0(l_bc)) = 18446744073709551615.0+double(v);
else
*(double*)(l_fp - asBC_SWORDARG0(l_bc)) = double(v);
}
#else
*(double*)(l_fp - asBC_SWORDARG0(l_bc)) = double(*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)));
#endif
l_bc++;
break;
case asBC_NEGi64:
*(asINT64*)(l_fp - asBC_SWORDARG0(l_bc)) = -*(asINT64*)(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
case asBC_INCi64:
++(**(asQWORD**)&m_regs.valueRegister);
l_bc++;
break;
case asBC_DECi64:
--(**(asQWORD**)&m_regs.valueRegister);
l_bc++;
break;
case asBC_BNOT64:
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = ~*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
case asBC_ADDi64:
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asQWORD*)(l_fp - asBC_SWORDARG1(l_bc)) + *(asQWORD*)(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_SUBi64:
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asQWORD*)(l_fp - asBC_SWORDARG1(l_bc)) - *(asQWORD*)(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_MULi64:
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asQWORD*)(l_fp - asBC_SWORDARG1(l_bc)) * *(asQWORD*)(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_DIVi64:
{
asINT64 divider = *(asINT64*)(l_fp - asBC_SWORDARG2(l_bc));
if( divider == 0 )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_DIVIDE_BY_ZERO);
return;
}
else if( divider == -1 )
{
// Need to check if the value that is divided is 1<<63
// as dividing it with -1 will cause an overflow exception
if( *(asINT64*)(l_fp - asBC_SWORDARG1(l_bc)) == (asINT64(1)<<63) )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_DIVIDE_OVERFLOW);
return;
}
}
*(asINT64*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asINT64*)(l_fp - asBC_SWORDARG1(l_bc)) / divider;
}
l_bc += 2;
break;
case asBC_MODi64:
{
asINT64 divider = *(asINT64*)(l_fp - asBC_SWORDARG2(l_bc));
if( divider == 0 )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_DIVIDE_BY_ZERO);
return;
}
else if( divider == -1 )
{
// Need to check if the value that is divided is 1<<63
// as dividing it with -1 will cause an overflow exception
if( *(asINT64*)(l_fp - asBC_SWORDARG1(l_bc)) == (asINT64(1)<<63) )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_DIVIDE_OVERFLOW);
return;
}
}
*(asINT64*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asINT64*)(l_fp - asBC_SWORDARG1(l_bc)) % divider;
}
l_bc += 2;
break;
case asBC_BAND64:
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asQWORD*)(l_fp - asBC_SWORDARG1(l_bc)) & *(asQWORD*)(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_BOR64:
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asQWORD*)(l_fp - asBC_SWORDARG1(l_bc)) | *(asQWORD*)(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_BXOR64:
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asQWORD*)(l_fp - asBC_SWORDARG1(l_bc)) ^ *(asQWORD*)(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_BSLL64:
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asQWORD*)(l_fp - asBC_SWORDARG1(l_bc)) << *(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_BSRL64:
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asQWORD*)(l_fp - asBC_SWORDARG1(l_bc)) >> *(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_BSRA64:
*(asINT64*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asINT64*)(l_fp - asBC_SWORDARG1(l_bc)) >> *(l_fp - asBC_SWORDARG2(l_bc));
l_bc += 2;
break;
case asBC_CMPi64:
{
asINT64 i1 = *(asINT64*)(l_fp - asBC_SWORDARG0(l_bc));
asINT64 i2 = *(asINT64*)(l_fp - asBC_SWORDARG1(l_bc));
if( i1 == i2 ) *(int*)&m_regs.valueRegister = 0;
else if( i1 < i2 ) *(int*)&m_regs.valueRegister = -1;
else *(int*)&m_regs.valueRegister = 1;
l_bc += 2;
}
break;
case asBC_CMPu64:
{
asQWORD d1 = *(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc));
asQWORD d2 = *(asQWORD*)(l_fp - asBC_SWORDARG1(l_bc));
if( d1 == d2 ) *(int*)&m_regs.valueRegister = 0;
else if( d1 < d2 ) *(int*)&m_regs.valueRegister = -1;
else *(int*)&m_regs.valueRegister = 1;
l_bc += 2;
}
break;
case asBC_ChkNullS:
{
// Verify if the pointer on the stack is null
// This is used for example when validating handles passed as function arguments
asPWORD a = *(asPWORD*)(l_sp + asBC_WORDARG0(l_bc));
if( a == 0 )
{
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
SetInternalException(TXT_NULL_POINTER_ACCESS);
return;
}
}
l_bc++;
break;
case asBC_ClrHi:
#if AS_SIZEOF_BOOL == 1
{
// Clear the upper bytes, so that trash data don't interfere with boolean operations
// We need to use volatile here to tell the compiler it cannot
// change the order of read and write operations on the pointer.
volatile asBYTE *ptr = (asBYTE*)&m_regs.valueRegister;
ptr[1] = 0; // The boolean value is stored in the lower byte, so we clear the rest
ptr[2] = 0;
ptr[3] = 0;
}
#else
// We don't have anything to do here
#endif
l_bc++;
break;
case asBC_JitEntry:
{
if( m_currentFunction->scriptData->jitFunction )
{
asPWORD jitArg = asBC_PTRARG(l_bc);
if( jitArg )
{
// Resume JIT operation
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
(m_currentFunction->scriptData->jitFunction)(&m_regs, jitArg);
l_bc = m_regs.programPointer;
l_sp = m_regs.stackPointer;
l_fp = m_regs.stackFramePointer;
// If status isn't active anymore then we must stop
if( m_status != asEXECUTION_ACTIVE )
return;
break;
}
}
// Not a JIT resume point, treat as nop
l_bc += 1+AS_PTR_SIZE;
}
break;
case asBC_CallPtr:
{
// Get the function pointer from the local variable
asCScriptFunction *func = *(asCScriptFunction**)(l_fp - asBC_SWORDARG0(l_bc));
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
if( func == 0 )
{
// Need to update the program pointer anyway for the exception handler
m_regs.programPointer++;
// Tell the exception handler to clean up the arguments to this method
m_needToCleanupArgs = true;
// TODO: funcdef: Should we have a different exception string?
SetInternalException(TXT_UNBOUND_FUNCTION);
return;
}
else
{
if( func->funcType == asFUNC_SCRIPT )
{
m_regs.programPointer++;
CallScriptFunction(func);
}
else if( func->funcType == asFUNC_DELEGATE )
{
// Push the object pointer on the stack. There is always a reserved space for this so
// we don't don't need to worry about overflowing the allocated memory buffer
asASSERT( m_regs.stackPointer - AS_PTR_SIZE >= m_stackBlocks[m_stackIndex] );
m_regs.stackPointer -= AS_PTR_SIZE;
*(asPWORD*)m_regs.stackPointer = asPWORD(func->objForDelegate);
// Call the delegated method
if( func->funcForDelegate->funcType == asFUNC_SYSTEM )
{
m_regs.stackPointer += CallSystemFunction(func->funcForDelegate->id, this);
// Update program position after the call so the line number
// is correct in case the system function queries it
m_regs.programPointer++;
}
else
{
m_regs.programPointer++;
// TODO: run-time optimize: The true method could be figured out when creating the delegate
CallInterfaceMethod(func->funcForDelegate);
}
}
else
{
asASSERT( func->funcType == asFUNC_SYSTEM );
m_regs.stackPointer += CallSystemFunction(func->id, this);
// Update program position after the call so the line number
// is correct in case the system function queries it
m_regs.programPointer++;
}
}
// Extract the values from the context again
l_bc = m_regs.programPointer;
l_sp = m_regs.stackPointer;
l_fp = m_regs.stackFramePointer;
// If status isn't active anymore then we must stop
if( m_status != asEXECUTION_ACTIVE )
return;
}
break;
case asBC_FuncPtr:
// Push the function pointer on the stack. The pointer is in the argument
l_sp -= AS_PTR_SIZE;
*(asPWORD*)l_sp = asBC_PTRARG(l_bc);
l_bc += 1+AS_PTR_SIZE;
break;
case asBC_LoadThisR:
{
// PshVPtr 0
asPWORD tmp = *(asPWORD*)l_fp;
// Make sure the pointer is not null
if( tmp == 0 )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_NULL_POINTER_ACCESS);
return;
}
// ADDSi
tmp = tmp + asBC_SWORDARG0(l_bc);
// PopRPtr
*(asPWORD*)&m_regs.valueRegister = tmp;
l_bc += 2;
}
break;
// Push the qword value of a variable on the stack
case asBC_PshV8:
l_sp -= 2;
*(asQWORD*)l_sp = *(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc));
l_bc++;
break;
case asBC_DIVu:
{
asUINT divider = *(asUINT*)(l_fp - asBC_SWORDARG2(l_bc));
if( divider == 0 )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_DIVIDE_BY_ZERO);
return;
}
*(asUINT*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asUINT*)(l_fp - asBC_SWORDARG1(l_bc)) / divider;
}
l_bc += 2;
break;
case asBC_MODu:
{
asUINT divider = *(asUINT*)(l_fp - asBC_SWORDARG2(l_bc));
if( divider == 0 )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_DIVIDE_BY_ZERO);
return;
}
*(asUINT*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asUINT*)(l_fp - asBC_SWORDARG1(l_bc)) % divider;
}
l_bc += 2;
break;
case asBC_DIVu64:
{
asQWORD divider = *(asQWORD*)(l_fp - asBC_SWORDARG2(l_bc));
if( divider == 0 )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_DIVIDE_BY_ZERO);
return;
}
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asQWORD*)(l_fp - asBC_SWORDARG1(l_bc)) / divider;
}
l_bc += 2;
break;
case asBC_MODu64:
{
asQWORD divider = *(asQWORD*)(l_fp - asBC_SWORDARG2(l_bc));
if( divider == 0 )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_DIVIDE_BY_ZERO);
return;
}
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = *(asQWORD*)(l_fp - asBC_SWORDARG1(l_bc)) % divider;
}
l_bc += 2;
break;
case asBC_LoadRObjR:
{
// PshVPtr x
asPWORD tmp = *(asPWORD*)(l_fp - asBC_SWORDARG0(l_bc));
// Make sure the pointer is not null
if( tmp == 0 )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_NULL_POINTER_ACCESS);
return;
}
// ADDSi y
tmp = tmp + asBC_SWORDARG1(l_bc);
// PopRPtr
*(asPWORD*)&m_regs.valueRegister = tmp;
l_bc += 3;
}
break;
case asBC_LoadVObjR:
{
// PSF x
asPWORD tmp = (asPWORD)(l_fp - asBC_SWORDARG0(l_bc));
// ADDSi y
tmp = tmp + asBC_SWORDARG1(l_bc);
// PopRPtr
*(asPWORD*)&m_regs.valueRegister = tmp;
l_bc += 3;
}
break;
case asBC_RefCpyV:
// Same as PSF v, REFCPY
{
asCObjectType *objType = (asCObjectType*)asBC_PTRARG(l_bc);
asSTypeBehaviour *beh = &objType->beh;
// Determine destination from argument
void **d = (void**)asPWORD(l_fp - asBC_SWORDARG0(l_bc));
// Read wanted pointer from the stack
void *s = (void*)*(asPWORD*)l_sp;
// Need to move the values back to the context as the called functions
// may use the debug interface to inspect the registers
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
if( !(objType->flags & asOBJ_NOCOUNT) )
{
// Release previous object held by destination pointer
if( *d != 0 && beh->release )
m_engine->CallObjectMethod(*d, beh->release);
// Increase ref counter of wanted object
if( s != 0 && beh->addref )
m_engine->CallObjectMethod(s, beh->addref);
}
// Set the new object in the destination
*d = s;
}
l_bc += 1+AS_PTR_SIZE;
break;
case asBC_JLowZ:
if( *(asBYTE*)&m_regs.valueRegister == 0 )
l_bc += asBC_INTARG(l_bc) + 2;
else
l_bc += 2;
break;
case asBC_JLowNZ:
if( *(asBYTE*)&m_regs.valueRegister != 0 )
l_bc += asBC_INTARG(l_bc) + 2;
else
l_bc += 2;
break;
case asBC_AllocMem:
// Allocate a buffer and store the pointer in the local variable
{
// TODO: runtime optimize: As the list buffers are going to be short lived, it may be interesting
// to use a memory pool to avoid reallocating the memory all the time
asUINT size = asBC_DWORDARG(l_bc);
asBYTE **var = (asBYTE**)(l_fp - asBC_SWORDARG0(l_bc));
#ifndef WIP_16BYTE_ALIGN
*var = asNEWARRAY(asBYTE, size);
#else
*var = asNEWARRAYALIGNED(asBYTE, size, MAX_TYPE_ALIGNMENT);
#endif
// Clear the buffer for the pointers that will be placed in it
memset(*var, 0, size);
}
l_bc += 2;
break;
case asBC_SetListSize:
{
// Set the size element in the buffer
asBYTE *var = *(asBYTE**)(l_fp - asBC_SWORDARG0(l_bc));
asUINT off = asBC_DWORDARG(l_bc);
asUINT size = asBC_DWORDARG(l_bc+1);
asASSERT( var );
*(asUINT*)(var+off) = size;
}
l_bc += 3;
break;
case asBC_PshListElmnt:
{
// Push the pointer to the list element on the stack
// In essence it does the same as PSF, RDSPtr, ADDSi
asBYTE *var = *(asBYTE**)(l_fp - asBC_SWORDARG0(l_bc));
asUINT off = asBC_DWORDARG(l_bc);
asASSERT( var );
l_sp -= AS_PTR_SIZE;
*(asPWORD*)l_sp = asPWORD(var+off);
}
l_bc += 2;
break;
case asBC_SetListType:
{
// Set the type id in the buffer
asBYTE *var = *(asBYTE**)(l_fp - asBC_SWORDARG0(l_bc));
asUINT off = asBC_DWORDARG(l_bc);
asUINT type = asBC_DWORDARG(l_bc+1);
asASSERT( var );
*(asUINT*)(var+off) = type;
}
l_bc += 3;
break;
//------------------------------
// Exponent operations
case asBC_POWi:
{
bool isOverflow;
*(int*)(l_fp - asBC_SWORDARG0(l_bc)) = as_powi(*(int*)(l_fp - asBC_SWORDARG1(l_bc)), *(int*)(l_fp - asBC_SWORDARG2(l_bc)), isOverflow);
if( isOverflow )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_POW_OVERFLOW);
return;
}
}
l_bc += 2;
break;
case asBC_POWu:
{
bool isOverflow;
*(asDWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = as_powu(*(asDWORD*)(l_fp - asBC_SWORDARG1(l_bc)), *(asDWORD*)(l_fp - asBC_SWORDARG2(l_bc)), isOverflow);
if( isOverflow )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_POW_OVERFLOW);
return;
}
}
l_bc += 2;
break;
case asBC_POWf:
{
float r = powf(*(float*)(l_fp - asBC_SWORDARG1(l_bc)), *(float*)(l_fp - asBC_SWORDARG2(l_bc)));
*(float*)(l_fp - asBC_SWORDARG0(l_bc)) = r;
if( r == float(HUGE_VAL) )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_POW_OVERFLOW);
return;
}
}
l_bc += 2;
break;
case asBC_POWd:
{
double r = pow(*(double*)(l_fp - asBC_SWORDARG1(l_bc)), *(double*)(l_fp - asBC_SWORDARG2(l_bc)));
*(double*)(l_fp - asBC_SWORDARG0(l_bc)) = r;
if( r == HUGE_VAL )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_POW_OVERFLOW);
return;
}
}
l_bc += 2;
break;
case asBC_POWdi:
{
double r = pow(*(double*)(l_fp - asBC_SWORDARG1(l_bc)), *(int*)(l_fp - asBC_SWORDARG2(l_bc)));
*(double*)(l_fp - asBC_SWORDARG0(l_bc)) = r;
if( r == HUGE_VAL )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_POW_OVERFLOW);
return;
}
l_bc += 2;
}
break;
case asBC_POWi64:
{
bool isOverflow;
*(asINT64*)(l_fp - asBC_SWORDARG0(l_bc)) = as_powi64(*(asINT64*)(l_fp - asBC_SWORDARG1(l_bc)), *(asINT64*)(l_fp - asBC_SWORDARG2(l_bc)), isOverflow);
if( isOverflow )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_POW_OVERFLOW);
return;
}
}
l_bc += 2;
break;
case asBC_POWu64:
{
bool isOverflow;
*(asQWORD*)(l_fp - asBC_SWORDARG0(l_bc)) = as_powu64(*(asQWORD*)(l_fp - asBC_SWORDARG1(l_bc)), *(asQWORD*)(l_fp - asBC_SWORDARG2(l_bc)), isOverflow);
if( isOverflow )
{
// Need to move the values back to the context
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Raise exception
SetInternalException(TXT_POW_OVERFLOW);
return;
}
}
l_bc += 2;
break;
case asBC_Thiscall1:
// This instruction is a faster version of asBC_CALLSYS. It is faster because
// it has much less runtime overhead with determining the calling convention
// and no dynamic code for loading the parameters. The instruction can only
// be used to call functions with the following signatures:
//
// type &obj::func(int)
// type &obj::func(uint)
// void obj::func(int)
// void obj::func(uint)
{
// Get function ID from the argument
int i = asBC_INTARG(l_bc);
// Need to move the values back to the context as the called functions
// may use the debug interface to inspect the registers
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
// Pop the thispointer from the stack
void *obj = *(void**)l_sp;
if (obj == 0)
SetInternalException(TXT_NULL_POINTER_ACCESS);
else
{
// Only update the stack pointer if all is OK so the
// exception handler can properly clean up the stack
l_sp += AS_PTR_SIZE;
// Pop the int arg from the stack
int arg = *(int*)l_sp;
l_sp++;
// Call the method
m_callingSystemFunction = m_engine->scriptFunctions[i];
void *ptr = 0;
#ifdef AS_NO_EXCEPTIONS
ptr = m_engine->CallObjectMethodRetPtr(obj, arg, m_callingSystemFunction);
#else
// This try/catch block is to catch potential exception that may
// be thrown by the registered function.
try
{
ptr = m_engine->CallObjectMethodRetPtr(obj, arg, m_callingSystemFunction);
}
catch (...)
{
// Convert the exception to a script exception so the VM can
// properly report the error to the application and then clean up
HandleAppException();
}
#endif
m_callingSystemFunction = 0;
*(asPWORD*)&m_regs.valueRegister = (asPWORD)ptr;
}
// Update the program position after the call so that line number is correct
l_bc += 2;
if( m_regs.doProcessSuspend )
{
// Should the execution be suspended?
if( m_doSuspend )
{
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
m_status = asEXECUTION_SUSPENDED;
return;
}
// An exception might have been raised
if( m_status != asEXECUTION_ACTIVE )
{
m_regs.programPointer = l_bc;
m_regs.stackPointer = l_sp;
m_regs.stackFramePointer = l_fp;
return;
}
}
}
break;
// Don't let the optimizer optimize for size,
// since it requires extra conditions and jumps
case 201: l_bc = (asDWORD*)201; break;
case 202: l_bc = (asDWORD*)202; break;
case 203: l_bc = (asDWORD*)203; break;
case 204: l_bc = (asDWORD*)204; break;
case 205: l_bc = (asDWORD*)205; break;
case 206: l_bc = (asDWORD*)206; break;
case 207: l_bc = (asDWORD*)207; break;
case 208: l_bc = (asDWORD*)208; break;
case 209: l_bc = (asDWORD*)209; break;
case 210: l_bc = (asDWORD*)210; break;
case 211: l_bc = (asDWORD*)211; break;
case 212: l_bc = (asDWORD*)212; break;
case 213: l_bc = (asDWORD*)213; break;
case 214: l_bc = (asDWORD*)214; break;
case 215: l_bc = (asDWORD*)215; break;
case 216: l_bc = (asDWORD*)216; break;
case 217: l_bc = (asDWORD*)217; break;
case 218: l_bc = (asDWORD*)218; break;
case 219: l_bc = (asDWORD*)219; break;
case 220: l_bc = (asDWORD*)220; break;
case 221: l_bc = (asDWORD*)221; break;
case 222: l_bc = (asDWORD*)222; break;
case 223: l_bc = (asDWORD*)223; break;
case 224: l_bc = (asDWORD*)224; break;
case 225: l_bc = (asDWORD*)225; break;
case 226: l_bc = (asDWORD*)226; break;
case 227: l_bc = (asDWORD*)227; break;
case 228: l_bc = (asDWORD*)228; break;
case 229: l_bc = (asDWORD*)229; break;
case 230: l_bc = (asDWORD*)230; break;
case 231: l_bc = (asDWORD*)231; break;
case 232: l_bc = (asDWORD*)232; break;
case 233: l_bc = (asDWORD*)233; break;
case 234: l_bc = (asDWORD*)234; break;
case 235: l_bc = (asDWORD*)235; break;
case 236: l_bc = (asDWORD*)236; break;
case 237: l_bc = (asDWORD*)237; break;
case 238: l_bc = (asDWORD*)238; break;
case 239: l_bc = (asDWORD*)239; break;
case 240: l_bc = (asDWORD*)240; break;
case 241: l_bc = (asDWORD*)241; break;
case 242: l_bc = (asDWORD*)242; break;
case 243: l_bc = (asDWORD*)243; break;
case 244: l_bc = (asDWORD*)244; break;
case 245: l_bc = (asDWORD*)245; break;
case 246: l_bc = (asDWORD*)246; break;
case 247: l_bc = (asDWORD*)247; break;
case 248: l_bc = (asDWORD*)248; break;
case 249: l_bc = (asDWORD*)249; break;
case 250: l_bc = (asDWORD*)250; break;
case 251: l_bc = (asDWORD*)251; break;
case 252: l_bc = (asDWORD*)252; break;
case 253: l_bc = (asDWORD*)253; break;
case 254: l_bc = (asDWORD*)254; break;
case 255: l_bc = (asDWORD*)255; break;
#ifdef AS_DEBUG
default:
asASSERT(false);
SetInternalException(TXT_UNRECOGNIZED_BYTE_CODE);
#endif
#if defined(_MSC_VER) && !defined(AS_DEBUG)
default:
// This Microsoft specific code allows the
// compiler to optimize the switch case as
// it will know that the code will never
// reach this point
__assume(0);
#endif
}
#ifdef AS_DEBUG
asDWORD instr = *(asBYTE*)old;
if( instr != asBC_JMP && instr != asBC_JMPP && (instr < asBC_JZ || instr > asBC_JNP) && instr != asBC_JLowZ && instr != asBC_JLowNZ &&
instr != asBC_CALL && instr != asBC_CALLBND && instr != asBC_CALLINTF && instr != asBC_RET && instr != asBC_ALLOC && instr != asBC_CallPtr &&
instr != asBC_JitEntry )
{
asASSERT( (l_bc - old) == asBCTypeSize[asBCInfo[instr].type] );
}
#endif
}
}
// interface
int asCContext::SetException(const char *descr, bool allowCatch)
{
// Only allow this if we're executing a CALL byte code
if( m_callingSystemFunction == 0 ) return asERROR;
SetInternalException(descr, allowCatch);
return 0;
}
void asCContext::SetInternalException(const char *descr, bool allowCatch)
{
if( m_inExceptionHandler )
{
asASSERT(false); // Shouldn't happen
return; // but if it does, at least this will not crash the application
}
m_status = asEXECUTION_EXCEPTION;
m_regs.doProcessSuspend = true;
m_exceptionString = descr;
m_exceptionFunction = m_currentFunction->id;
if( m_currentFunction->scriptData )
{
m_exceptionLine = m_currentFunction->GetLineNumber(int(m_regs.programPointer - m_currentFunction->scriptData->byteCode.AddressOf()), &m_exceptionSectionIdx);
m_exceptionColumn = m_exceptionLine >> 20;
m_exceptionLine &= 0xFFFFF;
}
else
{
m_exceptionSectionIdx = 0;
m_exceptionLine = 0;
m_exceptionColumn = 0;
}
// Recursively search the callstack for try/catch blocks
m_exceptionWillBeCaught = allowCatch && FindExceptionTryCatch();
if( m_exceptionCallback )
CallExceptionCallback();
}
// interface
bool asCContext::WillExceptionBeCaught()
{
return m_exceptionWillBeCaught;
}
void asCContext::CleanReturnObject()
{
if( m_initialFunction && m_initialFunction->DoesReturnOnStack() && m_status == asEXECUTION_FINISHED )
{
// If function returns on stack we need to call the destructor on the returned object
if(CastToObjectType(m_initialFunction->returnType.GetTypeInfo())->beh.destruct )
m_engine->CallObjectMethod(GetReturnObject(), CastToObjectType(m_initialFunction->returnType.GetTypeInfo())->beh.destruct);
return;
}
if( m_regs.objectRegister == 0 ) return;
asASSERT( m_regs.objectType != 0 );
if( m_regs.objectType )
{
if (m_regs.objectType->GetFlags() & asOBJ_FUNCDEF)
{
// Release the function pointer
reinterpret_cast<asIScriptFunction*>(m_regs.objectRegister)->Release();
m_regs.objectRegister = 0;
}
else
{
// Call the destructor on the object
asSTypeBehaviour *beh = &(CastToObjectType(reinterpret_cast<asCTypeInfo*>(m_regs.objectType))->beh);
if (m_regs.objectType->GetFlags() & asOBJ_REF)
{
asASSERT(beh->release || (m_regs.objectType->GetFlags() & asOBJ_NOCOUNT));
if (beh->release)
m_engine->CallObjectMethod(m_regs.objectRegister, beh->release);
m_regs.objectRegister = 0;
}
else
{
if (beh->destruct)
m_engine->CallObjectMethod(m_regs.objectRegister, beh->destruct);
// Free the memory
m_engine->CallFree(m_regs.objectRegister);
m_regs.objectRegister = 0;
}
}
}
}
void asCContext::CleanStack(bool catchException)
{
m_inExceptionHandler = true;
// Run the clean up code and move to catch block
bool caught = CleanStackFrame(catchException);
if( !caught )
{
// Set the status to exception so that the stack unwind is done correctly.
// This shouldn't be done for the current function, which is why we only
// do this after the first CleanStackFrame() is done.
m_status = asEXECUTION_EXCEPTION;
while (!caught && m_callStack.GetLength() > 0)
{
// Only clean up until the top most marker for a nested call
asPWORD *s = m_callStack.AddressOf() + m_callStack.GetLength() - CALLSTACK_FRAME_SIZE;
if (s[0] == 0)
break;
PopCallState();
caught = CleanStackFrame(catchException);
}
}
// If the exception was caught, then move the status to
// active as is now possible to resume the execution
if (caught)
m_status = asEXECUTION_ACTIVE;
m_inExceptionHandler = false;
}
// Interface
bool asCContext::IsVarInScope(asUINT varIndex, asUINT stackLevel)
{
// Don't return anything if there is no bytecode, e.g. before calling Execute()
if( m_regs.programPointer == 0 ) return false;
if( stackLevel >= GetCallstackSize() ) return false;
asCScriptFunction *func;
asUINT pos;
if( stackLevel == 0 )
{
func = m_currentFunction;
if( func->scriptData == 0 ) return false;
pos = asUINT(m_regs.programPointer - func->scriptData->byteCode.AddressOf());
}
else
{
asPWORD *s = m_callStack.AddressOf() + (GetCallstackSize()-stackLevel-1)*CALLSTACK_FRAME_SIZE;
func = (asCScriptFunction*)s[1];
if( func->scriptData == 0 ) return false;
pos = asUINT((asDWORD*)s[2] - func->scriptData->byteCode.AddressOf());
}
// First determine if the program position is after the variable declaration
if( func->scriptData->variables.GetLength() <= varIndex ) return false;
if( func->scriptData->variables[varIndex]->declaredAtProgramPos > pos ) return false;
asUINT declaredAt = func->scriptData->variables[varIndex]->declaredAtProgramPos;
// If the program position is after the variable declaration it is necessary
// determine if the program position is still inside the statement block where
// the variable was delcared.
for( int n = 0; n < (int)func->scriptData->objVariableInfo.GetLength(); n++ )
{
if( func->scriptData->objVariableInfo[n].programPos >= declaredAt )
{
// If the current block ends between the declaredAt and current
// program position, then we know the variable is no longer visible
int level = 0;
for( ; n < (int)func->scriptData->objVariableInfo.GetLength(); n++ )
{
if( func->scriptData->objVariableInfo[n].programPos > pos )
break;
if( func->scriptData->objVariableInfo[n].option == asBLOCK_BEGIN ) level++;
if( func->scriptData->objVariableInfo[n].option == asBLOCK_END && --level < 0 )
return false;
}
break;
}
}
// Variable is visible
return true;
}
// Internal
void asCContext::DetermineLiveObjects(asCArray<int> &liveObjects, asUINT stackLevel)
{
asASSERT( stackLevel < GetCallstackSize() );
asCScriptFunction *func;
asUINT pos;
if( stackLevel == 0 )
{
func = m_currentFunction;
if( func->scriptData == 0 )
return;
pos = asUINT(m_regs.programPointer - func->scriptData->byteCode.AddressOf());
if( m_status == asEXECUTION_EXCEPTION )
{
// Don't consider the last instruction as executed, as it failed with an exception
// It's not actually necessary to decrease the exact size of the instruction. Just
// before the current position is enough to disconsider it.
pos--;
}
}
else
{
asPWORD *s = m_callStack.AddressOf() + (GetCallstackSize()-stackLevel-1)*CALLSTACK_FRAME_SIZE;
func = (asCScriptFunction*)s[1];
if( func->scriptData == 0 )
return;
pos = asUINT((asDWORD*)s[2] - func->scriptData->byteCode.AddressOf());
// Don't consider the last instruction as executed, as the function that was called by it
// is still being executed. If we consider it as executed already, then a value object
// returned by value would be considered alive, which it is not.
pos--;
}
// Determine which object variables that are really live ones
liveObjects.SetLength(func->scriptData->objVariablePos.GetLength());
memset(liveObjects.AddressOf(), 0, sizeof(int)*liveObjects.GetLength());
for( int n = 0; n < (int)func->scriptData->objVariableInfo.GetLength(); n++ )
{
// Find the first variable info with a larger position than the current
// As the variable info are always placed on the instruction right after the
// one that initialized or freed the object, the current position needs to be
// considered as valid.
if( func->scriptData->objVariableInfo[n].programPos > pos )
{
// We've determined how far the execution ran, now determine which variables are alive
for( --n; n >= 0; n-- )
{
switch( func->scriptData->objVariableInfo[n].option )
{
case asOBJ_UNINIT: // Object was destroyed
{
// TODO: optimize: This should have been done by the compiler already
// Which variable is this?
asUINT var = 0;
for( asUINT v = 0; v < func->scriptData->objVariablePos.GetLength(); v++ )
if( func->scriptData->objVariablePos[v] == func->scriptData->objVariableInfo[n].variableOffset )
{
var = v;
break;
}
liveObjects[var] -= 1;
}
break;
case asOBJ_INIT: // Object was created
{
// Which variable is this?
asUINT var = 0;
for( asUINT v = 0; v < func->scriptData->objVariablePos.GetLength(); v++ )
if( func->scriptData->objVariablePos[v] == func->scriptData->objVariableInfo[n].variableOffset )
{
var = v;
break;
}
liveObjects[var] += 1;
}
break;
case asBLOCK_BEGIN: // Start block
// We should ignore start blocks, since it just means the
// program was within the block when the exception occurred
break;
case asBLOCK_END: // End block
// We need to skip the entire block, as the objects created
// and destroyed inside this block are already out of scope
{
int nested = 1;
while( nested > 0 )
{
int option = func->scriptData->objVariableInfo[--n].option;
if( option == 3 )
nested++;
if( option == 2 )
nested--;
}
}
break;
case asOBJ_VARDECL: // A variable was declared
// We don't really care about the variable declarations at this moment
break;
}
}
// We're done with the investigation
break;
}
}
}
void asCContext::CleanArgsOnStack()
{
if( !m_needToCleanupArgs )
return;
asASSERT( m_currentFunction->scriptData );
// Find the instruction just before the current program pointer
asDWORD *instr = m_currentFunction->scriptData->byteCode.AddressOf();
asDWORD *prevInstr = 0;
while( instr < m_regs.programPointer )
{
prevInstr = instr;
instr += asBCTypeSize[asBCInfo[*(asBYTE*)(instr)].type];
}
// Determine what function was being called
asCScriptFunction *func = 0;
asBYTE bc = *(asBYTE*)prevInstr;
if( bc == asBC_CALL || bc == asBC_CALLSYS || bc == asBC_CALLINTF )
{
int funcId = asBC_INTARG(prevInstr);
func = m_engine->scriptFunctions[funcId];
}
else if( bc == asBC_CALLBND )
{
int funcId = asBC_INTARG(prevInstr);
func = m_engine->importedFunctions[funcId & ~FUNC_IMPORTED]->importedFunctionSignature;
}
else if( bc == asBC_CallPtr )
{
asUINT v;
int var = asBC_SWORDARG0(prevInstr);
// Find the funcdef from the local variable
for( v = 0; v < m_currentFunction->scriptData->objVariablePos.GetLength(); v++ )
if( m_currentFunction->scriptData->objVariablePos[v] == var )
{
func = CastToFuncdefType(m_currentFunction->scriptData->objVariableTypes[v])->funcdef;
break;
}
if( func == 0 )
{
// Look in parameters
int paramPos = 0;
if( m_currentFunction->objectType )
paramPos -= AS_PTR_SIZE;
if( m_currentFunction->DoesReturnOnStack() )
paramPos -= AS_PTR_SIZE;
for( v = 0; v < m_currentFunction->parameterTypes.GetLength(); v++ )
{
if( var == paramPos )
{
if (m_currentFunction->parameterTypes[v].IsFuncdef())
func = CastToFuncdefType(m_currentFunction->parameterTypes[v].GetTypeInfo())->funcdef;
break;
}
paramPos -= m_currentFunction->parameterTypes[v].GetSizeOnStackDWords();
}
}
}
else
asASSERT( false );
asASSERT( func );
// Clean parameters
int offset = 0;
if( func->objectType )
offset += AS_PTR_SIZE;
if( func->DoesReturnOnStack() )
offset += AS_PTR_SIZE;
for( asUINT n = 0; n < func->parameterTypes.GetLength(); n++ )
{
if( (func->parameterTypes[n].IsObject() || func->parameterTypes[n].IsFuncdef()) && !func->parameterTypes[n].IsReference() )
{
// TODO: cleanup: This logic is repeated twice in CleanStackFrame too. Should create a common function to share the code
if( *(asPWORD*)&m_regs.stackPointer[offset] )
{
// Call the object's destructor
asSTypeBehaviour *beh = func->parameterTypes[n].GetBehaviour();
if (func->parameterTypes[n].GetTypeInfo()->flags & asOBJ_FUNCDEF)
{
(*(asCScriptFunction**)&m_regs.stackPointer[offset])->Release();
}
else if( func->parameterTypes[n].GetTypeInfo()->flags & asOBJ_REF )
{
asASSERT( (func->parameterTypes[n].GetTypeInfo()->flags & asOBJ_NOCOUNT) || beh->release );
if( beh->release )
m_engine->CallObjectMethod((void*)*(asPWORD*)&m_regs.stackPointer[offset], beh->release);
}
else
{
if( beh->destruct )
m_engine->CallObjectMethod((void*)*(asPWORD*)&m_regs.stackPointer[offset], beh->destruct);
// Free the memory
m_engine->CallFree((void*)*(asPWORD*)&m_regs.stackPointer[offset]);
}
*(asPWORD*)&m_regs.stackPointer[offset] = 0;
}
}
offset += func->parameterTypes[n].GetSizeOnStackDWords();
}
m_needToCleanupArgs = false;
}
bool asCContext::FindExceptionTryCatch()
{
// Check each of the script functions on the callstack to see if
// the current program position is within a try/catch block
if (m_currentFunction && m_currentFunction->scriptData)
{
asUINT currPos = asUINT(m_regs.programPointer - m_currentFunction->scriptData->byteCode.AddressOf());
for (asUINT n = 0; n < m_currentFunction->scriptData->tryCatchInfo.GetLength(); n++)
{
if (currPos >= m_currentFunction->scriptData->tryCatchInfo[n].tryPos &&
currPos < m_currentFunction->scriptData->tryCatchInfo[n].catchPos)
return true;
}
}
int stackSize = GetCallstackSize();
for (int level = 1; level < stackSize; level++)
{
asPWORD *s = m_callStack.AddressOf() + (stackSize - level - 1)*CALLSTACK_FRAME_SIZE;
asCScriptFunction *func = (asCScriptFunction*)s[1];
if (func && func->scriptData)
{
asUINT currPos = asUINT((asDWORD*)s[2] - func->scriptData->byteCode.AddressOf());
for (asUINT n = 0; n < func->scriptData->tryCatchInfo.GetLength(); n++)
{
if (currPos >= func->scriptData->tryCatchInfo[n].tryPos &&
currPos < func->scriptData->tryCatchInfo[n].catchPos)
return true;
}
}
}
return false;
}
bool asCContext::CleanStackFrame(bool catchException)
{
bool exceptionCaught = false;
asSTryCatchInfo *tryCatchInfo = 0;
// Clean object variables on the stack
// If the stack memory is not allocated or the program pointer
// is not set, then there is nothing to clean up on the stack frame
if( !m_isStackMemoryNotAllocated && m_regs.programPointer )
{
// If the exception occurred while calling a function it is necessary
// to clean up the arguments that were put on the stack.
CleanArgsOnStack();
// Check if this function will catch the exception
// Try blocks can be nested, so use the innermost block
asASSERT(m_currentFunction->scriptData);
if (catchException && m_currentFunction->scriptData)
{
asUINT currPos = asUINT(m_regs.programPointer - m_currentFunction->scriptData->byteCode.AddressOf());
for (asUINT n = 0; n < m_currentFunction->scriptData->tryCatchInfo.GetLength(); n++)
{
if (currPos >= m_currentFunction->scriptData->tryCatchInfo[n].tryPos &&
currPos < m_currentFunction->scriptData->tryCatchInfo[n].catchPos)
{
tryCatchInfo = &m_currentFunction->scriptData->tryCatchInfo[n];
exceptionCaught = true;
}
if (currPos < m_currentFunction->scriptData->tryCatchInfo[n].tryPos)
break;
}
}
// Restore the stack pointer
if( !exceptionCaught )
m_regs.stackPointer += m_currentFunction->scriptData->variableSpace;
// Determine which object variables that are really live ones
asCArray<int> liveObjects;
DetermineLiveObjects(liveObjects, 0);
for( asUINT n = 0; n < m_currentFunction->scriptData->objVariablePos.GetLength(); n++ )
{
int pos = m_currentFunction->scriptData->objVariablePos[n];
// If the exception was caught, then only clean up objects within the try block
if (exceptionCaught)
{
// Find out where the variable was declared, and skip cleaning of those that were declared before the try catch
// Multiple variables in different scopes may occupy the same slot on the stack so it is necessary to search
// the entire list to determine which variable occupies the slot now.
int skipClean = 0;
for( asUINT p = 0; p < m_currentFunction->scriptData->objVariableInfo.GetLength(); p++ )
{
asSObjectVariableInfo &info = m_currentFunction->scriptData->objVariableInfo[p];
if (info.variableOffset == pos &&
info.option == asOBJ_VARDECL )
{
asUINT progPos = info.programPos;
if (progPos < tryCatchInfo->tryPos )
{
if( skipClean >= 0 )
skipClean = 1;
break;
}
else if( progPos < tryCatchInfo->catchPos )
{
skipClean = -1;
break;
}
}
}
// Skip only variables that have been declared before the try block. Variables declared
// within the try block and variables whose declaration was not identified (temporary objects)
// will not be skipped.
// TODO: What if a temporary variable reuses a slot from a declared variable that is no longer in scope?
if (skipClean > 0)
continue;
}
if( n < m_currentFunction->scriptData->objVariablesOnHeap )
{
// Check if the pointer is initialized
if( *(asPWORD*)&m_regs.stackFramePointer[-pos] )
{
// Call the object's destructor
if (m_currentFunction->scriptData->objVariableTypes[n]->flags & asOBJ_FUNCDEF)
{
(*(asCScriptFunction**)&m_regs.stackFramePointer[-pos])->Release();
}
else if( m_currentFunction->scriptData->objVariableTypes[n]->flags & asOBJ_REF )
{
asSTypeBehaviour *beh = &CastToObjectType(m_currentFunction->scriptData->objVariableTypes[n])->beh;
asASSERT( (m_currentFunction->scriptData->objVariableTypes[n]->flags & asOBJ_NOCOUNT) || beh->release );
if( beh->release )
m_engine->CallObjectMethod((void*)*(asPWORD*)&m_regs.stackFramePointer[-pos], beh->release);
}
else
{
asSTypeBehaviour *beh = &CastToObjectType(m_currentFunction->scriptData->objVariableTypes[n])->beh;
if( beh->destruct )
m_engine->CallObjectMethod((void*)*(asPWORD*)&m_regs.stackFramePointer[-pos], beh->destruct);
else if( m_currentFunction->scriptData->objVariableTypes[n]->flags & asOBJ_LIST_PATTERN )
m_engine->DestroyList((asBYTE*)*(asPWORD*)&m_regs.stackFramePointer[-pos], CastToObjectType(m_currentFunction->scriptData->objVariableTypes[n]));
// Free the memory
m_engine->CallFree((void*)*(asPWORD*)&m_regs.stackFramePointer[-pos]);
}
*(asPWORD*)&m_regs.stackFramePointer[-pos] = 0;
}
}
else
{
asASSERT( m_currentFunction->scriptData->objVariableTypes[n]->GetFlags() & asOBJ_VALUE );
// Only destroy the object if it is truly alive
if( liveObjects[n] > 0 )
{
asSTypeBehaviour *beh = &CastToObjectType(m_currentFunction->scriptData->objVariableTypes[n])->beh;
if( beh->destruct )
m_engine->CallObjectMethod((void*)(asPWORD*)&m_regs.stackFramePointer[-pos], beh->destruct);
}
}
}
}
else
m_isStackMemoryNotAllocated = false;
// If the exception was caught then move the program position to the catch block then stop the unwinding
if (exceptionCaught)
{
m_regs.programPointer = m_currentFunction->scriptData->byteCode.AddressOf() + tryCatchInfo->catchPos;
return exceptionCaught;
}
// Functions that do not own the object and parameters shouldn't do any clean up
if( m_currentFunction->dontCleanUpOnException )
return exceptionCaught;
// Clean object and parameters
int offset = 0;
if( m_currentFunction->objectType )
offset += AS_PTR_SIZE;
if( m_currentFunction->DoesReturnOnStack() )
offset += AS_PTR_SIZE;
for( asUINT n = 0; n < m_currentFunction->parameterTypes.GetLength(); n++ )
{
if( (m_currentFunction->parameterTypes[n].IsObject() ||m_currentFunction->parameterTypes[n].IsFuncdef()) && !m_currentFunction->parameterTypes[n].IsReference() )
{
if( *(asPWORD*)&m_regs.stackFramePointer[offset] )
{
// Call the object's destructor
asSTypeBehaviour *beh = m_currentFunction->parameterTypes[n].GetBehaviour();
if (m_currentFunction->parameterTypes[n].GetTypeInfo()->flags & asOBJ_FUNCDEF)
{
(*(asCScriptFunction**)&m_regs.stackFramePointer[offset])->Release();
}
else if( m_currentFunction->parameterTypes[n].GetTypeInfo()->flags & asOBJ_REF )
{
asASSERT( (m_currentFunction->parameterTypes[n].GetTypeInfo()->flags & asOBJ_NOCOUNT) || beh->release );
if( beh->release )
m_engine->CallObjectMethod((void*)*(asPWORD*)&m_regs.stackFramePointer[offset], beh->release);
}
else
{
if( beh->destruct )
m_engine->CallObjectMethod((void*)*(asPWORD*)&m_regs.stackFramePointer[offset], beh->destruct);
// Free the memory
m_engine->CallFree((void*)*(asPWORD*)&m_regs.stackFramePointer[offset]);
}
*(asPWORD*)&m_regs.stackFramePointer[offset] = 0;
}
}
offset += m_currentFunction->parameterTypes[n].GetSizeOnStackDWords();
}
return exceptionCaught;
}
// interface
int asCContext::GetExceptionLineNumber(int *column, const char **sectionName)
{
// Return the last exception even if the context is no longer in the exception state
// if( GetState() != asEXECUTION_EXCEPTION ) return asERROR;
if( column ) *column = m_exceptionColumn;
if( sectionName )
{
// The section index can be -1 if the exception was raised in a generated function, e.g. $fact for templates
if( m_exceptionSectionIdx >= 0 )
*sectionName = m_engine->scriptSectionNames[m_exceptionSectionIdx]->AddressOf();
else
*sectionName = 0;
}
return m_exceptionLine;
}
// interface
asIScriptFunction *asCContext::GetExceptionFunction()
{
// Return the last exception even if the context is no longer in the exception state
// if( GetState() != asEXECUTION_EXCEPTION ) return 0;
return m_engine->scriptFunctions[m_exceptionFunction];
}
// interface
const char *asCContext::GetExceptionString()
{
// Return the last exception even if the context is no longer in the exception state
// if( GetState() != asEXECUTION_EXCEPTION ) return 0;
return m_exceptionString.AddressOf();
}
// interface
asEContextState asCContext::GetState() const
{
return m_status;
}
// interface
int asCContext::SetLineCallback(asSFuncPtr callback, void *obj, int callConv)
{
// First turn off the line callback to avoid a second thread
// attempting to call it while the new one is still being set
m_lineCallback = false;
m_lineCallbackObj = obj;
bool isObj = false;
if( (unsigned)callConv == asCALL_GENERIC || (unsigned)callConv == asCALL_THISCALL_OBJFIRST || (unsigned)callConv == asCALL_THISCALL_OBJLAST )
{
m_regs.doProcessSuspend = m_doSuspend;
return asNOT_SUPPORTED;
}
if( (unsigned)callConv >= asCALL_THISCALL )
{
isObj = true;
if( obj == 0 )
{
m_regs.doProcessSuspend = m_doSuspend;
return asINVALID_ARG;
}
}
int r = DetectCallingConvention(isObj, callback, callConv, 0, &m_lineCallbackFunc);
// Turn on the line callback after setting both the function pointer and object pointer
if( r >= 0 ) m_lineCallback = true;
// The BC_SUSPEND instruction should be processed if either line
// callback is set or if the application has requested a suspension
m_regs.doProcessSuspend = m_doSuspend || m_lineCallback;
return r;
}
void asCContext::CallLineCallback()
{
if( m_lineCallbackFunc.callConv < ICC_THISCALL )
m_engine->CallGlobalFunction(this, m_lineCallbackObj, &m_lineCallbackFunc, 0);
else
m_engine->CallObjectMethod(m_lineCallbackObj, this, &m_lineCallbackFunc, 0);
}
// interface
int asCContext::SetExceptionCallback(asSFuncPtr callback, void *obj, int callConv)
{
m_exceptionCallback = true;
m_exceptionCallbackObj = obj;
bool isObj = false;
if( (unsigned)callConv == asCALL_GENERIC || (unsigned)callConv == asCALL_THISCALL_OBJFIRST || (unsigned)callConv == asCALL_THISCALL_OBJLAST )
return asNOT_SUPPORTED;
if( (unsigned)callConv >= asCALL_THISCALL )
{
isObj = true;
if( obj == 0 )
{
m_exceptionCallback = false;
return asINVALID_ARG;
}
}
int r = DetectCallingConvention(isObj, callback, callConv, 0, &m_exceptionCallbackFunc);
if( r < 0 ) m_exceptionCallback = false;
return r;
}
void asCContext::CallExceptionCallback()
{
if( m_exceptionCallbackFunc.callConv < ICC_THISCALL )
m_engine->CallGlobalFunction(this, m_exceptionCallbackObj, &m_exceptionCallbackFunc, 0);
else
m_engine->CallObjectMethod(m_exceptionCallbackObj, this, &m_exceptionCallbackFunc, 0);
}
#ifndef AS_NO_EXCEPTIONS
// internal
void asCContext::HandleAppException()
{
// This method is called from within a catch(...) block
if (m_engine->translateExceptionCallback)
{
// Allow the application to translate the application exception to a proper exception string
if (m_engine->translateExceptionCallbackFunc.callConv < ICC_THISCALL)
m_engine->CallGlobalFunction(this, m_engine->translateExceptionCallbackObj, &m_engine->translateExceptionCallbackFunc, 0);
else
m_engine->CallObjectMethod(m_engine->translateExceptionCallbackObj, this, &m_engine->translateExceptionCallbackFunc, 0);
}
// Make sure an exception is set even if the application decides not to do any specific translation
if( m_status != asEXECUTION_EXCEPTION )
SetException(TXT_EXCEPTION_CAUGHT);
}
#endif
// interface
void asCContext::ClearLineCallback()
{
m_lineCallback = false;
m_regs.doProcessSuspend = m_doSuspend;
}
// interface
void asCContext::ClearExceptionCallback()
{
m_exceptionCallback = false;
}
int asCContext::CallGeneric(asCScriptFunction *descr)
{
asSSystemFunctionInterface *sysFunc = descr->sysFuncIntf;
void (*func)(asIScriptGeneric*) = (void (*)(asIScriptGeneric*))sysFunc->func;
int popSize = sysFunc->paramSize;
asDWORD *args = m_regs.stackPointer;
// Verify the object pointer if it is a class method
void *currentObject = 0;
asASSERT( sysFunc->callConv == ICC_GENERIC_FUNC || sysFunc->callConv == ICC_GENERIC_METHOD );
if( sysFunc->callConv == ICC_GENERIC_METHOD )
{
// The object pointer should be popped from the context stack
popSize += AS_PTR_SIZE;
// Check for null pointer
currentObject = (void*)*(asPWORD*)(args);
if( currentObject == 0 )
{
SetInternalException(TXT_NULL_POINTER_ACCESS);
return 0;
}
asASSERT( sysFunc->baseOffset == 0 );
// Skip object pointer
args += AS_PTR_SIZE;
}
if( descr->DoesReturnOnStack() )
{
// Skip the address where the return value will be stored
args += AS_PTR_SIZE;
popSize += AS_PTR_SIZE;
}
asCGeneric gen(m_engine, descr, currentObject, args);
m_callingSystemFunction = descr;
#ifdef AS_NO_EXCEPTIONS
func(&gen);
#else
// This try/catch block is to catch potential exception that may
// be thrown by the registered function.
try
{
func(&gen);
}
catch (...)
{
// Convert the exception to a script exception so the VM can
// properly report the error to the application and then clean up
HandleAppException();
}
#endif
m_callingSystemFunction = 0;
m_regs.valueRegister = gen.returnVal;
m_regs.objectRegister = gen.objectRegister;
m_regs.objectType = descr->returnType.GetTypeInfo();
// Increase the returned handle if the function has been declared with autohandles
// and the engine is not set to use the old mode for the generic calling convention
if (sysFunc->returnAutoHandle && m_engine->ep.genericCallMode == 1 && m_regs.objectRegister)
{
asASSERT(!(descr->returnType.GetTypeInfo()->flags & asOBJ_NOCOUNT));
m_engine->CallObjectMethod(m_regs.objectRegister, CastToObjectType(descr->returnType.GetTypeInfo())->beh.addref);
}
// Clean up arguments
const asUINT cleanCount = sysFunc->cleanArgs.GetLength();
if( cleanCount )
{
asSSystemFunctionInterface::SClean *clean = sysFunc->cleanArgs.AddressOf();
for( asUINT n = 0; n < cleanCount; n++, clean++ )
{
void **addr = (void**)&args[clean->off];
if( clean->op == 0 )
{
if( *addr != 0 )
{
m_engine->CallObjectMethod(*addr, clean->ot->beh.release);
*addr = 0;
}
}
else
{
asASSERT( clean->op == 1 || clean->op == 2 );
asASSERT( *addr );
if( clean->op == 2 )
m_engine->CallObjectMethod(*addr, clean->ot->beh.destruct);
m_engine->CallFree(*addr);
}
}
}
// Return how much should be popped from the stack
return popSize;
}
// interface
int asCContext::GetVarCount(asUINT stackLevel)
{
asIScriptFunction *func = GetFunction(stackLevel);
if( func == 0 ) return asINVALID_ARG;
return func->GetVarCount();
}
// interface
const char *asCContext::GetVarName(asUINT varIndex, asUINT stackLevel)
{
asIScriptFunction *func = GetFunction(stackLevel);
if( func == 0 ) return 0;
const char *name = 0;
int r = func->GetVar(varIndex, &name);
return r >= 0 ? name : 0;
}
// interface
const char *asCContext::GetVarDeclaration(asUINT varIndex, asUINT stackLevel, bool includeNamespace)
{
asIScriptFunction *func = GetFunction(stackLevel);
if( func == 0 ) return 0;
return func->GetVarDecl(varIndex, includeNamespace);
}
// interface
int asCContext::GetVarTypeId(asUINT varIndex, asUINT stackLevel)
{
asIScriptFunction *func = GetFunction(stackLevel);
if( func == 0 ) return asINVALID_ARG;
int typeId;
int r = func->GetVar(varIndex, 0, &typeId);
return r < 0 ? r : typeId;
}
// interface
void *asCContext::GetAddressOfVar(asUINT varIndex, asUINT stackLevel)
{
// Don't return anything if there is no bytecode, e.g. before calling Execute()
if( m_regs.programPointer == 0 ) return 0;
if( stackLevel >= GetCallstackSize() ) return 0;
asCScriptFunction *func;
asDWORD *sf;
if( stackLevel == 0 )
{
func = m_currentFunction;
sf = m_regs.stackFramePointer;
}
else
{
asPWORD *s = m_callStack.AddressOf() + (GetCallstackSize()-stackLevel-1)*CALLSTACK_FRAME_SIZE;
func = (asCScriptFunction*)s[1];
sf = (asDWORD*)s[0];
}
if( func == 0 )
return 0;
if( func->scriptData == 0 )
return 0;
if( varIndex >= func->scriptData->variables.GetLength() )
return 0;
// For object variables it's necessary to dereference the pointer to get the address of the value
// Reference parameters must also be dereferenced to give the address of the value
int pos = func->scriptData->variables[varIndex]->stackOffset;
if( (func->scriptData->variables[varIndex]->type.IsObject() && !func->scriptData->variables[varIndex]->type.IsObjectHandle()) || (pos <= 0) )
{
// Determine if the object is really on the heap
bool onHeap = false;
if( func->scriptData->variables[varIndex]->type.IsObject() &&
!func->scriptData->variables[varIndex]->type.IsObjectHandle() )
{
onHeap = true;
if( func->scriptData->variables[varIndex]->type.GetTypeInfo()->GetFlags() & asOBJ_VALUE )
{
for( asUINT n = 0; n < func->scriptData->objVariablePos.GetLength(); n++ )
{
if( func->scriptData->objVariablePos[n] == pos )
{
onHeap = n < func->scriptData->objVariablesOnHeap;
if( !onHeap )
{
// If the object on the stack is not initialized return a null pointer instead
asCArray<int> liveObjects;
DetermineLiveObjects(liveObjects, stackLevel);
if( liveObjects[n] <= 0 )
return 0;
}
break;
}
}
}
}
// If it wasn't an object on the heap, then check if it is a reference parameter
if( !onHeap && pos <= 0 )
{
// Determine what function argument this position matches
int stackPos = 0;
if( func->objectType )
stackPos -= AS_PTR_SIZE;
if( func->DoesReturnOnStack() )
stackPos -= AS_PTR_SIZE;
for( asUINT n = 0; n < func->parameterTypes.GetLength(); n++ )
{
if( stackPos == pos )
{
// The right argument was found. Is this a reference parameter?
if( func->inOutFlags[n] != asTM_NONE )
onHeap = true;
break;
}
stackPos -= func->parameterTypes[n].GetSizeOnStackDWords();
}
}
if( onHeap )
return *(void**)(sf - func->scriptData->variables[varIndex]->stackOffset);
}
return sf - func->scriptData->variables[varIndex]->stackOffset;
}
// interface
// returns the typeId of the 'this' object at the given call stack level (0 for current)
// returns 0 if the function call at the given stack level is not a method
int asCContext::GetThisTypeId(asUINT stackLevel)
{
asIScriptFunction *func = GetFunction(stackLevel);
if( func == 0 ) return asINVALID_ARG;
if( func->GetObjectType() == 0 )
return 0; // not in a method
// create a datatype
asCDataType dt = asCDataType::CreateType((asCObjectType*)func->GetObjectType(), false);
// return a typeId from the data type
return m_engine->GetTypeIdFromDataType(dt);
}
// interface
// returns the 'this' object pointer at the given call stack level (0 for current)
// returns 0 if the function call at the given stack level is not a method
void *asCContext::GetThisPointer(asUINT stackLevel)
{
if( stackLevel >= GetCallstackSize() )
return 0;
asCScriptFunction *func;
asDWORD *sf;
if( stackLevel == 0 )
{
func = m_currentFunction;
sf = m_regs.stackFramePointer;
}
else
{
asPWORD *s = m_callStack.AddressOf() + (GetCallstackSize()-stackLevel-1)*CALLSTACK_FRAME_SIZE;
func = (asCScriptFunction*)s[1];
sf = (asDWORD*)s[0];
}
if( func == 0 )
return 0;
if( func->objectType == 0 )
return 0; // not in a method
void *thisPointer = (void*)*(asPWORD*)(sf);
if( thisPointer == 0 )
{
return 0;
}
// NOTE: this returns the pointer to the 'this' while the GetVarPointer functions return
// a pointer to a pointer. I can't imagine someone would want to change the 'this'
return thisPointer;
}
// TODO: Move these to as_utils.cpp
struct POW_INFO
{
asQWORD MaxBaseu64;
asDWORD MaxBasei64;
asWORD MaxBaseu32;
asWORD MaxBasei32;
char HighBit;
};
const POW_INFO pow_info[] =
{
{ 0ULL, 0UL, 0, 0, 0 }, // 0 is a special case
{ 0ULL, 0UL, 0, 0, 1 }, // 1 is a special case
{ 3037000499ULL, 2147483647UL, 65535, 46340, 2 }, // 2
{ 2097152ULL, 1664510UL, 1625, 1290, 2 }, // 3
{ 55108ULL, 46340UL, 255, 215, 3 }, // 4
{ 6208ULL, 5404UL, 84, 73, 3 }, // 5
{ 1448ULL, 1290UL, 40, 35, 3 }, // 6
{ 511ULL, 463UL, 23, 21, 3 }, // 7
{ 234ULL, 215UL, 15, 14, 4 }, // 8
{ 128ULL, 118UL, 11, 10, 4 }, // 9
{ 78ULL, 73UL, 9, 8, 4 }, // 10
{ 52ULL, 49UL, 7, 7, 4 }, // 11
{ 38ULL, 35UL, 6, 5, 4 }, // 12
{ 28ULL, 27UL, 5, 5, 4 }, // 13
{ 22ULL, 21UL, 4, 4, 4 }, // 14
{ 18ULL, 17UL, 4, 4, 4 }, // 15
{ 15ULL, 14UL, 3, 3, 5 }, // 16
{ 13ULL, 12UL, 3, 3, 5 }, // 17
{ 11ULL, 10UL, 3, 3, 5 }, // 18
{ 9ULL, 9UL, 3, 3, 5 }, // 19
{ 8ULL, 8UL, 3, 2, 5 }, // 20
{ 8ULL, 7UL, 2, 2, 5 }, // 21
{ 7ULL, 7UL, 2, 2, 5 }, // 22
{ 6ULL, 6UL, 2, 2, 5 }, // 23
{ 6ULL, 5UL, 2, 2, 5 }, // 24
{ 5ULL, 5UL, 2, 2, 5 }, // 25
{ 5ULL, 5UL, 2, 2, 5 }, // 26
{ 5ULL, 4UL, 2, 2, 5 }, // 27
{ 4ULL, 4UL, 2, 2, 5 }, // 28
{ 4ULL, 4UL, 2, 2, 5 }, // 29
{ 4ULL, 4UL, 2, 2, 5 }, // 30
{ 4ULL, 4UL, 2, 1, 5 }, // 31
{ 3ULL, 3UL, 1, 1, 6 }, // 32
{ 3ULL, 3UL, 1, 1, 6 }, // 33
{ 3ULL, 3UL, 1, 1, 6 }, // 34
{ 3ULL, 3UL, 1, 1, 6 }, // 35
{ 3ULL, 3UL, 1, 1, 6 }, // 36
{ 3ULL, 3UL, 1, 1, 6 }, // 37
{ 3ULL, 3UL, 1, 1, 6 }, // 38
{ 3ULL, 3UL, 1, 1, 6 }, // 39
{ 2ULL, 2UL, 1, 1, 6 }, // 40
{ 2ULL, 2UL, 1, 1, 6 }, // 41
{ 2ULL, 2UL, 1, 1, 6 }, // 42
{ 2ULL, 2UL, 1, 1, 6 }, // 43
{ 2ULL, 2UL, 1, 1, 6 }, // 44
{ 2ULL, 2UL, 1, 1, 6 }, // 45
{ 2ULL, 2UL, 1, 1, 6 }, // 46
{ 2ULL, 2UL, 1, 1, 6 }, // 47
{ 2ULL, 2UL, 1, 1, 6 }, // 48
{ 2ULL, 2UL, 1, 1, 6 }, // 49
{ 2ULL, 2UL, 1, 1, 6 }, // 50
{ 2ULL, 2UL, 1, 1, 6 }, // 51
{ 2ULL, 2UL, 1, 1, 6 }, // 52
{ 2ULL, 2UL, 1, 1, 6 }, // 53
{ 2ULL, 2UL, 1, 1, 6 }, // 54
{ 2ULL, 2UL, 1, 1, 6 }, // 55
{ 2ULL, 2UL, 1, 1, 6 }, // 56
{ 2ULL, 2UL, 1, 1, 6 }, // 57
{ 2ULL, 2UL, 1, 1, 6 }, // 58
{ 2ULL, 2UL, 1, 1, 6 }, // 59
{ 2ULL, 2UL, 1, 1, 6 }, // 60
{ 2ULL, 2UL, 1, 1, 6 }, // 61
{ 2ULL, 2UL, 1, 1, 6 }, // 62
{ 2ULL, 1UL, 1, 1, 6 }, // 63
};
int as_powi(int base, int exponent, bool& isOverflow)
{
if( exponent < 0 )
{
if( base == 0 )
// Divide by zero
isOverflow = true;
else
// Result is less than 1, so it truncates to 0
isOverflow = false;
return 0;
}
else if( exponent == 0 && base == 0 )
{
// Domain error
isOverflow = true;
return 0;
}
else if( exponent >= 31 )
{
switch( base )
{
case -1:
isOverflow = false;
return exponent & 1 ? -1 : 1;
case 0:
isOverflow = false;
break;
case 1:
isOverflow = false;
return 1;
default:
isOverflow = true;
break;
}
return 0;
}
else
{
const asWORD max_base = pow_info[exponent].MaxBasei32;
const char high_bit = pow_info[exponent].HighBit;
if( max_base != 0 && max_base < (base < 0 ? -base : base) )
{
isOverflow = true;
return 0; // overflow
}
int result = 1;
switch( high_bit )
{
case 5:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 4:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 3:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 2:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 1:
if( exponent ) result *= base;
default:
isOverflow = false;
return result;
}
}
}
asDWORD as_powu(asDWORD base, asDWORD exponent, bool& isOverflow)
{
if( exponent == 0 && base == 0 )
{
// Domain error
isOverflow = true;
return 0;
}
else if( exponent >= 32 )
{
switch( base )
{
case 0:
isOverflow = false;
break;
case 1:
isOverflow = false;
return 1;
default:
isOverflow = true;
break;
}
return 0;
}
else
{
const asWORD max_base = pow_info[exponent].MaxBaseu32;
const char high_bit = pow_info[exponent].HighBit;
if( max_base != 0 && max_base < base )
{
isOverflow = true;
return 0; // overflow
}
asDWORD result = 1;
switch( high_bit )
{
case 5:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 4:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 3:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 2:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 1:
if( exponent ) result *= base;
default:
isOverflow = false;
return result;
}
}
}
asINT64 as_powi64(asINT64 base, asINT64 exponent, bool& isOverflow)
{
if( exponent < 0 )
{
if( base == 0 )
// Divide by zero
isOverflow = true;
else
// Result is less than 1, so it truncates to 0
isOverflow = false;
return 0;
}
else if( exponent == 0 && base == 0 )
{
// Domain error
isOverflow = true;
return 0;
}
else if( exponent >= 63 )
{
switch( base )
{
case -1:
isOverflow = false;
return exponent & 1 ? -1 : 1;
case 0:
isOverflow = false;
break;
case 1:
isOverflow = false;
return 1;
default:
isOverflow = true;
break;
}
return 0;
}
else
{
const asDWORD max_base = pow_info[exponent].MaxBasei64;
const char high_bit = pow_info[exponent].HighBit;
if( max_base != 0 && max_base < (base < 0 ? -base : base) )
{
isOverflow = true;
return 0; // overflow
}
asINT64 result = 1;
switch( high_bit )
{
case 6:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 5:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 4:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 3:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 2:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 1:
if( exponent ) result *= base;
default:
isOverflow = false;
return result;
}
}
}
asQWORD as_powu64(asQWORD base, asQWORD exponent, bool& isOverflow)
{
if( exponent == 0 && base == 0 )
{
// Domain error
isOverflow = true;
return 0;
}
else if( exponent >= 64 )
{
switch( base )
{
case 0:
isOverflow = false;
break;
case 1:
isOverflow = false;
return 1;
default:
isOverflow = true;
break;
}
return 0;
}
else
{
const asQWORD max_base = pow_info[exponent].MaxBaseu64;
const char high_bit = pow_info[exponent].HighBit;
if( max_base != 0 && max_base < base )
{
isOverflow = true;
return 0; // overflow
}
asQWORD result = 1;
switch( high_bit )
{
case 6:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 5:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 4:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 3:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 2:
if( exponent & 1 ) result *= base;
exponent >>= 1;
base *= base;
case 1:
if( exponent ) result *= base;
default:
isOverflow = false;
return result;
}
}
}
END_AS_NAMESPACE