Angelscript/angelscript/source/as_restore.cpp

5853 lines
155 KiB
C++

/*
AngelCode Scripting Library
Copyright (c) 2003-2021 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_restore.cpp
//
// Functions for saving and restoring module bytecode
// asCRestore was originally written by Dennis Bollyn, dennis@gyrbo.be
#include "as_config.h"
#include "as_restore.h"
#include "as_bytecode.h"
#include "as_scriptobject.h"
#include "as_texts.h"
#include "as_debug.h"
BEGIN_AS_NAMESPACE
// Macros for doing endianess agnostic bitmask serialization
#define SAVE_TO_BIT(dst, val, bit) ((dst) |= ((val) << (bit)))
#define LOAD_FROM_BIT(dst, val, bit) ((dst) = ((val) >> (bit)) & 1)
asCReader::asCReader(asCModule* _module, asIBinaryStream* _stream, asCScriptEngine* _engine)
: module(_module), stream(_stream), engine(_engine)
{
error = false;
bytesRead = 0;
}
int asCReader::ReadData(void *data, asUINT size)
{
asASSERT(size == 1 || size == 2 || size == 4 || size == 8);
int ret = 0;
#if defined(AS_BIG_ENDIAN)
for( asUINT n = 0; ret >= 0 && n < size; n++ )
ret = stream->Read(((asBYTE*)data)+n, 1);
#else
for( int n = size-1; ret >= 0 && n >= 0; n-- )
ret = stream->Read(((asBYTE*)data)+n, 1);
#endif
if (ret < 0)
Error(TXT_UNEXPECTED_END_OF_FILE);
bytesRead += size;
return ret;
}
int asCReader::Read(bool *wasDebugInfoStripped)
{
TimeIt("asCReader::Read");
// Before starting the load, make sure that
// any existing resources have been freed
module->InternalReset();
// Call the inner method to do the actual loading
int r = ReadInner();
if( r < 0 )
{
// Something went wrong while loading the bytecode, so we need
// to clean-up whatever has been created during the process.
// Make sure none of the loaded functions attempt to release
// references that have not yet been increased
asUINT i;
for( i = 0; i < module->m_scriptFunctions.GetLength(); i++ )
if( !dontTranslate.MoveTo(0, module->m_scriptFunctions[i]) )
if( module->m_scriptFunctions[i]->scriptData )
module->m_scriptFunctions[i]->scriptData->byteCode.SetLength(0);
asCSymbolTable<asCGlobalProperty>::iterator it = module->m_scriptGlobals.List();
for( ; it; it++ )
if( (*it)->GetInitFunc() )
if( (*it)->GetInitFunc()->scriptData )
(*it)->GetInitFunc()->scriptData->byteCode.SetLength(0);
module->InternalReset();
}
else
{
// Init system functions properly
engine->PrepareEngine();
// Initialize the global variables (unless requested not to)
if( engine->ep.initGlobalVarsAfterBuild )
r = module->ResetGlobalVars(0);
if( wasDebugInfoStripped )
*wasDebugInfoStripped = noDebugInfo;
}
// Clean up the loaded string constants
for (asUINT n = 0; n < usedStringConstants.GetLength(); n++)
engine->stringFactory->ReleaseStringConstant(usedStringConstants[n]);
usedStringConstants.SetLength(0);
return r;
}
int asCReader::Error(const char *msg)
{
// Don't write if it has already been reported an error earlier
if( !error )
{
asCString str;
str.Format(msg, bytesRead);
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
error = true;
}
return asERROR;
}
int asCReader::ReadInner()
{
TimeIt("asCReader::ReadInner");
// This function will load each entity one by one from the stream.
// If any error occurs, it will return to the caller who is
// responsible for cleaning up the partially loaded entities.
engine->deferValidationOfTemplateTypes = true;
unsigned long i, count;
asCScriptFunction* func;
// Read the flag as 1 byte even on platforms with 4byte booleans
noDebugInfo = ReadEncodedUInt() ? VALUE_OF_BOOLEAN_TRUE : 0;
// Read enums
count = SanityCheck(ReadEncodedUInt(), 1000000);
module->m_enumTypes.Allocate(count, false);
for( i = 0; i < count && !error; i++ )
{
asCEnumType *et = asNEW(asCEnumType)(engine);
if( et == 0 )
{
error = true;
return asOUT_OF_MEMORY;
}
bool isExternal = false;
ReadTypeDeclaration(et, 1, &isExternal);
// If the type is shared then we should use the original if it exists
bool sharedExists = false;
if( et->IsShared() )
{
for( asUINT n = 0; n < engine->sharedScriptTypes.GetLength(); n++ )
{
asCTypeInfo *t = engine->sharedScriptTypes[n];
if( t &&
t->IsShared() &&
t->name == et->name &&
t->nameSpace == et->nameSpace &&
(t->flags & asOBJ_ENUM) )
{
asDELETE(et, asCEnumType);
et = CastToEnumType(t);
sharedExists = true;
break;
}
}
}
if (isExternal && !sharedExists)
{
asCString msg;
msg.Format(TXT_EXTERNAL_SHARED_s_NOT_FOUND, et->name.AddressOf());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, msg.AddressOf());
asDELETE(et, asCEnumType);
error = true;
return asERROR;
}
if( sharedExists )
{
existingShared.Insert(et, true);
et->AddRefInternal();
}
else
{
if( et->IsShared() )
{
engine->sharedScriptTypes.PushLast(et);
et->AddRefInternal();
}
// Set this module as the owner
et->module = module;
}
module->AddEnumType(et);
if (isExternal)
module->m_externalTypes.PushLast(et);
ReadTypeDeclaration(et, 2);
}
if( error ) return asERROR;
// classTypes[]
// First restore the structure names, then the properties
count = SanityCheck(ReadEncodedUInt(), 1000000);
module->m_classTypes.Allocate(count, false);
for( i = 0; i < count && !error; ++i )
{
asCObjectType *ot = asNEW(asCObjectType)(engine);
if( ot == 0 )
{
error = true;
return asOUT_OF_MEMORY;
}
bool isExternal = false;
ReadTypeDeclaration(ot, 1, &isExternal);
// If the type is shared, then we should use the original if it exists
bool sharedExists = false;
if( ot->IsShared() )
{
for( asUINT n = 0; n < engine->sharedScriptTypes.GetLength(); n++ )
{
asCTypeInfo *ti = engine->sharedScriptTypes[n];
asCObjectType *t = CastToObjectType(ti);
if( t &&
t->IsShared() &&
t->name == ot->name &&
t->nameSpace == ot->nameSpace &&
t->IsInterface() == ot->IsInterface() )
{
asDELETE(ot, asCObjectType);
ot = CastToObjectType(t);
sharedExists = true;
break;
}
}
}
if (isExternal && !sharedExists)
{
asCString msg;
msg.Format(TXT_EXTERNAL_SHARED_s_NOT_FOUND, ot->name.AddressOf());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, msg.AddressOf());
asDELETE(ot, asCObjectType);
error = true;
return asERROR;
}
if( sharedExists )
{
existingShared.Insert(ot, true);
ot->AddRefInternal();
}
else
{
if( ot->IsShared() )
{
engine->sharedScriptTypes.PushLast(ot);
ot->AddRefInternal();
}
// Set this module as the owner
ot->module = module;
}
module->AddClassType(ot);
if (isExternal)
module->m_externalTypes.PushLast(ot);
}
if( error ) return asERROR;
// Read func defs
count = SanityCheck(ReadEncodedUInt(), 1000000);
module->m_funcDefs.Allocate(count, false);
for( i = 0; i < count && !error; i++ )
{
bool isNew, isExternal;
asCScriptFunction *funcDef = ReadFunction(isNew, false, true, true, &isExternal);
if(funcDef)
{
funcDef->module = module;
asCFuncdefType *fdt = funcDef->funcdefType;
fdt->module = module;
module->AddFuncDef(fdt);
engine->funcDefs.PushLast(fdt);
// TODO: clean up: This is also done by the builder. It should probably be moved to a method in the module
// Check if there is another identical funcdef from another module and if so reuse that instead
if(funcDef->IsShared())
{
for( asUINT n = 0; n < engine->funcDefs.GetLength(); n++ )
{
asCFuncdefType *f2 = engine->funcDefs[n];
if( f2 == 0 || fdt == f2 )
continue;
if( !f2->funcdef->IsShared() )
continue;
if( f2->name == fdt->name &&
f2->nameSpace == fdt->nameSpace &&
f2->parentClass == fdt->parentClass &&
f2->funcdef->IsSignatureExceptNameEqual(funcDef) )
{
// Replace our funcdef for the existing one
module->ReplaceFuncDef(fdt, f2);
f2->AddRefInternal();
if (isExternal)
module->m_externalTypes.PushLast(f2);
engine->funcDefs.RemoveValue(fdt);
savedFunctions[savedFunctions.IndexOf(funcDef)] = f2->funcdef;
if (fdt->parentClass)
{
// The real funcdef should already be in the object
asASSERT(fdt->parentClass->childFuncDefs.IndexOf(f2) >= 0);
fdt->parentClass = 0;
}
fdt->ReleaseInternal();
funcDef = 0;
break;
}
}
}
// Add the funcdef to the parentClass if this is a child funcdef
if (funcDef && fdt->parentClass)
fdt->parentClass->childFuncDefs.PushLast(fdt);
// Check if an external shared funcdef was really found
if (isExternal && funcDef)
{
asCString msg;
msg.Format(TXT_EXTERNAL_SHARED_s_NOT_FOUND, funcDef->name.AddressOf());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, msg.AddressOf());
error = true;
return asERROR;
}
}
else
Error(TXT_INVALID_BYTECODE_d);
}
// Read interface methods
for( i = 0; i < module->m_classTypes.GetLength() && !error; i++ )
{
if( module->m_classTypes[i]->IsInterface() )
ReadTypeDeclaration(module->m_classTypes[i], 2);
}
// Read class methods and behaviours
for( i = 0; i < module->m_classTypes.GetLength() && !error; ++i )
{
if( !module->m_classTypes[i]->IsInterface() )
ReadTypeDeclaration(module->m_classTypes[i], 2);
}
// Read class properties
for( i = 0; i < module->m_classTypes.GetLength() && !error; ++i )
{
if( !module->m_classTypes[i]->IsInterface() )
ReadTypeDeclaration(module->m_classTypes[i], 3);
}
if( error ) return asERROR;
// Read typedefs
count = SanityCheck(ReadEncodedUInt(), 1000000);
module->m_typeDefs.Allocate(count, false);
for( i = 0; i < count && !error; i++ )
{
asCTypedefType *td = asNEW(asCTypedefType)(engine);
if( td == 0 )
{
error = true;
return asOUT_OF_MEMORY;
}
bool isExternal = false;
ReadTypeDeclaration(td, 1, &isExternal);
td->module = module;
module->AddTypeDef(td);
ReadTypeDeclaration(td, 2);
}
if( error ) return asERROR;
// scriptGlobals[]
count = SanityCheck(ReadEncodedUInt(), 1000000);
if( count && engine->ep.disallowGlobalVars )
{
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, TXT_GLOBAL_VARS_NOT_ALLOWED);
Error(TXT_INVALID_BYTECODE_d);
}
module->m_scriptGlobals.Allocate(count, false);
for( i = 0; i < count && !error; ++i )
{
ReadGlobalProperty();
}
// scriptFunctions[]
count = SanityCheck(ReadEncodedUInt(), 1000000);
for( i = 0; i < count && !error; ++i )
{
size_t len = module->m_scriptFunctions.GetLength();
bool isNew, isExternal;
func = ReadFunction(isNew, true, true, true, &isExternal);
if( func == 0 )
{
Error(TXT_INVALID_BYTECODE_d);
break;
}
// Is the function shared and was it created now?
if( func->IsShared() && len != module->m_scriptFunctions.GetLength() )
{
// If the function already existed in another module, then
// we need to replace it with previously existing one
for( asUINT n = 0; n < engine->scriptFunctions.GetLength() && !error; n++ )
{
asCScriptFunction *realFunc = engine->scriptFunctions[n];
if( realFunc &&
realFunc != func &&
realFunc->IsShared() &&
realFunc->nameSpace == func->nameSpace &&
realFunc->IsSignatureEqual(func) )
{
// Replace the recently created function with the pre-existing function
module->m_scriptFunctions[module->m_scriptFunctions.GetLength()-1] = realFunc;
realFunc->AddRefInternal();
savedFunctions[savedFunctions.GetLength()-1] = realFunc;
engine->RemoveScriptFunction(func);
// Insert the function in the dontTranslate array
dontTranslate.Insert(realFunc, true);
if (isExternal)
module->m_externalFunctions.PushLast(realFunc);
// Release the function, but make sure nothing else is released
func->id = 0;
if( func->scriptData )
func->scriptData->byteCode.SetLength(0);
func->ReleaseInternal();
func = 0;
break;
}
}
}
// Check if an external shared func was really found
if (isExternal && func)
{
asCString msg;
msg.Format(TXT_EXTERNAL_SHARED_s_NOT_FOUND, func->name.AddressOf());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, msg.AddressOf());
error = true;
return asERROR;
}
}
// globalFunctions[]
count = SanityCheck(ReadEncodedUInt(), 1000000);
for( i = 0; i < count && !error; ++i )
{
bool isNew;
func = ReadFunction(isNew, false, false);
if( func )
{
// All the global functions were already loaded while loading the scriptFunctions, here
// we're just re-reading the references to know which goes into the globalFunctions array
asASSERT( !isNew );
module->m_globalFunctions.Put(func);
}
else
Error(TXT_INVALID_BYTECODE_d);
}
if( error ) return asERROR;
// bindInformations[]
count = SanityCheck(ReadEncodedUInt(), 1000000);
module->m_bindInformations.Allocate(count, false);
for( i = 0; i < count && !error; ++i )
{
sBindInfo *info = asNEW(sBindInfo);
if( info == 0 )
{
error = true;
return asOUT_OF_MEMORY;
}
bool isNew;
info->importedFunctionSignature = ReadFunction(isNew, false, false);
if( info->importedFunctionSignature == 0 )
{
Error(TXT_INVALID_BYTECODE_d);
break;
}
if( engine->freeImportedFunctionIdxs.GetLength() )
{
int id = engine->freeImportedFunctionIdxs.PopLast();
info->importedFunctionSignature->id = int(FUNC_IMPORTED + id);
engine->importedFunctions[id] = info;
}
else
{
info->importedFunctionSignature->id = int(FUNC_IMPORTED + engine->importedFunctions.GetLength());
engine->importedFunctions.PushLast(info);
}
ReadString(&info->importFromModule);
info->boundFunctionId = -1;
module->m_bindInformations.PushLast(info);
}
if( error ) return asERROR;
// usedTypes[]
count = SanityCheck(ReadEncodedUInt(), 1000000);
usedTypes.Allocate(count, false);
for( i = 0; i < count && !error; ++i )
{
asCTypeInfo *ti = ReadTypeInfo();
usedTypes.PushLast(ti);
}
// usedTypeIds[]
if( !error )
ReadUsedTypeIds();
// usedFunctions[]
if( !error )
ReadUsedFunctions();
// usedGlobalProperties[]
if( !error )
ReadUsedGlobalProps();
// usedStringConstants[]
if( !error )
ReadUsedStringConstants();
// usedObjectProperties
if( !error )
ReadUsedObjectProps();
// Validate the template types
if( !error )
{
for( i = 0; i < usedTypes.GetLength() && !error; i++ )
{
asCObjectType *ot = CastToObjectType(usedTypes[i]);
if( !ot ||
!(ot->flags & asOBJ_TEMPLATE) ||
!ot->beh.templateCallback )
continue;
bool dontGarbageCollect = false;
asCScriptFunction *callback = engine->scriptFunctions[ot->beh.templateCallback];
if( !engine->CallGlobalFunctionRetBool(ot, &dontGarbageCollect, callback->sysFuncIntf, callback) )
{
asCString sub = ot->templateSubTypes[0].Format(ot->nameSpace);
for( asUINT n = 1; n < ot->templateSubTypes.GetLength(); n++ )
{
sub += ",";
sub += ot->templateSubTypes[n].Format(ot->nameSpace);
}
asCString str;
str.Format(TXT_INSTANCING_INVLD_TMPL_TYPE_s_s, ot->name.AddressOf(), sub.AddressOf());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
Error(TXT_INVALID_BYTECODE_d);
}
else
{
// If the callback said this template instance won't be garbage collected then remove the flag
if( dontGarbageCollect )
ot->flags &= ~asOBJ_GC;
}
}
}
engine->deferValidationOfTemplateTypes = false;
if( error ) return asERROR;
// Update the loaded bytecode to point to the correct types, property offsets,
// function ids, etc. This is basically a linking stage.
for( i = 0; i < module->m_scriptFunctions.GetLength() && !error; i++ )
if( module->m_scriptFunctions[i]->funcType == asFUNC_SCRIPT )
TranslateFunction(module->m_scriptFunctions[i]);
asCSymbolTable<asCGlobalProperty>::iterator globIt = module->m_scriptGlobals.List();
while( globIt && !error )
{
asCScriptFunction *initFunc = (*globIt)->GetInitFunc();
if( initFunc )
TranslateFunction(initFunc);
globIt++;
}
if( error ) return asERROR;
// Add references for all functions (except for the pre-existing shared code)
for( i = 0; i < module->m_scriptFunctions.GetLength(); i++ )
if( !dontTranslate.MoveTo(0, module->m_scriptFunctions[i]) )
module->m_scriptFunctions[i]->AddReferences();
globIt = module->m_scriptGlobals.List();
while( globIt )
{
asCScriptFunction *initFunc = (*globIt)->GetInitFunc();
if( initFunc )
initFunc->AddReferences();
globIt++;
}
return error ? asERROR : asSUCCESS;
}
void asCReader::ReadUsedStringConstants()
{
TimeIt("asCReader::ReadUsedStringConstants");
asCString str;
asUINT count;
count = SanityCheck(ReadEncodedUInt(), 1000000);
if (count > 0 && engine->stringFactory == 0)
{
Error(TXT_STRINGS_NOT_RECOGNIZED);
return;
}
usedStringConstants.Allocate(count, false);
for( asUINT i = 0; i < count; ++i )
{
ReadString(&str);
usedStringConstants.PushLast(const_cast<void*>(engine->stringFactory->GetStringConstant(str.AddressOf(), (asUINT)str.GetLength())));
}
}
void asCReader::ReadUsedFunctions()
{
TimeIt("asCReader::ReadUsedFunctions");
asUINT count;
count = SanityCheck(ReadEncodedUInt(), 1000000);
usedFunctions.SetLength(count);
if( usedFunctions.GetLength() != count )
{
// Out of memory
error = true;
return;
}
memset(usedFunctions.AddressOf(), 0, sizeof(asCScriptFunction *)*count);
for( asUINT n = 0; n < usedFunctions.GetLength(); n++ )
{
char c;
// Read the data to be able to uniquely identify the function
// Is the function from the module or the application?
ReadData(&c, 1);
if( c == 'n' )
{
// Null function pointer
usedFunctions[n] = 0;
}
else
{
asCScriptFunction func(engine, c == 'm' ? module : 0, asFUNC_DUMMY);
asCObjectType *parentClass = 0;
ReadFunctionSignature(&func, &parentClass);
if( error )
{
func.funcType = asFUNC_DUMMY;
return;
}
// Find the correct function
if( c == 'm' )
{
if( func.funcType == asFUNC_IMPORTED )
{
for( asUINT i = 0; i < module->m_bindInformations.GetLength(); i++ )
{
asCScriptFunction *f = module->m_bindInformations[i]->importedFunctionSignature;
if( func.objectType != f->objectType ||
func.funcType != f->funcType ||
func.nameSpace != f->nameSpace ||
!func.IsSignatureEqual(f) )
continue;
usedFunctions[n] = f;
break;
}
}
else if( func.funcType == asFUNC_FUNCDEF )
{
const asCArray<asCFuncdefType *> &funcs = module->m_funcDefs;
for( asUINT i = 0; i < funcs.GetLength(); i++ )
{
asCScriptFunction *f = funcs[i]->funcdef;
if( f == 0 ||
func.name != f->name ||
!func.IsSignatureExceptNameAndObjectTypeEqual(f) ||
funcs[i]->parentClass != parentClass )
continue;
asASSERT( f->objectType == 0 );
usedFunctions[n] = f;
break;
}
}
else
{
// TODO: optimize: Global functions should be searched for in module->globalFunctions
// TODO: optimize: funcdefs should be searched for in module->funcDefs
// TODO: optimize: object methods should be searched for directly in the object type
for( asUINT i = 0; i < module->m_scriptFunctions.GetLength(); i++ )
{
asCScriptFunction *f = module->m_scriptFunctions[i];
if( func.objectType != f->objectType ||
func.funcType != f->funcType ||
func.nameSpace != f->nameSpace ||
!func.IsSignatureEqual(f) )
continue;
usedFunctions[n] = f;
break;
}
}
}
else if (c == 's')
{
// Look for shared entities in the engine, as they may not necessarily be part
// of the scope of the module if they have been inhereted from other modules.
if (func.funcType == asFUNC_FUNCDEF)
{
const asCArray<asCFuncdefType *> &funcs = engine->funcDefs;
for (asUINT i = 0; i < funcs.GetLength(); i++)
{
asCScriptFunction *f = funcs[i]->funcdef;
if (f == 0 ||
func.name != f->name ||
!func.IsSignatureExceptNameAndObjectTypeEqual(f) ||
funcs[i]->parentClass != parentClass)
continue;
asASSERT(f->objectType == 0);
usedFunctions[n] = f;
break;
}
}
else
{
for (asUINT i = 0; i < engine->scriptFunctions.GetLength(); i++)
{
asCScriptFunction *f = engine->scriptFunctions[i];
if (f == 0 || !f->IsShared() ||
func.objectType != f->objectType ||
func.funcType != f->funcType ||
func.nameSpace != f->nameSpace ||
!func.IsSignatureEqual(f))
continue;
usedFunctions[n] = f;
break;
}
}
}
else
{
asASSERT(c == 'a');
if( func.funcType == asFUNC_FUNCDEF )
{
// This is a funcdef (registered or shared)
const asCArray<asCFuncdefType *> &funcs = engine->funcDefs;
for( asUINT i = 0; i < funcs.GetLength(); i++ )
{
asCScriptFunction *f = funcs[i]->funcdef;
if( f == 0 || func.name != f->name || !func.IsSignatureExceptNameAndObjectTypeEqual(f) || funcs[i]->parentClass != parentClass )
continue;
asASSERT( f->objectType == 0 );
usedFunctions[n] = f;
break;
}
}
else if( func.name[0] == '$' )
{
// This is a special function
if( func.name == "$beh0" && func.objectType )
{
if (func.objectType->flags & asOBJ_TEMPLATE)
{
// Look for the matching constructor inside the factory stubs generated for the template instance
// See asCCompiler::PerformFunctionCall
for (asUINT i = 0; i < func.objectType->beh.constructors.GetLength(); i++)
{
asCScriptFunction *f = engine->scriptFunctions[func.objectType->beh.constructors[i]];
// Find the id of the real constructor and not the generated stub
asUINT id = 0;
asDWORD *bc = f->scriptData->byteCode.AddressOf();
while (bc)
{
if ((*(asBYTE*)bc) == asBC_CALLSYS)
{
id = asBC_INTARG(bc);
break;
}
bc += asBCTypeSize[asBCInfo[*(asBYTE*)bc].type];
}
f = engine->scriptFunctions[id];
if (f == 0 ||
!func.IsSignatureExceptNameAndObjectTypeEqual(f))
continue;
usedFunctions[n] = f;
break;
}
}
if( usedFunctions[n] == 0 )
{
// This is a class constructor, so we can search directly in the object type's constructors
for (asUINT i = 0; i < func.objectType->beh.constructors.GetLength(); i++)
{
asCScriptFunction *f = engine->scriptFunctions[func.objectType->beh.constructors[i]];
if (f == 0 ||
!func.IsSignatureExceptNameAndObjectTypeEqual(f))
continue;
usedFunctions[n] = f;
break;
}
}
}
else if( func.name == "$fact" || func.name == "$beh3" )
{
// This is a factory (or stub), so look for the function in the return type's factories
asCObjectType *objType = CastToObjectType(func.returnType.GetTypeInfo());
if( objType )
{
for( asUINT i = 0; i < objType->beh.factories.GetLength(); i++ )
{
asCScriptFunction *f = engine->scriptFunctions[objType->beh.factories[i]];
if( f == 0 ||
!func.IsSignatureExceptNameAndObjectTypeEqual(f) )
continue;
usedFunctions[n] = f;
break;
}
}
}
else if( func.name == "$list" )
{
// listFactory is used for both factory is global and returns a handle and constructor that is a method
asCObjectType *objType = func.objectType ? func.objectType : CastToObjectType(func.returnType.GetTypeInfo());
if( objType )
{
asCScriptFunction *f = engine->scriptFunctions[objType->beh.listFactory];
if( f && func.IsSignatureExceptNameAndObjectTypeEqual(f) )
usedFunctions[n] = f;
}
}
else if( func.name == "$beh2" )
{
// This is a destructor, so check the object type's destructor
asCObjectType *objType = func.objectType;
if( objType )
{
asCScriptFunction *f = engine->scriptFunctions[objType->beh.destruct];
if( f && func.IsSignatureExceptNameAndObjectTypeEqual(f) )
usedFunctions[n] = f;
}
}
else if( func.name == "$dlgte" )
{
// This is the delegate factory
asCScriptFunction *f = engine->registeredGlobalFuncs.GetFirst(engine->nameSpaces[0], DELEGATE_FACTORY);
asASSERT( f && func.IsSignatureEqual(f) );
usedFunctions[n] = f;
}
else
{
// Must match one of the above cases
asASSERT(false);
}
}
else if( func.objectType == 0 )
{
// This is a global function
const asCArray<asUINT> &funcs = engine->registeredGlobalFuncs.GetIndexes(func.nameSpace, func.name);
for( asUINT i = 0; i < funcs.GetLength(); i++ )
{
asCScriptFunction *f = engine->registeredGlobalFuncs.Get(funcs[i]);
if( f == 0 ||
!func.IsSignatureExceptNameAndObjectTypeEqual(f) )
continue;
usedFunctions[n] = f;
break;
}
}
else if( func.objectType )
{
// It is a class member, so we can search directly in the object type's members
// TODO: virtual function is different that implemented method
for( asUINT i = 0; i < func.objectType->methods.GetLength(); i++ )
{
asCScriptFunction *f = engine->scriptFunctions[func.objectType->methods[i]];
if( f == 0 ||
!func.IsSignatureEqual(f) )
continue;
usedFunctions[n] = f;
break;
}
}
if( usedFunctions[n] == 0 )
{
// TODO: clean up: This part of the code should never happen. All functions should
// be found in the above logic. The only valid reason to come here
// is if the bytecode is wrong and the function doesn't exist anyway.
// This loop is kept temporarily until we can be certain all scenarios
// are covered.
for( asUINT i = 0; i < engine->scriptFunctions.GetLength(); i++ )
{
asCScriptFunction *f = engine->scriptFunctions[i];
if( f == 0 ||
func.objectType != f->objectType ||
func.nameSpace != f->nameSpace ||
!func.IsSignatureEqual(f) )
continue;
usedFunctions[n] = f;
break;
}
// No function is expected to be found
asASSERT(usedFunctions[n] == 0);
}
}
// Set the type to dummy so it won't try to release the id
func.funcType = asFUNC_DUMMY;
if( usedFunctions[n] == 0 )
{
Error(TXT_INVALID_BYTECODE_d);
return;
}
}
}
}
void asCReader::ReadFunctionSignature(asCScriptFunction *func, asCObjectType **parentClass)
{
asUINT i, count;
asCDataType dt;
int num;
ReadString(&func->name);
if( func->name == DELEGATE_FACTORY )
{
// It's not necessary to read anymore, everything is known
asCScriptFunction *f = engine->registeredGlobalFuncs.GetFirst(engine->nameSpaces[0], DELEGATE_FACTORY);
asASSERT( f );
func->returnType = f->returnType;
func->parameterTypes = f->parameterTypes;
func->inOutFlags = f->inOutFlags;
func->funcType = f->funcType;
func->defaultArgs = f->defaultArgs;
func->nameSpace = f->nameSpace;
return;
}
ReadDataType(&func->returnType);
count = SanityCheck(ReadEncodedUInt(), 256);
func->parameterTypes.Allocate(count, false);
for( i = 0; i < count; ++i )
{
ReadDataType(&dt);
func->parameterTypes.PushLast(dt);
}
func->inOutFlags.SetLength(func->parameterTypes.GetLength());
if( func->inOutFlags.GetLength() != func->parameterTypes.GetLength() )
{
// Out of memory
error = true;
return;
}
memset(func->inOutFlags.AddressOf(), 0, sizeof(asETypeModifiers)*func->inOutFlags.GetLength());
if (func->parameterTypes.GetLength() > 0)
{
count = ReadEncodedUInt();
if (count > func->parameterTypes.GetLength())
{
// Cannot be more than the number of arguments
Error(TXT_INVALID_BYTECODE_d);
return;
}
for (i = 0; i < count; ++i)
{
num = ReadEncodedUInt();
func->inOutFlags[i] = static_cast<asETypeModifiers>(num);
}
}
func->funcType = (asEFuncType)ReadEncodedUInt();
// Read the default args, from last to first
if (func->parameterTypes.GetLength() > 0)
{
count = ReadEncodedUInt();
if (count > func->parameterTypes.GetLength())
{
// Cannot be more than the number of arguments
Error(TXT_INVALID_BYTECODE_d);
return;
}
if (count)
{
func->defaultArgs.SetLength(func->parameterTypes.GetLength());
if (func->defaultArgs.GetLength() != func->parameterTypes.GetLength())
{
// Out of memory
error = true;
return;
}
memset(func->defaultArgs.AddressOf(), 0, sizeof(asCString*)*func->defaultArgs.GetLength());
for (i = 0; i < count; i++)
{
asCString *str = asNEW(asCString);
if (str == 0)
{
// Out of memory
error = true;
return;
}
func->defaultArgs[func->defaultArgs.GetLength() - 1 - i] = str;
ReadString(str);
}
}
}
func->objectType = CastToObjectType(ReadTypeInfo());
if( func->objectType )
{
func->objectType->AddRefInternal();
asBYTE b;
ReadData(&b, 1);
func->SetReadOnly((b & 1) ? true : false);
func->SetPrivate((b & 2) ? true : false);
func->SetProtected((b & 4) ? true : false);
func->nameSpace = func->objectType->nameSpace;
}
else
{
if (func->funcType == asFUNC_FUNCDEF)
{
asBYTE b;
ReadData(&b, 1);
if (b == 'n')
{
asCString ns;
ReadString(&ns);
func->nameSpace = engine->AddNameSpace(ns.AddressOf());
}
else if (b == 'o')
{
func->nameSpace = 0;
if (parentClass)
*parentClass = CastToObjectType(ReadTypeInfo());
else
error = true;
}
else
error = true;
}
else
{
asCString ns;
ReadString(&ns);
func->nameSpace = engine->AddNameSpace(ns.AddressOf());
}
}
}
asCScriptFunction *asCReader::ReadFunction(bool &isNew, bool addToModule, bool addToEngine, bool addToGC, bool *isExternal)
{
isNew = false;
if (isExternal) *isExternal = false;
if( error ) return 0;
char c;
ReadData(&c, 1);
if( c == '\0' )
{
// There is no function, so return a null pointer
return 0;
}
if( c == 'r' )
{
// This is a reference to a previously saved function
asUINT index = ReadEncodedUInt();
if( index < savedFunctions.GetLength() )
return savedFunctions[index];
else
{
Error(TXT_INVALID_BYTECODE_d);
return 0;
}
}
// Load the new function
isNew = true;
asCScriptFunction *func = asNEW(asCScriptFunction)(engine,0,asFUNC_DUMMY);
if( func == 0 )
{
// Out of memory
error = true;
return 0;
}
savedFunctions.PushLast(func);
int i, count;
asCDataType dt;
int num;
asCObjectType *parentClass = 0;
ReadFunctionSignature(func, &parentClass);
if( error )
{
func->DestroyHalfCreated();
return 0;
}
if( func->funcType == asFUNC_SCRIPT )
{
// Skip this for external shared entities
if (module->m_externalTypes.IndexOf(func->objectType) >= 0)
{
// Replace with the real function from the existing entity
isNew = false;
asCObjectType *ot = func->objectType;
for (asUINT n = 0; n < ot->methods.GetLength(); n++)
{
asCScriptFunction *func2 = engine->scriptFunctions[ot->methods[n]];
if (func2->funcType == asFUNC_VIRTUAL)
func2 = ot->virtualFunctionTable[func2->vfTableIdx];
if (func->IsSignatureEqual(func2))
{
func->DestroyHalfCreated();
// as this is an existing function it shouldn't be translated as if just loaded
dontTranslate.Insert(func2, true);
// update the saved functions for future references
savedFunctions[savedFunctions.GetLength() - 1] = func2;
// As it is an existing function it shouldn't be added to the module or the engine
return func2;
}
}
}
else
{
char bits;
ReadData(&bits, 1);
func->SetShared((bits & 1) ? true : false);
func->SetExplicit((bits & 32) ? true : false);
func->dontCleanUpOnException = (bits & 2) ? true : false;
if ((bits & 4) && isExternal)
*isExternal = true;
// for external shared functions the rest is not needed
if (!(bits & 4))
{
func->AllocateScriptFunctionData();
if (func->scriptData == 0)
{
// Out of memory
error = true;
func->DestroyHalfCreated();
return 0;
}
if (addToGC && !addToModule)
engine->gc.AddScriptObjectToGC(func, &engine->functionBehaviours);
ReadByteCode(func);
func->scriptData->variableSpace = SanityCheck(ReadEncodedUInt(), 1000000);
func->scriptData->objVariablesOnHeap = 0;
if (bits & 8)
{
count = SanityCheck(ReadEncodedUInt(), 1000000);
func->scriptData->objVariablePos.Allocate(count, false);
func->scriptData->objVariableTypes.Allocate(count, false);
for (i = 0; i < count; ++i)
{
func->scriptData->objVariableTypes.PushLast(ReadTypeInfo());
num = ReadEncodedUInt();
func->scriptData->objVariablePos.PushLast(num);
if (error)
{
// No need to continue (the error has already been reported before)
func->DestroyHalfCreated();
return 0;
}
}
if (count > 0)
func->scriptData->objVariablesOnHeap = SanityCheck(ReadEncodedUInt(), 10000);
int length = SanityCheck(ReadEncodedUInt(), 1000000);
func->scriptData->objVariableInfo.SetLength(length);
for (i = 0; i < length; ++i)
{
func->scriptData->objVariableInfo[i].programPos = SanityCheck(ReadEncodedUInt(), 1000000);
func->scriptData->objVariableInfo[i].variableOffset = SanityCheck(ReadEncodedInt(), 10000);
asEObjVarInfoOption option = (asEObjVarInfoOption)ReadEncodedUInt();
func->scriptData->objVariableInfo[i].option = option;
if (option != asOBJ_INIT &&
option != asOBJ_UNINIT &&
option != asBLOCK_BEGIN &&
option != asBLOCK_END &&
option != asOBJ_VARDECL)
{
error = true;
func->DestroyHalfCreated();
return 0;
}
}
}
if (bits & 16)
{
// Read info on try/catch blocks
int length = SanityCheck(ReadEncodedUInt(), 1000000);
func->scriptData->tryCatchInfo.SetLength(length);
for (i = 0; i < length; ++i)
{
// The program position must be adjusted to be in number of instructions
func->scriptData->tryCatchInfo[i].tryPos = SanityCheck(ReadEncodedUInt(), 1000000);
func->scriptData->tryCatchInfo[i].catchPos = SanityCheck(ReadEncodedUInt(), 1000000);
}
}
if (!noDebugInfo)
{
int length = SanityCheck(ReadEncodedUInt(), 1000000);
func->scriptData->lineNumbers.SetLength(length);
if (int(func->scriptData->lineNumbers.GetLength()) != length)
{
// Out of memory
error = true;
func->DestroyHalfCreated();
return 0;
}
for (i = 0; i < length; ++i)
func->scriptData->lineNumbers[i] = ReadEncodedUInt();
// Read the array of script sections
length = SanityCheck(ReadEncodedUInt(), 1000000);
func->scriptData->sectionIdxs.SetLength(length);
if (int(func->scriptData->sectionIdxs.GetLength()) != length)
{
// Out of memory
error = true;
func->DestroyHalfCreated();
return 0;
}
for (i = 0; i < length; ++i)
{
if ((i & 1) == 0)
func->scriptData->sectionIdxs[i] = ReadEncodedUInt();
else
{
asCString str;
ReadString(&str);
func->scriptData->sectionIdxs[i] = engine->GetScriptSectionNameIndex(str.AddressOf());
}
}
}
// Read the variable information
if (!noDebugInfo)
{
int length = SanityCheck(ReadEncodedUInt(), 1000000);
func->scriptData->variables.Allocate(length, false);
for (i = 0; i < length; i++)
{
asSScriptVariable *var = asNEW(asSScriptVariable);
if (var == 0)
{
// Out of memory
error = true;
func->DestroyHalfCreated();
return 0;
}
func->scriptData->variables.PushLast(var);
var->declaredAtProgramPos = ReadEncodedUInt();
var->stackOffset = SanityCheck(ReadEncodedInt(),10000);
ReadString(&var->name);
ReadDataType(&var->type);
if (error)
{
// No need to continue (the error has already been reported before)
func->DestroyHalfCreated();
return 0;
}
}
}
// Read script section name
if (!noDebugInfo)
{
asCString name;
ReadString(&name);
func->scriptData->scriptSectionIdx = engine->GetScriptSectionNameIndex(name.AddressOf());
func->scriptData->declaredAt = ReadEncodedUInt();
}
// Read parameter names
if (!noDebugInfo)
{
asUINT countParam = asUINT(ReadEncodedUInt64());
if (countParam > func->parameterTypes.GetLength())
{
error = true;
func->DestroyHalfCreated();
return 0;
}
func->parameterNames.SetLength(countParam);
for (asUINT n = 0; n < countParam; n++)
ReadString(&func->parameterNames[n]);
}
}
}
}
else if( func->funcType == asFUNC_VIRTUAL || func->funcType == asFUNC_INTERFACE )
{
func->vfTableIdx = ReadEncodedUInt();
}
else if( func->funcType == asFUNC_FUNCDEF )
{
asBYTE bits;
ReadData(&bits, 1);
if( bits & 1 )
func->SetShared(true);
if ((bits & 2) && isExternal)
*isExternal = true;
// The asCFuncdefType constructor adds itself to the func->funcdefType member
asCFuncdefType *fdt = asNEW(asCFuncdefType)(engine, func);
fdt->parentClass = parentClass;
}
// Methods loaded for shared objects, owned by other modules should not be created as new functions
if( func->objectType && func->objectType->module != module )
{
// Return the real function from the object
asCScriptFunction *realFunc = 0;
bool found = false;
if( func->funcType == asFUNC_SCRIPT )
{
realFunc = engine->scriptFunctions[func->objectType->beh.destruct];
if( realFunc && realFunc->funcType != asFUNC_VIRTUAL && func->IsSignatureEqual(realFunc) )
{
found = true;
}
for( asUINT n = 0; !found && n < func->objectType->beh.constructors.GetLength(); n++ )
{
realFunc = engine->scriptFunctions[func->objectType->beh.constructors[n]];
if( realFunc && realFunc->funcType != asFUNC_VIRTUAL && func->IsSignatureEqual(realFunc) )
{
found = true;
break;
}
}
for( asUINT n = 0; !found && n < func->objectType->beh.factories.GetLength(); n++ )
{
realFunc = engine->scriptFunctions[func->objectType->beh.factories[n]];
if( realFunc && realFunc->funcType != asFUNC_VIRTUAL && func->IsSignatureEqual(realFunc) )
{
found = true;
break;
}
}
for( asUINT n = 0; !found && n < func->objectType->methods.GetLength(); n++ )
{
realFunc = engine->scriptFunctions[func->objectType->methods[n]];
if( realFunc && realFunc->funcType == func->funcType && func->IsSignatureEqual(realFunc) )
{
found = true;
break;
}
}
for( asUINT n = 0; !found && n < func->objectType->virtualFunctionTable.GetLength(); n++ )
{
realFunc = func->objectType->virtualFunctionTable[n];
if( realFunc && realFunc->funcType == func->funcType && func->IsSignatureEqual(realFunc) )
{
found = true;
break;
}
}
}
else if( func->funcType == asFUNC_VIRTUAL || func->funcType == asFUNC_INTERFACE )
{
// If the loaded function is a virtual function, then look for the identical virtual function in the methods array
for( asUINT n = 0; n < func->objectType->methods.GetLength(); n++ )
{
realFunc = engine->scriptFunctions[func->objectType->methods[n]];
if( realFunc && realFunc->funcType == func->funcType && func->IsSignatureEqual(realFunc) )
{
asASSERT( func->vfTableIdx == realFunc->vfTableIdx );
found = true;
break;
}
}
}
if( found )
{
// as this is an existing function it shouldn't be translated as if just loaded
dontTranslate.Insert(realFunc, true);
// update the saved functions for future references
savedFunctions[savedFunctions.GetLength() - 1] = realFunc;
if( realFunc->funcType == asFUNC_VIRTUAL && addToModule )
{
// Virtual methods must be added to the module's script functions array,
// even if they are not owned by the module
module->m_scriptFunctions.PushLast(realFunc);
realFunc->AddRefInternal();
}
}
else
{
asCString str;
str.Format(TXT_SHARED_s_DOESNT_MATCH_ORIGINAL, func->objectType->GetName());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
Error(TXT_INVALID_BYTECODE_d);
savedFunctions.PopLast();
realFunc = 0;
}
// Destroy the newly created function instance since it has been replaced by an existing function
isNew = false;
func->DestroyHalfCreated();
// As it is an existing function it shouldn't be added to the module or the engine
return realFunc;
}
if( addToModule )
{
// The refCount is already 1
module->m_scriptFunctions.PushLast(func);
func->module = module;
}
if( addToEngine )
{
func->id = engine->GetNextScriptFunctionId();
engine->AddScriptFunction(func);
}
if( func->objectType )
func->ComputeSignatureId();
return func;
}
void asCReader::ReadTypeDeclaration(asCTypeInfo *type, int phase, bool *isExternal)
{
if( phase == 1 )
{
asASSERT(isExternal);
if (isExternal)
*isExternal = false;
// Read the initial attributes
ReadString(&type->name);
ReadData(&type->flags, 4);
type->size = SanityCheck(ReadEncodedUInt(), 1000000);
asCString ns;
ReadString(&ns);
type->nameSpace = engine->AddNameSpace(ns.AddressOf());
// Verify that the flags match the asCTypeInfo
if ((CastToEnumType(type) && !(type->flags & asOBJ_ENUM)) ||
(CastToFuncdefType(type) && !(type->flags & asOBJ_FUNCDEF)) ||
(CastToObjectType(type) && !(type->flags & (asOBJ_REF | asOBJ_VALUE))))
{
error = true;
return;
}
// Reset the size of script classes, since it will be recalculated as properties are added
if( (type->flags & asOBJ_SCRIPT_OBJECT) && type->size != 0 )
type->size = sizeof(asCScriptObject);
asCObjectType *ot = CastToObjectType(type);
if (ot)
{
// Use the default script class behaviours
ot->beh = engine->scriptTypeBehaviours.beh;
ot->beh.construct = 0;
ot->beh.factory = 0;
ot->beh.constructors.PopLast(); // These will be read from the file
ot->beh.factories.PopLast(); // These will be read from the file
engine->scriptFunctions[ot->beh.addref]->AddRefInternal();
engine->scriptFunctions[ot->beh.release]->AddRefInternal();
engine->scriptFunctions[ot->beh.gcEnumReferences]->AddRefInternal();
engine->scriptFunctions[ot->beh.gcGetFlag]->AddRefInternal();
engine->scriptFunctions[ot->beh.gcGetRefCount]->AddRefInternal();
engine->scriptFunctions[ot->beh.gcReleaseAllReferences]->AddRefInternal();
engine->scriptFunctions[ot->beh.gcSetFlag]->AddRefInternal();
engine->scriptFunctions[ot->beh.copy]->AddRefInternal();
// TODO: weak: Should not do this if the class has been declared with 'noweak'
engine->scriptFunctions[ot->beh.getWeakRefFlag]->AddRefInternal();
}
// external shared flag
if (type->flags & asOBJ_SHARED)
{
char c;
ReadData(&c, 1);
if (c == 'e')
*isExternal = true;
else if (c != ' ')
{
error = true;
return;
}
}
}
else if( phase == 2 )
{
// external shared types doesn't store this
if ((type->flags & asOBJ_SHARED) && module->m_externalTypes.IndexOf(type) >= 0)
return;
if( type->flags & asOBJ_ENUM )
{
asCEnumType *t = CastToEnumType(type);
int count = SanityCheck(ReadEncodedUInt(), 1000000);
bool sharedExists = existingShared.MoveTo(0, type);
if( !sharedExists )
{
t->enumValues.Allocate(count, false);
for( int n = 0; n < count; n++ )
{
asSEnumValue *e = asNEW(asSEnumValue);
if( e == 0 )
{
// Out of memory
error = true;
return;
}
ReadString(&e->name);
ReadData(&e->value, 4); // TODO: Should be encoded
t->enumValues.PushLast(e);
}
}
else
{
// Verify that the enum values exists in the original
asCString name;
int value;
for( int n = 0; n < count; n++ )
{
ReadString(&name);
ReadData(&value, 4); // TODO: Should be encoded
bool found = false;
for( asUINT e = 0; e < t->enumValues.GetLength(); e++ )
{
if( t->enumValues[e]->name == name &&
t->enumValues[e]->value == value )
{
found = true;
break;
}
}
if( !found )
{
asCString str;
str.Format(TXT_SHARED_s_DOESNT_MATCH_ORIGINAL, type->GetName());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
Error(TXT_INVALID_BYTECODE_d);
}
}
}
}
else if( type->flags & asOBJ_TYPEDEF )
{
asCTypedefType *td = CastToTypedefType(type);
asASSERT(td);
eTokenType t = (eTokenType)ReadEncodedUInt();
td->aliasForType = asCDataType::CreatePrimitive(t, false);
}
else
{
asCObjectType *ot = CastToObjectType(type);
asASSERT(ot);
// If the type is shared and pre-existing, we should just
// validate that the loaded methods match the original
bool sharedExists = existingShared.MoveTo(0, type);
if( sharedExists )
{
asCObjectType *dt = CastToObjectType(ReadTypeInfo());
if( ot->derivedFrom != dt )
{
asCString str;
str.Format(TXT_SHARED_s_DOESNT_MATCH_ORIGINAL, type->GetName());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
Error(TXT_INVALID_BYTECODE_d);
}
}
else
{
ot->derivedFrom = CastToObjectType(ReadTypeInfo());
if( ot->derivedFrom )
ot->derivedFrom->AddRefInternal();
}
// interfaces[] / interfaceVFTOffsets[]
int size = SanityCheck(ReadEncodedUInt(), 1000000);
if( sharedExists )
{
for( int n = 0; n < size; n++ )
{
asCObjectType *intf = CastToObjectType(ReadTypeInfo());
if (!ot->IsInterface())
ReadEncodedUInt();
if( !type->Implements(intf) )
{
asCString str;
str.Format(TXT_SHARED_s_DOESNT_MATCH_ORIGINAL, type->GetName());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
Error(TXT_INVALID_BYTECODE_d);
}
}
}
else
{
ot->interfaces.Allocate(size, false);
if( !ot->IsInterface() )
ot->interfaceVFTOffsets.Allocate(size, false);
for( int n = 0; n < size; n++ )
{
asCObjectType *intf = CastToObjectType(ReadTypeInfo());
ot->interfaces.PushLast(intf);
if (!ot->IsInterface())
{
asUINT offset = SanityCheck(ReadEncodedUInt(), 1000000);
ot->interfaceVFTOffsets.PushLast(offset);
}
}
}
// behaviours
if( !ot->IsInterface() && type->flags != asOBJ_TYPEDEF && type->flags != asOBJ_ENUM )
{
bool isNew;
asCScriptFunction *func = ReadFunction(isNew, !sharedExists, !sharedExists, !sharedExists);
if( sharedExists )
{
// Find the real function in the object, and update the savedFunctions array
asCScriptFunction *realFunc = engine->GetScriptFunction(ot->beh.destruct);
if( (realFunc == 0 && func == 0) || realFunc->IsSignatureEqual(func) )
{
// If the function is not the last, then the substitution has already occurred before
if( func && savedFunctions[savedFunctions.GetLength()-1] == func )
savedFunctions[savedFunctions.GetLength()-1] = realFunc;
}
else
{
asCString str;
str.Format(TXT_SHARED_s_DOESNT_MATCH_ORIGINAL, type->GetName());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
Error(TXT_INVALID_BYTECODE_d);
}
if( func )
{
if( isNew )
{
// Destroy the function without releasing any references
func->id = 0;
func->scriptData->byteCode.SetLength(0);
func->ReleaseInternal();
}
dontTranslate.Insert(realFunc, true);
}
}
else
{
if( func )
{
ot->beh.destruct = func->id;
func->AddRefInternal();
}
else
ot->beh.destruct = 0;
}
size = SanityCheck(ReadEncodedUInt(), 1000000);
for( int n = 0; n < size; n++ )
{
func = ReadFunction(isNew, !sharedExists, !sharedExists, !sharedExists);
if( func )
{
if( sharedExists )
{
// Find the real function in the object, and update the savedFunctions array
bool found = false;
for( asUINT f = 0; f < ot->beh.constructors.GetLength(); f++ )
{
asCScriptFunction *realFunc = engine->GetScriptFunction(ot->beh.constructors[f]);
if( realFunc->IsSignatureEqual(func) )
{
// If the function is not the last, then the substitution has already occurred before
if( savedFunctions[savedFunctions.GetLength()-1] == func )
savedFunctions[savedFunctions.GetLength()-1] = realFunc;
found = true;
dontTranslate.Insert(realFunc, true);
break;
}
}
if( !found )
{
asCString str;
str.Format(TXT_SHARED_s_DOESNT_MATCH_ORIGINAL, type->GetName());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
Error(TXT_INVALID_BYTECODE_d);
}
if( isNew )
{
// Destroy the function without releasing any references
func->id = 0;
func->scriptData->byteCode.SetLength(0);
func->ReleaseInternal();
}
}
else
{
ot->beh.constructors.PushLast(func->id);
func->AddRefInternal();
if( func->parameterTypes.GetLength() == 0 )
ot->beh.construct = func->id;
}
}
else
{
Error(TXT_INVALID_BYTECODE_d);
}
func = ReadFunction(isNew, !sharedExists, !sharedExists, !sharedExists);
if( func )
{
if( sharedExists )
{
// Find the real function in the object, and update the savedFunctions array
bool found = false;
for( asUINT f = 0; f < ot->beh.factories.GetLength(); f++ )
{
asCScriptFunction *realFunc = engine->GetScriptFunction(ot->beh.factories[f]);
if( realFunc->IsSignatureEqual(func) )
{
// If the function is not the last, then the substitution has already occurred before
if( savedFunctions[savedFunctions.GetLength()-1] == func )
savedFunctions[savedFunctions.GetLength()-1] = realFunc;
found = true;
dontTranslate.Insert(realFunc, true);
break;
}
}
if( !found )
{
asCString str;
str.Format(TXT_SHARED_s_DOESNT_MATCH_ORIGINAL, type->GetName());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
Error(TXT_INVALID_BYTECODE_d);
}
if( isNew )
{
// Destroy the function without releasing any references
func->id = 0;
func->scriptData->byteCode.SetLength(0);
func->ReleaseInternal();
}
}
else
{
ot->beh.factories.PushLast(func->id);
func->AddRefInternal();
if( func->parameterTypes.GetLength() == 0 )
ot->beh.factory = func->id;
}
}
else
{
Error(TXT_INVALID_BYTECODE_d);
}
}
}
// methods[]
size = SanityCheck(ReadEncodedUInt(), 1000000);
int n;
for( n = 0; n < size; n++ )
{
bool isNew;
asCScriptFunction *func = ReadFunction(isNew, !sharedExists, !sharedExists, !sharedExists);
if( func )
{
if( sharedExists )
{
// Find the real function in the object, and update the savedFunctions array
bool found = false;
for( asUINT f = 0; f < ot->methods.GetLength(); f++ )
{
asCScriptFunction *realFunc = engine->GetScriptFunction(ot->methods[f]);
if( realFunc->IsSignatureEqual(func) )
{
// If the function is not the last, then the substitution has already occurred before
if( savedFunctions[savedFunctions.GetLength()-1] == func )
savedFunctions[savedFunctions.GetLength()-1] = realFunc;
found = true;
dontTranslate.Insert(realFunc, true);
break;
}
}
if( !found )
{
asCString str;
str.Format(TXT_SHARED_s_DOESNT_MATCH_ORIGINAL, type->GetName());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
Error(TXT_INVALID_BYTECODE_d);
}
if( isNew )
{
// Destroy the function without releasing any references
if( func->id == func->signatureId )
engine->signatureIds.RemoveValue(func);
func->id = 0;
if( func->scriptData )
func->scriptData->byteCode.SetLength(0);
func->ReleaseInternal();
}
}
else
{
// If the method is the assignment operator we need to replace the default implementation
if( func->name == "opAssign" && func->parameterTypes.GetLength() == 1 &&
func->parameterTypes[0].GetTypeInfo() == func->objectType &&
(func->inOutFlags[0] & asTM_INREF) )
{
engine->scriptFunctions[ot->beh.copy]->ReleaseInternal();
ot->beh.copy = func->id;
func->AddRefInternal();
}
ot->methods.PushLast(func->id);
func->AddRefInternal();
}
}
else
{
Error(TXT_INVALID_BYTECODE_d);
}
}
// virtualFunctionTable[]
size = SanityCheck(ReadEncodedUInt(), 1000000);
for( n = 0; n < size; n++ )
{
bool isNew;
asCScriptFunction *func = ReadFunction(isNew, !sharedExists, !sharedExists, !sharedExists);
if( func )
{
if( sharedExists )
{
// Find the real function in the object, and update the savedFunctions array
bool found = false;
for( asUINT f = 0; f < ot->virtualFunctionTable.GetLength(); f++ )
{
asCScriptFunction *realFunc = ot->virtualFunctionTable[f];
if( realFunc->IsSignatureEqual(func) )
{
// If the function is not the last, then the substitution has already occurred before
if( savedFunctions[savedFunctions.GetLength()-1] == func )
savedFunctions[savedFunctions.GetLength()-1] = realFunc;
found = true;
dontTranslate.Insert(realFunc, true);
break;
}
}
if( !found )
{
asCString str;
str.Format(TXT_SHARED_s_DOESNT_MATCH_ORIGINAL, type->GetName());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
Error(TXT_INVALID_BYTECODE_d);
}
if( isNew )
{
// Destroy the function without releasing any references
func->id = 0;
if( func->scriptData )
func->scriptData->byteCode.SetLength(0);
func->ReleaseInternal();
}
}
else
{
ot->virtualFunctionTable.PushLast(func);
func->AddRefInternal();
}
}
else
{
Error(TXT_INVALID_BYTECODE_d);
}
}
}
}
else if( phase == 3 )
{
// external shared types doesn't store this
if ((type->flags & asOBJ_SHARED) && module->m_externalTypes.IndexOf(type) >= 0)
return;
asCObjectType *ot = CastToObjectType(type);
// This is only done for object types
asASSERT(ot);
// properties[]
asUINT size = SanityCheck(ReadEncodedUInt(), 1000000);
for( asUINT n = 0; n < size; n++ )
ReadObjectProperty(ot);
}
}
asWORD asCReader::ReadEncodedUInt16()
{
asDWORD dw = ReadEncodedUInt();
if( (dw>>16) != 0 && (dw>>16) != 0xFFFF )
{
Error(TXT_INVALID_BYTECODE_d);
}
return asWORD(dw & 0xFFFF);
}
asUINT asCReader::ReadEncodedUInt()
{
asQWORD qw = ReadEncodedUInt64();
if( (qw>>32) != 0 && (qw>>32) != 0xFFFFFFFF )
{
Error(TXT_INVALID_BYTECODE_d);
}
return asUINT(qw & 0xFFFFFFFFu);
}
int asCReader::ReadEncodedInt()
{
return int(ReadEncodedUInt());
}
asQWORD asCReader::ReadEncodedUInt64()
{
asQWORD i = 0;
asBYTE b = 0xFF; // set to 0xFF to better catch if the stream doesn't update the value
ReadData(&b, 1);
bool isNegative = ( b & 0x80 ) ? true : false;
b &= 0x7F;
if( (b & 0x7F) == 0x7F )
{
ReadData(&b, 1); i = asQWORD(b) << 56;
ReadData(&b, 1); i += asQWORD(b) << 48;
ReadData(&b, 1); i += asQWORD(b) << 40;
ReadData(&b, 1); i += asQWORD(b) << 32;
ReadData(&b, 1); i += asUINT(b) << 24;
ReadData(&b, 1); i += asUINT(b) << 16;
ReadData(&b, 1); i += asUINT(b) << 8;
ReadData(&b, 1); i += b;
}
else if( (b & 0x7E) == 0x7E )
{
i = asQWORD(b & 0x01) << 48;
ReadData(&b, 1); i += asQWORD(b) << 40;
ReadData(&b, 1); i += asQWORD(b) << 32;
ReadData(&b, 1); i += asUINT(b) << 24;
ReadData(&b, 1); i += asUINT(b) << 16;
ReadData(&b, 1); i += asUINT(b) << 8;
ReadData(&b, 1); i += b;
}
else if( (b & 0x7C) == 0x7C )
{
i = asQWORD(b & 0x03) << 40;
ReadData(&b, 1); i += asQWORD(b) << 32;
ReadData(&b, 1); i += asUINT(b) << 24;
ReadData(&b, 1); i += asUINT(b) << 16;
ReadData(&b, 1); i += asUINT(b) << 8;
ReadData(&b, 1); i += b;
}
else if( (b & 0x78) == 0x78 )
{
i = asQWORD(b & 0x07) << 32;
ReadData(&b, 1); i += asUINT(b) << 24;
ReadData(&b, 1); i += asUINT(b) << 16;
ReadData(&b, 1); i += asUINT(b) << 8;
ReadData(&b, 1); i += b;
}
else if( (b & 0x70) == 0x70 )
{
i = asUINT(b & 0x0F) << 24;
ReadData(&b, 1); i += asUINT(b) << 16;
ReadData(&b, 1); i += asUINT(b) << 8;
ReadData(&b, 1); i += b;
}
else if( (b & 0x60) == 0x60 )
{
i = asUINT(b & 0x1F) << 16;
ReadData(&b, 1); i += asUINT(b) << 8;
ReadData(&b, 1); i += b;
}
else if( (b & 0x40) == 0x40 )
{
i = asUINT(b & 0x3F) << 8;
ReadData(&b, 1); i += b;
}
else
{
i = b;
}
if( isNegative )
i = (asQWORD)(-asINT64(i));
return i;
}
asUINT asCReader::SanityCheck(asUINT val, asUINT max)
{
if (val > max)
{
Error(TXT_INVALID_BYTECODE_d);
// Return 0 as default value
return 0;
}
return val;
}
int asCReader::SanityCheck(int val, asUINT max)
{
if (val > int(max) || val < -int(max))
{
Error(TXT_INVALID_BYTECODE_d);
// Return 0 as default value
return 0;
}
return val;
}
void asCReader::ReadString(asCString* str)
{
asUINT len = SanityCheck(ReadEncodedUInt(), 1000000);
if( len & 1 )
{
asUINT idx = len/2;
if( idx < savedStrings.GetLength() )
*str = savedStrings[idx];
else
Error(TXT_INVALID_BYTECODE_d);
}
else if( len > 0 )
{
len /= 2;
str->SetLength(len);
int r = stream->Read(str->AddressOf(), len);
if (r < 0)
Error(TXT_UNEXPECTED_END_OF_FILE);
savedStrings.PushLast(*str);
}
else
str->SetLength(0);
}
void asCReader::ReadGlobalProperty()
{
asCString name;
asCDataType type;
ReadString(&name);
asCString ns;
ReadString(&ns);
asSNameSpace *nameSpace = engine->AddNameSpace(ns.AddressOf());
ReadDataType(&type);
asCGlobalProperty *prop = module->AllocateGlobalProperty(name.AddressOf(), type, nameSpace);
// Read the initialization function
bool isNew;
// Do not add the function to the GC at this time. It will
// only be added to the GC when the module releases the property
asCScriptFunction *func = ReadFunction(isNew, false, true, false);
if( func )
{
// Make sure the function knows it is owned by the module
func->module = module;
prop->SetInitFunc(func);
func->ReleaseInternal();
}
}
void asCReader::ReadObjectProperty(asCObjectType *ot)
{
asCString name;
ReadString(&name);
asCDataType dt;
ReadDataType(&dt);
int flags = ReadEncodedUInt();
bool isPrivate = (flags & 1) ? true : false;
bool isProtected = (flags & 2) ? true : false;
bool isInherited = (flags & 4) ? true : false;
// TODO: shared: If the type is shared and pre-existing, we should just
// validate that the loaded methods match the original
if( !existingShared.MoveTo(0, ot) )
ot->AddPropertyToClass(name, dt, isPrivate, isProtected, isInherited);
}
void asCReader::ReadDataType(asCDataType *dt)
{
// Check if this is a previously used type
asUINT idx = ReadEncodedUInt();
if( idx != 0 )
{
// Get the datatype from the cache
*dt = savedDataTypes[idx-1];
return;
}
// Read the type definition
eTokenType tokenType = (eTokenType)ReadEncodedUInt();
// Reserve a spot in the savedDataTypes
asUINT saveSlot = savedDataTypes.GetLength();
savedDataTypes.PushLast(asCDataType());
// Read the datatype for the first time
asCTypeInfo *ti = 0;
if( tokenType == ttIdentifier )
ti = ReadTypeInfo();
// Read type flags as a bitmask
// Endian-safe code
bool isObjectHandle, isHandleToConst, isReference, isReadOnly;
char b = 0;
ReadData(&b, 1);
LOAD_FROM_BIT(isObjectHandle, b, 0);
LOAD_FROM_BIT(isHandleToConst, b, 1);
LOAD_FROM_BIT(isReference, b, 2);
LOAD_FROM_BIT(isReadOnly, b, 3);
if( tokenType == ttIdentifier )
*dt = asCDataType::CreateType(ti, false);
else
*dt = asCDataType::CreatePrimitive(tokenType, false);
if( isObjectHandle )
{
dt->MakeReadOnly(isHandleToConst ? true : false);
// Here we must allow a scoped type to be a handle
// e.g. if the datatype is for a system function
dt->MakeHandle(true, true);
}
dt->MakeReadOnly(isReadOnly ? true : false);
dt->MakeReference(isReference ? true : false);
// Update the previously saved slot
savedDataTypes[saveSlot] = *dt;
}
asCTypeInfo* asCReader::ReadTypeInfo()
{
asCTypeInfo *ot = 0;
char ch;
ReadData(&ch, 1);
if( ch == 'a' )
{
// Read the name of the template type
asCString typeName, ns;
ReadString(&typeName);
ReadString(&ns);
asSNameSpace *nameSpace = engine->AddNameSpace(ns.AddressOf());
asCTypeInfo *tmp = engine->GetRegisteredType(typeName.AddressOf(), nameSpace);
asCObjectType *tmpl = CastToObjectType(tmp);
if( tmpl == 0 )
{
asCString str;
str.Format(TXT_TEMPLATE_TYPE_s_DOESNT_EXIST, typeName.AddressOf());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
Error(TXT_INVALID_BYTECODE_d);
return 0;
}
asUINT numSubTypes = SanityCheck(ReadEncodedUInt(), 100);
asCArray<asCDataType> subTypes;
for( asUINT n = 0; n < numSubTypes; n++ )
{
ReadData(&ch, 1);
if( ch == 's' )
{
asCDataType dt;
ReadDataType(&dt);
subTypes.PushLast(dt);
}
else
{
eTokenType tokenType = (eTokenType)ReadEncodedUInt();
asCDataType dt = asCDataType::CreatePrimitive(tokenType, false);
subTypes.PushLast(dt);
}
}
// Return the actual template if the subtypes are the template's dummy types
if( tmpl->templateSubTypes == subTypes )
ot = tmpl;
else
{
// Get the template instance type based on the loaded subtypes
ot = engine->GetTemplateInstanceType(tmpl, subTypes, module);
}
if( ot == 0 )
{
// Show all subtypes in error message
asCString sub = subTypes[0].Format(nameSpace);
for( asUINT n = 1; n < subTypes.GetLength(); n++ )
{
sub += ",";
sub += subTypes[n].Format(nameSpace);
}
asCString str;
str.Format(TXT_INSTANCING_INVLD_TMPL_TYPE_s_s, typeName.AddressOf(), sub.AddressOf());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
Error(TXT_INVALID_BYTECODE_d);
return 0;
}
}
else if( ch == 'l' )
{
asCObjectType *st = CastToObjectType(ReadTypeInfo());
if( st == 0 || st->beh.listFactory == 0 )
{
Error(TXT_INVALID_BYTECODE_d);
return 0;
}
ot = engine->GetListPatternType(st->beh.listFactory);
}
else if( ch == 's' )
{
// Read the name of the template subtype
asCString typeName;
ReadString(&typeName);
// Find the template subtype
ot = 0;
for( asUINT n = 0; n < engine->templateSubTypes.GetLength(); n++ )
{
if( engine->templateSubTypes[n] && engine->templateSubTypes[n]->name == typeName )
{
ot = engine->templateSubTypes[n];
break;
}
}
if( ot == 0 )
{
asCString str;
str.Format(TXT_TEMPLATE_SUBTYPE_s_DOESNT_EXIST, typeName.AddressOf());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
Error(TXT_INVALID_BYTECODE_d);
return 0;
}
}
else if( ch == 'o' )
{
// Read the object type name
asCString typeName, ns;
ReadString(&typeName);
ReadString(&ns);
asSNameSpace *nameSpace = engine->AddNameSpace(ns.AddressOf());
if( typeName.GetLength() && typeName != "$obj" && typeName != "$func" )
{
// Find the object type
ot = module->GetType(typeName.AddressOf(), nameSpace);
if (!ot)
ot = engine->GetRegisteredType(typeName.AddressOf(), nameSpace);
if( ot == 0 )
{
asCString str;
str.Format(TXT_OBJECT_TYPE_s_DOESNT_EXIST, typeName.AddressOf());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
Error(TXT_INVALID_BYTECODE_d);
return 0;
}
}
else if( typeName == "$obj" )
{
ot = &engine->scriptTypeBehaviours;
}
else if( typeName == "$func" )
{
ot = &engine->functionBehaviours;
}
else
asASSERT( false );
}
else if (ch == 'c')
{
// Read the object type name
asCString typeName, ns;
ReadString(&typeName);
// Read the parent class
asCObjectType *parentClass = CastToObjectType(ReadTypeInfo());
if (parentClass == 0)
{
Error(TXT_INVALID_BYTECODE_d);
return 0;
}
// Find the child type in the parentClass
for (asUINT n = 0; n < parentClass->childFuncDefs.GetLength(); n++)
{
if (parentClass->childFuncDefs[n]->name == typeName)
ot = parentClass->childFuncDefs[n];
}
if (ot == 0)
{
asCString str;
str.Format(TXT_OBJECT_TYPE_s_DOESNT_EXIST, typeName.AddressOf());
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
Error(TXT_INVALID_BYTECODE_d);
return 0;
}
}
else
{
// No object type
asASSERT( ch == '\0' || error );
ot = 0;
}
return ot;
}
void asCReader::ReadByteCode(asCScriptFunction *func)
{
asASSERT( func->scriptData );
// Read number of instructions
asUINT total, numInstructions;
total = numInstructions = SanityCheck(ReadEncodedUInt(), 1000000);
// Reserve some space for the instructions
func->scriptData->byteCode.AllocateNoConstruct(numInstructions, false);
asUINT pos = 0;
while( numInstructions )
{
asBYTE b;
ReadData(&b, 1);
// Allocate the space for the instruction
asUINT len = asBCTypeSize[asBCInfo[b].type];
asUINT newSize = asUINT(func->scriptData->byteCode.GetLength()) + len;
if( func->scriptData->byteCode.GetCapacity() < newSize )
{
// Determine the average size of the loaded instructions and re-estimate the final size
asUINT size = asUINT(float(newSize) / (total - numInstructions) * total) + 1;
func->scriptData->byteCode.AllocateNoConstruct(size, true);
}
if( !func->scriptData->byteCode.SetLengthNoConstruct(newSize) )
{
// Out of memory
error = true;
return;
}
asDWORD *bc = func->scriptData->byteCode.AddressOf() + pos;
pos += len;
switch( asBCInfo[b].type )
{
case asBCTYPE_NO_ARG:
{
*(asBYTE*)(bc) = b;
bc++;
}
break;
case asBCTYPE_W_ARG:
case asBCTYPE_wW_ARG:
case asBCTYPE_rW_ARG:
{
*(asBYTE*)(bc) = b;
// Read the argument
asWORD w = ReadEncodedUInt16();
*(((asWORD*)bc)+1) = w;
bc++;
}
break;
case asBCTYPE_rW_DW_ARG:
case asBCTYPE_wW_DW_ARG:
case asBCTYPE_W_DW_ARG:
{
*(asBYTE*)(bc) = b;
// Read the word argument
asWORD w = ReadEncodedUInt16();
*(((asWORD*)bc)+1) = w;
bc++;
// Read the dword argument
*bc++ = ReadEncodedUInt();
}
break;
case asBCTYPE_DW_ARG:
{
*(asBYTE*)(bc) = b;
bc++;
// Read the argument
*bc++ = ReadEncodedUInt();
}
break;
case asBCTYPE_DW_DW_ARG:
{
*(asBYTE*)(bc) = b;
bc++;
// Read the first argument
*bc++ = ReadEncodedUInt();
// Read the second argument
*bc++ = ReadEncodedUInt();
}
break;
case asBCTYPE_wW_rW_rW_ARG:
{
*(asBYTE*)(bc) = b;
// Read the first argument
asWORD w = ReadEncodedUInt16();
*(((asWORD*)bc)+1) = w;
bc++;
// Read the second argument
w = ReadEncodedUInt16();
*(asWORD*)bc = w;
// Read the third argument
w = ReadEncodedUInt16();
*(((asWORD*)bc)+1) = w;
bc++;
}
break;
case asBCTYPE_wW_rW_ARG:
case asBCTYPE_rW_rW_ARG:
case asBCTYPE_wW_W_ARG:
{
*(asBYTE*)(bc) = b;
// Read the first argument
asWORD w = ReadEncodedUInt16();
*(((asWORD*)bc)+1) = w;
bc++;
// Read the second argument
w = ReadEncodedUInt16();
*(asWORD*)bc = w;
bc++;
}
break;
case asBCTYPE_wW_rW_DW_ARG:
case asBCTYPE_rW_W_DW_ARG:
{
*(asBYTE*)(bc) = b;
// Read the first argument
asWORD w = ReadEncodedUInt16();
*(((asWORD*)bc)+1) = w;
bc++;
// Read the second argument
w = ReadEncodedUInt16();
*(asWORD*)bc = w;
bc++;
// Read the third argument
asDWORD dw = ReadEncodedUInt();
*bc++ = dw;
}
break;
case asBCTYPE_QW_ARG:
{
*(asBYTE*)(bc) = b;
bc++;
// Read the argument
asQWORD qw = ReadEncodedUInt64();
*(asQWORD*)bc = qw;
bc += 2;
}
break;
case asBCTYPE_QW_DW_ARG:
{
*(asBYTE*)(bc) = b;
bc++;
// Read the first argument
asQWORD qw = ReadEncodedUInt64();
*(asQWORD*)bc = qw;
bc += 2;
// Read the second argument
asDWORD dw = ReadEncodedUInt();
*bc++ = dw;
}
break;
case asBCTYPE_rW_QW_ARG:
case asBCTYPE_wW_QW_ARG:
{
*(asBYTE*)(bc) = b;
// Read the first argument
asWORD w = ReadEncodedUInt16();
*(((asWORD*)bc)+1) = w;
bc++;
// Read the argument
asQWORD qw = ReadEncodedUInt64();
*(asQWORD*)bc = qw;
bc += 2;
}
break;
case asBCTYPE_rW_DW_DW_ARG:
{
*(asBYTE*)(bc) = b;
// Read the 1st argument
asWORD w = ReadEncodedUInt16();
*(((asWORD*)bc)+1) = w;
bc++;
// Read the 2nd argument
*bc++ = ReadEncodedUInt();
// Read the 3rd argument
*bc++ = ReadEncodedUInt();
}
break;
default:
{
// This should never happen
asASSERT(false);
// Read the next 3 bytes
asDWORD c; asBYTE t;
#if defined(AS_BIG_ENDIAN)
c = b << 24;
ReadData(&t, 1); c += t << 16;
ReadData(&t, 1); c += t << 8;
ReadData(&t, 1); c += t;
#else
c = b;
ReadData(&t, 1); c += t << 8;
ReadData(&t, 1); c += t << 16;
ReadData(&t, 1); c += t << 24;
#endif
*bc++ = c;
c = *(asBYTE*)&c;
// Read the bc as is
for( int n = 1; n < asBCTypeSize[asBCInfo[c].type]; n++ )
ReadData(&*bc++, 4);
}
}
numInstructions--;
}
// Correct the final size in case we over-estimated it
func->scriptData->byteCode.SetLengthNoConstruct(pos);
}
void asCReader::ReadUsedTypeIds()
{
TimeIt("asCReader::ReadUsedTypeIds");
asUINT count = SanityCheck(ReadEncodedUInt(), 1000000);
usedTypeIds.Allocate(count, false);
for( asUINT n = 0; n < count; n++ )
{
asCDataType dt;
ReadDataType(&dt);
usedTypeIds.PushLast(engine->GetTypeIdFromDataType(dt));
}
}
void asCReader::ReadUsedGlobalProps()
{
TimeIt("asCReader::ReadUsedGlobalProps");
int c = SanityCheck(ReadEncodedUInt(), 1000000);
usedGlobalProperties.Allocate(c, false);
for( int n = 0; n < c; n++ )
{
asCString name, ns;
asCDataType type;
char moduleProp;
ReadString(&name);
ReadString(&ns);
ReadDataType(&type);
ReadData(&moduleProp, 1);
asSNameSpace *nameSpace = engine->AddNameSpace(ns.AddressOf());
// Find the real property
asCGlobalProperty *globProp = 0;
if( moduleProp )
globProp = module->m_scriptGlobals.GetFirst(nameSpace, name);
else
globProp = engine->registeredGlobalProps.GetFirst(nameSpace, name);
void *prop = 0;
if( globProp && globProp->type == type )
prop = globProp->GetAddressOfValue();
usedGlobalProperties.PushLast(prop);
if( prop == 0 )
{
Error(TXT_INVALID_BYTECODE_d);
}
}
}
void asCReader::ReadUsedObjectProps()
{
TimeIt("asCReader::ReadUsedObjectProps");
asUINT c = SanityCheck(ReadEncodedUInt(), 1000000);
usedObjectProperties.SetLength(c);
for( asUINT n = 0; n < c; n++ )
{
asCObjectType *objType = CastToObjectType(ReadTypeInfo());
if( objType == 0 )
{
Error(TXT_INVALID_BYTECODE_d);
break;
}
asCString name;
ReadString(&name);
// Find the property
bool found = false;
for( asUINT p = 0; p < objType->properties.GetLength(); p++ )
{
if( objType->properties[p]->name == name )
{
usedObjectProperties[n].objType = objType;
usedObjectProperties[n].prop = objType->properties[p];
found = true;
break;
}
}
if( !found )
{
Error(TXT_INVALID_BYTECODE_d);
return;
}
}
}
short asCReader::FindObjectPropOffset(asWORD index)
{
static asCObjectProperty *lastCompositeProp = 0;
if (lastCompositeProp)
{
if (index != 0)
{
Error(TXT_INVALID_BYTECODE_d);
return 0;
}
short offset = (short)lastCompositeProp->byteOffset;
lastCompositeProp = 0;
return offset;
}
if( index >= usedObjectProperties.GetLength() )
{
Error(TXT_INVALID_BYTECODE_d);
return 0;
}
if (usedObjectProperties[index].prop->compositeOffset || usedObjectProperties[index].prop->isCompositeIndirect)
{
lastCompositeProp = usedObjectProperties[index].prop;
return (short)lastCompositeProp->compositeOffset;
}
return (short)usedObjectProperties[index].prop->byteOffset;
}
asCScriptFunction *asCReader::FindFunction(int idx)
{
if( idx >= 0 && idx < (int)usedFunctions.GetLength() )
return usedFunctions[idx];
else
{
Error(TXT_INVALID_BYTECODE_d);
return 0;
}
}
void asCReader::TranslateFunction(asCScriptFunction *func)
{
// Skip this if the function is part of an pre-existing shared object
if( dontTranslate.MoveTo(0, func) ) return;
asASSERT( func->scriptData );
// Pre-compute the size of each instruction in order to translate jump offsets
asUINT n;
asDWORD *bc = func->scriptData->byteCode.AddressOf();
asUINT bcLength = (asUINT)func->scriptData->byteCode.GetLength();
asCArray<asUINT> bcSizes(bcLength);
asCArray<asUINT> instructionNbrToPos(bcLength);
for( n = 0; n < bcLength; )
{
int c = *(asBYTE*)&bc[n];
asUINT size = asBCTypeSize[asBCInfo[c].type];
if( size == 0 )
{
Error(TXT_INVALID_BYTECODE_d);
return;
}
bcSizes.PushLast(size);
instructionNbrToPos.PushLast(n);
n += size;
}
asUINT bcNum = 0;
for( n = 0; n < bcLength; bcNum++ )
{
int c = *(asBYTE*)&bc[n];
if( c == asBC_REFCPY ||
c == asBC_RefCpyV ||
c == asBC_OBJTYPE )
{
// Translate the index to the true object type
asPWORD *ot = (asPWORD*)&bc[n+1];
*(asCObjectType**)ot = CastToObjectType(FindType(int(*ot)));
}
else if( c == asBC_TYPEID ||
c == asBC_Cast )
{
// Translate the index to the type id
int *tid = (int*)&bc[n+1];
*tid = FindTypeId(*tid);
}
else if( c == asBC_ADDSi ||
c == asBC_LoadThisR )
{
// Translate the index to the type id
int *tid = (int*)&bc[n+1];
*tid = FindTypeId(*tid);
// Translate the prop index into the property offset
*(((short*)&bc[n])+1) = FindObjectPropOffset(*(((short*)&bc[n])+1));
}
else if( c == asBC_LoadRObjR ||
c == asBC_LoadVObjR )
{
// Translate the index to the type id
int *tid = (int*)&bc[n+2];
*tid = FindTypeId(*tid);
asCObjectType *ot = engine->GetObjectTypeFromTypeId(*tid);
if( ot && (ot->flags & asOBJ_LIST_PATTERN) )
{
// List patterns have a different way of adjusting the offsets
SListAdjuster *listAdj = listAdjusters[listAdjusters.GetLength()-1];
*(((short*)&bc[n])+2) = (short)listAdj->AdjustOffset(*(((short*)&bc[n])+2));
}
else
{
// Translate the prop index into the property offset
*(((short*)&bc[n])+2) = FindObjectPropOffset(*(((short*)&bc[n])+2));
}
}
else if( c == asBC_COPY )
{
// Translate the index to the type id
int *tid = (int*)&bc[n+1];
*tid = FindTypeId(*tid);
// COPY is used to copy POD types that don't have the opAssign method. It is
// also used to copy references to scoped types during variable initializations.
// Update the number of dwords to copy as it may be different on the target platform
if( (*tid) & asTYPEID_OBJHANDLE )
{
// It is the actual reference that is being copied, not the object itself
asBC_SWORDARG0(&bc[n]) = AS_PTR_SIZE;
}
else
{
asCDataType dt = engine->GetDataTypeFromTypeId(*tid);
if( !dt.IsValid() )
{
Error(TXT_INVALID_BYTECODE_d);
}
else
asBC_SWORDARG0(&bc[n]) = (short)dt.GetSizeInMemoryDWords();
}
}
else if( c == asBC_RET )
{
// Determine the correct amount of DWORDs to pop
asWORD dw = (asWORD)func->GetSpaceNeededForArguments();
if( func->DoesReturnOnStack() ) dw += AS_PTR_SIZE;
if( func->objectType ) dw += AS_PTR_SIZE;
asBC_WORDARG0(&bc[n]) = dw;
}
else if( c == asBC_CALL ||
c == asBC_CALLINTF ||
c == asBC_CALLSYS ||
c == asBC_Thiscall1 )
{
// Translate the index to the func id
int *fid = (int*)&bc[n+1];
asCScriptFunction *f = FindFunction(*fid);
if( f )
*fid = f->id;
else
{
Error(TXT_INVALID_BYTECODE_d);
return;
}
}
else if( c == asBC_FuncPtr )
{
// Translate the index to the func pointer
asPWORD *fid = (asPWORD*)&bc[n+1];
*fid = (asPWORD)FindFunction(int(*fid));
}
else if( c == asBC_ALLOC )
{
// Translate the index to the true object type
asPWORD *arg = (asPWORD*)&bc[n+1];
*(asCObjectType**)arg = CastToObjectType(FindType(int(*arg)));
// The constructor function id must be translated, unless it is zero
int *fid = (int*)&bc[n+1+AS_PTR_SIZE];
if( *fid != 0 )
{
// Subtract 1 from the id, as it was incremented during the writing
asCScriptFunction *f = FindFunction(*fid-1);
if( f )
*fid = f->id;
else
{
Error(TXT_INVALID_BYTECODE_d);
return;
}
}
}
else if( c == asBC_STR )
{
Error(TXT_INVALID_BYTECODE_d);
return;
}
else if( c == asBC_CALLBND )
{
// Translate the function id
asUINT *fid = (asUINT*)&bc[n+1];
if( *fid < module->m_bindInformations.GetLength() )
{
sBindInfo *bi = module->m_bindInformations[*fid];
if( bi )
*fid = bi->importedFunctionSignature->id;
else
{
Error(TXT_INVALID_BYTECODE_d);
return;
}
}
else
{
Error(TXT_INVALID_BYTECODE_d);
return;
}
}
else if( c == asBC_PGA ||
c == asBC_PshGPtr ||
c == asBC_LDG ||
c == asBC_PshG4 ||
c == asBC_LdGRdR4 ||
c == asBC_CpyGtoV4 ||
c == asBC_CpyVtoG4 ||
c == asBC_SetG4 )
{
// Translate the index to pointer
asPWORD *index = (asPWORD*)&bc[n + 1];
if ((*index & 1))
{
if ((asUINT(*index)>>1) < usedGlobalProperties.GetLength())
*(void**)index = usedGlobalProperties[asUINT(*index)>>1];
else
{
Error(TXT_INVALID_BYTECODE_d);
return;
}
}
else
{
// Only PGA and PshGPtr can hold string constants
asASSERT(c == asBC_PGA || c == asBC_PshGPtr);
if ((asUINT(*index)>>1) < usedStringConstants.GetLength())
*(void**)index = usedStringConstants[asUINT(*index)>>1];
else
{
Error(TXT_INVALID_BYTECODE_d);
return;
}
}
}
else if( c == asBC_JMP ||
c == asBC_JZ ||
c == asBC_JNZ ||
c == asBC_JLowZ ||
c == asBC_JLowNZ ||
c == asBC_JS ||
c == asBC_JNS ||
c == asBC_JP ||
c == asBC_JNP ) // The JMPP instruction doesn't need modification
{
// Get the offset
int offset = int(bc[n+1]);
// Count the instruction sizes to the destination instruction
int size = 0;
if( offset >= 0 )
// If moving ahead, then start from next instruction
for( asUINT num = bcNum+1; offset-- > 0; num++ )
size += bcSizes[num];
else
// If moving backwards, then start at current instruction
for( asUINT num = bcNum; offset++ < 0; num-- )
size -= bcSizes[num];
// The size is dword offset
bc[n+1] = size;
}
else if( c == asBC_AllocMem )
{
// The size of the allocated memory is only known after all the elements has been seen.
// This helper class will collect this information and adjust the size when the
// corresponding asBC_FREE is encountered
// The adjuster also needs to know the list type so it can know the type of the elements
asCObjectType *ot = CastToObjectType(func->GetTypeInfoOfLocalVar(asBC_SWORDARG0(&bc[n])));
listAdjusters.PushLast(asNEW(SListAdjuster)(this, &bc[n], ot));
}
else if( c == asBC_FREE )
{
// Translate the index to the true object type
asPWORD *pot = (asPWORD*)&bc[n+1];
*(asCObjectType**)pot = CastToObjectType(FindType(int(*pot)));
asCObjectType *ot = *(asCObjectType**)pot;
if( ot && (ot->flags & asOBJ_LIST_PATTERN) )
{
if( listAdjusters.GetLength() == 0 )
{
Error(TXT_INVALID_BYTECODE_d);
return;
}
// Finalize the adjustment of the list buffer that was initiated with asBC_AllocMem
SListAdjuster *list = listAdjusters.PopLast();
list->AdjustAllocMem();
asDELETE(list, SListAdjuster);
}
}
else if( c == asBC_SetListSize )
{
// Adjust the offset in the list where the size is informed
SListAdjuster *listAdj = listAdjusters[listAdjusters.GetLength()-1];
bc[n+1] = listAdj->AdjustOffset(bc[n+1]);
// Inform the list adjuster how many values will be repeated
listAdj->SetRepeatCount(bc[n+2]);
}
else if( c == asBC_PshListElmnt )
{
// Adjust the offset in the list where the size is informed
SListAdjuster *listAdj = listAdjusters[listAdjusters.GetLength()-1];
bc[n+1] = listAdj->AdjustOffset(bc[n+1]);
}
else if( c == asBC_SetListType )
{
// Adjust the offset in the list where the typeid is informed
SListAdjuster *listAdj = listAdjusters[listAdjusters.GetLength()-1];
bc[n+1] = listAdj->AdjustOffset(bc[n+1]);
// Translate the type id
bc[n+2] = FindTypeId(bc[n+2]);
// Inform the list adjuster the type id of the next element
listAdj->SetNextType(bc[n+2]);
}
n += asBCTypeSize[asBCInfo[c].type];
}
// Calculate the stack adjustments
CalculateAdjustmentByPos(func);
// Adjust all variable positions in the bytecode
bc = func->scriptData->byteCode.AddressOf();
for( n = 0; n < bcLength; )
{
int c = *(asBYTE*)&bc[n];
switch( asBCInfo[c].type )
{
case asBCTYPE_wW_ARG:
case asBCTYPE_rW_DW_ARG:
case asBCTYPE_wW_QW_ARG:
case asBCTYPE_rW_ARG:
case asBCTYPE_wW_DW_ARG:
case asBCTYPE_wW_W_ARG:
case asBCTYPE_rW_QW_ARG:
case asBCTYPE_rW_W_DW_ARG:
case asBCTYPE_rW_DW_DW_ARG:
{
asBC_SWORDARG0(&bc[n]) = (short)AdjustStackPosition(asBC_SWORDARG0(&bc[n]));
}
break;
case asBCTYPE_wW_rW_ARG:
case asBCTYPE_wW_rW_DW_ARG:
case asBCTYPE_rW_rW_ARG:
{
asBC_SWORDARG0(&bc[n]) = (short)AdjustStackPosition(asBC_SWORDARG0(&bc[n]));
asBC_SWORDARG1(&bc[n]) = (short)AdjustStackPosition(asBC_SWORDARG1(&bc[n]));
}
break;
case asBCTYPE_wW_rW_rW_ARG:
{
asBC_SWORDARG0(&bc[n]) = (short)AdjustStackPosition(asBC_SWORDARG0(&bc[n]));
asBC_SWORDARG1(&bc[n]) = (short)AdjustStackPosition(asBC_SWORDARG1(&bc[n]));
asBC_SWORDARG2(&bc[n]) = (short)AdjustStackPosition(asBC_SWORDARG2(&bc[n]));
}
break;
default:
// The other types don't treat variables so won't be modified
break;
}
n += asBCTypeSize[asBCInfo[c].type];
}
// Adjust the space needed for local variables
func->scriptData->variableSpace = AdjustStackPosition(func->scriptData->variableSpace);
// Adjust the variable information. This will be used during the adjustment below
for( n = 0; n < func->scriptData->variables.GetLength(); n++ )
{
func->scriptData->variables[n]->declaredAtProgramPos = instructionNbrToPos[func->scriptData->variables[n]->declaredAtProgramPos];
func->scriptData->variables[n]->stackOffset = AdjustStackPosition(func->scriptData->variables[n]->stackOffset);
}
// objVariablePos
for( n = 0; n < func->scriptData->objVariablePos.GetLength(); n++ )
func->scriptData->objVariablePos[n] = AdjustStackPosition(func->scriptData->objVariablePos[n]);
// Adjust the get offsets. This must be done in the second iteration because
// it relies on the function ids and variable position already being correct in the
// bytecodes that come after the GET instructions.
// TODO: optimize: Instead of doing a full extra loop. We can push the GET instructions
// on a stack, and then when a call instruction is found update all of them.
// This will also make the AdjustGetOffset() function quicker as it can
// receive the called function directly instead of having to search for it.
bc = func->scriptData->byteCode.AddressOf();
for( n = 0; n < bcLength; )
{
int c = *(asBYTE*)&bc[n];
if( c == asBC_GETREF ||
c == asBC_GETOBJ ||
c == asBC_GETOBJREF ||
c == asBC_ChkNullS )
{
asBC_WORDARG0(&bc[n]) = (asWORD)AdjustGetOffset(asBC_WORDARG0(&bc[n]), func, n);
}
n += asBCTypeSize[asBCInfo[c].type];
}
for( n = 0; n < func->scriptData->objVariableInfo.GetLength(); n++ )
{
// The program position must be adjusted as it is stored in number of instructions
func->scriptData->objVariableInfo[n].programPos = instructionNbrToPos[func->scriptData->objVariableInfo[n].programPos];
func->scriptData->objVariableInfo[n].variableOffset = AdjustStackPosition(func->scriptData->objVariableInfo[n].variableOffset);
}
for (n = 0; n < func->scriptData->tryCatchInfo.GetLength(); n++)
{
func->scriptData->tryCatchInfo[n].tryPos = instructionNbrToPos[func->scriptData->tryCatchInfo[n].tryPos];
func->scriptData->tryCatchInfo[n].catchPos = instructionNbrToPos[func->scriptData->tryCatchInfo[n].catchPos];
}
// The program position (every even number) needs to be adjusted
// for the line numbers to be in number of dwords instead of number of instructions
for( n = 0; n < func->scriptData->lineNumbers.GetLength(); n += 2 )
func->scriptData->lineNumbers[n] = instructionNbrToPos[func->scriptData->lineNumbers[n]];
for( n = 0; n < func->scriptData->sectionIdxs.GetLength(); n += 2 )
func->scriptData->sectionIdxs[n] = instructionNbrToPos[func->scriptData->sectionIdxs[n]];
CalculateStackNeeded(func);
}
asCReader::SListAdjuster::SListAdjuster(asCReader *rd, asDWORD *bc, asCObjectType *listType) :
reader(rd), allocMemBC(bc), maxOffset(0), patternType(listType), repeatCount(0), lastOffset(-1), nextOffset(0), nextTypeId(-1)
{
asASSERT( patternType && (patternType->flags & asOBJ_LIST_PATTERN) );
// Find the first expected value in the list
asSListPatternNode *node = patternType->engine->scriptFunctions[patternType->templateSubTypes[0].GetBehaviour()->listFactory]->listPattern;
asASSERT( node && node->type == asLPT_START );
patternNode = node->next;
}
int asCReader::SListAdjuster::AdjustOffset(int offset)
{
if( offset < lastOffset )
{
reader->Error(TXT_INVALID_BYTECODE_d);
return 0;
}
// If it is the same offset being accessed again, just return the same adjusted value
if( lastOffset == offset )
return lastAdjustedOffset;
lastOffset = offset;
lastAdjustedOffset = maxOffset;
// What is being expected at this position?
if( patternNode->type == asLPT_REPEAT || patternNode->type == asLPT_REPEAT_SAME )
{
// Align the offset to 4 bytes boundary
if( maxOffset & 0x3 )
{
maxOffset += 4 - (maxOffset & 0x3);
lastAdjustedOffset = maxOffset;
}
// Don't move the patternNode yet because the caller must make a call to SetRepeatCount too
maxOffset += 4;
nextOffset = offset+1;
return lastAdjustedOffset;
}
else if( patternNode->type == asLPT_TYPE )
{
const asCDataType &dt = reinterpret_cast<asSListPatternDataTypeNode*>(patternNode)->dataType;
if( dt.GetTokenType() == ttQuestion )
{
if( nextTypeId != -1 )
{
if( repeatCount > 0 )
repeatCount--;
asCDataType nextdt = patternType->engine->GetDataTypeFromTypeId(nextTypeId);
asUINT size;
if(nextdt.IsObjectHandle() || (nextdt.GetTypeInfo() && (nextdt.GetTypeInfo()->flags & asOBJ_REF)) )
size = AS_PTR_SIZE*4;
else
size = nextdt.GetSizeInMemoryBytes();
// Align the offset to 4 bytes boundary
if( size >= 4 && (maxOffset & 0x3) )
{
maxOffset += 4 - (maxOffset & 0x3);
lastAdjustedOffset = maxOffset;
}
// Only move the patternNode if we're not expecting any more repeated entries
if( repeatCount == 0 )
patternNode = patternNode->next;
nextTypeId = -1;
maxOffset += size;
nextOffset = offset+1;
return lastAdjustedOffset;
}
else
{
// Align the offset to 4 bytes boundary
if( maxOffset & 0x3 )
{
maxOffset += 4 - (maxOffset & 0x3);
lastAdjustedOffset = maxOffset;
}
// The first adjustment is for the typeId
maxOffset += 4;
nextOffset = offset+1;
return lastAdjustedOffset;
}
}
else
{
// Determine the size of the element
asUINT size;
if( dt.IsObjectHandle() || (dt.GetTypeInfo() && (dt.GetTypeInfo()->flags & asOBJ_REF)) )
size = AS_PTR_SIZE*4;
else
size = dt.GetSizeInMemoryBytes();
// If values are skipped, the offset needs to be incremented
while( nextOffset <= offset )
{
if( repeatCount > 0 )
repeatCount--;
// Align the offset to 4 bytes boundary
if( size >= 4 && (maxOffset & 0x3) )
maxOffset += 4 - (maxOffset & 0x3);
lastAdjustedOffset = maxOffset;
nextOffset += 1;
maxOffset += size;
}
// Only move the patternNode if we're not expecting any more repeated entries
if( repeatCount == 0 )
patternNode = patternNode->next;
nextOffset = offset+1;
return lastAdjustedOffset;
}
}
else if( patternNode->type == asLPT_START )
{
if( repeatCount > 0 )
repeatCount--;
SInfo info = {repeatCount, patternNode};
stack.PushLast(info);
repeatCount = 0;
patternNode = patternNode->next;
lastOffset--;
return AdjustOffset(offset);
}
else if( patternNode->type == asLPT_END )
{
if( stack.GetLength() == 0 )
{
reader->Error(TXT_INVALID_BYTECODE_d);
return 0;
}
SInfo info = stack.PopLast();
repeatCount = info.repeatCount;
if( repeatCount )
patternNode = info.startNode;
else
patternNode = patternNode->next;
lastOffset--;
return AdjustOffset(offset);
}
else
{
// Something is wrong with the pattern list declaration
reader->Error(TXT_INVALID_BYTECODE_d);
return 0;
}
UNREACHABLE_RETURN;
}
void asCReader::SListAdjuster::SetRepeatCount(asUINT rc)
{
// Make sure the list is expecting a repeat at this location
asASSERT( patternNode->type == asLPT_REPEAT || patternNode->type == asLPT_REPEAT_SAME );
// Now move to the next patternNode
patternNode = patternNode->next;
repeatCount = rc;
}
void asCReader::SListAdjuster::AdjustAllocMem()
{
allocMemBC[1] = maxOffset;
}
void asCReader::SListAdjuster::SetNextType(int typeId)
{
asASSERT( nextTypeId == -1 );
nextTypeId = typeId;
}
void asCReader::CalculateStackNeeded(asCScriptFunction *func)
{
asASSERT( func->scriptData );
int largestStackUsed = 0;
// Clear the known stack size for each bytecode
asCArray<int> stackSize;
stackSize.SetLength(func->scriptData->byteCode.GetLength());
memset(&stackSize[0], -1, stackSize.GetLength()*4);
// Add the first instruction to the list of unchecked code
// paths and set the stack size at that instruction to variableSpace
asCArray<asUINT> paths;
paths.PushLast(0);
stackSize[0] = func->scriptData->variableSpace;
// Go through each of the code paths
for( asUINT p = 0; p < paths.GetLength(); ++p )
{
asUINT pos = paths[p];
int currStackSize = stackSize[pos];
asBYTE bc = *(asBYTE*)&func->scriptData->byteCode[pos];
if( bc == asBC_RET )
continue;
// Determine the change in stack size for this instruction
int stackInc = asBCInfo[bc].stackInc;
if( stackInc == 0xFFFF )
{
// Determine the true delta from the instruction arguments
if( bc == asBC_CALL ||
bc == asBC_CALLSYS ||
bc == asBC_Thiscall1 ||
bc == asBC_CALLBND ||
bc == asBC_ALLOC ||
bc == asBC_CALLINTF ||
bc == asBC_CallPtr )
{
asCScriptFunction *called = GetCalledFunction(func, pos);
if( called )
{
stackInc = -called->GetSpaceNeededForArguments();
if( called->objectType )
stackInc -= AS_PTR_SIZE;
if( called->DoesReturnOnStack() )
stackInc -= AS_PTR_SIZE;
}
else
{
// It is an allocation for an object without a constructor
asASSERT( bc == asBC_ALLOC );
stackInc = -AS_PTR_SIZE;
}
}
}
currStackSize += stackInc;
asASSERT( currStackSize >= 0 );
if( currStackSize > largestStackUsed )
largestStackUsed = currStackSize;
if( bc == asBC_JMP )
{
// Find the label that we should jump to
int offset = asBC_INTARG(&func->scriptData->byteCode[pos]);
pos += 2 + offset;
// Add the destination as a new path
if( stackSize[pos] == -1 )
{
stackSize[pos] = currStackSize;
paths.PushLast(pos);
}
else
asASSERT(stackSize[pos] == currStackSize);
continue;
}
else if( bc == asBC_JZ || bc == asBC_JNZ ||
bc == asBC_JLowZ || bc == asBC_JLowNZ ||
bc == asBC_JS || bc == asBC_JNS ||
bc == asBC_JP || bc == asBC_JNP )
{
// Find the label that is being jumped to
int offset = asBC_INTARG(&func->scriptData->byteCode[pos]);
// Add both paths to the code paths
pos += 2;
if( stackSize[pos] == -1 )
{
stackSize[pos] = currStackSize;
paths.PushLast(pos);
}
else
asASSERT(stackSize[pos] == currStackSize);
pos += offset;
if( stackSize[pos] == -1 )
{
stackSize[pos] = currStackSize;
paths.PushLast(pos);
}
else
asASSERT(stackSize[pos] == currStackSize);
continue;
}
else if( bc == asBC_JMPP )
{
pos++;
// Add all subsequent JMP instructions to the path
while( *(asBYTE*)&func->scriptData->byteCode[pos] == asBC_JMP )
{
if( stackSize[pos] == -1 )
{
stackSize[pos] = currStackSize;
paths.PushLast(pos);
}
else
asASSERT(stackSize[pos] == currStackSize);
pos += 2;
}
continue;
}
else
{
// Add next instruction to the paths
pos += asBCTypeSize[asBCInfo[bc].type];
if( stackSize[pos] == -1 )
{
stackSize[pos] = currStackSize;
paths.PushLast(pos);
}
else
asASSERT(stackSize[pos] == currStackSize);
continue;
}
}
func->scriptData->stackNeeded = largestStackUsed;
}
void asCReader::CalculateAdjustmentByPos(asCScriptFunction *func)
{
// Adjust the offset of all negative variables (parameters) as
// all pointers have been stored as having a size of 1 dword
asUINT n;
asCArray<int> adjustments;
asUINT offset = 0;
if( func->objectType )
{
adjustments.PushLast(offset);
adjustments.PushLast(1-AS_PTR_SIZE);
offset += 1;
}
if( func->DoesReturnOnStack() )
{
adjustments.PushLast(offset);
adjustments.PushLast(1-AS_PTR_SIZE);
offset += 1;
}
for( n = 0; n < func->parameterTypes.GetLength(); n++ )
{
if( !func->parameterTypes[n].IsPrimitive() ||
func->parameterTypes[n].IsReference() )
{
adjustments.PushLast(offset);
adjustments.PushLast(1-AS_PTR_SIZE);
offset += 1;
}
else
{
asASSERT( func->parameterTypes[n].IsPrimitive() );
offset += func->parameterTypes[n].GetSizeOnStackDWords();
}
}
// Build look-up table with the adjustments for each stack position
adjustNegativeStackByPos.SetLength(offset);
memset(adjustNegativeStackByPos.AddressOf(), 0, adjustNegativeStackByPos.GetLength()*sizeof(int));
for( n = 0; n < adjustments.GetLength(); n+=2 )
{
int pos = adjustments[n];
int adjust = adjustments[n+1];
for( asUINT i = pos+1; i < adjustNegativeStackByPos.GetLength(); i++ )
adjustNegativeStackByPos[i] += adjust;
}
// The bytecode has been stored as if all object variables take up only 1 dword.
// It is necessary to adjust to the size according to the current platform.
adjustments.SetLength(0);
int highestPos = 0;
for( n = 0; n < func->scriptData->objVariableTypes.GetLength(); n++ )
{
// Determine the size the variable currently occupies on the stack
int size = AS_PTR_SIZE;
// objVariableTypes is null if the type is a null pointer
if( func->scriptData->objVariableTypes[n] &&
(func->scriptData->objVariableTypes[n]->GetFlags() & asOBJ_VALUE) &&
n >= func->scriptData->objVariablesOnHeap )
{
size = func->scriptData->objVariableTypes[n]->GetSize();
if( size < 4 )
size = 1;
else
size /= 4;
}
// Check if type has a different size than stored
if( size > 1 )
{
if( func->scriptData->objVariablePos[n] > highestPos )
highestPos = func->scriptData->objVariablePos[n];
adjustments.PushLast(func->scriptData->objVariablePos[n]);
adjustments.PushLast(size-1);
}
}
// Count position 0 too
adjustByPos.SetLength(highestPos+1);
memset(adjustByPos.AddressOf(), 0, adjustByPos.GetLength()*sizeof(int));
// Build look-up table with the adjustments for each stack position
for( n = 0; n < adjustments.GetLength(); n+=2 )
{
int pos = adjustments[n];
int adjust = adjustments[n+1];
for( asUINT i = pos; i < adjustByPos.GetLength(); i++ )
adjustByPos[i] += adjust;
}
}
int asCReader::AdjustStackPosition(int pos)
{
if( pos >= (int)adjustByPos.GetLength() )
{
// It can be higher for primitives allocated on top of highest object variable
if( adjustByPos.GetLength() )
pos += (short)adjustByPos[adjustByPos.GetLength()-1];
}
else if( pos >= 0 )
pos += (short)adjustByPos[pos];
else if( -pos >= (int)adjustNegativeStackByPos.GetLength() )
Error(TXT_INVALID_BYTECODE_d);
else
pos += (short)adjustNegativeStackByPos[-pos];
return pos;
}
asCScriptFunction *asCReader::GetCalledFunction(asCScriptFunction *func, asDWORD programPos)
{
asBYTE bc = *(asBYTE*)&func->scriptData->byteCode[programPos];
if( bc == asBC_CALL ||
bc == asBC_CALLSYS ||
bc == asBC_Thiscall1 ||
bc == asBC_CALLINTF )
{
// Find the function from the function id in bytecode
int funcId = asBC_INTARG(&func->scriptData->byteCode[programPos]);
return engine->scriptFunctions[funcId];
}
else if( bc == asBC_ALLOC )
{
// Find the function from the function id in the bytecode
int funcId = asBC_INTARG(&func->scriptData->byteCode[programPos+AS_PTR_SIZE]);
return engine->scriptFunctions[funcId];
}
else if( bc == asBC_CALLBND )
{
// Find the function from the engine's bind array
int funcId = asBC_INTARG(&func->scriptData->byteCode[programPos]);
return engine->importedFunctions[funcId & ~FUNC_IMPORTED]->importedFunctionSignature;
}
else if( bc == asBC_CallPtr )
{
asUINT v;
int var = asBC_SWORDARG0(&func->scriptData->byteCode[programPos]);
// Find the funcdef from the local variable
for( v = 0; v < func->scriptData->objVariablePos.GetLength(); v++ )
if( func->scriptData->objVariablePos[v] == var )
return CastToFuncdefType(func->scriptData->objVariableTypes[v])->funcdef;
// Look in parameters
int paramPos = 0;
if( func->objectType )
paramPos -= AS_PTR_SIZE;
if( func->DoesReturnOnStack() )
paramPos -= AS_PTR_SIZE;
for( v = 0; v < func->parameterTypes.GetLength(); v++ )
{
if (var == paramPos)
{
if (func->parameterTypes[v].IsFuncdef())
return CastToFuncdefType(func->parameterTypes[v].GetTypeInfo())->funcdef;
else
{
error = true;
return 0;
}
}
paramPos -= func->parameterTypes[v].GetSizeOnStackDWords();
}
}
return 0;
}
int asCReader::AdjustGetOffset(int offset, asCScriptFunction *func, asDWORD programPos)
{
// TODO: optimize: multiple instructions for the same function doesn't need to look for the function everytime
// the function can remember where it found the function and check if the programPos is still valid
// Get offset 0 doesn't need adjustment
if( offset == 0 ) return 0;
bool bcAlloc = false;
// Find out which function that will be called
asCScriptFunction *calledFunc = 0;
int stackDelta = 0;
for( asUINT n = programPos; func->scriptData->byteCode.GetLength(); )
{
asBYTE bc = *(asBYTE*)&func->scriptData->byteCode[n];
if( bc == asBC_CALL ||
bc == asBC_CALLSYS ||
bc == asBC_Thiscall1 ||
bc == asBC_CALLINTF ||
bc == asBC_ALLOC ||
bc == asBC_CALLBND ||
bc == asBC_CallPtr )
{
// The alloc instruction allocates the object memory
// so it doesn't take the this pointer as input
if (bc == asBC_ALLOC)
bcAlloc = true;
calledFunc = GetCalledFunction(func, n);
break;
}
else if( bc == asBC_REFCPY ||
bc == asBC_COPY )
{
// In this case we know there is only 1 pointer on the stack above
asASSERT( offset == 1 );
return offset - (1 - AS_PTR_SIZE);
}
// Keep track of the stack size between the
// instruction that needs to be adjusted and the call
stackDelta += asBCInfo[bc].stackInc;
n += asBCTypeSize[asBCInfo[bc].type];
}
if( calledFunc == 0 )
{
Error(TXT_INVALID_BYTECODE_d);
return offset;
}
// Count the number of pointers pushed on the stack above the
// current offset, and then adjust the offset accordingly
asUINT numPtrs = 0;
int currOffset = -stackDelta;
if( offset > currOffset && calledFunc->GetObjectType() && !bcAlloc )
{
currOffset++;
if( currOffset > 0 )
numPtrs++;
#if AS_PTR_SIZE == 2
// For 64bit platforms it is necessary to increment the currOffset by one more
// DWORD since the stackDelta was counting the full 64bit size of the pointer
else if( stackDelta )
currOffset++;
#endif
}
if( offset > currOffset && calledFunc->DoesReturnOnStack() )
{
currOffset++;
if( currOffset > 0 )
numPtrs++;
#if AS_PTR_SIZE == 2
// For 64bit platforms it is necessary to increment the currOffset by one more
// DWORD since the stackDelta was counting the full 64bit size of the pointer
else if( stackDelta )
currOffset++;
#endif
}
for( asUINT p = 0; p < calledFunc->parameterTypes.GetLength(); p++ )
{
if( offset <= currOffset ) break;
if( !calledFunc->parameterTypes[p].IsPrimitive() ||
calledFunc->parameterTypes[p].IsReference() )
{
currOffset++;
if( currOffset > 0 )
numPtrs++;
#if AS_PTR_SIZE == 2
// For 64bit platforms it is necessary to increment the currOffset by one more
// DWORD since the stackDelta was counting the full 64bit size of the pointer
else if( stackDelta )
currOffset++;
#endif
// The variable arg ? has an additiona 32bit integer with the typeid
if( calledFunc->parameterTypes[p].IsAnyType() )
currOffset += 1;
}
else
{
// Enums or built-in primitives are passed by value
asASSERT( calledFunc->parameterTypes[p].IsPrimitive() );
currOffset += calledFunc->parameterTypes[p].GetSizeOnStackDWords();
}
}
return offset - numPtrs * (1 - AS_PTR_SIZE);
}
int asCReader::FindTypeId(int idx)
{
if( idx >= 0 && idx < (int)usedTypeIds.GetLength() )
return usedTypeIds[idx];
else
{
Error(TXT_INVALID_BYTECODE_d);
return 0;
}
}
asCTypeInfo *asCReader::FindType(int idx)
{
if( idx < 0 || idx >= (int)usedTypes.GetLength() )
{
Error(TXT_INVALID_BYTECODE_d);
return 0;
}
return usedTypes[idx];
}
#ifndef AS_NO_COMPILER
asCWriter::asCWriter(asCModule* _module, asIBinaryStream* _stream, asCScriptEngine* _engine, bool _stripDebug)
: module(_module), stream(_stream), engine(_engine), stripDebugInfo(_stripDebug), error(false), bytesWritten(0)
{
}
int asCWriter::Error(const char *msg)
{
// Don't write if it has already been reported an error earlier
if (!error)
{
asCString str;
str.Format(msg, bytesWritten);
engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, str.AddressOf());
error = true;
}
return asERROR;
}
int asCWriter::WriteData(const void *data, asUINT size)
{
asASSERT(size == 1 || size == 2 || size == 4 || size == 8);
int ret = 0;
#if defined(AS_BIG_ENDIAN)
for( asUINT n = 0; ret >= 0 && n < size; n++ )
ret = stream->Write(((asBYTE*)data)+n, 1);
#else
for( int n = size-1; ret >= 0 && n >= 0; n-- )
ret = stream->Write(((asBYTE*)data)+n, 1);
#endif
if (ret < 0)
Error(TXT_UNEXPECTED_END_OF_FILE);
bytesWritten += size;
return ret;
}
int asCWriter::Write()
{
TimeIt("asCWriter::Write");
unsigned long i, count;
// Store everything in the same order that the builder parses scripts
// TODO: Should be possible to skip saving the enum values. They are usually not needed after the script is compiled anyway
// TODO: Should be possible to skip saving the typedefs. They are usually not needed after the script is compiled anyway
// TODO: Should be possible to skip saving constants. They are usually not needed after the script is compiled anyway
// Write the flag as 1byte even on platforms with 4byte booleans
WriteEncodedInt64(stripDebugInfo ? 1 : 0);
// Store enums
{
TimeIt("store enums");
count = (asUINT)module->m_enumTypes.GetLength();
WriteEncodedInt64(count);
for( i = 0; i < count; i++ )
{
WriteTypeDeclaration(module->m_enumTypes[i], 1);
WriteTypeDeclaration(module->m_enumTypes[i], 2);
}
}
// Store type declarations first
{
TimeIt("type declarations");
count = (asUINT)module->m_classTypes.GetLength();
WriteEncodedInt64(count);
for( i = 0; i < count; i++ )
{
// Store only the name of the class/interface types
WriteTypeDeclaration(module->m_classTypes[i], 1);
}
}
// Store func defs
{
TimeIt("func defs");
count = (asUINT)module->m_funcDefs.GetLength();
WriteEncodedInt64(count);
for( i = 0; i < count; i++ )
WriteFunction(module->m_funcDefs[i]->funcdef);
}
// Now store all interface methods
{
TimeIt("interface methods");
count = (asUINT)module->m_classTypes.GetLength();
for( i = 0; i < count; i++ )
{
if( module->m_classTypes[i]->IsInterface() )
WriteTypeDeclaration(module->m_classTypes[i], 2);
}
}
// Then store the class methods and behaviours
{
TimeIt("class methods and behaviours");
for( i = 0; i < count; ++i )
{
if( !module->m_classTypes[i]->IsInterface() )
WriteTypeDeclaration(module->m_classTypes[i], 2);
}
}
// Then store the class properties
{
TimeIt("class properties");
for( i = 0; i < count; ++i )
{
if( !module->m_classTypes[i]->IsInterface() )
WriteTypeDeclaration(module->m_classTypes[i], 3);
}
}
// Store typedefs
{
TimeIt("type defs");
count = (asUINT)module->m_typeDefs.GetLength();
WriteEncodedInt64(count);
for( i = 0; i < count; i++ )
{
WriteTypeDeclaration(module->m_typeDefs[i], 1);
WriteTypeDeclaration(module->m_typeDefs[i], 2);
}
}
// scriptGlobals[]
{
TimeIt("script globals");
count = (asUINT)module->m_scriptGlobals.GetSize();
WriteEncodedInt64(count);
asCSymbolTable<asCGlobalProperty>::iterator it = module->m_scriptGlobals.List();
for( ; it; it++ )
WriteGlobalProperty(*it);
}
// scriptFunctions[]
{
TimeIt("scriptFunctions");
count = 0;
for( i = 0; i < module->m_scriptFunctions.GetLength(); i++ )
if( module->m_scriptFunctions[i]->objectType == 0 )
count++;
WriteEncodedInt64(count);
for( i = 0; i < module->m_scriptFunctions.GetLength(); ++i )
if( module->m_scriptFunctions[i]->objectType == 0 )
WriteFunction(module->m_scriptFunctions[i]);
}
// globalFunctions[]
{
TimeIt("globalFunctions");
count = (int)module->m_globalFunctions.GetSize();
asCSymbolTable<asCScriptFunction>::iterator funcIt = module->m_globalFunctions.List();
WriteEncodedInt64(count);
while( funcIt )
{
WriteFunction(*funcIt);
funcIt++;
}
}
// bindInformations[]
{
TimeIt("bindInformations");
count = (asUINT)module->m_bindInformations.GetLength();
WriteEncodedInt64(count);
for( i = 0; i < count; ++i )
{
WriteFunction(module->m_bindInformations[i]->importedFunctionSignature);
WriteString(&module->m_bindInformations[i]->importFromModule);
}
}
// usedTypes[]
{
TimeIt("usedTypes");
count = (asUINT)usedTypes.GetLength();
WriteEncodedInt64(count);
for( i = 0; i < count; ++i )
WriteTypeInfo(usedTypes[i]);
}
// usedTypeIds[]
WriteUsedTypeIds();
// usedFunctions[]
WriteUsedFunctions();
// usedGlobalProperties[]
WriteUsedGlobalProps();
// usedStringConstants[]
WriteUsedStringConstants();
// usedObjectProperties[]
WriteUsedObjectProps();
return error ? asERROR : asSUCCESS;
}
int asCWriter::FindStringConstantIndex(void *str)
{
asSMapNode<void*, int> *cursor = 0;
if (stringToIndexMap.MoveTo(&cursor, str))
return cursor->value;
usedStringConstants.PushLast(str);
int index = int(usedStringConstants.GetLength() - 1);
stringToIndexMap.Insert(str, index);
return index;
}
void asCWriter::WriteUsedStringConstants()
{
TimeIt("asCWriter::WriteUsedStringConstants");
asUINT count = (asUINT)usedStringConstants.GetLength();
WriteEncodedInt64(count);
asCString str;
for (asUINT i = 0; i < count; ++i)
{
asUINT length;
engine->stringFactory->GetRawStringData(usedStringConstants[i], 0, &length);
str.SetLength(length);
engine->stringFactory->GetRawStringData(usedStringConstants[i], str.AddressOf(), &length);
WriteString(&str);
}
}
void asCWriter::WriteUsedFunctions()
{
TimeIt("asCWriter::WriteUsedFunctions");
asUINT count = (asUINT)usedFunctions.GetLength();
WriteEncodedInt64(count);
for( asUINT n = 0; n < usedFunctions.GetLength(); n++ )
{
char c;
// Write enough data to be able to uniquely identify the function upon load
asCScriptFunction *func = usedFunctions[n];
if(func)
{
// Is the function from the module or the application?
c = func->module ? 'm' : 'a';
// Functions and methods that are shared should be stored as 's' as the bytecode
// may be imported from other modules (even if the current module have received ownership)
if (c == 'm' && func->IsShared() )
c = 's';
WriteData(&c, 1);
WriteFunctionSignature(func);
}
else
{
// null function pointer
c = 'n';
WriteData(&c, 1);
}
}
}
void asCWriter::WriteFunctionSignature(asCScriptFunction *func)
{
asUINT i, count;
WriteString(&func->name);
if( func->name == DELEGATE_FACTORY )
{
// It's not necessary to write anything else
return;
}
WriteDataType(&func->returnType);
count = (asUINT)func->parameterTypes.GetLength();
WriteEncodedInt64(count);
for( i = 0; i < count; ++i )
WriteDataType(&func->parameterTypes[i]);
// Only write the inout flags if any of them are set
// If the number of parameters is 0, then no need to save this
if (func->parameterTypes.GetLength() > 0)
{
count = 0;
for (i = asUINT(func->inOutFlags.GetLength()); i > 0; i--)
if (func->inOutFlags[i - 1] != asTM_NONE)
{
count = i;
break;
}
WriteEncodedInt64(count);
for (i = 0; i < count; ++i)
WriteEncodedInt64(func->inOutFlags[i]);
}
WriteEncodedInt64(func->funcType);
// Write the default args, from last to first
// If the number of parameters is 0, then no need to save this
if (func->parameterTypes.GetLength() > 0)
{
count = 0;
for (i = (asUINT)func->defaultArgs.GetLength(); i-- > 0; )
if (func->defaultArgs[i])
count++;
WriteEncodedInt64(count);
for (i = (asUINT)func->defaultArgs.GetLength(); i-- > 0; )
if (func->defaultArgs[i])
WriteString(func->defaultArgs[i]);
}
WriteTypeInfo(func->objectType);
if( func->objectType )
{
asBYTE b = 0;
b += func->IsReadOnly() ? 1 : 0;
b += func->IsPrivate() ? 2 : 0;
b += func->IsProtected() ? 4 : 0;
WriteData(&b, 1);
}
else
{
if (func->funcType == asFUNC_FUNCDEF)
{
if (func->nameSpace)
{
// This funcdef was declared as global entity
asBYTE b = 'n';
WriteData(&b, 1);
WriteString(&func->nameSpace->name);
}
else
{
// This funcdef was declared as class member
asBYTE b = 'o';
WriteData(&b, 1);
WriteTypeInfo(func->funcdefType->parentClass);
}
}
else
WriteString(&func->nameSpace->name);
}
}
void asCWriter::WriteFunction(asCScriptFunction* func)
{
char c;
// If there is no function, then store a null char
if( func == 0 )
{
c = '\0';
WriteData(&c, 1);
return;
}
// First check if the function has been saved already
for( asUINT f = 0; f < savedFunctions.GetLength(); f++ )
{
if( savedFunctions[f] == func )
{
c = 'r';
WriteData(&c, 1);
WriteEncodedInt64(f);
return;
}
}
// Keep a reference to the function in the list
savedFunctions.PushLast(func);
c = 'f';
WriteData(&c, 1);
asUINT i, count;
WriteFunctionSignature(func);
if( func->funcType == asFUNC_SCRIPT )
{
// Skip this for external shared entities
if (module->m_externalTypes.IndexOf(func->objectType) >= 0)
return;
char bits = 0;
bits += func->IsShared() ? 1 : 0;
bits += func->dontCleanUpOnException ? 2 : 0;
if (module->m_externalFunctions.IndexOf(func) >= 0)
bits += 4;
if (func->scriptData->objVariablePos.GetLength() || func->scriptData->objVariableInfo.GetLength())
bits += 8;
if (func->scriptData->tryCatchInfo.GetLength())
bits += 16;
bits += func->IsExplicit() ? 32 : 0;
WriteData(&bits, 1);
// For external shared functions the rest is not needed
if (bits & 4)
return;
// Calculate the adjustment by position lookup table
CalculateAdjustmentByPos(func);
WriteByteCode(func);
asDWORD varSpace = AdjustStackPosition(func->scriptData->variableSpace);
WriteEncodedInt64(varSpace);
if (bits & 8)
{
count = (asUINT)func->scriptData->objVariablePos.GetLength();
WriteEncodedInt64(count);
for (i = 0; i < count; ++i)
{
WriteTypeInfo(func->scriptData->objVariableTypes[i]);
WriteEncodedInt64(AdjustStackPosition(func->scriptData->objVariablePos[i]));
}
if (count > 0)
WriteEncodedInt64(func->scriptData->objVariablesOnHeap);
WriteEncodedInt64((asUINT)func->scriptData->objVariableInfo.GetLength());
for (i = 0; i < func->scriptData->objVariableInfo.GetLength(); ++i)
{
// The program position must be adjusted to be in number of instructions
WriteEncodedInt64(bytecodeNbrByPos[func->scriptData->objVariableInfo[i].programPos]);
WriteEncodedInt64(AdjustStackPosition(func->scriptData->objVariableInfo[i].variableOffset));
WriteEncodedInt64(func->scriptData->objVariableInfo[i].option);
}
}
if (bits & 16)
{
// Write info on try/catch blocks
WriteEncodedInt64((asUINT)func->scriptData->tryCatchInfo.GetLength());
for (i = 0; i < func->scriptData->tryCatchInfo.GetLength(); ++i)
{
// The program position must be adjusted to be in number of instructions
WriteEncodedInt64(bytecodeNbrByPos[func->scriptData->tryCatchInfo[i].tryPos]);
WriteEncodedInt64(bytecodeNbrByPos[func->scriptData->tryCatchInfo[i].catchPos]);
}
}
// The program position (every even number) needs to be adjusted
// to be in number of instructions instead of DWORD offset
if( !stripDebugInfo )
{
asUINT length = (asUINT)func->scriptData->lineNumbers.GetLength();
WriteEncodedInt64(length);
for( i = 0; i < length; ++i )
{
if( (i & 1) == 0 )
WriteEncodedInt64(bytecodeNbrByPos[func->scriptData->lineNumbers[i]]);
else
WriteEncodedInt64(func->scriptData->lineNumbers[i]);
}
// Write the array of script sections
length = (asUINT)func->scriptData->sectionIdxs.GetLength();
WriteEncodedInt64(length);
for( i = 0; i < length; ++i )
{
if( (i & 1) == 0 )
WriteEncodedInt64(bytecodeNbrByPos[func->scriptData->sectionIdxs[i]]);
else
{
if( func->scriptData->sectionIdxs[i] >= 0 )
WriteString(engine->scriptSectionNames[func->scriptData->sectionIdxs[i]]);
else
{
c = 0;
WriteData(&c, 1);
}
}
}
}
// Write the variable information
if( !stripDebugInfo )
{
WriteEncodedInt64((asUINT)func->scriptData->variables.GetLength());
for( i = 0; i < func->scriptData->variables.GetLength(); i++ )
{
// The program position must be adjusted to be in number of instructions
WriteEncodedInt64(bytecodeNbrByPos[func->scriptData->variables[i]->declaredAtProgramPos]);
// The stack position must be adjusted according to the pointer sizes
WriteEncodedInt64(AdjustStackPosition(func->scriptData->variables[i]->stackOffset));
WriteString(&func->scriptData->variables[i]->name);
WriteDataType(&func->scriptData->variables[i]->type);
}
}
// Store script section name
if( !stripDebugInfo )
{
if( func->scriptData->scriptSectionIdx >= 0 )
WriteString(engine->scriptSectionNames[func->scriptData->scriptSectionIdx]);
else
{
c = 0;
WriteData(&c, 1);
}
WriteEncodedInt64(func->scriptData->declaredAt);
}
// Store the parameter names
if( !stripDebugInfo )
{
count = asUINT(func->parameterNames.GetLength());
WriteEncodedInt64(count);
for( asUINT n = 0; n < count; n++ )
WriteString(&func->parameterNames[n]);
}
}
else if( func->funcType == asFUNC_VIRTUAL || func->funcType == asFUNC_INTERFACE )
{
// TODO: Do we really need to store this? It can probably be reconstructed by the reader
WriteEncodedInt64(func->vfTableIdx);
}
else if( func->funcType == asFUNC_FUNCDEF )
{
char bits = 0;
bits += func->IsShared() ? 1 : 0;
if (module->m_externalTypes.IndexOf(func->funcdefType) >= 0)
bits += 2;
WriteData(&bits,1);
}
}
void asCWriter::WriteTypeDeclaration(asCTypeInfo *type, int phase)
{
if( phase == 1 )
{
// name
WriteString(&type->name);
// flags
WriteData(&type->flags, 4);
// size
// TODO: Do we really need to store this? The reader should be able to
// determine the correct size from the object type's flags
if( (type->flags & asOBJ_SCRIPT_OBJECT) && type->size > 0 )
{
// The size for script objects may vary from platform to platform so
// only store 1 to diferentiate from interfaces that have size 0.
WriteEncodedInt64(1);
}
else
{
// Enums, typedefs, and interfaces have fixed sizes independently
// of platform so it is safe to serialize the size directly.
WriteEncodedInt64(type->size);
}
// namespace
WriteString(&type->nameSpace->name);
// external shared flag
if ((type->flags & asOBJ_SHARED))
{
char c = ' ';
if (module->m_externalTypes.IndexOf(type) >= 0)
c = 'e';
WriteData(&c, 1);
}
}
else if( phase == 2 )
{
// external shared types doesn't need to save this
if ((type->flags & asOBJ_SHARED) && module->m_externalTypes.IndexOf(type) >= 0)
return;
if(type->flags & asOBJ_ENUM )
{
// enumValues[]
asCEnumType *t = CastToEnumType(type);
int size = (int)t->enumValues.GetLength();
WriteEncodedInt64(size);
for( int n = 0; n < size; n++ )
{
WriteString(&t->enumValues[n]->name);
WriteData(&t->enumValues[n]->value, 4);
}
}
else if(type->flags & asOBJ_TYPEDEF )
{
asCTypedefType *td = CastToTypedefType(type);
eTokenType t = td->aliasForType.GetTokenType();
WriteEncodedInt64(t);
}
else
{
asCObjectType *t = CastToObjectType(type);
WriteTypeInfo(t->derivedFrom);
// interfaces[] / interfaceVFTOffsets[]
// TOOD: Is it really necessary to store the VFTOffsets? Can't the reader calculate those?
int size = (asUINT)t->interfaces.GetLength();
WriteEncodedInt64(size);
asUINT n;
asASSERT( t->IsInterface() || t->interfaces.GetLength() == t->interfaceVFTOffsets.GetLength() );
for( n = 0; n < t->interfaces.GetLength(); n++ )
{
WriteTypeInfo(t->interfaces[n]);
if( !t->IsInterface() )
WriteEncodedInt64(t->interfaceVFTOffsets[n]);
}
// behaviours
// TODO: Default behaviours should just be stored as a indicator
// to avoid storing the actual function object
if( !t->IsInterface() && type->flags != asOBJ_TYPEDEF && type->flags != asOBJ_ENUM )
{
WriteFunction(engine->scriptFunctions[t->beh.destruct]);
size = (int)t->beh.constructors.GetLength();
WriteEncodedInt64(size);
for( n = 0; n < t->beh.constructors.GetLength(); n++ )
{
WriteFunction(engine->scriptFunctions[t->beh.constructors[n]]);
WriteFunction(engine->scriptFunctions[t->beh.factories[n]]);
}
}
// methods[]
// TODO: Avoid storing inherited methods in interfaces, as the reader
// can add those directly from the base interface
size = (int)t->methods.GetLength();
WriteEncodedInt64(size);
for( n = 0; n < t->methods.GetLength(); n++ )
{
WriteFunction(engine->scriptFunctions[t->methods[n]]);
}
// virtualFunctionTable[]
// TODO: Is it really necessary to store this? Can't it be easily rebuilt by the reader
size = (int)t->virtualFunctionTable.GetLength();
WriteEncodedInt64(size);
for( n = 0; n < (asUINT)size; n++ )
{
WriteFunction(t->virtualFunctionTable[n]);
}
}
}
else if( phase == 3 )
{
// external shared types doesn't need to save this
if ((type->flags & asOBJ_SHARED) && module->m_externalTypes.IndexOf(type) >= 0)
return;
// properties[]
asCObjectType *t = CastToObjectType(type);
// This is only done for object types
asASSERT(t);
asUINT size = (asUINT)t->properties.GetLength();
WriteEncodedInt64(size);
for (asUINT n = 0; n < t->properties.GetLength(); n++)
{
WriteObjectProperty(t->properties[n]);
}
}
}
void asCWriter::WriteEncodedInt64(asINT64 i)
{
asBYTE signBit = ( i & asINT64(1)<<63 ) ? 0x80 : 0;
if( signBit ) i = -i;
asBYTE b;
if( i < (1<<6) )
{
b = (asBYTE)(signBit + i); WriteData(&b, 1);
}
else if( i < (1<<13) )
{
b = asBYTE(0x40 + signBit + (i >> 8)); WriteData(&b, 1);
b = asBYTE(i & 0xFF); WriteData(&b, 1);
}
else if( i < (1<<20) )
{
b = asBYTE(0x60 + signBit + (i >> 16)); WriteData(&b, 1);
b = asBYTE((i >> 8) & 0xFF); WriteData(&b, 1);
b = asBYTE(i & 0xFF); WriteData(&b, 1);
}
else if( i < (1<<27) )
{
b = asBYTE(0x70 + signBit + (i >> 24)); WriteData(&b, 1);
b = asBYTE((i >> 16) & 0xFF); WriteData(&b, 1);
b = asBYTE((i >> 8) & 0xFF); WriteData(&b, 1);
b = asBYTE(i & 0xFF); WriteData(&b, 1);
}
else if( i < (asINT64(1)<<34) )
{
b = asBYTE(0x78 + signBit + (i >> 32)); WriteData(&b, 1);
b = asBYTE((i >> 24) & 0xFF); WriteData(&b, 1);
b = asBYTE((i >> 16) & 0xFF); WriteData(&b, 1);
b = asBYTE((i >> 8) & 0xFF); WriteData(&b, 1);
b = asBYTE(i & 0xFF); WriteData(&b, 1);
}
else if( i < (asINT64(1)<<41) )
{
b = asBYTE(0x7C + signBit + (i >> 40)); WriteData(&b, 1);
b = asBYTE((i >> 32) & 0xFF); WriteData(&b, 1);
b = asBYTE((i >> 24) & 0xFF); WriteData(&b, 1);
b = asBYTE((i >> 16) & 0xFF); WriteData(&b, 1);
b = asBYTE((i >> 8) & 0xFF); WriteData(&b, 1);
b = asBYTE(i & 0xFF); WriteData(&b, 1);
}
else if( i < (asINT64(1)<<48) )
{
b = asBYTE(0x7E + signBit + (i >> 48)); WriteData(&b, 1);
b = asBYTE((i >> 40) & 0xFF); WriteData(&b, 1);
b = asBYTE((i >> 32) & 0xFF); WriteData(&b, 1);
b = asBYTE((i >> 24) & 0xFF); WriteData(&b, 1);
b = asBYTE((i >> 16) & 0xFF); WriteData(&b, 1);
b = asBYTE((i >> 8) & 0xFF); WriteData(&b, 1);
b = asBYTE(i & 0xFF); WriteData(&b, 1);
}
else
{
b = asBYTE(0x7F + signBit); WriteData(&b, 1);
b = asBYTE((i >> 56) & 0xFF); WriteData(&b, 1);
b = asBYTE((i >> 48) & 0xFF); WriteData(&b, 1);
b = asBYTE((i >> 40) & 0xFF); WriteData(&b, 1);
b = asBYTE((i >> 32) & 0xFF); WriteData(&b, 1);
b = asBYTE((i >> 24) & 0xFF); WriteData(&b, 1);
b = asBYTE((i >> 16) & 0xFF); WriteData(&b, 1);
b = asBYTE((i >> 8) & 0xFF); WriteData(&b, 1);
b = asBYTE(i & 0xFF); WriteData(&b, 1);
}
}
void asCWriter::WriteString(asCString* str)
{
// First check if the string hasn't been saved already
asSMapNode<asCString, int> *cursor = 0;
if (stringToIdMap.MoveTo(&cursor, *str))
{
// Save a reference to the existing string
// The lowest bit is set to 1 to indicate a reference
WriteEncodedInt64(cursor->value*2+1);
return;
}
// Save a new string
// The lowest bit is set to 0 to indicate a new string
asUINT len = (asUINT)str->GetLength();
WriteEncodedInt64(len*2);
if( len > 0 )
{
stream->Write(str->AddressOf(), (asUINT)len);
bytesWritten += len;
savedStrings.PushLast(*str);
stringToIdMap.Insert(*str, int(savedStrings.GetLength()) - 1);
}
}
void asCWriter::WriteGlobalProperty(asCGlobalProperty* prop)
{
// TODO: We might be able to avoid storing the name and type of the global
// properties twice if we merge this with the WriteUsedGlobalProperties.
WriteString(&prop->name);
WriteString(&prop->nameSpace->name);
WriteDataType(&prop->type);
// Store the initialization function
WriteFunction(prop->GetInitFunc());
}
void asCWriter::WriteObjectProperty(asCObjectProperty* prop)
{
WriteString(&prop->name);
WriteDataType(&prop->type);
int flags = 0;
if( prop->isPrivate ) flags |= 1;
if( prop->isProtected ) flags |= 2;
if( prop->isInherited ) flags |= 4;
WriteEncodedInt64(flags);
}
void asCWriter::WriteDataType(const asCDataType *dt)
{
// First check if the datatype has already been saved
for( asUINT n = 0; n < savedDataTypes.GetLength(); n++ )
{
if( *dt == savedDataTypes[n] )
{
WriteEncodedInt64(n+1);
return;
}
}
// Indicate a new type with a null byte
asUINT c = 0;
WriteEncodedInt64(c);
// Save the new datatype
savedDataTypes.PushLast(*dt);
int t = dt->GetTokenType();
WriteEncodedInt64(t);
if( t == ttIdentifier )
WriteTypeInfo(dt->GetTypeInfo());
// Endianess safe bitmask
char bits = 0;
SAVE_TO_BIT(bits, dt->IsObjectHandle(), 0);
SAVE_TO_BIT(bits, dt->IsHandleToConst(), 1);
SAVE_TO_BIT(bits, dt->IsReference(), 2);
SAVE_TO_BIT(bits, dt->IsReadOnly(), 3);
WriteData(&bits, 1);
}
void asCWriter::WriteTypeInfo(asCTypeInfo* ti)
{
char ch;
if( ti )
{
// Check for template instances/specializations
asCObjectType *ot = CastToObjectType(ti);
if( ot && ot->templateSubTypes.GetLength() )
{
// Check for list pattern type or template type
if( ot->flags & asOBJ_LIST_PATTERN )
{
ch = 'l'; // list
WriteData(&ch, 1);
WriteTypeInfo(ot->templateSubTypes[0].GetTypeInfo());
}
else
{
ch = 'a'; // array
WriteData(&ch, 1);
WriteString(&ot->name);
WriteString(&ot->nameSpace->name);
WriteEncodedInt64(ot->templateSubTypes.GetLength());
for( asUINT n = 0; n < ot->templateSubTypes.GetLength(); n++ )
{
if( !ot->templateSubTypes[n].IsPrimitive() || ot->templateSubTypes[n].IsEnumType() )
{
ch = 's'; // sub type
WriteData(&ch, 1);
WriteDataType(&ot->templateSubTypes[n]);
}
else
{
ch = 't'; // token
WriteData(&ch, 1);
eTokenType t = ot->templateSubTypes[n].GetTokenType();
WriteEncodedInt64(t);
}
}
}
}
else if( ti->flags & asOBJ_TEMPLATE_SUBTYPE )
{
ch = 's'; // sub type
WriteData(&ch, 1);
WriteString(&ti->name);
}
else if( !ti->GetParentType() )
{
ch = 'o'; // object
WriteData(&ch, 1);
WriteString(&ti->name);
WriteString(&ti->nameSpace->name);
}
else
{
asASSERT(ti->flags & asOBJ_FUNCDEF);
ch = 'c'; // child type
WriteData(&ch, 1);
WriteString(&ti->name);
WriteTypeInfo(CastToFuncdefType(ti)->parentClass);
}
}
else
{
ch = '\0';
WriteData(&ch, 1);
}
}
void asCWriter::CalculateAdjustmentByPos(asCScriptFunction *func)
{
// Adjust the offset of all negative variables (parameters) so all pointers will have a size of 1 dword
asUINT n;
asCArray<int> adjustments;
asUINT offset = 0;
if( func->objectType )
{
adjustments.PushLast(offset);
adjustments.PushLast(1-AS_PTR_SIZE);
offset += AS_PTR_SIZE;
}
if( func->DoesReturnOnStack() )
{
adjustments.PushLast(offset);
adjustments.PushLast(1-AS_PTR_SIZE);
offset += AS_PTR_SIZE;
}
for( n = 0; n < func->parameterTypes.GetLength(); n++ )
{
if( !func->parameterTypes[n].IsPrimitive() ||
func->parameterTypes[n].IsReference() )
{
adjustments.PushLast(offset);
adjustments.PushLast(1-AS_PTR_SIZE);
offset += AS_PTR_SIZE;
}
else
{
asASSERT( func->parameterTypes[n].IsPrimitive() );
offset += func->parameterTypes[n].GetSizeOnStackDWords();
}
}
// Build look-up table with the adjustments for each stack position
adjustNegativeStackByPos.SetLength(offset);
memset(adjustNegativeStackByPos.AddressOf(), 0, adjustNegativeStackByPos.GetLength()*sizeof(int));
for( n = 0; n < adjustments.GetLength(); n+=2 )
{
int pos = adjustments[n];
int adjust = adjustments[n+1];
for( asUINT i = pos+1; i < adjustNegativeStackByPos.GetLength(); i++ )
adjustNegativeStackByPos[i] += adjust;
}
// Adjust the offset of all positive variables so that all object types and handles have a size of 1 dword
// This is similar to how the adjustment is done in the asCReader::TranslateFunction, only the reverse
adjustments.SetLength(0);
for( n = 0; n < func->scriptData->objVariableTypes.GetLength(); n++ )
{
// Determine the size the variable currently occupies on the stack
int size = AS_PTR_SIZE;
// objVariableTypes is null if the variable type is a null pointer
if( func->scriptData->objVariableTypes[n] &&
(func->scriptData->objVariableTypes[n]->GetFlags() & asOBJ_VALUE) &&
n >= func->scriptData->objVariablesOnHeap )
{
size = func->scriptData->objVariableTypes[n]->GetSize();
if( size < 4 )
size = 1;
else
size /= 4;
}
// If larger than 1 dword, adjust the offsets accordingly
if (size > 1)
{
// How much needs to be adjusted?
adjustments.PushLast(func->scriptData->objVariablePos[n]);
adjustments.PushLast(-(size - 1));
}
}
// Build look-up table with the adjustments for each stack position
adjustStackByPos.SetLength(func->scriptData->stackNeeded);
memset(adjustStackByPos.AddressOf(), 0, adjustStackByPos.GetLength()*sizeof(int));
for( n = 0; n < adjustments.GetLength(); n+=2 )
{
int pos = adjustments[n];
int adjust = adjustments[n+1];
for( asUINT i = pos; i < adjustStackByPos.GetLength(); i++ )
adjustStackByPos[i] += adjust;
}
// Compute the sequence number of each bytecode instruction in order to update the jump offsets
asUINT length = func->scriptData->byteCode.GetLength();
asDWORD *bc = func->scriptData->byteCode.AddressOf();
bytecodeNbrByPos.SetLength(length);
asUINT num;
for( offset = 0, num = 0; offset < length; )
{
bytecodeNbrByPos[offset] = num;
offset += asBCTypeSize[asBCInfo[*(asBYTE*)(bc+offset)].type];
num++;
}
// Store the number of instructions in the last position of bytecodeNbrByPos,
// so this can be easily queried in SaveBytecode. Normally this is already done
// as most functions end with BC_RET, but in some cases the last instruction in
// the function is not a BC_RET, e.g. when a function has a never ending loop.
bytecodeNbrByPos[length - 1] = num - 1;
}
int asCWriter::AdjustStackPosition(int pos)
{
if( pos >= (int)adjustStackByPos.GetLength() )
{
// This happens for example if the function only have temporary variables
// The adjustByPos can also be empty if the function doesn't have any variables at all, but receive a handle by parameter
if( adjustStackByPos.GetLength() > 0 )
pos += adjustStackByPos[adjustStackByPos.GetLength()-1];
}
else if( pos >= 0 )
pos += adjustStackByPos[pos];
else
{
asASSERT( -pos < (int)adjustNegativeStackByPos.GetLength() );
pos -= (short)adjustNegativeStackByPos[-pos];
}
return pos;
}
int asCWriter::AdjustGetOffset(int offset, asCScriptFunction *func, asDWORD programPos)
{
// TODO: optimize: multiple instructions for the same function doesn't need to look for the function everytime
// the function can remember where it found the function and check if the programPos is still valid
// Get offset 0 doesn't need adjustment
if( offset == 0 ) return 0;
bool bcAlloc = false;
// Find out which function that will be called
asCScriptFunction *calledFunc = 0;
int stackDelta = 0;
for( asUINT n = programPos; n < func->scriptData->byteCode.GetLength(); )
{
asBYTE bc = *(asBYTE*)&func->scriptData->byteCode[n];
if( bc == asBC_CALL ||
bc == asBC_CALLSYS ||
bc == asBC_Thiscall1 ||
bc == asBC_CALLINTF )
{
// Find the function from the function id in bytecode
int funcId = asBC_INTARG(&func->scriptData->byteCode[n]);
calledFunc = engine->scriptFunctions[funcId];
break;
}
else if( bc == asBC_ALLOC )
{
// The alloc instruction doesn't take the object pointer on the stack,
// as the memory will be allocated by the instruction itself
bcAlloc = true;
// Find the function from the function id in the bytecode
int funcId = asBC_INTARG(&func->scriptData->byteCode[n+AS_PTR_SIZE]);
calledFunc = engine->scriptFunctions[funcId];
break;
}
else if( bc == asBC_CALLBND )
{
// Find the function from the engine's bind array
int funcId = asBC_INTARG(&func->scriptData->byteCode[n]);
calledFunc = engine->importedFunctions[funcId & ~FUNC_IMPORTED]->importedFunctionSignature;
break;
}
else if( bc == asBC_CallPtr )
{
int var = asBC_SWORDARG0(&func->scriptData->byteCode[n]);
asUINT v;
// Find the funcdef from the local variable
for( v = 0; v < func->scriptData->objVariablePos.GetLength(); v++ )
{
if( func->scriptData->objVariablePos[v] == var )
{
calledFunc = CastToFuncdefType(func->scriptData->objVariableTypes[v])->funcdef;
break;
}
}
if( !calledFunc )
{
// Look in parameters
int paramPos = 0;
if( func->objectType )
paramPos -= AS_PTR_SIZE;
if( func->DoesReturnOnStack() )
paramPos -= AS_PTR_SIZE;
for( v = 0; v < func->parameterTypes.GetLength(); v++ )
{
if( var == paramPos )
{
calledFunc = CastToFuncdefType(func->parameterTypes[v].GetTypeInfo())->funcdef;
break;
}
paramPos -= func->parameterTypes[v].GetSizeOnStackDWords();
}
}
break;
}
else if( bc == asBC_REFCPY ||
bc == asBC_COPY )
{
// In this case we know there is only 1 pointer on the stack above
asASSERT( offset == AS_PTR_SIZE );
return offset + (1 - AS_PTR_SIZE);
}
// Keep track of the stack size between the
// instruction that needs to be adjusted and the call
stackDelta += asBCInfo[bc].stackInc;
n += asBCTypeSize[asBCInfo[bc].type];
}
asASSERT( calledFunc );
// Count the number of pointers pushed on the stack above the
// current offset, and then adjust the offset accordingly
asUINT numPtrs = 0;
int currOffset = -stackDelta;
if( offset > currOffset && calledFunc->GetObjectType() && !bcAlloc )
{
currOffset += AS_PTR_SIZE;
if( currOffset > 0 )
numPtrs++;
}
if( offset > currOffset && calledFunc->DoesReturnOnStack() )
{
currOffset += AS_PTR_SIZE;
if( currOffset > 0 )
numPtrs++;
}
for( asUINT p = 0; p < calledFunc->parameterTypes.GetLength(); p++ )
{
if( offset <= currOffset ) break;
if( !calledFunc->parameterTypes[p].IsPrimitive() ||
calledFunc->parameterTypes[p].IsReference() )
{
// objects and references are passed by pointer
currOffset += AS_PTR_SIZE;
if( currOffset > 0 )
numPtrs++;
// The variable arg ? has an additional 32bit int with the typeid
if( calledFunc->parameterTypes[p].IsAnyType() )
currOffset += 1;
}
else
{
// built-in primitives or enums are passed by value
asASSERT( calledFunc->parameterTypes[p].IsPrimitive() );
currOffset += calledFunc->parameterTypes[p].GetSizeOnStackDWords();
}
}
// The get offset must match one of the parameter offsets
asASSERT( offset == currOffset );
return offset + numPtrs * (1 - AS_PTR_SIZE);
}
void asCWriter::WriteByteCode(asCScriptFunction *func)
{
asDWORD *bc = func->scriptData->byteCode.AddressOf();
size_t length = func->scriptData->byteCode.GetLength();
// The length cannot be stored, because it is platform dependent,
// instead we store the number of instructions
asUINT count = bytecodeNbrByPos[bytecodeNbrByPos.GetLength()-1] + 1;
WriteEncodedInt64(count);
asDWORD *startBC = bc;
while( length )
{
asDWORD tmpBC[4]; // The biggest instructions take up 4 DWORDs
asDWORD c = *(asBYTE*)bc;
// Copy the instruction to a temp buffer so we can work on it before saving
memcpy(tmpBC, bc, asBCTypeSize[asBCInfo[c].type]*sizeof(asDWORD));
if( c == asBC_ALLOC ) // PTR_DW_ARG
{
// Translate the object type
asCObjectType *ot = *(asCObjectType**)(tmpBC+1);
*(asPWORD*)(tmpBC+1) = FindTypeInfoIdx(ot);
// Translate the constructor func id, unless it is 0
if( *(int*)&tmpBC[1+AS_PTR_SIZE] != 0 )
{
// Increment 1 to the translated function id, as 0 will be reserved for no function
*(int*)&tmpBC[1+AS_PTR_SIZE] = 1+FindFunctionIndex(engine->scriptFunctions[*(int*)&tmpBC[1+AS_PTR_SIZE]]);
}
}
else if( c == asBC_REFCPY || // PTR_ARG
c == asBC_RefCpyV || // wW_PTR_ARG
c == asBC_OBJTYPE ) // PTR_ARG
{
// Translate object type pointers into indices
*(asPWORD*)(tmpBC+1) = FindTypeInfoIdx(*(asCObjectType**)(tmpBC+1));
}
else if( c == asBC_JitEntry ) // PTR_ARG
{
// We don't store the JIT argument
*(asPWORD*)(tmpBC+1) = 0;
}
else if( c == asBC_TYPEID || // DW_ARG
c == asBC_Cast ) // DW_ARG
{
// Translate type ids into indices
*(int*)(tmpBC+1) = FindTypeIdIdx(*(int*)(tmpBC+1));
}
else if( c == asBC_ADDSi || // W_DW_ARG
c == asBC_LoadThisR ) // W_DW_ARG
{
// Translate property offsets into indices
*(((short*)tmpBC)+1) = (short)FindObjectPropIndex(*(((short*)tmpBC)+1), *(int*)(tmpBC+1), bc);
// Translate type ids into indices
*(int*)(tmpBC+1) = FindTypeIdIdx(*(int*)(tmpBC+1));
}
else if( c == asBC_LoadRObjR || // rW_W_DW_ARG
c == asBC_LoadVObjR ) // rW_W_DW_ARG
{
asCObjectType *ot = engine->GetObjectTypeFromTypeId(*(int*)(tmpBC+2));
if( ot->flags & asOBJ_LIST_PATTERN )
{
// List patterns have a different way of translating the offsets
SListAdjuster *listAdj = listAdjusters[listAdjusters.GetLength()-1];
*(((short*)tmpBC)+2) = (short)listAdj->AdjustOffset(*(((short*)tmpBC)+2), ot);
}
else
{
// Translate property offsets into indices
*(((short*)tmpBC)+2) = (short)FindObjectPropIndex(*(((short*)tmpBC)+2), *(int*)(tmpBC+2), bc);
}
// Translate type ids into indices
*(int*)(tmpBC+2) = FindTypeIdIdx(*(int*)(tmpBC+2));
}
else if( c == asBC_COPY ) // W_DW_ARG
{
// Translate type ids into indices
*(int*)(tmpBC+1) = FindTypeIdIdx(*(int*)(tmpBC+1));
// Update the WORDARG0 to 0, as this will be recalculated on the target platform
asBC_WORDARG0(tmpBC) = 0;
}
else if( c == asBC_RET ) // W_ARG
{
// Save with arg 0, as this will be recalculated on the target platform
asBC_WORDARG0(tmpBC) = 0;
}
else if( c == asBC_CALL || // DW_ARG
c == asBC_CALLINTF || // DW_ARG
c == asBC_CALLSYS || // DW_ARG
c == asBC_Thiscall1 ) // DW_ARG
{
// Translate the function id
*(int*)(tmpBC+1) = FindFunctionIndex(engine->scriptFunctions[*(int*)(tmpBC+1)]);
}
else if( c == asBC_FuncPtr ) // PTR_ARG
{
// Translate the function pointer
*(asPWORD*)(tmpBC+1) = FindFunctionIndex(*(asCScriptFunction**)(tmpBC+1));
}
else if( c == asBC_CALLBND ) // DW_ARG
{
// Translate the function id
int funcId = tmpBC[1];
for( asUINT n = 0; n < module->m_bindInformations.GetLength(); n++ )
if( module->m_bindInformations[n]->importedFunctionSignature->id == funcId )
{
funcId = n;
break;
}
tmpBC[1] = funcId;
}
else if( c == asBC_PGA || // PTR_ARG
c == asBC_PshGPtr || // PTR_ARG
c == asBC_LDG || // PTR_ARG
c == asBC_PshG4 || // PTR_ARG
c == asBC_LdGRdR4 || // wW_PTR_ARG
c == asBC_CpyGtoV4 || // wW_PTR_ARG
c == asBC_CpyVtoG4 || // rW_PTR_ARG
c == asBC_SetG4 ) // PTR_DW_ARG
{
// Check if the address is a global property or a string constant
void *ptr = *(void**)(tmpBC + 1);
if (engine->varAddressMap.MoveTo(0, ptr))
{
// Translate global variable pointers into indices
// Flag the first bit to signal global property
*(asPWORD*)(tmpBC + 1) = (FindGlobalPropPtrIndex(*(void**)(tmpBC + 1)) << 1) + 1;
}
else
{
// Only PGA and PshGPtr can hold string constants
asASSERT(c == asBC_PGA || c == asBC_PshGPtr);
// Translate string constants into indices
// Leave the first bit clear to signal string constant
*(asPWORD*)(tmpBC + 1) = FindStringConstantIndex(*(void**)(tmpBC + 1)) << 1;
}
}
else if( c == asBC_JMP || // DW_ARG
c == asBC_JZ ||
c == asBC_JNZ ||
c == asBC_JLowZ ||
c == asBC_JLowNZ ||
c == asBC_JS ||
c == asBC_JNS ||
c == asBC_JP ||
c == asBC_JNP ) // The JMPP instruction doesn't need modification
{
// Get the DWORD offset from arg
int offset = *(int*)(tmpBC+1);
// Determine instruction number for next instruction and destination
int bcSeqNum = bytecodeNbrByPos[asUINT(bc - startBC)] + 1;
asDWORD *targetBC = bc + 2 + offset;
int targetBcSeqNum = bytecodeNbrByPos[asUINT(targetBC - startBC)];
// Set the offset in number of instructions
*(int*)(tmpBC+1) = targetBcSeqNum - bcSeqNum;
}
else if( c == asBC_GETOBJ || // W_ARG
c == asBC_GETOBJREF ||
c == asBC_GETREF ||
c == asBC_ChkNullS )
{
// Adjust the offset according to the function call that comes after
asBC_WORDARG0(tmpBC) = (asWORD)AdjustGetOffset(asBC_WORDARG0(tmpBC), func, asDWORD(bc - startBC));
}
else if( c == asBC_AllocMem )
{
// It's not necessary to store the size of the list buffer, as it will be recalculated in the reader
asBC_DWORDARG(tmpBC) = 0;
// Determine the type of the list pattern from the variable
short var = asBC_WORDARG0(tmpBC);
asCObjectType *ot = CastToObjectType(func->GetTypeInfoOfLocalVar(var));
// Create this helper object to adjust the offset of the elements accessed in the buffer
listAdjusters.PushLast(asNEW(SListAdjuster)(ot));
}
else if( c == asBC_FREE ) // wW_PTR_ARG
{
// Translate object type pointers into indices
asCObjectType *ot = *(asCObjectType**)(tmpBC+1);
*(asPWORD*)(tmpBC+1) = FindTypeInfoIdx(ot);
// Pop and destroy the list adjuster helper that was created with asBC_AllocMem
if( ot && (ot->flags & asOBJ_LIST_PATTERN) )
{
SListAdjuster *list = listAdjusters.PopLast();
asDELETE(list, SListAdjuster);
}
}
else if( c == asBC_SetListSize )
{
// Adjust the offset in the initialization list
SListAdjuster *listAdj = listAdjusters[listAdjusters.GetLength()-1];
tmpBC[1] = listAdj->AdjustOffset(tmpBC[1], listAdj->patternType);
// Tell the adjuster how many repeated values there are
listAdj->SetRepeatCount(tmpBC[2]);
}
else if( c == asBC_PshListElmnt ) // W_DW_ARG
{
// Adjust the offset in the initialization list
SListAdjuster *listAdj = listAdjusters[listAdjusters.GetLength()-1];
tmpBC[1] = listAdj->AdjustOffset(tmpBC[1], listAdj->patternType);
}
else if( c == asBC_SetListType )
{
// Adjust the offset in the initialization list
SListAdjuster *listAdj = listAdjusters[listAdjusters.GetLength()-1];
tmpBC[1] = listAdj->AdjustOffset(tmpBC[1], listAdj->patternType);
// Inform the adjuster of the type id of the next element
listAdj->SetNextType(tmpBC[2]);
// Translate the type id
tmpBC[2] = FindTypeIdIdx(tmpBC[2]);
}
// Adjust the variable offsets
switch( asBCInfo[c].type )
{
case asBCTYPE_wW_ARG:
case asBCTYPE_rW_DW_ARG:
case asBCTYPE_wW_QW_ARG:
case asBCTYPE_rW_ARG:
case asBCTYPE_wW_DW_ARG:
case asBCTYPE_wW_W_ARG:
case asBCTYPE_rW_QW_ARG:
case asBCTYPE_rW_W_DW_ARG:
case asBCTYPE_rW_DW_DW_ARG:
{
asBC_SWORDARG0(tmpBC) = (short)AdjustStackPosition(asBC_SWORDARG0(tmpBC));
}
break;
case asBCTYPE_wW_rW_ARG:
case asBCTYPE_wW_rW_DW_ARG:
case asBCTYPE_rW_rW_ARG:
{
asBC_SWORDARG0(tmpBC) = (short)AdjustStackPosition(asBC_SWORDARG0(tmpBC));
asBC_SWORDARG1(tmpBC) = (short)AdjustStackPosition(asBC_SWORDARG1(tmpBC));
}
break;
case asBCTYPE_wW_rW_rW_ARG:
{
asBC_SWORDARG0(tmpBC) = (short)AdjustStackPosition(asBC_SWORDARG0(tmpBC));
asBC_SWORDARG1(tmpBC) = (short)AdjustStackPosition(asBC_SWORDARG1(tmpBC));
asBC_SWORDARG2(tmpBC) = (short)AdjustStackPosition(asBC_SWORDARG2(tmpBC));
}
break;
default:
// The other types don't treat variables so won't be modified
break;
}
// TODO: bytecode: Must make sure that floats and doubles are always stored the same way regardless of platform.
// Some platforms may not use the IEEE 754 standard, in which case it is necessary to encode the values
// Now store the instruction in the smallest possible way
switch( asBCInfo[c].type )
{
case asBCTYPE_NO_ARG:
{
// Just write 1 byte
asBYTE b = (asBYTE)c;
WriteData(&b, 1);
}
break;
case asBCTYPE_W_ARG:
case asBCTYPE_wW_ARG:
case asBCTYPE_rW_ARG:
{
// Write the instruction code
asBYTE b = (asBYTE)c;
WriteData(&b, 1);
// Write the argument
short w = *(((short*)tmpBC)+1);
WriteEncodedInt64(w);
}
break;
case asBCTYPE_rW_DW_ARG:
case asBCTYPE_wW_DW_ARG:
case asBCTYPE_W_DW_ARG:
{
// Write the instruction code
asBYTE b = (asBYTE)c;
WriteData(&b, 1);
// Write the word argument
short w = *(((short*)tmpBC)+1);
WriteEncodedInt64(w);
// Write the dword argument
WriteEncodedInt64((int)tmpBC[1]);
}
break;
case asBCTYPE_DW_ARG:
{
// Write the instruction code
asBYTE b = (asBYTE)c;
WriteData(&b, 1);
// Write the argument
WriteEncodedInt64((int)tmpBC[1]);
}
break;
case asBCTYPE_DW_DW_ARG:
{
// Write the instruction code
asBYTE b = (asBYTE)c;
WriteData(&b, 1);
// Write the dword argument
WriteEncodedInt64((int)tmpBC[1]);
// Write the dword argument
WriteEncodedInt64((int)tmpBC[2]);
}
break;
case asBCTYPE_wW_rW_rW_ARG:
{
// Write the instruction code
asBYTE b = (asBYTE)c;
WriteData(&b, 1);
// Write the first argument
short w = *(((short*)tmpBC)+1);
WriteEncodedInt64(w);
// Write the second argument
w = *(((short*)tmpBC)+2);
WriteEncodedInt64(w);
// Write the third argument
w = *(((short*)tmpBC)+3);
WriteEncodedInt64(w);
}
break;
case asBCTYPE_wW_rW_ARG:
case asBCTYPE_rW_rW_ARG:
case asBCTYPE_wW_W_ARG:
{
// Write the instruction code
asBYTE b = (asBYTE)c;
WriteData(&b, 1);
// Write the first argument
short w = *(((short*)tmpBC)+1);
WriteEncodedInt64(w);
// Write the second argument
w = *(((short*)tmpBC)+2);
WriteEncodedInt64(w);
}
break;
case asBCTYPE_wW_rW_DW_ARG:
case asBCTYPE_rW_W_DW_ARG:
{
// Write the instruction code
asBYTE b = (asBYTE)c;
WriteData(&b, 1);
// Write the first argument
short w = *(((short*)tmpBC)+1);
WriteEncodedInt64(w);
// Write the second argument
w = *(((short*)tmpBC)+2);
WriteEncodedInt64(w);
// Write the third argument
int dw = tmpBC[2];
WriteEncodedInt64(dw);
}
break;
case asBCTYPE_QW_ARG:
{
// Write the instruction code
asBYTE b = (asBYTE)c;
WriteData(&b, 1);
// Write the argument
asQWORD qw = *(asQWORD*)&tmpBC[1];
WriteEncodedInt64(qw);
}
break;
case asBCTYPE_QW_DW_ARG:
{
// Write the instruction code
asBYTE b = (asBYTE)c;
WriteData(&b, 1);
// Write the argument
asQWORD qw = *(asQWORD*)&tmpBC[1];
WriteEncodedInt64(qw);
// Write the second argument
int dw = tmpBC[3];
WriteEncodedInt64(dw);
}
break;
case asBCTYPE_rW_QW_ARG:
case asBCTYPE_wW_QW_ARG:
{
// Write the instruction code
asBYTE b = (asBYTE)c;
WriteData(&b, 1);
// Write the first argument
short w = *(((short*)tmpBC)+1);
WriteEncodedInt64(w);
// Write the argument
asQWORD qw = *(asQWORD*)&tmpBC[1];
WriteEncodedInt64(qw);
}
break;
case asBCTYPE_rW_DW_DW_ARG:
{
// Write the instruction code
asBYTE b = (asBYTE)c;
WriteData(&b, 1);
// Write the short argument
short w = *(((short*)tmpBC)+1);
WriteEncodedInt64(w);
// Write the dword argument
WriteEncodedInt64((int)tmpBC[1]);
// Write the dword argument
WriteEncodedInt64((int)tmpBC[2]);
}
break;
default:
{
// This should never happen
asASSERT(false);
// Store the bc as is
for( int n = 0; n < asBCTypeSize[asBCInfo[c].type]; n++ )
WriteData(&tmpBC[n], 4);
}
}
// Move to the next instruction
bc += asBCTypeSize[asBCInfo[c].type];
length -= asBCTypeSize[asBCInfo[c].type];
}
}
asCWriter::SListAdjuster::SListAdjuster(asCObjectType *ot) : patternType(ot), repeatCount(0), entries(0), lastOffset(-1), nextOffset(0), nextTypeId(-1)
{
asASSERT( ot && (ot->flags & asOBJ_LIST_PATTERN) );
// Find the first expected value in the list
asSListPatternNode *node = ot->engine->scriptFunctions[patternType->templateSubTypes[0].GetBehaviour()->listFactory]->listPattern;
asASSERT( node && node->type == asLPT_START );
patternNode = node->next;
}
int asCWriter::SListAdjuster::AdjustOffset(int offset, asCObjectType *listPatternType)
{
// TODO: cleanup: The listPatternType parameter is not needed
asASSERT( patternType == listPatternType );
UNUSED_VAR(listPatternType);
asASSERT( offset >= lastOffset );
// If it is the same offset being accessed again, just return the same adjusted value
if( offset == lastOffset )
return entries-1;
asASSERT( offset >= nextOffset );
// Update last offset for next call
lastOffset = offset;
// What is being expected at this position?
if( patternNode->type == asLPT_REPEAT || patternNode->type == asLPT_REPEAT_SAME )
{
// Don't move the patternNode yet because the caller must make a call to SetRepeatCount too
nextOffset = offset + 4;
return entries++;
}
else if( patternNode->type == asLPT_TYPE )
{
const asCDataType &dt = reinterpret_cast<asSListPatternDataTypeNode*>(patternNode)->dataType;
if( dt.GetTokenType() == ttQuestion )
{
// The bytecode need to inform the type that will
// come next and then adjust that position too before
// we can move to the next node
if( nextTypeId != -1 )
{
nextOffset = offset + 4;
if( repeatCount > 0 )
repeatCount--;
// Only move the patternNode if we're not expecting any more repeated entries
if( repeatCount == 0 )
patternNode = patternNode->next;
nextTypeId = -1;
}
}
else
{
if( repeatCount > 0 )
{
// Was any value skipped?
asUINT size;
if( dt.IsObjectHandle() || (dt.GetTypeInfo() && (dt.GetTypeInfo()->flags & asOBJ_REF)) )
size = AS_PTR_SIZE*4;
else
size = dt.GetSizeInMemoryBytes();
int count = 0;
while( nextOffset <= offset )
{
count++;
nextOffset += size;
// Align the offset on 4 byte boundaries
if( size >= 4 && (nextOffset & 0x3) )
nextOffset += 4 - (nextOffset & 0x3);
}
if( --count > 0 )
{
// Skip these values
repeatCount -= count;
entries += count;
}
nextOffset = offset + size;
repeatCount--;
}
// Only move the patternNode if we're not expecting any more repeated entries
if( repeatCount == 0 )
patternNode = patternNode->next;
}
return entries++;
}
else if( patternNode->type == asLPT_START )
{
if( repeatCount > 0 )
repeatCount--;
SInfo info = {repeatCount, patternNode};
stack.PushLast(info);
repeatCount = 0;
patternNode = patternNode->next;
lastOffset--;
return AdjustOffset(offset, listPatternType);
}
else if( patternNode->type == asLPT_END )
{
SInfo info = stack.PopLast();
repeatCount = info.repeatCount;
if( repeatCount )
patternNode = info.startNode;
else
patternNode = patternNode->next;
lastOffset--;
return AdjustOffset(offset, listPatternType);
}
else
{
// Something is wrong with the pattern list declaration
asASSERT( false );
}
return 0;
}
void asCWriter::SListAdjuster::SetRepeatCount(asUINT rc)
{
// Make sure the list is expecting a repeat at this location
asASSERT( patternNode->type == asLPT_REPEAT || patternNode->type == asLPT_REPEAT_SAME );
// Now move to the next patternNode
patternNode = patternNode->next;
repeatCount = rc;
}
void asCWriter::SListAdjuster::SetNextType(int typeId)
{
// Make sure the list is expecting a type at this location
asASSERT( patternNode->type == asLPT_TYPE &&
reinterpret_cast<asSListPatternDataTypeNode*>(patternNode)->dataType.GetTokenType() == ttQuestion );
// Inform the type id for the next adjustment
nextTypeId = typeId;
}
void asCWriter::WriteUsedTypeIds()
{
TimeIt("asCWriter::WriteUsedTypeIds");
asUINT count = (asUINT)usedTypeIds.GetLength();
WriteEncodedInt64(count);
for( asUINT n = 0; n < count; n++ )
{
asCDataType dt = engine->GetDataTypeFromTypeId(usedTypeIds[n]);
WriteDataType(&dt);
}
}
int asCWriter::FindGlobalPropPtrIndex(void *ptr)
{
int i = usedGlobalProperties.IndexOf(ptr);
if( i >= 0 ) return i;
usedGlobalProperties.PushLast(ptr);
return (int)usedGlobalProperties.GetLength()-1;
}
void asCWriter::WriteUsedGlobalProps()
{
TimeIt("asCWriter::WriteUsedGlobalProps");
int c = (int)usedGlobalProperties.GetLength();
WriteEncodedInt64(c);
for( int n = 0; n < c; n++ )
{
asPWORD *p = (asPWORD*)usedGlobalProperties[n];
// Find the property descriptor from the address
asCGlobalProperty *prop = 0;
asSMapNode<void*, asCGlobalProperty*> *cursor;
if( engine->varAddressMap.MoveTo(&cursor, p) )
{
prop = engine->varAddressMap.GetValue(cursor);
}
asASSERT(prop);
// Store the name and type of the property so we can find it again on loading
WriteString(&prop->name);
WriteString(&prop->nameSpace->name);
WriteDataType(&prop->type);
// Also store whether the property is a module property or a registered property
char moduleProp = 0;
if( prop->realAddress == 0 )
moduleProp = 1;
WriteData(&moduleProp, 1);
}
}
void asCWriter::WriteUsedObjectProps()
{
TimeIt("asCWriter::WriteUsedObjectProps");
int c = (int)usedObjectProperties.GetLength();
WriteEncodedInt64(c);
for( asUINT n = 0; n < usedObjectProperties.GetLength(); n++ )
{
WriteTypeInfo(usedObjectProperties[n].objType);
WriteString(&usedObjectProperties[n].prop->name);
}
}
int asCWriter::FindObjectPropIndex(short offset, int typeId, asDWORD *bc)
{
// If the last property was a composite property, then just return 0, because it won't be translated
static bool lastWasComposite = false;
if (lastWasComposite)
{
lastWasComposite = false;
return 0;
}
asCObjectType *objType = engine->GetObjectTypeFromTypeId(typeId);
asCObjectProperty *objProp = 0;
// Look for composite properties first
for (asUINT n = 0; objProp == 0 && n < objType->properties.GetLength(); n++)
{
// TODO: Composite: Perhaps it would be better to add metadata to the bytecode instruction to give the exact property.
// That would also allow me to remove the typeId from the bytecode instruction itself
// Or perhaps a new bytecode instruction all together for accessing composite properties
// One that would do both offsets and indirection in a single go.
// TODO: Composite: Need to be able to handle instructions replaced in bytecode optimizations too
if (objType->properties[n]->compositeOffset == offset)
{
// This is a potential composite property. Need to check the following instructions to be sure
objProp = objType->properties[n];
asDWORD *bcTemp = bc;
bcTemp += asBCTypeSize[asBCInfo[*(asBYTE*)bcTemp].type];
if (objProp->isCompositeIndirect)
{
// The next instruction would be a asBC_RDSPtr
if ((*(asBYTE*)bcTemp) != asBC_RDSPtr)
{
objProp = 0;
continue;
}
bcTemp += asBCTypeSize[asBCInfo[*(asBYTE*)bcTemp].type];
}
// The next instruction would be asBC_ADDSi
if ((*(asBYTE*)bcTemp) != asBC_ADDSi)
{
objProp = 0;
continue;
}
// Make sure the offset is the expected one
if (*(((short*)bcTemp) + 1) != objProp->byteOffset)
{
objProp = 0;
continue;
}
}
}
// If none of the composite properties matched, then look for ordinary property
for (asUINT n = 0; objProp == 0 && n < objType->properties.GetLength(); n++)
{
if (objType->properties[n]->byteOffset == offset && !(objType->properties[n]->compositeOffset || objType->properties[n]->isCompositeIndirect))
objProp = objType->properties[n];
}
asASSERT(objProp);
// Remember if this is a composite property as the next call will then be for the same property
if (objProp->compositeOffset || objProp->isCompositeIndirect)
lastWasComposite = true;
// Now check if the same property has already been accessed
for( asUINT n = 0; n < usedObjectProperties.GetLength(); n++ )
{
if( usedObjectProperties[n].objType == objType &&
usedObjectProperties[n].prop == objProp )
return n;
}
// Insert the new property
SObjProp prop = {objType, objProp};
usedObjectProperties.PushLast(prop);
return (int)usedObjectProperties.GetLength() - 1;
}
int asCWriter::FindFunctionIndex(asCScriptFunction *func)
{
for( asUINT n = 0; n < usedFunctions.GetLength(); n++ )
{
if( usedFunctions[n] == func )
return n;
}
usedFunctions.PushLast(func);
return (int)usedFunctions.GetLength() - 1;
}
int asCWriter::FindTypeIdIdx(int typeId)
{
asUINT n;
for( n = 0; n < usedTypeIds.GetLength(); n++ )
{
if( usedTypeIds[n] == typeId )
return n;
}
usedTypeIds.PushLast(typeId);
return (int)usedTypeIds.GetLength() - 1;
}
int asCWriter::FindTypeInfoIdx(asCTypeInfo *obj)
{
asUINT n;
for( n = 0; n < usedTypes.GetLength(); n++ )
{
if( usedTypes[n] == obj )
return n;
}
usedTypes.PushLast(obj);
return (int)usedTypes.GetLength() - 1;
}
#endif // AS_NO_COMPILER
END_AS_NAMESPACE