stk-code_catmod/lib/angelscript/source/as_module.cpp
Bryan Quigley 73c94f571d Update Angelscript from 2.32.0 to 2.35.1
Didn't require any changes except dos2unix.
2021-11-04 17:59:10 -07:00

1889 lines
48 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_module.cpp
//
// A class that holds a script module
//
#include "as_config.h"
#include "as_module.h"
#include "as_builder.h"
#include "as_context.h"
#include "as_texts.h"
#include "as_debug.h"
#include "as_restore.h"
BEGIN_AS_NAMESPACE
// internal
asCModule::asCModule(const char *name, asCScriptEngine *engine)
{
m_name = name;
m_engine = engine;
m_userData = 0;
m_builder = 0;
m_isGlobalVarInitialized = false;
m_accessMask = 1;
m_defaultNamespace = engine->nameSpaces[0];
}
// internal
asCModule::~asCModule()
{
InternalReset();
// The builder is not removed by InternalReset because it holds the script
// sections that will be built, so we need to explictly remove it now if it exists
if( m_builder )
{
asDELETE(m_builder,asCBuilder);
m_builder = 0;
}
if( m_engine )
{
// Clean the user data
for( asUINT n = 0; n < m_userData.GetLength(); n += 2 )
{
if( m_userData[n+1] )
{
for( asUINT c = 0; c < m_engine->cleanModuleFuncs.GetLength(); c++ )
if( m_engine->cleanModuleFuncs[c].type == m_userData[n] )
m_engine->cleanModuleFuncs[c].cleanFunc(this);
}
}
// Remove the module from the engine
ACQUIREEXCLUSIVE(m_engine->engineRWLock);
// The module must have been discarded before it is deleted
asASSERT( !m_engine->scriptModules.Exists(this) );
m_engine->discardedModules.RemoveValue(this);
RELEASEEXCLUSIVE(m_engine->engineRWLock);
}
}
// interface
void asCModule::Discard()
{
// Reset the global variables already so that no object in the global variables keep the module alive forever.
// If any live object tries to access the global variables during clean up they will fail with a script exception,
// so the application must keep that in mind before discarding a module.
CallExit();
// Keep a local copy of the engine pointer, because once the module is moved do the discarded
// pile, it is possible that another thread might discard it while we are still in here. So no
// further access to members may be done after that
asCScriptEngine *engine = m_engine;
// Instead of deleting the module immediately, move it to the discarded pile
// This will turn it invisible to the application, yet keep it alive until all
// external references to its entities have been released.
ACQUIREEXCLUSIVE(engine->engineRWLock);
if( engine->lastModule == this )
engine->lastModule = 0;
engine->scriptModules.RemoveValue(this);
engine->discardedModules.PushLast(this);
RELEASEEXCLUSIVE(engine->engineRWLock);
// Allow the engine to go over the list of discarded modules to see what can be cleaned up at this moment.
// Don't do this if the engine is already shutting down, as it will be done explicitly by the engine itself with error reporting
if( !engine->shuttingDown )
{
if( engine->ep.autoGarbageCollect )
engine->GarbageCollect();
else
{
// GarbageCollect calls DeleteDiscardedModules, so no need
// to call it again if we already called GarbageCollect
engine->DeleteDiscardedModules();
}
}
}
// interface
void *asCModule::SetUserData(void *data, asPWORD type)
{
// As a thread might add a new new user data at the same time as another
// it is necessary to protect both read and write access to the userData member
ACQUIREEXCLUSIVE(m_engine->engineRWLock);
// It is not intended to store a lot of different types of userdata,
// so a more complex structure like a associative map would just have
// more overhead than a simple array.
for( asUINT n = 0; n < m_userData.GetLength(); n += 2 )
{
if( m_userData[n] == type )
{
void *oldData = reinterpret_cast<void*>(m_userData[n+1]);
m_userData[n+1] = reinterpret_cast<asPWORD>(data);
RELEASEEXCLUSIVE(m_engine->engineRWLock);
return oldData;
}
}
m_userData.PushLast(type);
m_userData.PushLast(reinterpret_cast<asPWORD>(data));
RELEASEEXCLUSIVE(m_engine->engineRWLock);
return 0;
}
// interface
void *asCModule::GetUserData(asPWORD type) const
{
// There may be multiple threads reading, but when
// setting the user data nobody must be reading.
ACQUIRESHARED(m_engine->engineRWLock);
for( asUINT n = 0; n < m_userData.GetLength(); n += 2 )
{
if( m_userData[n] == type )
{
void *ud = reinterpret_cast<void*>(m_userData[n+1]);
RELEASESHARED(m_engine->engineRWLock);
return ud;
}
}
RELEASESHARED(m_engine->engineRWLock);
return 0;
}
// interface
asIScriptEngine *asCModule::GetEngine() const
{
return m_engine;
}
// interface
void asCModule::SetName(const char *in_name)
{
m_name = in_name;
}
// interface
const char *asCModule::GetName() const
{
return m_name.AddressOf();
}
// interface
const char *asCModule::GetDefaultNamespace() const
{
return m_defaultNamespace->name.AddressOf();
}
// interface
int asCModule::SetDefaultNamespace(const char *nameSpace)
{
// TODO: cleanup: This function is similar to asCScriptEngine::SetDefaultNamespace. Can we reuse the code?
if( nameSpace == 0 )
return asINVALID_ARG;
asCString ns = nameSpace;
if( ns != "" )
{
// Make sure the namespace is composed of alternating identifier and ::
size_t pos = 0;
bool expectIdentifier = true;
size_t len;
eTokenType t = ttIdentifier;
for( ; pos < ns.GetLength(); pos += len )
{
t = m_engine->tok.GetToken(ns.AddressOf() + pos, ns.GetLength() - pos, &len);
if( (expectIdentifier && t != ttIdentifier) || (!expectIdentifier && t != ttScope) )
return asINVALID_DECLARATION;
expectIdentifier = !expectIdentifier;
}
// If the namespace ends with :: then strip it off
if( t == ttScope )
ns.SetLength(ns.GetLength()-2);
}
m_defaultNamespace = m_engine->AddNameSpace(ns.AddressOf());
return 0;
}
// interface
int asCModule::AddScriptSection(const char *in_name, const char *in_code, size_t in_codeLength, int in_lineOffset)
{
#ifdef AS_NO_COMPILER
UNUSED_VAR(in_name);
UNUSED_VAR(in_code);
UNUSED_VAR(in_codeLength);
UNUSED_VAR(in_lineOffset);
return asNOT_SUPPORTED;
#else
if( !m_builder )
{
m_builder = asNEW(asCBuilder)(m_engine, this);
if( m_builder == 0 )
return asOUT_OF_MEMORY;
}
return m_builder->AddCode(in_name, in_code, (int)in_codeLength, in_lineOffset, (int)m_engine->GetScriptSectionNameIndex(in_name ? in_name : ""), m_engine->ep.copyScriptSections);
#endif
}
// internal
void asCModule::JITCompile()
{
asIJITCompiler *jit = m_engine->GetJITCompiler();
if( !jit )
return;
for (unsigned int i = 0; i < m_scriptFunctions.GetLength(); i++)
m_scriptFunctions[i]->JITCompile();
}
// interface
int asCModule::Build()
{
#ifdef AS_NO_COMPILER
return asNOT_SUPPORTED;
#else
TimeIt("asCModule::Build");
// Don't allow the module to be rebuilt if there are still
// external references that will need the previous code
// TODO: interface: The asIScriptModule must have a method for querying if the module is used
if( HasExternalReferences(false) )
{
m_engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, TXT_MODULE_IS_IN_USE);
return asMODULE_IS_IN_USE;
}
// Only one thread may build at one time
// TODO: It should be possible to have multiple threads perform compilations
int r = m_engine->RequestBuild();
if( r < 0 )
return r;
m_engine->PrepareEngine();
if( m_engine->configFailed )
{
m_engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, TXT_INVALID_CONFIGURATION);
m_engine->BuildCompleted();
return asINVALID_CONFIGURATION;
}
InternalReset();
if( !m_builder )
{
m_engine->BuildCompleted();
return asSUCCESS;
}
// Compile the script
r = m_builder->Build();
asDELETE(m_builder,asCBuilder);
m_builder = 0;
if( r < 0 )
{
// Reset module again
InternalReset();
m_engine->BuildCompleted();
return r;
}
JITCompile();
m_engine->PrepareEngine();
#ifdef AS_DEBUG
// Verify that there are no unwanted gaps in the scriptFunctions array.
for( asUINT n = 1; n < m_engine->scriptFunctions.GetLength(); n++ )
{
int id = n;
if( m_engine->scriptFunctions[n] == 0 && !m_engine->freeScriptFunctionIds.Exists(id) )
asASSERT( false );
}
#endif
m_engine->BuildCompleted();
// Initialize global variables
if( r >= 0 && m_engine->ep.initGlobalVarsAfterBuild )
r = ResetGlobalVars(0);
return r;
#endif
}
// interface
int asCModule::ResetGlobalVars(asIScriptContext *ctx)
{
if( m_isGlobalVarInitialized )
CallExit();
return CallInit(ctx);
}
// interface
asIScriptFunction *asCModule::GetFunctionByIndex(asUINT index) const
{
return const_cast<asCScriptFunction*>(m_globalFunctions.Get(index));
}
// internal
int asCModule::CallInit(asIScriptContext *myCtx)
{
if( m_isGlobalVarInitialized )
return asERROR;
// Each global variable needs to be cleared individually
asCSymbolTableIterator<asCGlobalProperty> it = m_scriptGlobals.List();
while( it )
{
asCGlobalProperty *desc = *it;
memset(desc->GetAddressOfValue(), 0, sizeof(asDWORD)*desc->type.GetSizeOnStackDWords());
it++;
}
// Call the init function for each of the global variables
asIScriptContext *ctx = myCtx;
int r = asEXECUTION_FINISHED;
it = m_scriptGlobals.List();
while( it && r == asEXECUTION_FINISHED )
{
asCGlobalProperty *desc = *it;
it++;
if( desc->GetInitFunc() )
{
if( ctx == 0 )
{
ctx = m_engine->RequestContext();
if( ctx == 0 )
break;
}
r = InitGlobalProp(desc, ctx);
}
}
if( ctx && !myCtx )
{
m_engine->ReturnContext(ctx);
ctx = 0;
}
// Even if the initialization failed we need to set the
// flag that the variables have been initialized, otherwise
// the module won't free those variables that really were
// initialized.
m_isGlobalVarInitialized = true;
if( r != asEXECUTION_FINISHED )
return asINIT_GLOBAL_VARS_FAILED;
return asSUCCESS;
}
// internal
// This function assumes the memory for the global property is already cleared
int asCModule::InitGlobalProp(asCGlobalProperty *prop, asIScriptContext *myCtx)
{
// Call the init function for each of the global variables
asIScriptContext *ctx = myCtx;
int r = asEXECUTION_FINISHED;
if( prop->GetInitFunc() )
{
if( ctx == 0 )
{
ctx = m_engine->RequestContext();
if( ctx == 0 )
return asERROR;
}
r = ctx->Prepare(prop->GetInitFunc());
if( r >= 0 )
{
r = ctx->Execute();
if( r != asEXECUTION_FINISHED )
{
asCString msg;
msg.Format(TXT_FAILED_TO_INITIALIZE_s, prop->name.AddressOf());
asCScriptFunction *func = prop->GetInitFunc();
m_engine->WriteMessage(func->scriptData->scriptSectionIdx >= 0 ? m_engine->scriptSectionNames[func->scriptData->scriptSectionIdx]->AddressOf() : "",
func->GetLineNumber(0, 0) & 0xFFFFF,
func->GetLineNumber(0, 0) >> 20,
asMSGTYPE_ERROR,
msg.AddressOf());
if( r == asEXECUTION_EXCEPTION )
{
const asIScriptFunction *function = ctx->GetExceptionFunction();
msg.Format(TXT_EXCEPTION_s_IN_s, ctx->GetExceptionString(), function->GetDeclaration());
m_engine->WriteMessage(function->GetScriptSectionName(),
ctx->GetExceptionLineNumber(),
0,
asMSGTYPE_INFORMATION,
msg.AddressOf());
}
}
}
}
if( ctx && !myCtx )
{
m_engine->ReturnContext(ctx);
ctx = 0;
}
// Even if the initialization failed we need to set the
// flag that the variables have been initialized, otherwise
// the module won't free those variables that really were
// initialized.
m_isGlobalVarInitialized = true;
if( r != asEXECUTION_FINISHED )
return asINIT_GLOBAL_VARS_FAILED;
return asSUCCESS;
}
// internal
void asCModule::UninitializeGlobalProp(asCGlobalProperty *prop)
{
if (prop == 0)
return;
if (prop->type.IsObject())
{
void **obj = (void**)prop->GetAddressOfValue();
if (*obj)
{
asCObjectType *ot = CastToObjectType(prop->type.GetTypeInfo());
if (ot->flags & asOBJ_REF)
{
asASSERT((ot->flags & asOBJ_NOCOUNT) || ot->beh.release);
if (ot->beh.release)
m_engine->CallObjectMethod(*obj, ot->beh.release);
}
else
{
if (ot->beh.destruct)
m_engine->CallObjectMethod(*obj, ot->beh.destruct);
m_engine->CallFree(*obj);
}
// Set the address to 0 as someone might try to access the variable afterwards
*obj = 0;
}
}
else if (prop->type.IsFuncdef())
{
asCScriptFunction **func = (asCScriptFunction**)prop->GetAddressOfValue();
if (*func)
{
(*func)->Release();
*func = 0;
}
}
}
// internal
void asCModule::CallExit()
{
if( !m_isGlobalVarInitialized ) return;
asCSymbolTableIterator<asCGlobalProperty> it = m_scriptGlobals.List();
while( it )
{
UninitializeGlobalProp(*it);
it++;
}
m_isGlobalVarInitialized = false;
}
// internal
bool asCModule::HasExternalReferences(bool shuttingDown)
{
// Check all entities in the module for any external references.
// If there are any external references the module cannot be deleted yet.
asCSymbolTableIterator<asCGlobalProperty> it = m_scriptGlobals.List();
while (it)
{
asCGlobalProperty *desc = *it;
if (desc->GetInitFunc() && desc->GetInitFunc()->externalRefCount.get())
{
if( !shuttingDown )
return true;
else
{
asCString msg;
msg.Format(TXT_EXTRNL_REF_TO_MODULE_s, m_name.AddressOf());
m_engine->WriteMessage("", 0, 0, asMSGTYPE_WARNING, msg.AddressOf());
// TODO: Use a better error message
asCString tmpName = "init " + desc->name;
msg.Format(TXT_PREV_FUNC_IS_NAMED_s_TYPE_IS_d, tmpName.AddressOf(), desc->GetInitFunc()->GetFuncType());
m_engine->WriteMessage("", 0, 0, asMSGTYPE_INFORMATION, msg.AddressOf());
}
}
it++;
}
for (asUINT n = 0; n < m_scriptFunctions.GetLength(); n++)
{
asCScriptFunction *func = m_scriptFunctions[n];
if (func && func->externalRefCount.get())
{
// If the func is shared and can be moved to another module then this is not a reason to keep the module alive
if (func->IsShared() && m_engine->FindNewOwnerForSharedFunc(func, this) != this)
continue;
if (!shuttingDown)
return true;
else
{
asCString msg;
msg.Format(TXT_EXTRNL_REF_TO_MODULE_s, m_name.AddressOf());
m_engine->WriteMessage("", 0, 0, asMSGTYPE_WARNING, msg.AddressOf());
msg.Format(TXT_PREV_FUNC_IS_NAMED_s_TYPE_IS_d, m_scriptFunctions[n]->GetName(), m_scriptFunctions[n]->GetFuncType());
m_engine->WriteMessage("", 0, 0, asMSGTYPE_INFORMATION, msg.AddressOf());
}
}
}
for (asUINT n = 0; n < m_classTypes.GetLength(); n++)
{
asCObjectType *obj = m_classTypes[n];
if (obj && obj->externalRefCount.get())
{
// If the obj is shared and can be moved to another module then this is not a reason to keep the module alive
if (obj->IsShared() && m_engine->FindNewOwnerForSharedType(obj, this) != this)
continue;
if (!shuttingDown)
return true;
else
{
asCString msg;
msg.Format(TXT_EXTRNL_REF_TO_MODULE_s, m_name.AddressOf());
m_engine->WriteMessage("", 0, 0, asMSGTYPE_WARNING, msg.AddressOf());
msg.Format(TXT_PREV_TYPE_IS_NAMED_s, m_classTypes[n]->GetName());
m_engine->WriteMessage("", 0, 0, asMSGTYPE_INFORMATION, msg.AddressOf());
}
}
}
for (asUINT n = 0; n < m_funcDefs.GetLength(); n++)
{
asCFuncdefType *func = m_funcDefs[n];
if (func && func->externalRefCount.get())
{
// If the funcdef is shared and can be moved to another module then this is not a reason to keep the module alive
if (func->IsShared() && m_engine->FindNewOwnerForSharedType(func, this) != this)
continue;
if (!shuttingDown)
return true;
else
{
asCString msg;
msg.Format(TXT_EXTRNL_REF_TO_MODULE_s, m_name.AddressOf());
m_engine->WriteMessage("", 0, 0, asMSGTYPE_WARNING, msg.AddressOf());
msg.Format(TXT_PREV_FUNC_IS_NAMED_s_TYPE_IS_d, m_funcDefs[n]->GetName(), m_funcDefs[n]->funcdef->GetFuncType());
m_engine->WriteMessage("", 0, 0, asMSGTYPE_INFORMATION, msg.AddressOf());
}
}
}
for (asUINT n = 0; n < m_templateInstances.GetLength(); n++)
{
asCObjectType *obj = m_templateInstances[n];
if (obj && obj->externalRefCount.get())
{
// If the template can be moved to another module then this is not a reason to keep the module alive
if (obj->IsShared() && m_engine->FindNewOwnerForSharedType(obj, this) != this)
continue;
if (!shuttingDown)
return true;
else
{
asCString msg;
msg.Format(TXT_EXTRNL_REF_TO_MODULE_s, m_name.AddressOf());
m_engine->WriteMessage("", 0, 0, asMSGTYPE_WARNING, msg.AddressOf());
msg.Format(TXT_PREV_TYPE_IS_NAMED_s, m_templateInstances[n]->GetName());
m_engine->WriteMessage("", 0, 0, asMSGTYPE_INFORMATION, msg.AddressOf());
}
}
}
return false;
}
// internal
void asCModule::InternalReset()
{
CallExit();
asUINT n;
// Remove all global functions
m_globalFunctions.Clear();
// Destroy the internals of the global properties here, but do not yet remove them from the
// engine, because functions need the engine's varAddressMap to get to the property. If the
// property is removed already, it may leak as the refCount doesn't reach 0.
asCSymbolTableIterator<asCGlobalProperty> globIt = m_scriptGlobals.List();
while( globIt )
{
(*globIt)->DestroyInternal();
globIt++;
}
UnbindAllImportedFunctions();
// Free bind information
for( n = 0; n < m_bindInformations.GetLength(); n++ )
{
if( m_bindInformations[n] )
{
m_bindInformations[n]->importedFunctionSignature->ReleaseInternal();
asDELETE(m_bindInformations[n], sBindInfo);
}
}
m_bindInformations.SetLength(0);
// Free declared types, including classes, typedefs, and enums
for( n = 0; n < m_templateInstances.GetLength(); n++ )
{
asCObjectType *type = m_templateInstances[n];
if( m_engine->FindNewOwnerForSharedType(type, this) != this )
{
// The type is owned by another module, just release our reference
type->ReleaseInternal();
continue;
}
// Orphan the template instance
type->module = 0;
// No other module is holding the template type
m_engine->RemoveTemplateInstanceType(type);
type->ReleaseInternal();
}
m_templateInstances.SetLength(0);
for( n = 0; n < m_classTypes.GetLength(); n++ )
{
asCObjectType *type = m_classTypes[n];
if( type->IsShared() )
{
// The type is shared, so transfer ownership to another module that also uses it
if( m_engine->FindNewOwnerForSharedType(type, this) != this )
{
// The type is owned by another module, just release our reference
type->ReleaseInternal();
continue;
}
}
// The type should be destroyed now
type->DestroyInternal();
// Remove the type from the engine
if( type->IsShared() )
{
m_engine->sharedScriptTypes.RemoveValue(type);
type->ReleaseInternal();
}
// Release it from the module
type->module = 0;
type->ReleaseInternal();
}
m_classTypes.SetLength(0);
for( n = 0; n < m_enumTypes.GetLength(); n++ )
{
asCEnumType *type = m_enumTypes[n];
if( type->IsShared() )
{
// The type is shared, so transfer ownership to another module that also uses it
if( m_engine->FindNewOwnerForSharedType(type, this) != this )
{
// The type is owned by another module, just release our reference
type->ReleaseInternal();
continue;
}
}
// Remove the type from the engine
if( type->IsShared() )
{
m_engine->sharedScriptTypes.RemoveValue(type);
type->ReleaseInternal();
}
// Release it from the module
type->module = 0;
type->ReleaseInternal();
}
m_enumTypes.SetLength(0);
for( n = 0; n < m_typeDefs.GetLength(); n++ )
{
asCTypedefType *type = m_typeDefs[n];
// The type should be destroyed now
type->DestroyInternal();
// Release it from the module
type->module = 0;
type->ReleaseInternal();
}
m_typeDefs.SetLength(0);
// Free funcdefs
for( n = 0; n < m_funcDefs.GetLength(); n++ )
{
asCFuncdefType *func = m_funcDefs[n];
asASSERT(func);
if( func->funcdef && func->funcdef->IsShared() )
{
// The funcdef is shared, so transfer ownership to another module that also uses it
if( m_engine->FindNewOwnerForSharedType(func, this) != this )
{
// The funcdef is owned by another module, just release our reference
func->ReleaseInternal();
continue;
}
}
func->DestroyInternal();
m_engine->RemoveFuncdef(func);
func->module = 0;
func->ReleaseInternal();
}
m_funcDefs.SetLength(0);
// Then release the functions
for( n = 0; n < m_scriptFunctions.GetLength(); n++ )
{
asCScriptFunction *func = m_scriptFunctions[n];
if( func->IsShared() )
{
// The func is shared, so transfer ownership to another module that also uses it
if( m_engine->FindNewOwnerForSharedFunc(func, this) != this )
{
// The func is owned by another module, just release our reference
func->ReleaseInternal();
continue;
}
}
func->DestroyInternal();
func->module = 0;
func->ReleaseInternal();
}
m_scriptFunctions.SetLength(0);
// Now remove and release the global properties as there are no more references to them
globIt = m_scriptGlobals.List();
while( globIt )
{
m_engine->RemoveGlobalProperty(*globIt);
asASSERT( (*globIt)->refCount.get() == 1 );
(*globIt)->Release();
globIt++;
}
m_scriptGlobals.Clear();
// Clear the type lookup
// The references were already released as the types were removed from the respective arrays
m_typeLookup.EraseAll();
asASSERT( IsEmpty() );
}
// interface
asIScriptFunction *asCModule::GetFunctionByName(const char *in_name) const
{
asCString name;
asSNameSpace *ns = 0;
if( m_engine->DetermineNameAndNamespace(in_name, m_defaultNamespace, name, ns) < 0 )
return 0;
// Search recursively in the given namespace, moving up to parent namespace until the function is found
while( ns )
{
const asCArray<unsigned int> &idxs = m_globalFunctions.GetIndexes(ns, name);
if( idxs.GetLength() != 1 )
return 0;
const asIScriptFunction *func = m_globalFunctions.Get(idxs[0]);
if( func )
return const_cast<asIScriptFunction*>(func);
// Recursively search parent namespaces
ns = m_engine->GetParentNameSpace(ns);
}
return 0;
}
// interface
asUINT asCModule::GetImportedFunctionCount() const
{
return (asUINT)m_bindInformations.GetLength();
}
// interface
int asCModule::GetImportedFunctionIndexByDecl(const char *decl) const
{
asCBuilder bld(m_engine, const_cast<asCModule*>(this));
// Don't write parser errors to the message callback
bld.silent = true;
asCScriptFunction func(m_engine, const_cast<asCModule*>(this), asFUNC_DUMMY);
bld.ParseFunctionDeclaration(0, decl, &func, false, 0, 0, m_defaultNamespace);
// TODO: optimize: Improve linear search
// Search script functions for matching interface
int id = -1;
for( asUINT n = 0; n < m_bindInformations.GetLength(); ++n )
{
if( func.name == m_bindInformations[n]->importedFunctionSignature->name &&
func.returnType == m_bindInformations[n]->importedFunctionSignature->returnType &&
func.parameterTypes.GetLength() == m_bindInformations[n]->importedFunctionSignature->parameterTypes.GetLength() )
{
bool match = true;
for( asUINT p = 0; p < func.parameterTypes.GetLength(); ++p )
{
if( func.parameterTypes[p] != m_bindInformations[n]->importedFunctionSignature->parameterTypes[p] )
{
match = false;
break;
}
}
if( match )
{
if( id == -1 )
id = n;
else
return asMULTIPLE_FUNCTIONS;
}
}
}
if( id == -1 ) return asNO_FUNCTION;
return id;
}
// interface
asUINT asCModule::GetFunctionCount() const
{
return (asUINT)m_globalFunctions.GetSize();
}
// interface
asIScriptFunction *asCModule::GetFunctionByDecl(const char *decl) const
{
asCBuilder bld(m_engine, const_cast<asCModule*>(this));
// Don't write parser errors to the message callback
bld.silent = true;
asCScriptFunction func(m_engine, const_cast<asCModule*>(this), asFUNC_DUMMY);
int r = bld.ParseFunctionDeclaration(0, decl, &func, false, 0, 0, m_defaultNamespace);
if( r < 0 )
{
// Invalid declaration
// TODO: Write error to message stream
return 0;
}
// Use the defaultNamespace implicitly unless an explicit namespace has been provided
asSNameSpace *ns = func.nameSpace == m_engine->nameSpaces[0] ? m_defaultNamespace : func.nameSpace;
// Search script functions for matching interface
while( ns )
{
asIScriptFunction *f = 0;
const asCArray<unsigned int> &idxs = m_globalFunctions.GetIndexes(ns, func.name);
for( unsigned int n = 0; n < idxs.GetLength(); n++ )
{
const asCScriptFunction *funcPtr = m_globalFunctions.Get(idxs[n]);
if( funcPtr->objectType == 0 &&
func.returnType == funcPtr->returnType &&
func.parameterTypes.GetLength() == funcPtr->parameterTypes.GetLength()
)
{
bool match = true;
for( asUINT p = 0; p < func.parameterTypes.GetLength(); ++p )
{
if( func.parameterTypes[p] != funcPtr->parameterTypes[p] )
{
match = false;
break;
}
}
if( match )
{
if( f == 0 )
f = const_cast<asCScriptFunction*>(funcPtr);
else
// Multiple functions
return 0;
}
}
}
if( f )
return f;
else
{
// Search for matching functions in the parent namespace
ns = m_engine->GetParentNameSpace(ns);
}
}
return 0;
}
// interface
asUINT asCModule::GetGlobalVarCount() const
{
return (asUINT)m_scriptGlobals.GetSize();
}
// interface
int asCModule::GetGlobalVarIndexByName(const char *in_name) const
{
asCString name;
asSNameSpace *ns = 0;
if( m_engine->DetermineNameAndNamespace(in_name, m_defaultNamespace, name, ns) < 0 )
return asINVALID_ARG;
// Find the global var id
while( ns )
{
int id = m_scriptGlobals.GetFirstIndex(ns, name);
if( id >= 0 ) return id;
// Recursively search parent namespaces
ns = m_engine->GetParentNameSpace(ns);
}
return asNO_GLOBAL_VAR;
}
// interface
int asCModule::RemoveGlobalVar(asUINT index)
{
asCGlobalProperty *prop = m_scriptGlobals.Get(index);
if( !prop )
return asINVALID_ARG;
// If the global variables have already been initialized
// then uninitialize the variable before it is removed
if (m_isGlobalVarInitialized)
UninitializeGlobalProp(prop);
// Destroy the internal of the global variable (removes the initialization function)
prop->DestroyInternal();
// Check if the module is the only one referring to the property, if so remove it from the engine too
// If the property is not removed now, it will be removed later when the module is discarded
if( prop->refCount.get() == 2 )
m_engine->RemoveGlobalProperty(prop);
// Remove the global variable from the module
m_scriptGlobals.Erase(index);
prop->Release();
return 0;
}
// interface
int asCModule::GetGlobalVarIndexByDecl(const char *decl) const
{
asCBuilder bld(m_engine, const_cast<asCModule*>(this));
// Don't write parser errors to the message callback
bld.silent = true;
asCString declName;
asSNameSpace *nameSpace;
asCDataType dt;
int r = bld.ParseVariableDeclaration(decl, m_defaultNamespace, declName, nameSpace, dt);
if( r < 0 )
return r;
// Search global variables for a match
while( nameSpace )
{
int id = m_scriptGlobals.GetFirstIndex(nameSpace, declName, asCCompGlobPropType(dt));
if( id != -1 )
return id;
// Recursively search parent namespace
nameSpace = m_engine->GetParentNameSpace(nameSpace);
}
return asNO_GLOBAL_VAR;
}
// interface
void *asCModule::GetAddressOfGlobalVar(asUINT index)
{
asCGlobalProperty *prop = m_scriptGlobals.Get(index);
if( !prop )
return 0;
// For object variables it's necessary to dereference the pointer to get the address of the value
if( prop->type.IsObject() &&
!prop->type.IsObjectHandle() )
return *(void**)(prop->GetAddressOfValue());
return (void*)(prop->GetAddressOfValue());
}
// interface
const char *asCModule::GetGlobalVarDeclaration(asUINT index, bool includeNamespace) const
{
const asCGlobalProperty *prop = m_scriptGlobals.Get(index);
if (!prop) return 0;
asCString *tempString = &asCThreadManager::GetLocalData()->string;
*tempString = prop->type.Format(m_defaultNamespace);
*tempString += " ";
if( includeNamespace && prop->nameSpace->name != "" )
*tempString += prop->nameSpace->name + "::";
*tempString += prop->name;
return tempString->AddressOf();
}
// interface
int asCModule::GetGlobalVar(asUINT index, const char **out_name, const char **out_nameSpace, int *out_typeId, bool *out_isConst) const
{
const asCGlobalProperty *prop = m_scriptGlobals.Get(index);
if (!prop) return asINVALID_ARG;
if( out_name )
*out_name = prop->name.AddressOf();
if( out_nameSpace )
*out_nameSpace = prop->nameSpace->name.AddressOf();
if( out_typeId )
*out_typeId = m_engine->GetTypeIdFromDataType(prop->type);
if( out_isConst )
*out_isConst = prop->type.IsReadOnly();
return asSUCCESS;
}
// interface
asUINT asCModule::GetObjectTypeCount() const
{
return (asUINT)m_classTypes.GetLength();
}
// interface
asITypeInfo *asCModule::GetObjectTypeByIndex(asUINT index) const
{
if( index >= m_classTypes.GetLength() )
return 0;
return m_classTypes[index];
}
// interface
asITypeInfo *asCModule::GetTypeInfoByName(const char *in_name) const
{
asCString name;
asSNameSpace *ns = 0;
if( m_engine->DetermineNameAndNamespace(in_name, m_defaultNamespace, name, ns) < 0 )
return 0;
while (ns)
{
asITypeInfo* info = GetType(name, ns);
if(info)
{
return info;
}
// Recursively search parent namespace
ns = m_engine->GetParentNameSpace(ns);
}
return 0;
}
// interface
int asCModule::GetTypeIdByDecl(const char *decl) const
{
asCDataType dt;
// This const cast is safe since we know the engine won't be modified
asCBuilder bld(m_engine, const_cast<asCModule*>(this));
// Don't write parser errors to the message callback
bld.silent = true;
int r = bld.ParseDataType(decl, &dt, m_defaultNamespace);
if( r < 0 )
return asINVALID_TYPE;
return m_engine->GetTypeIdFromDataType(dt);
}
// interface
asITypeInfo *asCModule::GetTypeInfoByDecl(const char *decl) const
{
asCDataType dt;
// This const cast is safe since we know the engine won't be modified
asCBuilder bld(m_engine, const_cast<asCModule*>(this));
// Don't write parser errors to the message callback
bld.silent = true;
int r = bld.ParseDataType(decl, &dt, m_defaultNamespace);
if (r < 0)
return 0;
return dt.GetTypeInfo();
}
// interface
asUINT asCModule::GetEnumCount() const
{
return m_enumTypes.GetLength();
}
// interface
asITypeInfo *asCModule::GetEnumByIndex(asUINT index) const
{
if( index >= m_enumTypes.GetLength() )
return 0;
return m_enumTypes[index];
}
// interface
asUINT asCModule::GetTypedefCount() const
{
return (asUINT)m_typeDefs.GetLength();
}
// interface
asITypeInfo *asCModule::GetTypedefByIndex(asUINT index) const
{
if( index >= m_typeDefs.GetLength() )
return 0;
return m_typeDefs[index];
}
// internal
int asCModule::GetNextImportedFunctionId()
{
// TODO: multithread: This will break if one thread if freeing a module, while another is being compiled
if( m_engine->freeImportedFunctionIdxs.GetLength() )
return FUNC_IMPORTED | (asUINT)m_engine->freeImportedFunctionIdxs[m_engine->freeImportedFunctionIdxs.GetLength()-1];
return FUNC_IMPORTED | (asUINT)m_engine->importedFunctions.GetLength();
}
#ifndef AS_NO_COMPILER
// internal
int asCModule::AddScriptFunction(int sectionIdx, int declaredAt, int id, const asCString &funcName, const asCDataType &returnType, const asCArray<asCDataType> &params, const asCArray<asCString> &paramNames, const asCArray<asETypeModifiers> &inOutFlags, const asCArray<asCString *> &defaultArgs, bool isInterface, asCObjectType *objType, bool isGlobalFunction, asSFunctionTraits funcTraits, asSNameSpace *ns)
{
asASSERT(id >= 0);
// Store the function information
asCScriptFunction *func = asNEW(asCScriptFunction)(m_engine, this, isInterface ? asFUNC_INTERFACE : asFUNC_SCRIPT);
if( func == 0 )
{
// Free the default args
for( asUINT n = 0; n < defaultArgs.GetLength(); n++ )
if( defaultArgs[n] )
asDELETE(defaultArgs[n], asCString);
return asOUT_OF_MEMORY;
}
if( ns == 0 )
ns = m_engine->nameSpaces[0];
// All methods of shared objects are also shared
if( objType && objType->IsShared() )
funcTraits.SetTrait(asTRAIT_SHARED, true);
func->name = funcName;
func->nameSpace = ns;
func->id = id;
func->returnType = returnType;
if( func->funcType == asFUNC_SCRIPT )
{
func->scriptData->scriptSectionIdx = sectionIdx;
func->scriptData->declaredAt = declaredAt;
}
func->parameterTypes = params;
func->parameterNames = paramNames;
func->inOutFlags = inOutFlags;
func->defaultArgs = defaultArgs;
func->objectType = objType;
if( objType )
objType->AddRefInternal();
func->traits = funcTraits;
asASSERT( params.GetLength() == inOutFlags.GetLength() && params.GetLength() == defaultArgs.GetLength() );
// Verify that we are not assigning either the final or override specifier(s) if we are registering a non-member function
asASSERT( !(!objType && funcTraits.GetTrait(asTRAIT_FINAL)) );
asASSERT( !(!objType && funcTraits.GetTrait(asTRAIT_OVERRIDE)) );
// The internal ref count was already set by the constructor
m_scriptFunctions.PushLast(func);
m_engine->AddScriptFunction(func);
// Compute the signature id
if( objType )
func->ComputeSignatureId();
// Add reference
if( isGlobalFunction )
m_globalFunctions.Put(func);
return 0;
}
// internal
int asCModule::AddScriptFunction(asCScriptFunction *func)
{
m_scriptFunctions.PushLast(func);
func->AddRefInternal();
m_engine->AddScriptFunction(func);
// If the function that is being added is an already compiled shared function
// then it is necessary to look for anonymous functions that may be declared
// within it and add those as well
if( func->IsShared() && func->funcType == asFUNC_SCRIPT )
{
// Loop through the byte code and check all the
// asBC_FuncPtr instructions for anonymous functions
asDWORD *bc = func->scriptData->byteCode.AddressOf();
asUINT bcLength = (asUINT)func->scriptData->byteCode.GetLength();
for( asUINT n = 0; n < bcLength; )
{
int c = *(asBYTE*)&bc[n];
if( c == asBC_FuncPtr )
{
asCScriptFunction *f = reinterpret_cast<asCScriptFunction*>(asBC_PTRARG(&bc[n]));
// Anonymous functions start with $
// There are never two equal anonymous functions so it is not necessary to look for duplicates
if( f && f->name[0] == '$' )
{
AddScriptFunction(f);
m_globalFunctions.Put(f);
}
}
n += asBCTypeSize[asBCInfo[c].type];
}
}
return 0;
}
// internal
int asCModule::AddImportedFunction(int id, const asCString &funcName, const asCDataType &returnType, const asCArray<asCDataType> &params, const asCArray<asETypeModifiers> &inOutFlags, const asCArray<asCString *> &defaultArgs, asSFunctionTraits funcTraits, asSNameSpace *ns, const asCString &moduleName)
{
asASSERT(id >= 0);
// Store the function information
asCScriptFunction *func = asNEW(asCScriptFunction)(m_engine, this, asFUNC_IMPORTED);
if( func == 0 )
{
// Free the default args
for( asUINT n = 0; n < defaultArgs.GetLength(); n++ )
if( defaultArgs[n] )
asDELETE(defaultArgs[n], asCString);
return asOUT_OF_MEMORY;
}
func->name = funcName;
func->id = id;
func->returnType = returnType;
func->nameSpace = ns;
func->parameterTypes = params;
func->inOutFlags = inOutFlags;
func->defaultArgs = defaultArgs;
func->objectType = 0;
func->traits = funcTraits;
sBindInfo *info = asNEW(sBindInfo);
if( info == 0 )
{
asDELETE(func, asCScriptFunction);
return asOUT_OF_MEMORY;
}
info->importedFunctionSignature = func;
info->boundFunctionId = -1;
info->importFromModule = moduleName;
m_bindInformations.PushLast(info);
// Add the info to the array in the engine
if( m_engine->freeImportedFunctionIdxs.GetLength() )
m_engine->importedFunctions[m_engine->freeImportedFunctionIdxs.PopLast()] = info;
else
m_engine->importedFunctions.PushLast(info);
return 0;
}
#endif
// internal
asCScriptFunction *asCModule::GetImportedFunction(int index) const
{
return m_bindInformations[index]->importedFunctionSignature;
}
// interface
int asCModule::BindImportedFunction(asUINT index, asIScriptFunction *func)
{
// First unbind the old function
int r = UnbindImportedFunction(index);
if( r < 0 ) return r;
// Must verify that the interfaces are equal
asCScriptFunction *dst = GetImportedFunction(index);
if( dst == 0 ) return asNO_FUNCTION;
if( func == 0 )
return asINVALID_ARG;
asCScriptFunction *src = m_engine->GetScriptFunction(func->GetId());
if( src == 0 )
return asNO_FUNCTION;
// Verify return type
if( dst->returnType != src->returnType )
return asINVALID_INTERFACE;
if( dst->parameterTypes.GetLength() != src->parameterTypes.GetLength() )
return asINVALID_INTERFACE;
for( asUINT n = 0; n < dst->parameterTypes.GetLength(); ++n )
{
if( dst->parameterTypes[n] != src->parameterTypes[n] )
return asINVALID_INTERFACE;
}
m_bindInformations[index]->boundFunctionId = src->GetId();
src->AddRefInternal();
return asSUCCESS;
}
// interface
int asCModule::UnbindImportedFunction(asUINT index)
{
if( index >= m_bindInformations.GetLength() )
return asINVALID_ARG;
// Remove reference to old module
if( m_bindInformations[index] )
{
int oldFuncID = m_bindInformations[index]->boundFunctionId;
if( oldFuncID != -1 )
{
m_bindInformations[index]->boundFunctionId = -1;
m_engine->scriptFunctions[oldFuncID]->ReleaseInternal();
}
}
return asSUCCESS;
}
// interface
const char *asCModule::GetImportedFunctionDeclaration(asUINT index) const
{
asCScriptFunction *func = GetImportedFunction(index);
if( func == 0 ) return 0;
asCString *tempString = &asCThreadManager::GetLocalData()->string;
// TODO: Allow the application to decide if the parameter name should be included or not (requires change in the interface)
*tempString = func->GetDeclarationStr(true, true, false);
return tempString->AddressOf();
}
// interface
const char *asCModule::GetImportedFunctionSourceModule(asUINT index) const
{
if( index >= m_bindInformations.GetLength() )
return 0;
return m_bindInformations[index]->importFromModule.AddressOf();
}
// inteface
int asCModule::BindAllImportedFunctions()
{
bool notAllFunctionsWereBound = false;
// Bind imported functions
int c = GetImportedFunctionCount();
for( int n = 0; n < c; ++n )
{
asCScriptFunction *importFunc = GetImportedFunction(n);
if( importFunc == 0 ) return asERROR;
asCString str = importFunc->GetDeclarationStr(false, true);
// Get module name from where the function should be imported
const char *moduleName = GetImportedFunctionSourceModule(n);
if( moduleName == 0 ) return asERROR;
asCModule *srcMod = m_engine->GetModule(moduleName, false);
asIScriptFunction *func = 0;
if( srcMod )
func = srcMod->GetFunctionByDecl(str.AddressOf());
if( func == 0 )
notAllFunctionsWereBound = true;
else
{
if( BindImportedFunction(n, func) < 0 )
notAllFunctionsWereBound = true;
}
}
if( notAllFunctionsWereBound )
return asCANT_BIND_ALL_FUNCTIONS;
return asSUCCESS;
}
// interface
int asCModule::UnbindAllImportedFunctions()
{
asUINT c = GetImportedFunctionCount();
for( asUINT n = 0; n < c; ++n )
UnbindImportedFunction(n);
return asSUCCESS;
}
// internal
void asCModule::AddClassType(asCObjectType* type)
{
m_classTypes.PushLast(type);
m_typeLookup.Insert(asSNameSpaceNamePair(type->nameSpace, type->name), type);
}
// internal
void asCModule::AddEnumType(asCEnumType* type)
{
m_enumTypes.PushLast(type);
m_typeLookup.Insert(asSNameSpaceNamePair(type->nameSpace, type->name), type);
}
// internal
void asCModule::AddTypeDef(asCTypedefType* type)
{
m_typeDefs.PushLast(type);
m_typeLookup.Insert(asSNameSpaceNamePair(type->nameSpace, type->name), type);
}
// internal
void asCModule::AddFuncDef(asCFuncdefType* type)
{
m_funcDefs.PushLast(type);
m_typeLookup.Insert(asSNameSpaceNamePair(type->nameSpace, type->name), type);
}
// internal
void asCModule::ReplaceFuncDef(asCFuncdefType* type, asCFuncdefType* newType)
{
int i = m_funcDefs.IndexOf(type);
if( i >= 0 )
{
m_funcDefs[i] = newType;
// Replace it in the lookup map too
asSMapNode<asSNameSpaceNamePair, asCTypeInfo*>* result = 0;
if(m_typeLookup.MoveTo(&result, asSNameSpaceNamePair(type->nameSpace, type->name)))
{
asASSERT( result->value == type );
result->value = newType;
}
}
}
// internal
asCTypeInfo *asCModule::GetType(const asCString &type, asSNameSpace *ns) const
{
asSMapNode<asSNameSpaceNamePair, asCTypeInfo*>* result = 0;
if(m_typeLookup.MoveTo(&result, asSNameSpaceNamePair(ns, type)))
{
return result->value;
}
return 0;
}
// internal
asCObjectType *asCModule::GetObjectType(const char *type, asSNameSpace *ns) const
{
asSMapNode<asSNameSpaceNamePair, asCTypeInfo*>* result = 0;
if(m_typeLookup.MoveTo(&result, asSNameSpaceNamePair(ns, type)))
{
return CastToObjectType(result->value);
}
return 0;
}
// internal
asCGlobalProperty *asCModule::AllocateGlobalProperty(const char *propName, const asCDataType &dt, asSNameSpace *ns)
{
asCGlobalProperty *prop = m_engine->AllocateGlobalProperty();
prop->name = propName;
prop->nameSpace = ns;
// Allocate the memory for this property based on its type
prop->type = dt;
prop->AllocateMemory();
// Make an entry in the address to variable map
m_engine->varAddressMap.Insert(prop->GetAddressOfValue(), prop);
// Store the variable in the module scope
m_scriptGlobals.Put(prop);
prop->AddRef();
return prop;
}
// internal
bool asCModule::IsEmpty() const
{
if( m_scriptFunctions.GetLength() ) return false;
if( m_globalFunctions.GetSize() ) return false;
if( m_bindInformations.GetLength() ) return false;
if( m_scriptGlobals.GetSize() ) return false;
if( m_classTypes.GetLength() ) return false;
if( m_enumTypes.GetLength() ) return false;
if( m_typeDefs.GetLength() ) return false;
if( m_funcDefs.GetLength() ) return false;
return true;
}
// interface
int asCModule::SaveByteCode(asIBinaryStream *out, bool stripDebugInfo) const
{
#ifdef AS_NO_COMPILER
UNUSED_VAR(out);
UNUSED_VAR(stripDebugInfo);
return asNOT_SUPPORTED;
#else
if( out == 0 ) return asINVALID_ARG;
// Make sure there is actually something to save
if( IsEmpty() )
return asERROR;
asCWriter write(const_cast<asCModule*>(this), out, m_engine, stripDebugInfo);
return write.Write();
#endif
}
// interface
int asCModule::LoadByteCode(asIBinaryStream *in, bool *wasDebugInfoStripped)
{
if( in == 0 ) return asINVALID_ARG;
// Don't allow the module to be rebuilt if there are still
// external references that will need the previous code
if( HasExternalReferences(false) )
{
m_engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, TXT_MODULE_IS_IN_USE);
return asMODULE_IS_IN_USE;
}
// Only permit loading bytecode if no other thread is currently compiling
// TODO: It should be possible to have multiple threads perform compilations
int r = m_engine->RequestBuild();
if( r < 0 )
return r;
asCReader read(this, in, m_engine);
r = read.Read(wasDebugInfoStripped);
if (r < 0)
{
m_engine->BuildCompleted();
return r;
}
JITCompile();
#ifdef AS_DEBUG
// Verify that there are no unwanted gaps in the scriptFunctions array.
for( asUINT n = 1; n < m_engine->scriptFunctions.GetLength(); n++ )
{
int id = n;
if( m_engine->scriptFunctions[n] == 0 && !m_engine->freeScriptFunctionIds.Exists(id) )
asASSERT( false );
}
#endif
m_engine->BuildCompleted();
return r;
}
// interface
int asCModule::CompileGlobalVar(const char *sectionName, const char *code, int lineOffset)
{
#ifdef AS_NO_COMPILER
UNUSED_VAR(sectionName);
UNUSED_VAR(code);
UNUSED_VAR(lineOffset);
return asNOT_SUPPORTED;
#else
// Validate arguments
if( code == 0 )
return asINVALID_ARG;
// Only one thread may build at one time
// TODO: It should be possible to have multiple threads perform compilations
int r = m_engine->RequestBuild();
if( r < 0 )
return r;
// Prepare the engine
m_engine->PrepareEngine();
if( m_engine->configFailed )
{
m_engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, TXT_INVALID_CONFIGURATION);
m_engine->BuildCompleted();
return asINVALID_CONFIGURATION;
}
// Compile the global variable and add it to the module scope
asCBuilder varBuilder(m_engine, this);
asCString str = code;
r = varBuilder.CompileGlobalVar(sectionName, str.AddressOf(), lineOffset);
m_engine->BuildCompleted();
// Initialize the variable
if( r >= 0 )
{
// Clear the memory
asCGlobalProperty *prop = m_scriptGlobals.GetLast();
if( prop )
{
memset(prop->GetAddressOfValue(), 0, sizeof(asDWORD)*prop->type.GetSizeOnStackDWords());
}
if( prop && m_engine->ep.initGlobalVarsAfterBuild )
{
// Flag that there are initialized global variables
m_isGlobalVarInitialized = true;
r = InitGlobalProp(prop, 0);
}
}
return r;
#endif
}
// interface
int asCModule::CompileFunction(const char* sectionName, const char* code, int lineOffset, asDWORD compileFlags, asIScriptFunction** outFunc)
{
// Make sure the outFunc is null if the function fails, so the
// application doesn't attempt to release a non-existent function
if (outFunc)
*outFunc = 0;
#ifdef AS_NO_COMPILER
UNUSED_VAR(sectionName);
UNUSED_VAR(code);
UNUSED_VAR(lineOffset);
UNUSED_VAR(compileFlags);
return asNOT_SUPPORTED;
#else
// Validate arguments
if (code == 0 ||
(compileFlags != 0 && compileFlags != asCOMP_ADD_TO_MODULE))
return asINVALID_ARG;
// Only one thread may build at one time
// TODO: It should be possible to have multiple threads perform compilations
int r = m_engine->RequestBuild();
if (r < 0)
return r;
// Prepare the engine
m_engine->PrepareEngine();
if (m_engine->configFailed)
{
m_engine->WriteMessage("", 0, 0, asMSGTYPE_ERROR, TXT_INVALID_CONFIGURATION);
m_engine->BuildCompleted();
return asINVALID_CONFIGURATION;
}
// Compile the single function
asCBuilder funcBuilder(m_engine, this);
asCString str = code;
asCScriptFunction* func = 0;
r = funcBuilder.CompileFunction(sectionName, str.AddressOf(), lineOffset, compileFlags, &func);
if (r >= 0)
{
// Invoke the JIT compiler if it has been set
asIJITCompiler* jit = m_engine->GetJITCompiler();
if (jit)
{
func->JITCompile();
}
}
m_engine->BuildCompleted();
if( r >= 0 && outFunc && func )
{
// Return the function to the caller and add an external reference
*outFunc = func;
func->AddRef();
}
// Release our reference to the function
if( func )
func->ReleaseInternal();
return r;
#endif
}
// interface
int asCModule::RemoveFunction(asIScriptFunction *func)
{
// Find the global function
asCScriptFunction *f = static_cast<asCScriptFunction*>(func);
int idx = m_globalFunctions.GetIndex(f);
if( idx >= 0 )
{
m_globalFunctions.Erase(idx);
m_scriptFunctions.RemoveValue(f);
f->ReleaseInternal();
return 0;
}
return asNO_FUNCTION;
}
#ifndef AS_NO_COMPILER
// internal
int asCModule::AddFuncDef(const asCString &funcName, asSNameSpace *ns, asCObjectType *parent)
{
// namespace and parent are mutually exclusive
asASSERT((ns == 0 && parent) || (ns && parent == 0));
asCScriptFunction *func = asNEW(asCScriptFunction)(m_engine, 0, asFUNC_FUNCDEF);
if (func == 0)
return asOUT_OF_MEMORY;
func->name = funcName;
func->nameSpace = ns;
func->module = this;
asCFuncdefType *fdt = asNEW(asCFuncdefType)(m_engine, func);
AddFuncDef(fdt); // The constructor set the refcount to 1
m_engine->funcDefs.PushLast(fdt); // doesn't increase refcount
func->id = m_engine->GetNextScriptFunctionId();
m_engine->AddScriptFunction(func);
if (parent)
{
parent->childFuncDefs.PushLast(fdt);
fdt->parentClass = parent;
}
return (int)m_funcDefs.GetLength()-1;
}
#endif
// interface
asDWORD asCModule::SetAccessMask(asDWORD mask)
{
asDWORD old = m_accessMask;
m_accessMask = mask;
return old;
}
END_AS_NAMESPACE