// Shader.h
private static void FShaderMapPointerTable_LoadFromArchive(FMaterialResourceProxyReader Ar)
{
if (GIsHybridUE5)
{
FPointerTableBase_LoadFromArchive(Ar);
}
var numTypes = Ar.Read <int>();
var numVFTypes = Ar.Read <int>();
for (var typeIndex = 0; typeIndex < numTypes; ++typeIndex)
{
var typeName = Ar.Read <FHashedName>();
}
for (var vfTypeIndex = 0; vfTypeIndex < numVFTypes; ++vfTypeIndex)
{
var vfTypeName = Ar.Read <FHashedName>();
}
if (!GIsHybridUE5)
{
FPointerTableBase_LoadFromArchive(Ar);
}
}
public void DeserializeInlineShaderMap(FMaterialResourceProxyReader Ar)
{
var cooked = Ar.ReadBoolean();
//check(cooked)
var valid = Ar.ReadBoolean();
//check(valid)
var loadedShaderMap = new FMaterialShaderMap();
loadedShaderMap.Deserialize(Ar);
}
// MemoryImage.cpp
private static void FPointerTableBase_LoadFromArchive(FMaterialResourceProxyReader Ar)
{
var numDependencies = Ar.Read <int>();
for (var i = 0; i < numDependencies; ++i)
{
var nameHash = Ar.Read <ulong>();
var savedLayoutSize = Ar.Read <uint>();
var savedLayoutHash = new FSHAHash(Ar);
}
}
public void DeserializeInlineShaderMap(FMaterialResourceProxyReader Ar)
{
var bCooked = Ar.ReadBoolean();
if (!bCooked)
{
return;
}
var bValid = Ar.ReadBoolean();
if (bValid)
{
LoadedShaderMap = new FMaterialShaderMap();
LoadedShaderMap.Deserialize(Ar);
}
else
{
Log.Warning("Loading a material resource '{0}' with an invalid ShaderMap!", Ar.Name);
}
}
public void Deserialize(FMaterialResourceProxyReader Ar)
{
var bUseNewFormat = Ar.Versions["ShaderMap.UseNewCookedFormat"];
ImageResult = new FMemoryImageResult(Ar);
var bShareCode = Ar.ReadBoolean();
if (bUseNewFormat)
{
var ShaderPlatform = Ar.Read <EShaderPlatform>();
}
if (bShareCode)
{
ResourceHash = new FSHAHash(Ar);
}
else
{
Code = new FShaderMapResourceCode(Ar);
}
}
public FMaterialShaderMapId(FMaterialResourceProxyReader Ar)
{
var bIsLegacyPackage = Ar.Ver < (UE4Version)260;
if (!bIsLegacyPackage)
{
QualityLevel = (EMaterialQualityLevel)Ar.Read <int>();
FeatureLevel = (ERHIFeatureLevel)Ar.Read <int>();
}
else
{
var legacyQualityLevel = Ar.Read <byte>();
}
// Cooked so can assume this is valid
CookedShaderMapIdHash = new FSHAHash(Ar);
if (!bIsLegacyPackage)
{
LayoutParams = Ar.Read <FPlatformTypeLayoutParameters>();
}
}
public new void Deserialize(FMaterialResourceProxyReader Ar)
{
ShaderMapId = new FMaterialShaderMapId(Ar);
base.Deserialize(Ar);
}
public void Deserialize(FMaterialResourceProxyReader Ar)
{
#region FMemoryImageResult::LoadFromArchive, MemoryImage.cpp
if (GIsHybridUE5)
{
var layoutParameters = Ar.Read <FPlatformTypeLayoutParameters>();
}
var frozenSize = Ar.Read <int>();
var frozenObject = Ar.ReadBytes(frozenSize);
if (GIsHybridUE5)
{
//var bFrozenObjectIsValid = pointerTable.LoadFromArchive(Ar, layoutParameters, frozenObject);
FShaderMapPointerTable_LoadFromArchive(Ar);
}
var numVTables = Ar.Read <uint>();
var numScriptNames = Ar.Read <uint>();
var numMinimalNames = Ar.Read <uint>();
for (var i = 0; i < numVTables; i++)
{
var typeNameHash = Ar.Read <ulong>();
var numPatches = Ar.Read <uint>();
for (var patchIndex = 0; patchIndex < numPatches; ++patchIndex)
{
var vTableOffset = Ar.Read <uint>();
var offset = Ar.Read <uint>();
}
}
for (var i = 0; i < numScriptNames; i++)
{
var name = Ar.ReadFName();
var numPatches = Ar.Read <uint>();
for (var patchIndex = 0; patchIndex < numPatches; ++patchIndex)
{
var offset = Ar.Read <uint>();
}
}
for (var i = 0; i < numMinimalNames; i++)
{
var name = Ar.ReadFName();
var numPatches = Ar.Read <uint>();
for (var patchIndex = 0; patchIndex < numPatches; ++patchIndex)
{
var offset = Ar.Read <uint>();
}
}
#endregion
if (!GIsHybridUE5)
{
FShaderMapPointerTable_LoadFromArchive(Ar);
}
var bShareCode = Ar.ReadBoolean();
if (GIsHybridUE5)
{
var shaderPlatform = Ar.Read <byte>();
}
if (bShareCode)
{
var resourceHash = new FSHAHash(Ar);
}
else
{
throw new NotImplementedException();
}
}
