static String GenerateNameFromType(ShortStringHash typeHash)
{
if (unknownTypeToName.Contains(typeHash))
return unknownTypeToName[typeHash];
String test;
// Begin brute-force search
unsigned numLetters = letters.Length();
unsigned combinations = numLetters;
bool found = false;
for (unsigned i = 1; i < 6; ++i)
{
test.Resize(i);
for (unsigned j = 0; j < combinations; ++j)
{
unsigned current = j;
for (unsigned k = 0; k < i; ++k)
{
test[k] = letters[current % numLetters];
current /= numLetters;
}
if (ShortStringHash(test) == typeHash)
{
found = true;
break;
}
}
if (found)
break;
combinations *= numLetters;
}
unknownTypeToName[typeHash] = test;
return test;
}
void AnimatedModel::CloneGeometries()
{
const Vector<SharedPtr<VertexBuffer> >& originalVertexBuffers = model_->GetVertexBuffers();
HashMap<VertexBuffer*, SharedPtr<VertexBuffer> > clonedVertexBuffers;
morphVertexBuffers_.Resize(originalVertexBuffers.Size());
for (unsigned i = 0; i < originalVertexBuffers.Size(); ++i)
{
VertexBuffer* original = originalVertexBuffers[i];
if (model_->GetMorphRangeCount(i))
{
SharedPtr<VertexBuffer> clone(new VertexBuffer(context_));
clone->SetShadowed(true);
clone->SetSize(original->GetVertexCount(), morphElementMask_ & original->GetElementMask(), true);
void* dest = clone->Lock(0, original->GetVertexCount());
if (dest)
{
CopyMorphVertices(dest, original->GetShadowData(), original->GetVertexCount(), clone, original);
clone->Unlock();
}
clonedVertexBuffers[original] = clone;
morphVertexBuffers_[i] = clone;
}
else
morphVertexBuffers_[i].Reset();
}
// Geometries will always be cloned fully. They contain only references to buffer, so they are relatively light
for (unsigned i = 0; i < geometries_.Size(); ++i)
{
for (unsigned j = 0; j < geometries_[i].Size(); ++j)
{
SharedPtr<Geometry> original = geometries_[i][j];
SharedPtr<Geometry> clone(new Geometry(context_));
// Add an additional vertex stream into the clone, which supplies only the morphable vertex data, while the static
// data comes from the original vertex buffer(s)
const Vector<SharedPtr<VertexBuffer> >& originalBuffers = original->GetVertexBuffers();
unsigned totalBuf = originalBuffers.Size();
for (unsigned k = 0; k < originalBuffers.Size(); ++k)
{
VertexBuffer* originalBuffer = originalBuffers[k];
if (clonedVertexBuffers.Contains(originalBuffer))
++totalBuf;
}
clone->SetNumVertexBuffers(totalBuf);
unsigned l = 0;
for (unsigned k = 0; k < originalBuffers.Size(); ++k)
{
VertexBuffer* originalBuffer = originalBuffers[k];
if (clonedVertexBuffers.Contains(originalBuffer))
{
VertexBuffer* clonedBuffer = clonedVertexBuffers[originalBuffer];
clone->SetVertexBuffer(l++, originalBuffer);
// Specify the morph buffer at a greater index to override the model's original positions/normals/tangents
clone->SetVertexBuffer(l++, clonedBuffer);
}
else
clone->SetVertexBuffer(l++, originalBuffer);
}
clone->SetIndexBuffer(original->GetIndexBuffer());
clone->SetDrawRange(original->GetPrimitiveType(), original->GetIndexStart(), original->GetIndexCount());
clone->SetLodDistance(original->GetLodDistance());
geometries_[i][j] = clone;
}
}
// Make sure the rendering batches use the new cloned geometries
ResetLodLevels();
MarkMorphsDirty();
}
void LoadMesh(const String& inputFileName, bool generateTangents, bool splitSubMeshes, bool exportMorphs)
{
File meshFileSource(context_);
meshFileSource.Open(inputFileName);
if (!meshFile_->Load(meshFileSource))
ErrorExit("Could not load input file " + inputFileName);
XMLElement root = meshFile_->GetRoot("mesh");
XMLElement subMeshes = root.GetChild("submeshes");
XMLElement skeletonLink = root.GetChild("skeletonlink");
if (root.IsNull())
ErrorExit("Could not load input file " + inputFileName);
String skeletonName = skeletonLink.GetAttribute("name");
if (!skeletonName.Empty())
LoadSkeleton(GetPath(inputFileName) + GetFileName(skeletonName) + ".skeleton.xml");
// Check whether there's benefit of avoiding 32bit indices by splitting each submesh into own buffer
XMLElement subMesh = subMeshes.GetChild("submesh");
unsigned totalVertices = 0;
unsigned maxSubMeshVertices = 0;
while (subMesh)
{
materialNames_.Push(subMesh.GetAttribute("material"));
XMLElement geometry = subMesh.GetChild("geometry");
if (geometry)
{
unsigned vertices = geometry.GetInt("vertexcount");
totalVertices += vertices;
if (maxSubMeshVertices < vertices)
maxSubMeshVertices = vertices;
}
++numSubMeshes_;
subMesh = subMesh.GetNext("submesh");
}
XMLElement sharedGeometry = root.GetChild("sharedgeometry");
if (sharedGeometry)
{
unsigned vertices = sharedGeometry.GetInt("vertexcount");
totalVertices += vertices;
if (maxSubMeshVertices < vertices)
maxSubMeshVertices = vertices;
}
if (!sharedGeometry && (splitSubMeshes || (totalVertices > 65535 && maxSubMeshVertices <= 65535)))
{
useOneBuffer_ = false;
vertexBuffers_.Resize(numSubMeshes_);
indexBuffers_.Resize(numSubMeshes_);
}
else
{
vertexBuffers_.Resize(1);
indexBuffers_.Resize(1);
}
subMesh = subMeshes.GetChild("submesh");
unsigned indexStart = 0;
unsigned vertexStart = 0;
unsigned subMeshIndex = 0;
PODVector<unsigned> vertexStarts;
vertexStarts.Resize(numSubMeshes_);
while (subMesh)
{
XMLElement geometry = subMesh.GetChild("geometry");
XMLElement faces = subMesh.GetChild("faces");
// If no submesh vertexbuffer, process the shared geometry, but do it only once
unsigned vertices = 0;
if (!geometry)
{
vertexStart = 0;
if (!subMeshIndex)
geometry = root.GetChild("sharedgeometry");
}
if (geometry)
vertices = geometry.GetInt("vertexcount");
ModelSubGeometryLodLevel subGeometryLodLevel;
ModelVertexBuffer* vBuf;
ModelIndexBuffer* iBuf;
if (useOneBuffer_)
{
vBuf = &vertexBuffers_[0];
if (vertices)
vBuf->vertices_.Resize(vertexStart + vertices);
iBuf = &indexBuffers_[0];
subGeometryLodLevel.vertexBuffer_ = 0;
subGeometryLodLevel.indexBuffer_ = 0;
}
else
{
vertexStart = 0;
indexStart = 0;
vBuf = &vertexBuffers_[subMeshIndex];
vBuf->vertices_.Resize(vertices);
iBuf = &indexBuffers_[subMeshIndex];
subGeometryLodLevel.vertexBuffer_ = subMeshIndex;
subGeometryLodLevel.indexBuffer_ = subMeshIndex;
}
// Store the start vertex for later use
vertexStarts[subMeshIndex] = vertexStart;
// Ogre may have multiple buffers in one submesh. These will be merged into one
XMLElement bufferDef;
if (geometry)
bufferDef = geometry.GetChild("vertexbuffer");
while (bufferDef)
{
if (bufferDef.HasAttribute("positions"))
vBuf->elementMask_ |= MASK_POSITION;
if (bufferDef.HasAttribute("normals"))
vBuf->elementMask_ |= MASK_NORMAL;
if (bufferDef.HasAttribute("texture_coords"))
{
vBuf->elementMask_ |= MASK_TEXCOORD1;
if (bufferDef.GetInt("texture_coords") > 1)
vBuf->elementMask_ |= MASK_TEXCOORD2;
}
unsigned vertexNum = vertexStart;
if (vertices)
{
XMLElement vertex = bufferDef.GetChild("vertex");
while (vertex)
{
XMLElement position = vertex.GetChild("position");
if (position)
{
// Convert from right- to left-handed
float x = position.GetFloat("x");
float y = position.GetFloat("y");
float z = position.GetFloat("z");
Vector3 vec(x, y, -z);
vBuf->vertices_[vertexNum].position_ = vec;
boundingBox_.Merge(vec);
}
XMLElement normal = vertex.GetChild("normal");
if (normal)
{
// Convert from right- to left-handed
float x = normal.GetFloat("x");
float y = normal.GetFloat("y");
float z = normal.GetFloat("z");
Vector3 vec(x, y, -z);
vBuf->vertices_[vertexNum].normal_ = vec;
}
XMLElement uv = vertex.GetChild("texcoord");
if (uv)
{
float x = uv.GetFloat("u");
float y = uv.GetFloat("v");
Vector2 vec(x, y);
vBuf->vertices_[vertexNum].texCoord1_ = vec;
if (vBuf->elementMask_ & MASK_TEXCOORD2)
{
uv = uv.GetNext("texcoord");
if (uv)
{
float x = uv.GetFloat("u");
float y = uv.GetFloat("v");
Vector2 vec(x, y);
vBuf->vertices_[vertexNum].texCoord2_ = vec;
}
}
}
vertexNum++;
vertex = vertex.GetNext("vertex");
}
}
bufferDef = bufferDef.GetNext("vertexbuffer");
}
unsigned triangles = faces.GetInt("count");
unsigned indices = triangles * 3;
XMLElement triangle = faces.GetChild("face");
while (triangle)
{
unsigned v1 = triangle.GetInt("v1");
unsigned v2 = triangle.GetInt("v2");
unsigned v3 = triangle.GetInt("v3");
iBuf->indices_.Push(v3 + vertexStart);
iBuf->indices_.Push(v2 + vertexStart);
iBuf->indices_.Push(v1 + vertexStart);
triangle = triangle.GetNext("face");
}
subGeometryLodLevel.indexStart_ = indexStart;
subGeometryLodLevel.indexCount_ = indices;
if (vertexStart + vertices > 65535)
iBuf->indexSize_ = sizeof(unsigned);
XMLElement boneAssignments = subMesh.GetChild("boneassignments");
if (bones_.Size())
{
if (boneAssignments)
{
XMLElement boneAssignment = boneAssignments.GetChild("vertexboneassignment");
while (boneAssignment)
{
unsigned vertex = boneAssignment.GetInt("vertexindex") + vertexStart;
unsigned bone = boneAssignment.GetInt("boneindex");
float weight = boneAssignment.GetFloat("weight");
BoneWeightAssignment assign;
assign.boneIndex_ = bone;
assign.weight_ = weight;
// Source data might have 0 weights. Disregard these
if (assign.weight_ > 0.0f)
{
subGeometryLodLevel.boneWeights_[vertex].Push(assign);
// Require skinning weight to be sufficiently large before vertex contributes to bone hitbox
if (assign.weight_ > 0.33f)
{
// Check distance of vertex from bone to get bone max. radius information
Vector3 bonePos = bones_[bone].derivedPosition_;
Vector3 vertexPos = vBuf->vertices_[vertex].position_;
float distance = (bonePos - vertexPos).Length();
if (distance > bones_[bone].radius_)
{
bones_[bone].collisionMask_ |= 1;
bones_[bone].radius_ = distance;
}
// Build the hitbox for the bone
bones_[bone].boundingBox_.Merge(bones_[bone].inverseWorldTransform_ * (vertexPos));
bones_[bone].collisionMask_ |= 2;
}
}
boneAssignment = boneAssignment.GetNext("vertexboneassignment");
}
}
if ((subGeometryLodLevel.boneWeights_.Size()) && bones_.Size())
{
vBuf->elementMask_ |= MASK_BLENDWEIGHTS | MASK_BLENDINDICES;
bool sorted = false;
// If amount of bones is larger than supported by HW skinning, must remap per submesh
if (bones_.Size() > maxBones_)
{
HashMap<unsigned, unsigned> usedBoneMap;
unsigned remapIndex = 0;
for (HashMap<unsigned, PODVector<BoneWeightAssignment> >::Iterator i =
subGeometryLodLevel.boneWeights_.Begin(); i != subGeometryLodLevel.boneWeights_.End(); ++i)
{
// Sort the bone assigns by weight
Sort(i->second_.Begin(), i->second_.End(), CompareWeights);
// Use only the first 4 weights
for (unsigned j = 0; j < i->second_.Size() && j < 4; ++j)
{
unsigned originalIndex = i->second_[j].boneIndex_;
if (!usedBoneMap.Contains(originalIndex))
{
usedBoneMap[originalIndex] = remapIndex;
remapIndex++;
}
i->second_[j].boneIndex_ = usedBoneMap[originalIndex];
}
}
// If still too many bones in one subgeometry, error
if (usedBoneMap.Size() > maxBones_)
ErrorExit("Too many bones (limit " + String(maxBones_) + ") in submesh " + String(subMeshIndex + 1));
// Write mapping of vertex buffer bone indices to original bone indices
subGeometryLodLevel.boneMapping_.Resize(usedBoneMap.Size());
for (HashMap<unsigned, unsigned>::Iterator j = usedBoneMap.Begin(); j != usedBoneMap.End(); ++j)
subGeometryLodLevel.boneMapping_[j->second_] = j->first_;
sorted = true;
}
for (HashMap<unsigned, PODVector<BoneWeightAssignment> >::Iterator i = subGeometryLodLevel.boneWeights_.Begin();
i != subGeometryLodLevel.boneWeights_.End(); ++i)
{
// Sort the bone assigns by weight, if not sorted yet in bone remapping pass
if (!sorted)
Sort(i->second_.Begin(), i->second_.End(), CompareWeights);
float totalWeight = 0.0f;
float normalizationFactor = 0.0f;
// Calculate normalization factor in case there are more than 4 blend weights, or they do not add up to 1
for (unsigned j = 0; j < i->second_.Size() && j < 4; ++j)
totalWeight += i->second_[j].weight_;
if (totalWeight > 0.0f)
normalizationFactor = 1.0f / totalWeight;
for (unsigned j = 0; j < i->second_.Size() && j < 4; ++j)
{
vBuf->vertices_[i->first_].blendIndices_[j] = i->second_[j].boneIndex_;
vBuf->vertices_[i->first_].blendWeights_[j] = i->second_[j].weight_ * normalizationFactor;
}
// If there are less than 4 blend weights, fill rest with zero
for (unsigned j = i->second_.Size(); j < 4; ++j)
{
vBuf->vertices_[i->first_].blendIndices_[j] = 0;
vBuf->vertices_[i->first_].blendWeights_[j] = 0.0f;
}
vBuf->vertices_[i->first_].hasBlendWeights_ = true;
}
}
}
else if (boneAssignments)
PrintLine("No skeleton loaded, skipping skinning information");
// Calculate center for the subgeometry
Vector3 center = Vector3::ZERO;
for (unsigned i = 0; i < iBuf->indices_.Size(); i += 3)
{
center += vBuf->vertices_[iBuf->indices_[i]].position_;
center += vBuf->vertices_[iBuf->indices_[i + 1]].position_;
center += vBuf->vertices_[iBuf->indices_[i + 2]].position_;
}
if (iBuf->indices_.Size())
center /= (float)iBuf->indices_.Size();
subGeometryCenters_.Push(center);
indexStart += indices;
vertexStart += vertices;
OptimizeIndices(&subGeometryLodLevel, vBuf, iBuf);
PrintLine("Processed submesh " + String(subMeshIndex + 1) + ": " + String(vertices) + " vertices " +
String(triangles) + " triangles");
Vector<ModelSubGeometryLodLevel> thisSubGeometry;
thisSubGeometry.Push(subGeometryLodLevel);
subGeometries_.Push(thisSubGeometry);
subMesh = subMesh.GetNext("submesh");
subMeshIndex++;
}
// Process LOD levels, if any
XMLElement lods = root.GetChild("levelofdetail");
if (lods)
{
try
{
// For now, support only generated LODs, where the vertices are the same
XMLElement lod = lods.GetChild("lodgenerated");
while (lod)
{
float distance = M_EPSILON;
if (lod.HasAttribute("fromdepthsquared"))
distance = sqrtf(lod.GetFloat("fromdepthsquared"));
if (lod.HasAttribute("value"))
distance = lod.GetFloat("value");
XMLElement lodSubMesh = lod.GetChild("lodfacelist");
while (lodSubMesh)
{
unsigned subMeshIndex = lodSubMesh.GetInt("submeshindex");
unsigned triangles = lodSubMesh.GetInt("numfaces");
ModelSubGeometryLodLevel newLodLevel;
ModelSubGeometryLodLevel& originalLodLevel = subGeometries_[subMeshIndex][0];
// Copy all initial values
newLodLevel = originalLodLevel;
ModelVertexBuffer* vBuf;
ModelIndexBuffer* iBuf;
if (useOneBuffer_)
{
vBuf = &vertexBuffers_[0];
iBuf = &indexBuffers_[0];
}
else
{
vBuf = &vertexBuffers_[subMeshIndex];
iBuf = &indexBuffers_[subMeshIndex];
}
unsigned indexStart = iBuf->indices_.Size();
unsigned indexCount = triangles * 3;
unsigned vertexStart = vertexStarts[subMeshIndex];
newLodLevel.distance_ = distance;
newLodLevel.indexStart_ = indexStart;
newLodLevel.indexCount_ = indexCount;
// Append indices to the original index buffer
XMLElement triangle = lodSubMesh.GetChild("face");
while (triangle)
{
unsigned v1 = triangle.GetInt("v1");
unsigned v2 = triangle.GetInt("v2");
unsigned v3 = triangle.GetInt("v3");
iBuf->indices_.Push(v3 + vertexStart);
iBuf->indices_.Push(v2 + vertexStart);
iBuf->indices_.Push(v1 + vertexStart);
triangle = triangle.GetNext("face");
}
OptimizeIndices(&newLodLevel, vBuf, iBuf);
subGeometries_[subMeshIndex].Push(newLodLevel);
PrintLine("Processed LOD level for submesh " + String(subMeshIndex + 1) + ": distance " + String(distance));
lodSubMesh = lodSubMesh.GetNext("lodfacelist");
}
lod = lod.GetNext("lodgenerated");
}
}
catch (...) {}
}
// Process poses/morphs
// First find out all pose definitions
if (exportMorphs)
{
try
{
Vector<XMLElement> poses;
XMLElement posesRoot = root.GetChild("poses");
if (posesRoot)
{
XMLElement pose = posesRoot.GetChild("pose");
while (pose)
{
poses.Push(pose);
pose = pose.GetNext("pose");
}
}
// Then process animations using the poses
XMLElement animsRoot = root.GetChild("animations");
if (animsRoot)
{
XMLElement anim = animsRoot.GetChild("animation");
while (anim)
{
String name = anim.GetAttribute("name");
float length = anim.GetFloat("length");
HashSet<unsigned> usedPoses;
XMLElement tracks = anim.GetChild("tracks");
if (tracks)
{
XMLElement track = tracks.GetChild("track");
while (track)
{
XMLElement keyframes = track.GetChild("keyframes");
if (keyframes)
{
XMLElement keyframe = keyframes.GetChild("keyframe");
while (keyframe)
{
float time = keyframe.GetFloat("time");
XMLElement poseref = keyframe.GetChild("poseref");
// Get only the end pose
if (poseref && time == length)
usedPoses.Insert(poseref.GetInt("poseindex"));
keyframe = keyframe.GetNext("keyframe");
}
}
track = track.GetNext("track");
}
}
if (usedPoses.Size())
{
ModelMorph newMorph;
newMorph.name_ = name;
if (useOneBuffer_)
newMorph.buffers_.Resize(1);
else
newMorph.buffers_.Resize(usedPoses.Size());
unsigned bufIndex = 0;
for (HashSet<unsigned>::Iterator i = usedPoses.Begin(); i != usedPoses.End(); ++i)
{
XMLElement pose = poses[*i];
unsigned targetSubMesh = pose.GetInt("index");
XMLElement poseOffset = pose.GetChild("poseoffset");
if (useOneBuffer_)
newMorph.buffers_[bufIndex].vertexBuffer_ = 0;
else
newMorph.buffers_[bufIndex].vertexBuffer_ = targetSubMesh;
newMorph.buffers_[bufIndex].elementMask_ = MASK_POSITION;
ModelVertexBuffer* vBuf = &vertexBuffers_[newMorph.buffers_[bufIndex].vertexBuffer_];
while (poseOffset)
{
// Convert from right- to left-handed
unsigned vertexIndex = poseOffset.GetInt("index") + vertexStarts[targetSubMesh];
float x = poseOffset.GetFloat("x");
float y = poseOffset.GetFloat("y");
float z = poseOffset.GetFloat("z");
Vector3 vec(x, y, -z);
if (vBuf->morphCount_ == 0)
{
vBuf->morphStart_ = vertexIndex;
vBuf->morphCount_ = 1;
}
else
{
unsigned first = vBuf->morphStart_;
unsigned last = first + vBuf->morphCount_ - 1;
if (vertexIndex < first)
first = vertexIndex;
if (vertexIndex > last)
last = vertexIndex;
vBuf->morphStart_ = first;
vBuf->morphCount_ = last - first + 1;
}
ModelVertex newVertex;
newVertex.position_ = vec;
newMorph.buffers_[bufIndex].vertices_.Push(MakePair(vertexIndex, newVertex));
poseOffset = poseOffset.GetNext("poseoffset");
}
if (!useOneBuffer_)
++bufIndex;
}
morphs_.Push(newMorph);
PrintLine("Processed morph " + name + " with " + String(usedPoses.Size()) + " sub-poses");
}
anim = anim.GetNext("animation");
}
}
}
catch (...) {}
}
// Check any of the buffers for vertices with missing blend weight assignments
for (unsigned i = 0; i < vertexBuffers_.Size(); ++i)
{
if (vertexBuffers_[i].elementMask_ & MASK_BLENDWEIGHTS)
{
for (unsigned j = 0; j < vertexBuffers_[i].vertices_.Size(); ++j)
if (!vertexBuffers_[i].vertices_[j].hasBlendWeights_)
ErrorExit("Found a vertex with missing skinning information");
}
}
// Tangent generation
if (generateTangents)
{
for (unsigned i = 0; i < subGeometries_.Size(); ++i)
{
for (unsigned j = 0; j < subGeometries_[i].Size(); ++j)
{
ModelVertexBuffer& vBuf = vertexBuffers_[subGeometries_[i][j].vertexBuffer_];
ModelIndexBuffer& iBuf = indexBuffers_[subGeometries_[i][j].indexBuffer_];
unsigned indexStart = subGeometries_[i][j].indexStart_;
unsigned indexCount = subGeometries_[i][j].indexCount_;
// If already has tangents, do not regenerate
if (vBuf.elementMask_ & MASK_TANGENT || vBuf.vertices_.Empty() || iBuf.indices_.Empty())
continue;
vBuf.elementMask_ |= MASK_TANGENT;
if ((vBuf.elementMask_ & (MASK_POSITION | MASK_NORMAL | MASK_TEXCOORD1)) != (MASK_POSITION | MASK_NORMAL |
MASK_TEXCOORD1))
ErrorExit("To generate tangents, positions normals and texcoords are required");
GenerateTangents(&vBuf.vertices_[0], sizeof(ModelVertex), &iBuf.indices_[0], sizeof(unsigned), indexStart,
indexCount, offsetof(ModelVertex, normal_), offsetof(ModelVertex, texCoord1_), offsetof(ModelVertex,
tangent_));
PrintLine("Generated tangents");
}
}
}
}
void JSBModule::Load(const String &moduleJSONFilename)
{
ResourceCache* cache = JSBind::context_->GetSubsystem<ResourceCache>();
JSONFile* moduleJSONFile = cache->GetResource<JSONFile>(moduleJSONFilename);
if (!moduleJSONFile)
{
LOGERRORF("Couldn't load module json: %s", moduleJSONFilename.CString());
ErrorExit("Couldn't load module json");
}
JSONValue moduleJSON = moduleJSONFile->GetRoot();
JSONValue sources = moduleJSON.GetChild("sources");
JSONValue classes = moduleJSON.GetChild("classes");
JSONValue includes = moduleJSON.GetChild("includes");
JSONValue classes_rename = moduleJSON.GetChild("classes_rename");
JSONValue overloads = moduleJSON.GetChild("overloads");
JSONValue requires = moduleJSON.GetChild("requires");
HashMap<String, String> rename;
if (requires.IsArray())
{
for (unsigned j = 0; j < requires.GetSize(); j++)
{
requirements_.Push(requires.GetString(j));
}
}
if (classes_rename.IsObject())
{
Vector<String> childNames = classes_rename.GetValueNames();
for (unsigned j = 0; j < childNames.Size(); j++)
{
String classname = childNames.At(j);
String crename = classes_rename.GetString(classname);
rename[classname] = crename;
}
}
if (includes.IsArray())
{
for (unsigned j = 0; j < includes.GetSize(); j++)
{
includes_.Push(includes.GetString(j));
}
}
if (classes.IsArray())
{
for (unsigned j = 0; j < classes.GetSize(); j++)
{
String classname = classes.GetString(j);
if (rename.Contains(classname))
bindings_->RegisterClass(classname, rename[classname]);
else
bindings_->RegisterClass(classname);
}
}
if (overloads.IsObject())
{
Vector<String> childNames = overloads.GetChildNames();
for (unsigned j = 0; j < childNames.Size(); j++)
{
String classname = childNames.At(j);
JSBClass* klass = bindings_->GetClass(classname);
if (!klass)
{
ErrorExit("Bad overload klass");
}
JSONValue classoverloads = overloads.GetChild(classname);
Vector<String> functionNames = classoverloads.GetChildNames();
for (unsigned k = 0; k < functionNames.Size(); k++)
{
JSONValue sig = classoverloads.GetChild(functionNames[k]);
if (!sig.IsArray())
{
ErrorExit("Bad overload defintion");
}
Vector<String> values;
for (unsigned x = 0; x < sig.GetSize(); x++)
{
values.Push(sig.GetString(x));
}
JSBFunctionOverride* fo = new JSBFunctionOverride(functionNames[k], values);
klass->AddFunctionOverride(fo);
}
}
}
this->name_ = moduleJSON.GetString("name");
if (this->name_ == "Graphics")
{
#ifdef _MSC_VER
sources.AddString("Graphics/Direct3D9");
#else
sources.AddString("Graphics/OpenGL");
#endif
}
for (unsigned j = 0; j < sources.GetSize(); j++)
{
String sourceFolder = sources.GetString(j);
Vector<String> fileNames;
String sourceRoot = "Atomic";
if (sourceFolder == "Javascript")
sourceRoot = "AtomicJS";
JSBind::fileSystem_->ScanDir(fileNames, JSBind::ROOT_FOLDER + "/Source/" + sourceRoot + "/" + sourceFolder, "*.h", SCAN_FILES, false);
for (unsigned k = 0; k < fileNames.Size(); k++)
{
// TODO: filter
String filepath = JSBind::ROOT_FOLDER + "/Source/" + sourceRoot + "/" + sourceFolder + "/" + fileNames[k];
this->headerFiles_.Push(filepath);
}
}
}
