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Author SHA1 Message Date
cb545da50f Entity Spatial Component API draft. 2023-03-12 14:19:58 +00:00
4ab31de209 Entity System API draft. 2023-03-12 13:16:48 +00:00
5c4137506b Entity Scene API draft 2023-03-12 12:58:18 +00:00
cc5400587c Entity Section API draft 2023-03-12 12:05:01 +00:00
33b27fc9a1 Component API draft 2023-03-11 07:57:03 +00:00
387bc84985 UUID & start on IDs 2023-03-11 07:14:36 +00:00
49 changed files with 884 additions and 2371 deletions

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@ -58,8 +58,8 @@ jobs:
- name: Make output folder - name: Make output folder
run: mkdir ./test-results run: mkdir ./test-results
- name: Test shadow-assets - name: Test shadow-file-format
run: ./bazel-bin/projs/shadow-assets/test.exe -r junit -o ./test-results/shadow-assets-test.xml run: ./bazel-bin/projs/shadow-file-format/test.exe -r junit -o ./test-results/shadow-file-format-test.xml
- name: Publish Test Results - name: Publish Test Results
uses: EnricoMi/publish-unit-test-result-action/composite@v1 uses: EnricoMi/publish-unit-test-result-action/composite@v1

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@ -5,36 +5,37 @@ Collapsed=0
DockId=0x00000008,0 DockId=0x00000008,0
[Window][Dear ImGui Demo] [Window][Dear ImGui Demo]
Pos=1193,111 Pos=1193,178
Size=62,92 Size=62,25
Collapsed=0 Collapsed=0
DockId=0x00000003,0 DockId=0x00000007,0
[Window][Game module window] [Window][Game module window]
Pos=956,275 Pos=1193,8
Size=302,121 Size=62,50
Collapsed=0 Collapsed=0
DockId=0x00000004,0
[Window][Time] [Window][Time]
Pos=1193,8 Pos=1193,60
Size=62,101 Size=62,49
Collapsed=0 Collapsed=0
DockId=0x00000002,0 DockId=0x00000005,0
[Window][Active Modules] [Window][Active Modules]
Pos=829,449 Pos=1193,111
Size=362,187 Size=62,65
Collapsed=0
[Window][Game View]
Pos=60,60
Size=656,515
Collapsed=0 Collapsed=0
DockId=0x00000006,0
[Docking][Data] [Docking][Data]
DockNode ID=0x00000001 Pos=1196,188 Size=379,195 Split=X DockNode ID=0x00000001 Pos=1196,188 Size=379,195 Split=X
DockNode ID=0x00000008 Parent=0x00000001 SizeRef=652,419 HiddenTabBar=1 Selected=0x55954704 DockNode ID=0x00000008 Parent=0x00000001 SizeRef=652,419 HiddenTabBar=1 Selected=0x55954704
DockNode ID=0x00000009 Parent=0x00000001 SizeRef=129,419 Split=Y DockNode ID=0x00000009 Parent=0x00000001 SizeRef=129,419 Split=Y
DockNode ID=0x00000002 Parent=0x00000009 SizeRef=219,34 Selected=0xE75A179E DockNode ID=0x00000002 Parent=0x00000009 SizeRef=219,34 Split=Y Selected=0xFC1D20C0
DockNode ID=0x00000003 Parent=0x00000009 SizeRef=219,31 Selected=0xE87781F4 DockNode ID=0x00000004 Parent=0x00000002 SizeRef=219,64 Selected=0xFC1D20C0
DockNode ID=0x00000005 Parent=0x00000002 SizeRef=219,62 Selected=0xE75A179E
DockNode ID=0x00000003 Parent=0x00000009 SizeRef=219,31 Split=Y Selected=0xEE305C78
DockNode ID=0x00000006 Parent=0x00000003 SizeRef=219,142 Selected=0xEE305C78
DockNode ID=0x00000007 Parent=0x00000003 SizeRef=219,55 Selected=0xE87781F4

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@ -7,17 +7,17 @@ set(CMAKE_WINDOWS_EXPORT_ALL_SYMBOLS ON)
FILE(GLOB_RECURSE SOURCES FILE(GLOB_RECURSE SOURCES
core/src/*.cpp core/src/*.cpp
shadow-entity/src/*.cpp
shadow-renderer/src/*.cpp shadow-renderer/src/*.cpp
shadow-reflection/src/*.cpp shadow-reflection/src/*.cpp
shadow-utility/src/*.cpp shadow-utility/src/*.cpp
shadow-assets/src/*.cpp
) )
FILE(GLOB_RECURSE HEADERS FILE(GLOB_RECURSE HEADERS
core/inc/*.h core/inc/*.h
shadow-entity/inc/*.h
shadow-renderer/inc/*.h shadow-renderer/inc/*.h
shadow-reflection/inc/*.h shadow-reflection/inc/*.h
shadow-utility/inc/*.h shadow-utility/inc/*.h
shadow-assets/src/*.h
) )
add_library(shadow-engine SHARED ${SOURCES} $<TARGET_OBJECTS:imgui>) add_library(shadow-engine SHARED ${SOURCES} $<TARGET_OBJECTS:imgui>)
@ -26,10 +26,10 @@ target_include_directories(shadow-engine
PRIVATE ${SDL2_INCLUDE_DIRS} PRIVATE ${SDL2_INCLUDE_DIRS}
PUBLIC PUBLIC
core/inc core/inc
shadow-entity/inc
shadow-renderer/inc shadow-renderer/inc
shadow-reflection/inc shadow-reflection/inc
shadow-utility/inc shadow-utility/inc
shadow-assets/src
${glm_SOURCE_DIR} ${glm_SOURCE_DIR}
INTERFACE INTERFACE
${imgui_SOURCE_DIR} ${imgui_SOURCE_DIR}

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@ -0,0 +1,64 @@
#pragma once
#include <cstdint>
#include <cstring>
#include <string>
// ShadowEntity temporary namespace
namespace SE {
/**
* Universally Unique ID.
* 128 Bits.
*
* Unique per runtime only - the suitability for serialization is undetermined.
*/
class UUID {
/**
* Data storage; 128 bits.
* 2 x 64 bit
* 4 x 32 bit
* 16 x 8 bit
*/
union Data {
uint64_t u64[2];
uint32_t u32[4];
uint8_t u8[16];
};
public:
// Create a new, unused, UUID.
static UUID Generate();
// Check whether the UUID is correctly formed.
static bool IsValidStr(char const* str);
// Create an empty UUID.
inline UUID() { std::memset(&data.u8, 0, 16); }
// Create a UUID based on the given values.
inline UUID(uint64_t i0, uint64_t i1) { data.u64[0] = i0; data.u64[1] = i1; }
inline UUID(uint32_t i0, uint32_t i1, uint32_t i2, uint32_t i3) { data.u32[0] = i0; data.u32[1] = i1; data.u32[2] = i2; data.u32[3] = i3; }
inline explicit UUID(std::string const& str) : UUID(str.c_str()) {}
// Create a UUID from the given format.
explicit UUID(char const* str);
// Check whether the UUID is nonzero.
inline bool IsValid() const { return data.u64[0] != 0 && data.u64[1] != 0; }
// Set the UUID to zero.
inline void Clear() { std::memset(&data.u8, 0, 16); }
// Get a section of the UUID's data as the given bit width.
inline uint8_t GetU8(size_t idx) const { return data.u8[idx]; }
inline uint32_t GetU32(size_t idx) const { return data.u32[idx]; }
inline uint64_t GetU64(size_t idx) const { return data.u64[idx]; }
// Check whether this and a given UUID are in/equal.
__inline bool operator==(UUID const& other) const { return data.u64[0] == other.data.u64[0] && data.u64[1] == other.data.u64[1]; }
__inline bool operator!=(UUID const& other) const { return !(*this == other); }
private:
Data data {};
};
}

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@ -0,0 +1,23 @@
#pragma once
#include <math/transform.h>
/**
* A temporary header that contains some of the bounds implementations.
*/
namespace Math {
/**
* A bounding box that can be rotated freely.
* Can be used as the collision box for an entity.
*/
struct OrientedBB {
OrientedBB() = default;
Quaternion orientation;
Vector center;
Vector extent;
};
}

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@ -0,0 +1,47 @@
#pragma once
/**
* A temporary header that contains some of the core transform logic.
*
*/
#include <xmmintrin.h>
namespace Math {
struct alignas(16) Vector {
Vector() = default;
union {
struct { float x, y, z, w; };
__m128 data;
};
};
struct alignas(16) Quaternion {
inline Quaternion() = default;
union {
struct { float x, y, z, w; };
__m128 data;
};
};
class Transform {
public:
Transform() = default;
const Vector& GetTranslation() const { return translation; }
const Quaternion& GetRotation() const { return rotation; }
inline Vector GetRightVector() const;
inline Vector GetForwardVector() const;
inline Vector GetUpVector() const;
private:
Quaternion rotation;
Vector translation;
Vector scale;
};
}

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@ -0,0 +1,56 @@
#include <id/UUID.h>
namespace SE {
static_assert(sizeof(UUID) == 16, "UUID has incorrect size");
/**
* Verify that a string has the correct format;
* XXXXXXXX-XXXX-XXX-XXXXX-XXXXXXXXXXXX
*
* The length must be 36.
* There must be dashes at index 8, 13, 18 and 23.
* @param str the input string
* @return whether the UUID string is correctly formed
*/
bool UUID::IsValidStr(const char *str) {
size_t const len = strlen(str);
if (len != 36) return false;
for (size_t i = 0; i < len; i++) {
char c = str[i];
if (c == '-') {
if (i != 8 && i != 13 && i != 18 && i != 23) return false;
} else if (! std::isxdigit(c)) {
return false;
}
}
return true;
}
UUID::UUID(char const* str ) {
// A single byte is two hex characters.
// Store them here so that we can use them later.
char c0 = '\0', c1;
size_t const len = strlen( str );
uint32_t byteIdx = 0;
for (size_t i = 0; i < len; i++ ) {
char const c = str[i];
if ( c == '-' )
continue;
// Scan for pairs of characters.
// Only assign a byte if two have been parsed.
if (c0 == '\0') {
c0 = c;
} else {
c1 = c;
data.u8[byteIdx++] = std::stoi(std::string(c0, c1));
// Reset the first char so that we can return to scanning a pair.
c0 = '\0';
}
}
}
}

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@ -1,265 +0,0 @@
#include <fs/file.h>
#include <vector>
#include "management/synchronization.h"
#include <spdlog/spdlog.h>
#include <filesystem>
#include <fs/path.h>
#include <map>
namespace ShadowEngine {
// Because fuck Linux? Need platform-specific source files!
#ifdef _WIN32
#define WIN32_LEAN_AND_MEAN
#include <Windows.h>
FileInput::FileInput() {
handle = (void*) INVALID_HANDLE_VALUE;
}
FileOutput::FileOutput() {
error = false;
handle = (void*) INVALID_HANDLE_VALUE;
}
bool FileOutput::open(std::string& path) {
}
#endif
/**
* An async operation to be performed.
* For reading files from disk into memory.
*/
struct AsyncRead {
enum class Flags : uint32_t {
FAILED = 0, // The read failed due to some error.
CANCELLED // The read was cancelled due to the resource not being needed any more.
};
AsyncRead() : data() {}
bool isFailed() const { return flags == Flags::FAILED; }
bool isCancelled() const { return flags == Flags::CANCELLED; }
FileSystem::ContentCallback callback;
OutputMemoryStream data;
std::string path;
uint32_t id = 0;
Flags flags;
};
// The FileSystem that operates on raw on-disk files.
struct DiskFS;
struct DiskFS : FileSystem {
explicit DiskFS(std::string& path) : sem(0, 0xffff) {
setBasePath(path);
}
bool hasWork() override {
return workCounter != 0;
}
std::string const& getBasePath() const override { return basePath; }
void setBasePath(std::string& path) final {
basePath = Path::normalise(path);
if (!basePath.ends_with('/') && !basePath.ends_with('\\'))
basePath.append("/");
}
bool saveSync(const Path& path, const uint8_t* data, const size_t size) override {
FileOutput file;
std::string fullPath(basePath.append(path.c_str()));
if (!file.open(fullPath)) return false;
bool res = file.write(data, size);
file.close();
return res;
}
bool readSync(const Path& path, struct OutputMemoryStream& content) override {
FileInput file;
std::string fullPath(basePath.append(path.c_str()));
if (!file.open(fullPath)) return false;
content.resize(file.size());
if (!file.read(content.dataMut(), content.size())) {
file.close();
return false;
}
file.close();
return true;
}
AsyncHandle readAsync(const Path& file, const ContentCallback& callback) override {
if (!file.isEmpty()) return AsyncHandle::invalid();
MutexGuard lock(mutex);
workCounter++;
AsyncRead& read = queue.emplace_back();
if (++lastID == 0) lastID++;
read.id = lastID;
read.path = file.c_str();
read.callback = callback;
sem.raise();
return AsyncHandle(read.id);
}
void cancelAsync(AsyncHandle& handle) override {
MutexGuard lock(mutex);
for (AsyncRead& read : queue) {
if (read.id == handle.value) {
read.flags = AsyncRead::Flags::CANCELLED;
workCounter--;
return;
}
}
for (AsyncRead& read : finished) {
if (read.id == handle.value) {
read.flags = AsyncRead::Flags::CANCELLED;
return;
}
}
}
bool open(std::string& path, FileInput& file) override {
return file.open(basePath.append(path));
}
bool open(std::string& path, FileOutput& file) override {
return file.open(basePath.append(path));
}
bool deleteFile(std::string& path) override {
return std::remove((basePath.append(path).c_str()));
}
bool moveFile(std::string& from, std::string& to) override {
try {
std::rename(basePath.append(from).c_str(), basePath.append(to).c_str());
} catch (std::filesystem::filesystem_error& e) {
return false;
}
return true;
}
bool copyFile(std::string& from, std::string& to) override {
try {
std::filesystem::copy(basePath.append(from).c_str(), basePath.append(to).c_str());
} catch (std::filesystem::filesystem_error& e) {
return false;
}
return true;
}
bool fileExists(std::string& path) override {
return std::filesystem::exists(path);
}
size_t getLastModified(std::string& path) override {
return std::filesystem::last_write_time(path).time_since_epoch().count();
}
// TODO: File iterators
void processCallbacks() override {
// TODO: Timeout this function!
for (;;) {
mutex.enter();
if (finished.empty() || workCounter == 0) {
mutex.exit();
break;
}
AsyncRead item = finished[0];
finished.erase(finished.begin());
--workCounter;
mutex.exit();
if (!item.isCancelled())
item.callback.invoke(item.data.size(), (const uint8_t*) item.data.data(), !item.isFailed());
}
}
// TODO: Task Management
std::string basePath;
std::vector<AsyncRead> queue;
uint64_t workCounter;
std::vector<AsyncRead> finished;
Mutex mutex;
Semaphore sem;
uint32_t lastID;
};
struct VFS : DiskFS {
VFS(std::string& root_pack_path) : DiskFS((std::string &) "vfs:/") {
if (!pack.open(root_pack_path)) {
spdlog::error("Unable to open " + root_pack_path + ", please check paths");
return;
}
const auto count = pack.read<size_t>();
for (size_t i = 0; i < count; i++) {
const auto hash = pack.read<PathHash>();
PackFile& file = packFiles[hash];
file.offset = pack.read<size_t>();
file.size = pack.read<size_t>();
}
}
~VFS() { pack.close(); }
bool readSync(const Path& path, OutputMemoryStream& content) override {
std::string basename = Path::getFilename(const_cast<std::string &>(path.get()));
PathHash hash = path.getHash();
auto i = packFiles.find(hash);
if (i == packFiles.end()) return false;
content.resize(i->second.size);
MutexGuard lock(mutex);
const size_t headerSize = sizeof(uint32_t) + packFiles.size() * (3 * sizeof(size_t));
if (pack.seek(i->second.offset + headerSize) || !pack.read(content.dataMut(), content.size())) {
spdlog::error("Could not read file " + path.get() + " from the pack file.");
return false;
}
return true;
}
struct PackFile {
size_t offset;
size_t size;
};
std::map<PathHash, PackFile> packFiles;
FileInput pack;
};
std::unique_ptr<FileSystem> FileSystem::createDiskFS(std::string &basePath) {
return std::make_unique<DiskFS>(basePath);
}
std::unique_ptr<FileSystem> FileSystem::createVFS(std::string& basePath) {
return std::make_unique<VFS>(basePath);
}
}

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@ -1,115 +0,0 @@
#pragma once
#include <fs/iostream.h>
#include <fs/path.h>
#include <management/delegate.h>
#include <memory>
template <class T> struct Delegate;
namespace ShadowEngine {
// An input stream that can read a file on disk.
struct FileInput final : InputStream {
FileInput();
~FileInput() = default;
[[nodiscard]] bool open(std::string& path);
void close();
using InputStream::read;
[[nodiscard]] bool read(void* data, size_t size) override;
const void* getBuffer() const override { return nullptr; }
size_t size() const override;
size_t pos();
[[nodiscard]] bool seek(size_t pos);
private:
void* handle;
};
// An output stream that can write to a file on disk.
struct FileOutput final : OutputStream {
FileOutput();
~FileOutput() = default;
[[nodiscard]] bool open(std::string& path);
void close();
void flush();
bool errored() const { return error; }
using OutputStream::write;
[[nodiscard]] bool write(const void* data, size_t size) override;
private:
FileOutput(const FileOutput&) = delete;
void* handle;
bool error;
};
struct FileInfo {
bool directory;
std::string filename;
};
/**
* A generic Filesystem API.
* Allows interacting with files on disk the same as files in our Virtual Package Format.
*/
struct FileSystem {
// A function called when the data of a file is updated, such as when an asynchronous operation completes.
using ContentCallback = Delegate<void(size_t, const uint8_t*, bool)>;
// A handle for asynchronous data movement; such as reading or writing a file.
struct AsyncHandle {
static AsyncHandle invalid() { return AsyncHandle(0xffffffff); }
explicit AsyncHandle(uint32_t val) : value(val) {}
[[nodiscard]] bool valid() const { return value != 0xffffffff; }
uint32_t value;
};
// Create a Filesystem that interacts with files on disk.
static std::unique_ptr<FileSystem> createDiskFS(std::string& basePath);
// Create a Virtual Filesystem based on the given path.
static std::unique_ptr<FileSystem> createVFS(std::string& basePath);
virtual ~FileSystem() = default;
// Open a file for reading.
virtual bool open(std::string& path, FileInput& input) = 0;
// Open a file for writing.
virtual bool open(std::string& path, FileOutput& output) = 0;
// Check whether a file exists at the given path.
virtual bool fileExists(std::string& path) = 0;
// Get the time a file at the given path was last modified.
virtual size_t getLastModified(std::string& path) = 0;
// Copy a file from one path to another.
virtual bool copyFile(std::string& from, std::string& to) = 0;
// Move a file from one path to another.
virtual bool moveFile(std::string& from, std::string& to) = 0;
// Disassociate any files at the given path (not an immediate delete)
virtual bool deleteFile(std::string& path) = 0;
// Get the path that this FileSystem originates at. The default is "/" for VFS, and whatever the Executable Path is for Disk FS.
virtual std::string const& getBasePath() const = 0;
// Set a new base path for the FileSystem. Any operations involving file paths will be relative to this new path.
virtual void setBasePath(std::string& path) = 0;
// Process all the callbacks for async file operations.
virtual void processCallbacks() = 0;
// Check whether there are any outstanding async operations that need work.
virtual bool hasWork() = 0;
// Write new content to a file synchronously. The thread will be blocked when doing this.
virtual bool saveSync(const Path& file, const uint8_t* content, size_t size) = 0;
// Read content from a file synchronously. The thread will be blocked when doing this.
virtual bool readSync(const Path& file, struct OutputMemoryStream& content) = 0;
// Read a file asynchronously. The given callback will be called with the file content once it is available.
virtual AsyncHandle readAsync(const Path& file, const ContentCallback& callback) = 0;
// Cancel an asynchronous operation, if it is not already complete. The associated callback will be called with a special flag.
virtual void cancelAsync(AsyncHandle& handle) = 0;
};
}

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@ -1,148 +0,0 @@
#include <fs/hash.h>
#include "xxhash.h"
namespace ShadowEngine {
StableHash::StableHash(const void *data, uint32_t length) {
hash = XXHash64::hash(data, length, 0);
}
StableHash::StableHash(std::string &str) {
hash = XXHash64::hash(str.data(), str.size(), 0);
}
HeapHash::HeapHash(const void *data, uint32_t length) {
hash = XXHash64::hash(data, length, 0);
}
HeapHash::HeapHash(std::string &str) {
hash = XXHash64::hash(str.data(), str.size(), 0);
}
HeapHash HeapHash::fromLong(size_t hash) {
HeapHash heap;
heap.hash = hash;
return heap;
}
HeapHash32 HeapHash32::fromInt(uint32_t hash) {
HeapHash32 heap;
heap.hash = hash;
return heap;
}
StableHash StableHash::fromLong(size_t hash) {
StableHash stable;
stable.hash = hash;
return stable;
}
StableHash32 StableHash32::fromInt(uint32_t hash) {
StableHash32 stable;
stable.hash = hash;
return stable;
}
static uint32_t CRC[256] = {
0x00000000, 0x77073096, 0xee0e612c, 0x990951ba, 0x076dc419, 0x706af48f,
0xe963a535, 0x9e6495a3, 0x0edb8832, 0x79dcb8a4, 0xe0d5e91e, 0x97d2d988,
0x09b64c2b, 0x7eb17cbd, 0xe7b82d07, 0x90bf1d91, 0x1db71064, 0x6ab020f2,
0xf3b97148, 0x84be41de, 0x1adad47d, 0x6ddde4eb, 0xf4d4b551, 0x83d385c7,
0x136c9856, 0x646ba8c0, 0xfd62f97a, 0x8a65c9ec, 0x14015c4f, 0x63066cd9,
0xfa0f3d63, 0x8d080df5, 0x3b6e20c8, 0x4c69105e, 0xd56041e4, 0xa2677172,
0x3c03e4d1, 0x4b04d447, 0xd20d85fd, 0xa50ab56b, 0x35b5a8fa, 0x42b2986c,
0xdbbbc9d6, 0xacbcf940, 0x32d86ce3, 0x45df5c75, 0xdcd60dcf, 0xabd13d59,
0x26d930ac, 0x51de003a, 0xc8d75180, 0xbfd06116, 0x21b4f4b5, 0x56b3c423,
0xcfba9599, 0xb8bda50f, 0x2802b89e, 0x5f058808, 0xc60cd9b2, 0xb10be924,
0x2f6f7c87, 0x58684c11, 0xc1611dab, 0xb6662d3d, 0x76dc4190, 0x01db7106,
0x98d220bc, 0xefd5102a, 0x71b18589, 0x06b6b51f, 0x9fbfe4a5, 0xe8b8d433,
0x7807c9a2, 0x0f00f934, 0x9609a88e, 0xe10e9818, 0x7f6a0dbb, 0x086d3d2d,
0x91646c97, 0xe6635c01, 0x6b6b51f4, 0x1c6c6162, 0x856530d8, 0xf262004e,
0x6c0695ed, 0x1b01a57b, 0x8208f4c1, 0xf50fc457, 0x65b0d9c6, 0x12b7e950,
0x8bbeb8ea, 0xfcb9887c, 0x62dd1ddf, 0x15da2d49, 0x8cd37cf3, 0xfbd44c65,
0x4db26158, 0x3ab551ce, 0xa3bc0074, 0xd4bb30e2, 0x4adfa541, 0x3dd895d7,
0xa4d1c46d, 0xd3d6f4fb, 0x4369e96a, 0x346ed9fc, 0xad678846, 0xda60b8d0,
0x44042d73, 0x33031de5, 0xaa0a4c5f, 0xdd0d7cc9, 0x5005713c, 0x270241aa,
0xbe0b1010, 0xc90c2086, 0x5768b525, 0x206f85b3, 0xb966d409, 0xce61e49f,
0x5edef90e, 0x29d9c998, 0xb0d09822, 0xc7d7a8b4, 0x59b33d17, 0x2eb40d81,
0xb7bd5c3b, 0xc0ba6cad, 0xedb88320, 0x9abfb3b6, 0x03b6e20c, 0x74b1d29a,
0xead54739, 0x9dd277af, 0x04db2615, 0x73dc1683, 0xe3630b12, 0x94643b84,
0x0d6d6a3e, 0x7a6a5aa8, 0xe40ecf0b, 0x9309ff9d, 0x0a00ae27, 0x7d079eb1,
0xf00f9344, 0x8708a3d2, 0x1e01f268, 0x6906c2fe, 0xf762575d, 0x806567cb,
0x196c3671, 0x6e6b06e7, 0xfed41b76, 0x89d32be0, 0x10da7a5a, 0x67dd4acc,
0xf9b9df6f, 0x8ebeeff9, 0x17b7be43, 0x60b08ed5, 0xd6d6a3e8, 0xa1d1937e,
0x38d8c2c4, 0x4fdff252, 0xd1bb67f1, 0xa6bc5767, 0x3fb506dd, 0x48b2364b,
0xd80d2bda, 0xaf0a1b4c, 0x36034af6, 0x41047a60, 0xdf60efc3, 0xa867df55,
0x316e8eef, 0x4669be79, 0xcb61b38c, 0xbc66831a, 0x256fd2a0, 0x5268e236,
0xcc0c7795, 0xbb0b4703, 0x220216b9, 0x5505262f, 0xc5ba3bbe, 0xb2bd0b28,
0x2bb45a92, 0x5cb36a04, 0xc2d7ffa7, 0xb5d0cf31, 0x2cd99e8b, 0x5bdeae1d,
0x9b64c2b0, 0xec63f226, 0x756aa39c, 0x026d930a, 0x9c0906a9, 0xeb0e363f,
0x72076785, 0x05005713, 0x95bf4a82, 0xe2b87a14, 0x7bb12bae, 0x0cb61b38,
0x92d28e9b, 0xe5d5be0d, 0x7cdcefb7, 0x0bdbdf21, 0x86d3d2d4, 0xf1d4e242,
0x68ddb3f8, 0x1fda836e, 0x81be16cd, 0xf6b9265b, 0x6fb077e1, 0x18b74777,
0x88085ae6, 0xff0f6a70, 0x66063bca, 0x11010b5c, 0x8f659eff, 0xf862ae69,
0x616bffd3, 0x166ccf45, 0xa00ae278, 0xd70dd2ee, 0x4e048354, 0x3903b3c2,
0xa7672661, 0xd06016f7, 0x4969474d, 0x3e6e77db, 0xaed16a4a, 0xd9d65adc,
0x40df0b66, 0x37d83bf0, 0xa9bcae53, 0xdebb9ec5, 0x47b2cf7f, 0x30b5ffe9,
0xbdbdf21c, 0xcabac28a, 0x53b39330, 0x24b4a3a6, 0xbad03605, 0xcdd70693,
0x54de5729, 0x23d967bf, 0xb3667a2e, 0xc4614ab8, 0x5d681b02, 0x2a6f2b94,
0xb40bbe37, 0xc30c8ea1, 0x5a05df1b, 0x2d02ef8d};
static uint32_t CRC32(const void* data, uint32_t length) {
const auto* c = static_cast<const uint8_t*>(data);
uint32_t crcTemp = 0xFFFFFFFF;
uint32_t len = length;
while (len) {
crcTemp = (crcTemp >> 8) ^ CRC[(crcTemp & 0xFF) ^ *c];
--len; ++c;
}
return ~crcTemp;
}
StableHash32::StableHash32(const void *data, uint32_t length) {
hash = CRC32(data, length);
}
StableHash32::StableHash32(std::string &str) {
hash = CRC32(str.data(), str.size());
}
static XXHash64 DeferredHashState(0);
DeferredHash::DeferredHash() {
DeferredHashState = XXHash64(0);
}
void DeferredHash::insert(const void *data, uint32_t length) {
DeferredHashState.add(data, length);
}
StableHash32 DeferredHash::submit32() {
const auto result = DeferredHashState.hash();
return StableHash32::fromInt(uint32_t(result ^ (result >> 32)));
}
StableHash DeferredHash::submit() {
const auto result = DeferredHashState.hash();
return StableHash::fromLong(result);
}
DeferredHeapHash::DeferredHeapHash() {
DeferredHashState = XXHash64(0);
}
void DeferredHeapHash::insert(const void *data, uint32_t length) {
DeferredHashState.add(data, length);
}
HeapHash32 DeferredHeapHash::submit32() {
const auto result = DeferredHashState.hash();
return HeapHash32::fromInt(uint32_t(result ^ (result >> 32)));
}
HeapHash DeferredHeapHash::submit() {
const auto result = DeferredHashState.hash();
return HeapHash::fromLong(result);
}
}

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#pragma once
#include <string>
namespace ShadowEngine {
/**
* A 64-bit hashing algorithm that uses the state of the allocation heap as a "salt".
* Outputs are NOT stable, so do not serialize this.
* However, because it uses the heap, it has a very low collision rate.
*/
struct HeapHash {
// For if you MUST recreate a hash exactly.
// Please only use this for testing.
static HeapHash fromLong(size_t hash);
HeapHash() = default;
// Hash a string; for paths and such.
explicit HeapHash(std::string& str);
// Hash arbitrary data.
HeapHash(const void* data, uint32_t length);
bool operator!= (const HeapHash& other) const { return hash != other.hash; }
bool operator== (const HeapHash& other) const { return hash == other.hash; }
size_t getHash() const { return hash; }
private:
size_t hash = 0;
};
/**
* A 32-bit hashing algorithm that uses the state of the allocation heap as a "salt".
* Outputs are NOT stable, so do not serialize this.
* However, because it uses the heap, it has a very low collision rate.
*/
struct HeapHash32 {
// For if you MUST recreate a hash exactly.
// Please only use this for testing.
static HeapHash32 fromInt(uint32_t hash);
HeapHash32() = default;
// Hash a string; for paths and such.
explicit HeapHash32(std::string& str);
// Hash arbitrary data.
HeapHash32(const void* data, uint32_t length);
bool operator!= (HeapHash32& other) const { return hash != other.hash; }
bool operator== (HeapHash32& other) const { return hash == other.hash; }
uint32_t getHash() const { return hash; }
private:
uint32_t hash = 0;
};
/**
* A 64-bit hashing algorithm that generates the same hash value per input every time.
* A little more likely to generate conflicts than the hash that uses the state of the heap as a salt.
* Suitable for serialization.
*/
struct StableHash {
static StableHash fromLong(size_t data);
StableHash() = default;
explicit StableHash(std::string& str);
StableHash(const void* data, uint32_t length);
bool operator!= (const StableHash& other) const { return hash != other.hash; }
bool operator== (const StableHash& other) const { return hash == other.hash; }
bool operator< (const StableHash& other) const { return hash < other.hash; }
[[nodiscard]] size_t getHash() const { return hash; }
private:
size_t hash = 0;
};
/**
* A 32-bit hashing algorithm that generates the same hash value per input every time.
* A little more likely to generate conflicts than the hash that uses the state of the heap as a salt.
* Suitable for serialization.
*/
struct StableHash32 {
static StableHash32 fromInt(uint32_t data);
StableHash32() = default;
StableHash32(std::string& str);
StableHash32(const void* data, uint32_t length);
bool operator!= (StableHash32& other) const { return hash != other.hash; }
bool operator== (StableHash32& other) const { return hash == other.hash; }
bool operator< (StableHash32& other) const { return hash < other.hash; }
uint32_t getHash() const { return hash; }
private:
uint32_t hash = 0;
};
// File Paths are hashed using the 64-bit StableHash system.
using PathHash = StableHash;
/**
* A hashing utility that lets you insert data piecemeal before committing to the hash.
* Useful for when you're parsing a file and need to wait for more data to be available before hashing.
* Generates a Stable Hash.
*/
struct DeferredHash {
DeferredHash();
// Insert new data to be considered for hashing
void insert(const void* data, uint32_t length);
// Submit the data to the hashing algorithm, and return a value in 64-bit StableHash
StableHash submit();
// Submit the data to the hashing algorithm, and return a value in 32-bit StableHash
StableHash32 submit32();
};
/**
* A hashing utility that lets you insert data piecemeal before committing to the hash.
* Useful for when you're parsing a file and need to wait for more data to be available before hashing.
* Generates a Heap Hash.
*/
struct DeferredHeapHash {
DeferredHeapHash();
// Insert new data to be considered for hashing
void insert(const void* data, uint32_t length);
// Submit the data to the hashing algorithm, and return a value in 64-bit HeapHash
HeapHash submit();
// Submit the data to the hashing algorithm, and return a value in 32-bit HeapHash
HeapHash32 submit32();
};
/** The implementations of these hashing algorithms */
template <class Hash> struct HashFunc;
template<> struct HashFunc<HeapHash> {
static uint32_t get(const HeapHash& h) {
const size_t hash = h.getHash();
return uint32_t(hash & (hash >> 16));
}
};
template<> struct HashFunc<StableHash> {
static uint32_t get(const StableHash& h) {
const size_t hash = h.getHash();
return uint32_t(hash & (hash >> 16));
}
};
template<> struct HashFunc<HeapHash32> {
static uint32_t get(const HeapHash32& h) {
return h.getHash();
}
};
template<> struct HashFunc<StableHash32> {
static uint32_t get(const StableHash& h) {
return h.getHash();
}
};
}

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#include <fs/iostream.h>
#include <cstring>
namespace ShadowEngine {
OutputMemoryStream::OutputMemoryStream(void *data, size_t size)
: buffer(static_cast<uint8_t *>(data)), capacity(size), usage(0) {}
OutputMemoryStream::OutputMemoryStream(ShadowEngine::OutputMemoryStream &&str) noexcept {
capacity = str.capacity;
buffer = str.buffer;
usage = str.usage;
str.free();
}
OutputMemoryStream& OutputMemoryStream::operator=(ShadowEngine::OutputMemoryStream &&str) noexcept {
capacity = str.capacity;
buffer = str.buffer;
usage = str.usage;
str.free();
return *this;
}
OutputMemoryStream& OutputMemoryStream::operator=(const ShadowEngine::OutputMemoryStream &rhs) noexcept {
usage = rhs.usage;
if (rhs.capacity > 0) {
buffer = (uint8_t*)malloc(rhs.capacity);
memcpy(buffer, rhs.buffer, rhs.capacity);
capacity = rhs.capacity;
} else {
buffer = nullptr;
capacity = 0;
}
return *this;
}
OutputMemoryStream::OutputMemoryStream(const ShadowEngine::OutputMemoryStream &rhs) noexcept {
usage = rhs.usage;
if (rhs.capacity > 0) {
buffer = (uint8_t*)malloc(rhs.capacity);
memcpy(buffer, rhs.buffer, rhs.capacity);
capacity = rhs.capacity;
} else {
buffer = nullptr;
capacity = 0;
}
}
OutputMemoryStream::~OutputMemoryStream() = default;
OutputStream &OutputStream::operator<<(std::string &str) {
write(str.data(), str.length());
return *this;
}
OutputStream &OutputStream::operator<<(const char* str) {
write(str, strlen(str));
return *this;
}
OutputStream &OutputStream::operator<<(uint32_t val) {
std::string str = std::to_string(val);
write(str.c_str(), str.length());
return *this;
}
OutputStream &OutputStream::operator<<(int32_t val) {
std::string str = std::to_string(val);
write(str.c_str(), str.length());
return *this;
}
OutputStream &OutputStream::operator<<(uint64_t val) {
std::string str = std::to_string(val);
write(str.c_str(), str.length());
return *this;
}
OutputStream &OutputStream::operator<<(int64_t val) {
std::string str = std::to_string(val);
write(str.c_str(), str.length());
return *this;
}
OutputStream &OutputStream::operator<<(float val) {
std::string str = std::to_string(val);
write(str.c_str(), str.length());
return *this;
}
OutputStream &OutputStream::operator<<(double val) {
std::string str = std::to_string(val);
write(str.c_str(), str.length());
return *this;
}
void OutputMemoryStream::write(std::string &str) {
write(str.c_str(), str.length());
}
void *OutputMemoryStream::skip(size_t size) {
if (size + usage > capacity) {
reserve((size + usage) << 1);
}
void* ret = (uint8_t*)buffer + usage;
usage += size;
return ret;
}
OutputMemoryStream& OutputMemoryStream::operator+=(size_t size) {
skip(size);
return *this;
}
OutputMemoryStream& OutputMemoryStream::operator++() {
skip(1);
return *this;
}
uint8_t OutputMemoryStream::operator[](size_t index) const {
return buffer[index];
}
uint8_t &OutputMemoryStream::operator[](size_t index) {
return buffer[index];
}
bool OutputMemoryStream::write(const void *data, size_t size) {
if (!size) return true;
if (usage + size > capacity) {
reserve((usage + size) << 1);
}
memcpy((uint8_t*)data + usage, data, size);
usage += size;
return true;
}
void OutputMemoryStream::clear() { usage = 0; }
void OutputMemoryStream::free() {
usage = 0;
capacity = 0;
delete[] buffer;
buffer = nullptr;
}
void OutputMemoryStream::reserve(size_t size) {
if (size < capacity) return;
auto* temp = static_cast<uint8_t *>(malloc(size));
memcpy(temp, buffer, capacity);
delete[] buffer;
buffer = temp;
capacity = size;
}
uint8_t *OutputMemoryStream::release() {
auto* temp = static_cast<uint8_t *>(malloc(usage));
memcpy(temp, buffer, usage);
free();
return temp;
}
InputMemoryStream::InputMemoryStream(const void *data, size_t size)
: data(static_cast<const uint8_t *>(data)), capacity(size), position(0) {}
InputMemoryStream::InputMemoryStream(const ShadowEngine::OutputMemoryStream &blob)
: data(blob.data()), capacity(blob.size()), position(0) {}
void InputMemoryStream::set(const void *newData, size_t size) {
data = (uint8_t*) newData; capacity = size; position = 0;
}
const void *InputMemoryStream::skip(size_t size) {
auto* pos = data + position;
position += size;
if (position > capacity) {
position = capacity;
}
return (const void*) pos;
}
bool InputMemoryStream::read(void *out, size_t size) {
if (position + (uint32_t) size > capacity) {
for (int32_t i = 0; i < size; i++)
((unsigned char*)out)[i] = 0;
return false;
}
if (size) {
memcpy(out, ((char*)data) + position, capacity);
}
position += size;
return true;
}
std::string InputMemoryStream::readString() {
const char* ret = (const char*) data + position;
while (position < capacity && data[position]) ++position;
++position;
return { ret };
}
}

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#pragma once
#include <string>
namespace ShadowEngine {
// A custom OutputStream that can be implemented to output to any arbitrary data structure.
// The idea is that it can write to a file, or into memory, or into a temporary buffer that is copied to both.
// As opposed to the hardcoded streams that exist in C++, which have a single purpose for their entire lifetime.
struct OutputStream {
virtual bool write(const void* data, size_t size) = 0;
OutputStream& operator<< (std::string& str);
OutputStream& operator<< (const char* str);
OutputStream& operator<< (size_t val);
OutputStream& operator<< (int64_t val);
OutputStream& operator<< (uint32_t val);
OutputStream& operator<< (int32_t val);
OutputStream& operator<< (float val);
OutputStream& operator<< (double val);
template <class T> bool write(const T& val);
};
// A custom InputStream that can be implemented to read from any arbitrary data structure.
// The idea is that it can read from a file, or from memory, or from a temporary buffer that is merged from both.
// As opposed to the hardcoded streams that exist in C++, which have a single purpose for their entire lifetime.
struct InputStream {
virtual bool read(void* buffer, size_t size) = 0;
virtual const void* getBuffer() const = 0;
virtual size_t size() const = 0;
template <class T> void read(T& val) { read(&val, sizeof(T)); }
template <class T> T read();
};
// A custom OutputStream that writes to memory.
struct OutputMemoryStream final : OutputStream {
OutputMemoryStream();
OutputMemoryStream(void* data, size_t size);
OutputMemoryStream(OutputMemoryStream&& str) noexcept;
OutputMemoryStream(const OutputMemoryStream& rhs) noexcept;
~OutputMemoryStream();
OutputMemoryStream& operator= (const OutputMemoryStream& rhs) noexcept;
OutputMemoryStream& operator= (OutputMemoryStream&& rhs) noexcept;
uint8_t operator[] (size_t index) const;
uint8_t& operator[] (size_t index);
OutputMemoryStream& operator+= (size_t index);
OutputMemoryStream& operator++ ();
bool write(const void* data, size_t size) override;
uint8_t* release();
void resize(size_t size);
void reserve(size_t size);
const uint8_t* data() const { return buffer; };
uint8_t* dataMut() { return buffer; };
size_t size() const { return usage; };
void clear();
void* skip(size_t size);
bool empty() const { return usage == 0; };
void free();
void write(std::string& str);
template <class T> void write(const T& val);
private:
uint8_t* buffer;
size_t capacity;
size_t usage;
};
template <class T> void OutputMemoryStream::write(const T& val){
write(&val, sizeof(T));
}
template <> inline void OutputMemoryStream::write<bool>(const bool& val) {
uint8_t v = val;
write(&v, sizeof(v));
}
// A custom InputStream that writes from memory.
struct InputMemoryStream final : InputStream {
InputMemoryStream(const void* data, size_t size);
explicit InputMemoryStream(const OutputMemoryStream& blob);
void set(const void* data, size_t size);
bool read(void* data, size_t size) override;
std::string readString();
const void* skip(size_t size);
const void* getData() const { return data; };
const void* getBuffer() const override { return data; };
size_t size() const override { return capacity; };
size_t pos() const { return position; };
void setPos(size_t pos) { position = pos; };
void restart() { position = 0; };
uint8_t readChar() { position++; return data[position-1]; };
template<class T>
T getAs() const {
static_assert(position + sizeof(T) < capacity);
return *(T*)(data + position);
}
using InputStream::read;
private:
const uint8_t* data;
size_t capacity;
size_t position;
};
template <class T>
T InputStream::read() {
T v;
read(&v, sizeof(T));
return v;
}
template<> inline bool InputStream::read<bool>() {
uint8_t v;
read(&v, sizeof(bool));
return v;
}
template <class T>
bool OutputStream::write(const T &val) {
return write(&val, sizeof(T));
}
}

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#include <fs/path.h>
#include <string.h>
#include <str/string.h>
namespace ShadowEngine {
Path::Path() : path {} { }
Path::Path(const std::string &str) {
set(normalise((std::string&) str));
}
void Path::set(const std::string &str) {
#ifdef _WIN32
std::string temp = Str::toLower((std::string&) str);
hash = PathHash(temp);
#else
hash = PathHash(str);
#endif
path = str;
}
Path& Path::operator=(const std::string &rhs) {
set(rhs);
return *this;
}
bool Path::operator==(const std::string &rhs) {
return path == rhs;
}
bool Path::operator==(const ShadowEngine::Path &rhs) {
return path == rhs.path;
}
bool Path::operator!=(const ShadowEngine::Path &rhs) {
return path != rhs.path;
}
std::string Path::normalise(std::string &str) {
bool prevSlash = false;
std::string temp;
const char* path = str.c_str();
size_t len = str.length();
size_t i = 0;
// Skip initial stuff.
size_t ind = str.find_first_of(":");
path += ind;
if (path[0] == '.' && (path[1] == '\\' || path[1] == '/'))
path += 2;
#ifdef _WIN32
if (path[0] == '\\' || path[0] == '/')
++path;
#endif
while (*path != '\0' && i < len) {
bool slash = *path == '\\' || *path == '/';
// Skip double slashes.
if (slash && prevSlash) {
path++; continue;
}
// Convert backslashes to forward slashes.
temp.append(std::to_string(*path == '\\' ? '/' : *path));
path++; i++; prevSlash = slash;
}
return temp;
}
std::string Path::getPrelude(std::string &path) {
return path.substr(0, path.find_first_of(":"));
}
std::string Path::getDomain(std::string &path) {
return path.substr(path.find_first_of(":"), path.find_first_of("/"));
}
std::string Path::getDirectory(std::string &path) {
return path.substr(path.find_first_of(":"), path.find_last_of("/"));
}
std::string Path::getFilename(std::string &path) {
return path.substr(path.find_last_of("/"), path.find_last_of("."));
}
std::string Path::getExtension(std::string &path) {
return path.substr(path.find_last_of("."), path.length());
}
std::string Path::replaceExtension(std::string &path, std::string &newExt) {
return path.substr(0, path.length() - newExt.length()).append(newExt);
}
bool Path::hasExtension(std::string &path, std::string &ext) {
return path.find_last_of(ext) == path.length() - ext.length();
}
PathInfo::PathInfo(std::string &str) {
std::string normalised = Path::normalise(str);
std::string preludeS = Path::getPrelude(normalised);
memcpy_s(prelude, 10, preludeS.c_str(), preludeS.length());
std::string domainS = Path::getDomain(normalised);
memcpy_s(domain, 256, domainS.c_str(), domainS.length());
std::string directoryS = Path::getDirectory(normalised);
memcpy_s(directory, 256, directoryS.c_str(), directoryS.length());
std::string filenameS = Path::getFilename(normalised);
memcpy_s(baseName, 256, filenameS.c_str(), filenameS.length());
std::string extensionS = Path::getExtension(normalised);
memcpy_s(extension, 10, extensionS.c_str(), extensionS.length());
}
}

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#pragma once
#include <string>
#include <fs/hash.h>
namespace ShadowEngine {
/**
* Stores split data about a path, for easy referencing and decomposition.
* Not to be used as a replacement for the Path class.
*/
struct PathInfo {
explicit PathInfo(std::string& str);
char extension[10];
char baseName[256];
char directory[256];
char domain[256];
char prelude[10];
};
/**
* Stores and handles paths in the VFS.
* All operations are copy-instantiated, nothing works in-place.
* A typical path is of the form:
* prelude:/domain/directory/filename.extension
*/
struct Path {
// Make sure the path is valid.
// Always from the root.
// One slash separating.
static std::string normalise(std::string& path);
// Get the prelude of the given path.
static std::string getPrelude(std::string& path);
// Get the domain of the given path.
static std::string getDomain(std::string& path);
// Get the directory of the given path.
static std::string getDirectory(std::string& path);
// Get the name of the file of the given path.
static std::string getFilename(std::string& path);
// Get the file extension of the given path.
static std::string getExtension(std::string& path);
// Check if the path has the given extension.
static bool hasExtension(std::string& path, std::string& ext);
// Replace the extension of the given path.
static std::string replaceExtension(std::string& path, std::string& newExt);
Path();
explicit Path(const std::string& str);
Path& operator=(const std::string& rhs);
bool operator==(const std::string& rhs);
bool operator==(const Path& rhs);
bool operator!=(const Path& rhs);
// Use this to set a new value into the path; it handles the hash too.
void set(const std::string& path);
[[nodiscard]] uint32_t length() const { return path.length(); };
[[nodiscard]] PathHash getHash() const { return hash; }
[[nodiscard]] const char* c_str() const { return path.data(); }
[[nodiscard]] std::string const& get() const { return path; }
[[nodiscard]] bool isEmpty() const { return path.length() == 0; }
private:
std::string path;
PathHash hash;
};
}

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#pragma once
#include <stdint.h> // for uint32_t and uint64_t
class XXHash64
{
public:
/// create new XXHash (64 bit)
/** @param seed your seed value, even zero is a valid seed **/
explicit XXHash64(uint64_t seed)
{
state[0] = seed + Prime1 + Prime2;
state[1] = seed + Prime2;
state[2] = seed;
state[3] = seed - Prime1;
bufferSize = 0;
totalLength = 0;
}
/// add a chunk of bytes
/** @param input pointer to a continuous block of data
@param length number of bytes
@return false if parameters are invalid / zero **/
bool add(const void* input, uint64_t length)
{
// no data ?
if (!input || length == 0)
return false;
totalLength += length;
// byte-wise access
const unsigned char* data = (const unsigned char*)input;
// unprocessed old data plus new data still fit in temporary buffer ?
if (bufferSize + length < MaxBufferSize)
{
// just add new data
while (length-- > 0)
buffer[bufferSize++] = *data++;
return true;
}
// point beyond last byte
const unsigned char* stop = data + length;
const unsigned char* stopBlock = stop - MaxBufferSize;
// some data left from previous update ?
if (bufferSize > 0)
{
// make sure temporary buffer is full (16 bytes)
while (bufferSize < MaxBufferSize)
buffer[bufferSize++] = *data++;
// process these 32 bytes (4x8)
process(buffer, state[0], state[1], state[2], state[3]);
}
// copying state to local variables helps optimizer A LOT
uint64_t s0 = state[0], s1 = state[1], s2 = state[2], s3 = state[3];
// 32 bytes at once
while (data <= stopBlock)
{
// local variables s0..s3 instead of state[0]..state[3] are much faster
process(data, s0, s1, s2, s3);
data += 32;
}
// copy back
state[0] = s0; state[1] = s1; state[2] = s2; state[3] = s3;
// copy remainder to temporary buffer
bufferSize = stop - data;
for (uint64_t i = 0; i < bufferSize; i++)
buffer[i] = data[i];
// done
return true;
}
/// get current hash
/** @return 64 bit XXHash **/
uint64_t hash() const
{
// fold 256 bit state into one single 64 bit value
uint64_t result;
if (totalLength >= MaxBufferSize)
{
result = rotateLeft(state[0], 1) +
rotateLeft(state[1], 7) +
rotateLeft(state[2], 12) +
rotateLeft(state[3], 18);
result = (result ^ processSingle(0, state[0])) * Prime1 + Prime4;
result = (result ^ processSingle(0, state[1])) * Prime1 + Prime4;
result = (result ^ processSingle(0, state[2])) * Prime1 + Prime4;
result = (result ^ processSingle(0, state[3])) * Prime1 + Prime4;
}
else
{
// internal state wasn't set in add(), therefore original seed is still stored in state2
result = state[2] + Prime5;
}
result += totalLength;
// process remaining bytes in temporary buffer
const unsigned char* data = buffer;
// point beyond last byte
const unsigned char* stop = data + bufferSize;
// at least 8 bytes left ? => eat 8 bytes per step
for (; data + 8 <= stop; data += 8)
result = rotateLeft(result ^ processSingle(0, *(uint64_t*)data), 27) * Prime1 + Prime4;
// 4 bytes left ? => eat those
if (data + 4 <= stop)
{
result = rotateLeft(result ^ (*(uint32_t*)data) * Prime1, 23) * Prime2 + Prime3;
data += 4;
}
// take care of remaining 0..3 bytes, eat 1 byte per step
while (data != stop)
result = rotateLeft(result ^ (*data++) * Prime5, 11) * Prime1;
// mix bits
result ^= result >> 33;
result *= Prime2;
result ^= result >> 29;
result *= Prime3;
result ^= result >> 32;
return result;
}
/// combine constructor, add() and hash() in one static function (C style)
/** @param input pointer to a continuous block of data
@param length number of bytes
@param seed your seed value, e.g. zero is a valid seed
@return 64 bit XXHash **/
static uint64_t hash(const void* input, uint64_t length, uint64_t seed)
{
XXHash64 hasher(seed);
hasher.add(input, length);
return hasher.hash();
}
private:
/// magic constants :-)
static const uint64_t Prime1 = 11400714785074694791ULL;
static const uint64_t Prime2 = 14029467366897019727ULL;
static const uint64_t Prime3 = 1609587929392839161ULL;
static const uint64_t Prime4 = 9650029242287828579ULL;
static const uint64_t Prime5 = 2870177450012600261ULL;
/// temporarily store up to 31 bytes between multiple add() calls
static const uint64_t MaxBufferSize = 31+1;
uint64_t state[4];
unsigned char buffer[MaxBufferSize];
uint64_t bufferSize;
uint64_t totalLength;
/// rotate bits, should compile to a single CPU instruction (ROL)
static inline uint64_t rotateLeft(uint64_t x, unsigned char bits)
{
return (x << bits) | (x >> (64 - bits));
}
/// process a single 64 bit value
static inline uint64_t processSingle(uint64_t previous, uint64_t input)
{
return rotateLeft(previous + input * Prime2, 31) * Prime1;
}
/// process a block of 4x4 bytes, this is the main part of the XXHash32 algorithm
static inline void process(const void* data, uint64_t& state0, uint64_t& state1, uint64_t& state2, uint64_t& state3)
{
const uint64_t* block = (const uint64_t*) data;
state0 = processSingle(state0, block[0]);
state1 = processSingle(state1, block[1]);
state2 = processSingle(state2, block[2]);
state3 = processSingle(state3, block[3]);
}
};

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#pragma once
namespace ShadowEngine {
template <typename T> struct Delegate;
/**
* A simple, generic callback template.
* A Delegate takes the form of a std::function that can be called, redirected and bound freely.
* Advantages over std::function includes the ability to reference types that aren't yet fully qualified.
*
* Idea taken from https://blog.molecular-matters.com/2011/09/19/generic-type-safe-delegates-and-events-in-c/
*
* @tparam R the return type
* @tparam Args the arguments to the function
*/
template <typename R, typename... Args> struct Delegate<R(Args...)> {
private:
using InstancePtr = void*;
using InternalFunction = R (*)(InstancePtr, Args...);
struct Stub {
InstancePtr first;
InternalFunction second;
};
template <R (*Function)(Args...)> static R FunctionStub(InstancePtr, Args... args) {
return (Function)(args...);
}
template <typename C, R(C::*Function)(Args...)>
static R ClassMethodStub(InstancePtr instance, Args... args) {
return (static_cast<C*>(instance)->*Function)(args...);
}
template <typename C, R(C::*Function)(Args...) const>
static R ClassMethodStub(InstancePtr instance, Args... args) {
return (static_cast<C*>(instance)->*Function)(args...);
}
public:
Delegate() {
m_stub.first = nullptr;
m_stub.second = nullptr;
}
template <typename T>
Delegate(const T& obj) {
m_stub.first = (InstancePtr)&obj;
m_stub.second = [](InstancePtr inst, Args... args) -> R {
const T& obj = *(const T*)inst;
return obj(args...);
};
}
bool isValid() { return m_stub.second != nullptr; }
template <R (*Function)(Args...)> void bind() {
m_stub.first = nullptr;
m_stub.second = &FunctionStub<Function>;
}
template <auto F, typename C> void bind(C* instance) {
m_stub.first = instance;
m_stub.second = &ClassMethodStub<C, F>;
}
R invoke(Args... args) const {
return m_stub.second(m_stub.first, args...);
}
bool operator==(const Delegate<R(Args...)>& rhs) {
return m_stub.first == rhs.m_stub.first && m_stub.second == rhs.m_stub.second;
}
private:
Stub m_stub;
};
template <typename T> struct ToDelegate_T;
template <typename R, typename C, typename... Args> struct ToDelegate_T<R (C::*)(Args...)> {
using Type = Delegate<R (Args...)>;
};
template <typename T> using ToDelegate = typename ToDelegate_T<T>::Type;
template <auto M, typename C>
auto makeDelegate(C* inst) {
ToDelegate<decltype(M)> res;
res.template bind<M, C>(inst);
return res;
};
}

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#pragma once
#include <management/delegate.h>
#include <vector>
#include <cstdint>
namespace ShadowEngine {
template <typename T> struct DelegateList;
template <typename R, typename... Args> struct DelegateList<R(Args...)> {
DelegateList() = default;
template <auto Function, typename C> void bind(C* instance) {
Delegate<R(Args...)> cb;
cb.template bind<Function>(instance);
m_delegates.push_back(cb);
}
template <R (*Function)(Args...)> void bind() {
Delegate<R(Args...)> cb;
cb.template bind<Function>();
m_delegates.push_back(cb);
}
template <R (*Function)(Args...)> void unbind() {
Delegate<R(Args...)> cb;
cb.template bind<Function>();
for (int i = 0; i < m_delegates.size(); ++i)
{
if (m_delegates[i] == cb)
{
m_delegates.swapAndPop(i);
break;
}
}
}
template <auto Function, typename C> void unbind(C* instance) {
Delegate<R(Args...)> cb;
cb.template bind<Function>(instance);
for (int i = 0; i < m_delegates.size(); ++i)
{
if (m_delegates[i] == cb)
{
m_delegates.swapAndPop(i);
break;
}
}
}
void invoke(Args... args) {
for (uint32_t i = 0, c = m_delegates.size(); i < c; ++i) m_delegates[i].invoke(args...);
}
private:
std::vector<Delegate<R(Args...)>> m_delegates;
};
}

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#include <management/synchronization.h>
// This doesn't work on Linux. Sucks to be you? dpeter won't let me do system-specific source files.
#ifdef _WIN32
#include <intrin.h>
#define WIN32_LEAN_AND_MEAN
#include <windows.h>
namespace ShadowEngine { struct NewPlaceholder {}; }
inline void* operator new(size_t, ShadowEngine::NewPlaceholder, void* where) { return where; }
inline void operator delete(void*, ShadowEngine::NewPlaceholder, void*) { }
namespace ShadowEngine {
Semaphore::Semaphore(int initCount, int maxCount) {
id = ::CreateSemaphore(nullptr, initCount, maxCount, nullptr);
}
Semaphore::~Semaphore() {
::CloseHandle(id);
}
void Semaphore::raise() {
::ReleaseSemaphore(id, 1, nullptr);
}
void Semaphore::wait() {
::WaitForSingleObject(id, INFINITE);
}
ConditionVariable::ConditionVariable() {
memset(data, 0, sizeof(data));
auto* var = new (NewPlaceholder(), data) CONDITION_VARIABLE;
InitializeConditionVariable(var);
}
ConditionVariable::~ConditionVariable() {
((CONDITION_VARIABLE*)data)->~CONDITION_VARIABLE();
}
void ConditionVariable::sleep(ShadowEngine::Mutex &mut) {
::SleepConditionVariableSRW((CONDITION_VARIABLE*) data, (SRWLOCK*) mut.data, INFINITE, 0);
}
void ConditionVariable::wake() {
::WakeConditionVariable((CONDITION_VARIABLE*) data);
}
Mutex::Mutex() {
memset(data, 0, sizeof(data));
auto* lock = new (NewPlaceholder(), data) SRWLOCK;
::InitializeSRWLock(lock);
}
Mutex::~Mutex() {
auto* lock = (SRWLOCK*) data;
lock->~SRWLOCK();
}
void Mutex::enter() {
auto* lock = (SRWLOCK*) data;
::AcquireSRWLockExclusive(lock);
}
void Mutex::exit() {
auto* lock = (SRWLOCK*) data;
::ReleaseSRWLockExclusive(lock);
}
}
#endif

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#pragma once
#include <cstdint>
#ifdef __linux__
#include <pthread.h>
#endif
namespace ShadowEngine {
// A simple synchronization system that allows one "accessing thread" at a time.
struct alignas(8) Mutex {
friend struct ConditionVariable;
Mutex();
Mutex(const Mutex&) = delete;
~Mutex();
void enter();
void exit();
private:
#ifdef _WIN32
uint8_t data[8] {};
#else
pthread_mutex_t mutex;
#endif
};
// A simple synchronization system that allows many threads to wait for one thread to complete an operation.
struct Semaphore {
Semaphore(int initcount, int maxcount);
Semaphore(const Semaphore&) = delete;
~Semaphore();
void raise();
void wait();
private:
#ifdef _WIN32
void* id;
#else
struct {
pthread_mutex_t mutex;
pthread_mutex_cond cond;
volatile int32_t count;
} id;
#endif
};
struct ConditionVariable {
ConditionVariable();
ConditionVariable(const ConditionVariable&) = delete;
~ConditionVariable();
void sleep(Mutex& mut);
void wake();
private:
#ifdef _WIN32
uint8_t data[64];
#else
pthread_cond_t cond;
#endif
};
// A simple RAII wrapper for Mutexes, that locks and unlocks as the Guard goes in and out of scope.
struct MutexGuard {
explicit MutexGuard(Mutex& mut) : mut(mut) {
mut.enter();
}
~MutexGuard() { mut.exit(); }
MutexGuard(const MutexGuard&) = delete;
void operator=(const MutexGuard&) = delete;
private:
Mutex& mut;
};
}

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#include <resource/Resource.h>
#include <resource/ResourceManager.h>
#include <spdlog/spdlog.h>
namespace ShadowEngine {
ResourceType::ResourceType(std::string& name) {
hash = HeapHash(name);
}
Resource::Resource(const ShadowEngine::Path& path, ShadowEngine::ResourceTypeManager &manager)
: references(0),
emptyDependencies(0),
failedDependencies(0),
state(State::EMPTY),
desiredState(State::EMPTY),
path(path),
size(),
callback(),
manager(manager),
handle(FileSystem::AsyncHandle::invalid()) {
}
Resource::~Resource() = default;
void Resource::refresh() {
if (state == State::EMPTY) return;
const State old = state;
state = State::EMPTY;
callback.invoke(old, state, *this);
checkState();
}
void Resource::checkState() {
State old = state;
if (failedDependencies > 0 && state != State::FAILED) {
state = State::FAILED;
} else if (failedDependencies == 0) {
if (emptyDependencies > 0 && state != State::EMPTY)
state = State::EMPTY;
if (emptyDependencies == 0 && state != State::READY && desiredState != State::EMPTY) {
onReadying();
if (emptyDependencies != 0 || state == State::READY || desiredState == State::EMPTY)
return;
if (failedDependencies != 0) {
checkState();
return;
}
state = State::READY;
}
}
callback.invoke(old, state, *this);
}
void Resource::fileLoaded(size_t fileSize, const uint8_t *mem, bool success) {
handle = FileSystem::AsyncHandle::invalid();
if (desiredState != State::READY) return;
if (!success) {
ResourceManager& owner = getManager().getOwner();
if (!hooked && owner.isHooked()) {
if (owner.onLoad(*this) == ResourceManager::LoadHook::Action::DEFERRED) {
hooked = true;
desiredState = State::READY;
increaseReferences();
return;
}
}
--emptyDependencies;
++failedDependencies;
checkState();
handle = FileSystem::AsyncHandle::invalid();
return;
}
const ResourceHeader* header = (const ResourceHeader*) mem;
if (size < sizeof(*header)) {
spdlog::error("Invalid resource: ", path.get(), ": size mismatch. Expected ", fileSize, ", got " , sizeof(*header));
failedDependencies++;
} else if (header->magic != ResourceHeader::MAGIC) {
spdlog::error("Invalid resource: " , path.get(), ": magic number mismatch. Expected " , ResourceHeader::MAGIC, ", got ", header->magic);
failedDependencies++;
} else if (header->version > 0) {
spdlog::error("Invalid resource: ", path.get(), ": verison mismatch. Expected 0, got ", header->version);
failedDependencies++;
} else {
// TODO: Compression?
if (!load(size - sizeof(*header), mem + sizeof(*header)))
failedDependencies++;
size = header->decompressedSize;
}
emptyDependencies--;
checkState();
handle = FileSystem::AsyncHandle::invalid();
}
void Resource::performUnload() {
if (handle.valid()) {
FileSystem& fs = manager.getOwner().getFileSystem();
fs.cancelAsync(handle);
handle = FileSystem::AsyncHandle::invalid();
}
hooked = false;
desiredState = State::EMPTY;
unload();
size = 0;
emptyDependencies = 1;
failedDependencies = 0;
checkState();
}
void Resource::onCreated(ShadowEngine::Resource::State newState) {
state = newState;
desiredState = State::READY;
failedDependencies = state == State::FAILED ? 1 : 0;
emptyDependencies = 0;
}
void Resource::doLoad() {
if (desiredState == State::READY) return;
desiredState = State::READY;
if (handle.valid()) return;
FileSystem& fs = manager.getOwner().getFileSystem();
FileSystem::ContentCallback cb = makeDelegate<&Resource::fileLoaded>(this);
const PathHash hash = path.getHash();
Path resourcePath("./resources/" + std::to_string(hash.getHash()) + ".res");
handle = fs.readAsync(resourcePath, cb);
}
void Resource::addDependency(ShadowEngine::Resource &dependent) {
dependent.callback.bind<&Resource::stateChanged>(this);
if (dependent.isEmpty()) emptyDependencies++;
if (dependent.isFailure()) failedDependencies++;
checkState();
}
void Resource::removeDependency(ShadowEngine::Resource &dependent) {
dependent.callback.unbind<&Resource::stateChanged>(this);
if (dependent.isEmpty()) --emptyDependencies;
if (dependent.isFailure()) --failedDependencies;
checkState();
}
uint32_t Resource::decreaseReferences() {
--references;
if (references == 0 && manager.unloadEnabled)
performUnload();
return references;
}
void Resource::stateChanged(ShadowEngine::Resource::State old, ShadowEngine::Resource::State newState,
ShadowEngine::Resource &) {
if (old == State::EMPTY) --emptyDependencies;
if (old == State::FAILED) --failedDependencies;
if (newState == State::EMPTY) ++emptyDependencies;
if (newState == State::FAILED) ++failedDependencies;
checkState();
}
static std::string type("prefab");
const ResourceType PrefabResource::TYPE(type);
PrefabResource::PrefabResource(const ShadowEngine::Path &path,
ShadowEngine::ResourceTypeManager &resource_manager) : Resource(path, resource_manager) {}
ResourceType PrefabResource::getType() const { return TYPE; }
void PrefabResource::unload() { data.clear(); }
bool PrefabResource::load(size_t size, const uint8_t *mem) {
data.resize(size);
memcpy(data.dataMut(), mem, size);
hash = StableHash(mem, size);
return true;
}
}

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#pragma once
#include "fs/hash.h"
#include "fs/path.h"
#include "fs/file.h"
#include <management/delegate_list.h>
namespace ShadowEngine {
/**
* A runtime-only struct that determines the type of a resource - whether it be a texture, mesh, animation, or other data.
* Provides some specializations for living in a map.
*/
struct ResourceType {
ResourceType() = default;
explicit ResourceType(std::string& name);
bool operator!=(const ResourceType& o) const { return o.hash != hash; }
bool operator==(const ResourceType& o) const { return o.hash == hash; }
bool operator< (const ResourceType& o) const { return o.hash.getHash() < hash.getHash(); }
bool isValid() const { return hash.getHash() != 0; }
HeapHash hash;
};
// A Resource Type that is guaranteed to be invalid.
static std::string empty;
const ResourceType INVALID_RESOURCE(empty);
// A specialization of HashFunc for ResourceTypes, since they already have a HeapHash within.
template<> struct HashFunc<ResourceType> {
static uint32_t get(const ResourceType& key) { return HashFunc<HeapHash>::get(key.hash); }
};
#pragma pack(1)
struct ResourceHeader {
static const uint32_t MAGIC = 'VXIP';
uint32_t magic = MAGIC; // VXI Package header
uint32_t version = 0;
uint32_t flags = 0;
uint32_t padding = 0;
uint32_t decompressedSize = 0;
};
#pragma pack()
/**
* A basic Resource type.
* Represents a single file loaded from disk.
* May have dependencies on other Resources, and other Resources may depend on this.
* Resources are reference-counted, and are removed when they go out of usage.
*/
struct Resource {
friend struct ResourceTypeManager;
friend struct ResourceManager;
enum class State : uint32_t {
EMPTY = 0,
READY,
FAILED
};
using Observer = DelegateList<void(State, State, Resource&)>;
virtual ~Resource();
virtual ResourceType getType() const = 0;
State getState() const { return state; }
bool isEmpty() const { return state == State::EMPTY; }
bool isReady() const { return state == State::READY; }
bool isFailure() const { return state == State::FAILED; }
uint32_t getReferenceCount() const { return references; }
Observer const& getCallback() const { return callback; }
size_t getSize() const { return size; }
const Path& getPath() const { return path; }
struct ResourceTypeManager& getManager() { return manager; }
uint32_t decreaseReferences();
uint32_t increaseReferences() { return references++; }
bool toInitialize() const { return desiredState == State::READY; }
bool isHooked() const { return hooked; }
template <auto Function, typename C> void onLoaded(C* instance) {
callback.bind<Function>(instance);
if (isReady()) (instance->*Function)(State::READY, State::READY, *this);
}
protected:
Resource(const Path& path, ResourceTypeManager& manager);
virtual void onReadying() {}
virtual void unload() = 0;
virtual bool load(size_t size, const uint8_t* mem) = 0;
void onCreated(State newState);
void performUnload();
void addDependency(Resource& dependent);
void removeDependency(Resource& dependent);
void checkState();
void refresh();
State desiredState;
uint16_t emptyDependencies;
ResourceTypeManager& manager;
private:
void doLoad();
void fileLoaded(size_t fileSize, const uint8_t* mem, bool success);
void stateChanged(State old, State newState, Resource&);
Resource(const Resource&) = delete;
void operator=(const Resource&) = delete;
Observer callback;
size_t size;
Path path;
uint32_t references;
uint16_t failedDependencies;
FileSystem::AsyncHandle handle;
State state;
bool hooked = false;
};
struct PrefabResource : Resource {
PrefabResource(const Path& path, ResourceTypeManager& resource_manager);
ResourceType getType() const override;
void unload() override;
bool load(size_t size, const uint8_t* data) override;
OutputMemoryStream data;
StableHash hash;
static const ResourceType TYPE;
};
}

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#include "ResourceManager.h"
#include "Resource.h"
#include "spdlog/spdlog.h"
namespace ShadowEngine {
void ResourceTypeManager::create(struct ResourceType type, struct ResourceManager &manager) {
manager.add(type, this);
owner = &manager;
}
void ResourceTypeManager::destroy() {
for (auto iter = resources.begin(), end = resources.end(); iter != end; ++iter) {
Resource* res = iter->second;
if (!res->isEmpty())
spdlog::error("Resource Type Manager destruction leaks ", res->path.get());
destroyResource(*res);
}
resources.clear();
}
Resource* ResourceTypeManager::get(const Path& path) {
auto it = resources.find(path.getHash());
if (it != resources.end()) return it->second;
return nullptr;
}
Resource* ResourceTypeManager::load(const Path &path) {
if (path.isEmpty()) return nullptr;
Resource* res = get(path);
if (res == nullptr) {
res = createResource(path);
resources[path.getHash()] = res;
}
if (res->isEmpty() && res->desiredState == Resource::State::EMPTY) {
if (owner->onLoad(*res) == ResourceManager::LoadHook::Action::DEFERRED) {
res->hooked = true;
res->desiredState = Resource::State::READY;
res->increaseReferences();
res->increaseReferences();
return res;
}
res->doLoad();
}
res->increaseReferences();
return res;
}
void ResourceTypeManager::removeUnreferencedResources() {
if (!unloadEnabled) return;
std::vector<Resource*> toRemove;
for (auto i : resources)
if (i.second->getReferenceCount() == 0) toRemove.push_back(i.second);
for (auto i : toRemove) {
auto iter = resources.find(i->getPath().getHash());
if (iter->second->isReady()) iter->second->performUnload();
}
}
void ResourceTypeManager::reload(const Path &path) {
Resource* res = get(path);
if (res) reload(*res);
}
void ResourceTypeManager::reload(Resource& res) {
if (res.state != Resource::State::EMPTY)
res.performUnload();
else if (res.desiredState == Resource::State::READY)
return;
if (owner->onLoad(res) == ResourceManager::LoadHook::Action::DEFERRED) {
res.hooked = true;
res.desiredState = Resource::State::READY;
res.increaseReferences();
res.increaseReferences();
} else {
res.performUnload();
}
}
void ResourceTypeManager::setUnloadable(bool status) {
unloadEnabled = status;
if (!unloadEnabled) return;
for (auto res : resources)
if (res.second->getReferenceCount() == 0)
res.second->performUnload();
}
ResourceTypeManager::ResourceTypeManager() :
resources(),
owner(nullptr),
unloadEnabled(true) {
}
ResourceTypeManager::~ResourceTypeManager() {
}
ResourceManager::ResourceManager() :
managers(),
hook(nullptr),
filesystem(nullptr) {
}
ResourceManager::~ResourceManager() = default;
void ResourceManager::init(FileSystem &fs) {
filesystem = &fs;
}
Resource* ResourceManager::load(ResourceType type, const Path& path) {
ResourceTypeManager* manager = get(type);
if (!manager) return nullptr;
return load(*manager, path);
}
Resource* ResourceManager::load(ResourceTypeManager& manager, const Path& path) {
return manager.load(path);
}
ResourceTypeManager* ResourceManager::get(ResourceType type) {
auto iter = managers.find(type);
if (iter == managers.end()) return nullptr;
return iter->second;
}
void ResourceManager::LoadHook::continueLoad(Resource &res) {
res.decreaseReferences();
res.hooked = false;
res.desiredState = Resource::State::EMPTY;
res.doLoad();
}
void ResourceManager::setLoadHook(LoadHook *loadHook) {
hook = loadHook;
if (hook)
for (auto manager : managers)
for (auto res : manager.second->getResources())
if (res.second->isFailure())
manager.second->reload(*res.second);
}
ResourceManager::LoadHook::Action ResourceManager::onLoad(Resource &res) const {
return hook ? hook->load(res) : LoadHook::Action::IMMEDIATE;
}
void ResourceManager::add(ResourceType type, ResourceTypeManager* manager) {
managers[type] = manager;
}
void ResourceManager::remove(ResourceType type) {
managers.erase(type);
}
void ResourceManager::removeUnreferenced() {
for (auto manager : managers)
manager.second->removeUnreferencedResources();
}
void ResourceManager::setUnloadable(bool enable) {
for (auto manager : managers)
manager.second->setUnloadable(enable);
}
void ResourceManager::reloadAll() {
while (filesystem->hasWork()) filesystem->processCallbacks();
std::vector<Resource*> toReload;
for (auto manager : managers) {
ResourceTypeManager::ResourceTable& resources = manager.second->getResources();
for (auto res : resources) {
if (res.second->isReady()) {
res.second->performUnload();
toReload.push_back(res.second);
}
}
}
}
void ResourceManager::reload(const Path& path) {
for (auto manager : managers)
manager.second->reload(path);
}
}

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@ -1,95 +0,0 @@
#pragma once
#include <map>
#include <fs/hash.h>
#include <fs/path.h>
namespace ShadowEngine {
/**
* Handles all of the Resources of a single Type.
* Handles reference counting, hot reloading, and etc.
*/
struct ResourceTypeManager {
friend struct Resource;
friend struct ResourceManager;
using ResourceTable = std::map<PathHash, struct Resource*>;
void create(struct ResourceType type, struct ResourceManager& manager);
void destroy();
void setUnloadable(bool status);
void removeUnreferencedResources();
void reload(const Path& path);
void reload(Resource& resource);
ResourceTable& getResources() { return resources; }
ResourceTypeManager();
virtual ~ResourceTypeManager();
ResourceManager& getOwner() const { return *owner; }
protected:
Resource* load(const Path& path);
virtual Resource* createResource(const Path& path) = 0;
virtual void destroyResource(Resource& res) = 0;
Resource* get(const Path& path);
ResourceTable resources;
ResourceManager* owner;
bool unloadEnabled;
};
/**
* Handles all of the ResourceTypeManagers, for every ResourceType with at least one applicable Resource
*/
struct ResourceManager {
using ResourceTypeManagers = std::map<ResourceType, ResourceTypeManager*>;
struct LoadHook {
enum class Action { IMMEDIATE, DEFERRED };
virtual ~LoadHook();
virtual Action load(Resource& res) = 0;
void continueLoad(Resource& res);
};
ResourceManager();
~ResourceManager();
ResourceManager(const ResourceManager& o) = delete;
void init(struct FileSystem& fs);
ResourceTypeManager* get(ResourceType);
const ResourceTypeManagers& getAll() const { return managers; }
template <typename R>
R* load(const Path& path) {
return static_cast<R*>(load(R::TYPE, path));
}
Resource* load(ResourceTypeManager& manager, const Path& path);
Resource* load(ResourceType type, const Path& path);
void setLoadHook(LoadHook* hook);
bool isHooked() const { return hook; }
LoadHook::Action onLoad(Resource& res) const;
void add(ResourceType, ResourceTypeManager* manager);
void remove(ResourceType type);
void reload(const Path& path);
void reloadAll();
void removeUnreferenced();
void setUnloadable(bool enable);
FileSystem& getFileSystem() { return *filesystem; }
private:
ResourceTypeManagers managers;
FileSystem* filesystem;
LoadHook* hook;
};
}

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@ -1,11 +0,0 @@
#include <str/string.h>
namespace ShadowEngine::Str {
std::string toLower(const std::string& str) {
std::string temp;
for (auto c : str) {
temp.append(std::to_string(tolower(c)));
}
return temp;
}
}

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@ -1,12 +0,0 @@
#pragma once
#include <string>
namespace ShadowEngine {
// String manipluation utilities.
// Because std::string is heavily lacking.
namespace Str {
// Convert the string to lower case, return a new string.
// This only works in ASCII encoding.
std::string toLower(std::string& str);
}
}

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#pragma once
#include <cstdint>
#include "id/ID.h"
namespace SE {
/**
* A Component is a part of an Entity that stores and manages data.
* This data is held separately from the Entity that requests it.
*
* Components can be Spatial (ie. Position, Rotation).
* Components can also be Visual (ie. Mesh, Collider).
* Components are part of the larger Entity-Component-System architecture.
*
* Systems operate over these Components.
* Entities may have their own Systems, and each Scene has its own set of global Systems.
* Components may be registered to only one of these.
*
* EntityComponent classes are not singleton; new EntityComponent(..) is valid.
*
*/
class EntityComponent {
public:
/**
* The Component's possible statuses.
*/
enum class Status: uint8_t {
Unloaded, // The component is not yet loaded.
Loading, // The component is being loaded.
Loaded, // The component is finished loading, but is not yet populated with data.
Failed, // The component encountered an error while loading.
Initialized // The component is finished loading, and is populated with data.
};
virtual ~EntityComponent();
// Get the ComponentID.
inline ComponentID const& GetID() const { return id; }
// Get the Name of this Component; guaranteed to be unique in a given entity.
inline std::string& GetName() { return name; }
// Get the Entity that owns this Component.
inline EntityID const& GetParent() const { return owner; }
inline Status GetStatus() const { return status; }
// Check Status
inline bool IsLoaded() const { return status == Status::Loaded; }
inline bool IsLoading() const { return status == Status::Loading; }
inline bool IsUnloaded() const { return status == Status::Unloaded; }
inline bool Failed() const { return status == Status::Failed; }
inline bool Initialized() const { return status == Status::Initialized; }
// Whether one instance of this Component is allowed per Entity
virtual bool IsSingleton() const { return false; }
protected:
EntityComponent() = default;
EntityComponent(std::string& name) : name(name) {}
// Load Component data. May perform background ops.
virtual void Load() = 0;
// Unload Component data. Must be blocking.
virtual void Unload() = 0;
// Check that everything went properly.
virtual void UpdateStatus() = 0;
// Update the status to Initialized. Must only be called if checks passed.
// The status must be Loaded.
virtual void Initialize() { status = Status::Initialized; }
// Prepare for unloading the Component. Must be called before the process begins.
// The status must be Initialized.
virtual void Close() { status == Status::Loaded; }
private:
// This Component's unique ID.
ComponentID id = ComponentID::Generate();
// The Entity that requested this Component.
EntityID owner;
// The name of the Component, for visualization
std::string name;
// The status of the Component
Status status = Status::Unloaded;
// Whether this Component is registered to the Entity's Local Systems.
bool localComponent = false;
// Whether this Component is registered to the Scene's Global Systems.
bool globalComponent = false;
};
}

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#pragma once
#include <array>
namespace SE {
/**
* An Entity Component that has a Spatial context.
* AKA, a Component with a position, a rotation, and a size.
*
* Spatial Components may exist in a hierarchy; where each subsequent object inherits the spatial positions of its' parents.
* This allows for things like complex articulation of large machines, etc.
*/
class EntitySpatialComponent : public EntityComponent {
public:
// Whether this is the root spatial component for this Entity.
inline bool IsSpatialRoot() const { return parent == nullptr; }
// Fetch the transforms and bounds.
inline Math::Transform const& GetLocalTransform() const { return transform; }
inline Math::OrientedBB const& GetLocalBounds() const { return bounds; }
inline Math::Transform const& GetWorldTransform() const { return worldTransform; }
inline Math::OrientedBB const& GetWorldBounds() const { return worldBounds; }
// Get the position in world-space.
inline Math::Vector const& GetPosition() const { return worldTransform.GetTranslation(); }
// Get the rotation in world-space.
inline Math::Quaternion const& GetRotation() const { return worldTransform.GetRotation(); }
// Get vectors relative to this spatial component.
inline Math::Vector GetForwardVector() const { return worldTransform.GetForwardVector(); }
inline Math::Vector GetUpVector() const { return worldTransform.GetUpVector(); }
inline Math::Vector GetRightVector() const { return worldTransform.GetRightVector(); }
// Update the local and world transforms
inline void SetLocalTransform(Math::Transform const& newTransform);
inline void SetWorldTransform(Math::Transform const& newTransform);
// Move this component by the specified amount of transform, rotation
inline void MoveBy(Math::Transform const& delta);
// Is there a child spatial component
inline bool HasChildren() const { return !children.empty(); }
// Get the ID of the parent of this Spatial Component
inline ComponentID const& GetParentID() const { return parent->GetID(); }
// Get the transform of the parent component
inline Math::Transform const& GetParentTransform() const { return parent->worldTransform; }
// Fetch how deep in the spatial hierarchy this Component is.
size_t GetHierarchyDepth(bool singleEntity = true) const;
// Check if we are a child of a given Component
bool IsChildOf(EntitySpatialComponent const* parent) const;
// Get the ID of the socket we are attached to
inline std::string const& GetAttachmentSocketID() const { return attachmentSocket; }
// Set the name of the socket we wish to be attached to.
inline void SetAttachmentSocket(std::string& id) { attachmentSocket = id;}
// Fetch the transform of a specific attachment.
Math::Transform const& GetAttachmentTransform(std::string& id) const;
// Whether this Component supports local scaling
virtual bool LocalScale() const { return false; }
// Fetch the local scale, if supported. { 1, 1, 1 } otherwise.
virtual std::array<float, 3> const& GetLocalScale() const { static auto ones = std::array<float, 3> { 1, 1, 1 }; return ones; }
// Convert a given world-space transform to a model-space transform.
inline Math::Transform const& ConvertWorldToLocalTransform(Math::Transform const& world);
protected:
virtual void Initialize() override;
// Set the local scale, if supported
virtual void SetLocalScale(std::array<float, 3> const& newScale) {}
// Calculate the local bounding box for the Component; the position should always be close to origin.
virtual Math::OrientedBB CalculateBounds() const;
// Update the local and world bounds for the Component.
void UpdateBounds();
// Attempt to find the given Socket in this Component, and return its' Transform if present.
bool GetAttachmentTransform(std::string& socketId, Math::Transform& out) const;
virtual bool FindAttachmentTransform(std::string& socketId, Math::Transform& out) const;
// Whether this Component has the given Socket.
// Default: No sockets.
virtual bool HasSocket(std::string& socket) const { return false;}
// Process the creation/destruction/movement of a Socket.
void UpdateSockets();
// Called whenever the World Transform is updated.
virtual void OnMoved() {}
// Set the World Transform for a component.
// Skips a lot of internal processing.
inline void SetWorldTransform(Math::Transform& newTransform, bool callback = true);
private:
inline void CalculateWorldTransform(bool callback = true);
// The location of this Component, relative to the world.
Math::Transform transform;
// The collision boundary of this Component.
Math::OrientedBB bounds;
// The world transform of this component; how to get to the position from the world origin.
Math::Transform worldTransform;
Math::OrientedBB worldBounds;
// The parent of this Spatial Component
EntitySpatialComponent* parent = nullptr;
// The socket (attachment point) of the parent entity that this Component is attached to.
std::string attachmentSocket;
// The Components that are attached to this Component.
std::vector<EntitySpatialComponent*> children;
};
}

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#pragma once
#include <id/UUID.h> // Shadow-Engine/core/inc/id
namespace SE {
// An ID for a section of the scene (which may be unloaded separately of the level; for ie. open world Cells.)
using EntitySectionID = UUID;
// An ID for a scene (which contains all sections and entities).
using EntitySceneID = UUID;
/**
* Contains the common data and functions for the Entity System's identifiers.
*/
struct IDContainer {
public:
IDContainer() = default;
explicit IDContainer(uint64_t v) : id(v) {}
// Check if the ID is valid (non-zero)
__inline virtual bool Valid() const { return id != 0; }
// Set this ID to be invalid (zero).
__inline virtual void Invalidate() { id = 0; }
// Check for in/equality against another ID.
__inline virtual bool operator==(IDContainer const& other) const { return id == other.id; }
__inline virtual bool operator!=(IDContainer const& other) const { return id != other.id; }
__inline virtual bool operator<(IDContainer const& other) const { return id < other.id; }
uint64_t id;
};
/**
* An ID used for an Entity.
* Is only guaranteed to be unique in the current scene (ie. a level change may also change the IDs of the entities within).
*/
struct EntityID : public IDContainer {
/**
* @return a new, unused Entity ID.
*/
static EntityID Generate();
EntityID() = default;
explicit EntityID(uint64_t v) : IDContainer(v) {}
};
/**
* An ID used for a Component (a segment of data attached to an Entity).
* Is only guaranteed to be unique in the current scene (ie. a level change may also change the IDs of the components within).
*/
struct ComponentID : public IDContainer {
/**
* @return a new, unused Component ID.
*/
static ComponentID Generate();
ComponentID() = default;
explicit ComponentID(uint64_t v) : IDContainer(v) {}
};
}

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#pragma once
#include <scene/EntitySection.h>
namespace SE {
/**
* A scene is a collection of Sections that contain Entities.
* Scenes have support for asynchronous task management.
* Scenes have their own input state, local to the world.
* Scenes have Systems that operate over all Scene Components of all entities within.
* Scenes can be either for Tools or for Gameplay.
*
* Scenes each have a primary viewport and any number of secondary viewports.
*
* Scenes contain Sections, which contain Entities.
* One of the Sections in the Scene is always loaded; similar to Spawn Chunks.
*
* Scenes have a local timescale, which can be increased to make physics and logic run faster.
*/
class EntityScene {
/**
* The type of the scene.
* More-or-less exists to allow differentiating between an Editor and a Runtime.
*/
enum Type {
TOOLS, // This scene exists for tooling support, ie. the builtin editor.
GAME // This scene exists for gameplay, ie. the runtime.
};
public:
EntityScene(Type wType = Type::GAME);
~EntityScene();
// Fetch the ID of this scene.
inline EntitySceneID const& GetID() const { return id; }
// Whether this is a Gameplay scene.
inline bool IsGameScene() const { return type == Type::GAME; }
// Prepare the Scene for processing entity updates. TODO: Systems.
void Initialize();
// Prepare all Regions and Entities for the closing of the Scene.
void Shutdown();
// Whether or not updates are suspended. ( Game is Paused )
inline bool IsSuspended() const { return suspended; }
// Stop all Regions, Entities and Systems from updating.
void Suspend() { suspended = true; }
// Resume updates to the Entities and Systems within.
void Resume() { suspended = false; }
// Run a single tick of Entity and System updates. TODO: context
void Update();
// Handle Entities, Regions, Resources that want to load or unload.
void UpdateLoads();
// TODO: Systems
// TODO: Input
// Check whether time is paused; the Scene itself can be unpaused during this, to allow movement through a paused world.
inline bool IsTimePaused() const { return timeScale <= 0.0f; }
// Pause time in the Scene.
inline void PauseTime() { timeScale = 0.0f; }
// The Time Scale for the Scene
inline float GetTimeScale() const { return timeScale; }
// Set the Time Scale for the Scene.
inline void SetTimeScale(float newScale) { timeScale = newScale; }
// Request a Time Step through a paused world.
inline void TimeStep() { timeStepNeeded = true; }
// Whether a Scene with Paused Time needs a time step
inline bool TimeStepRequested() const { return timeStepNeeded; }
// How long a single Time Step last, at most.
inline float TimeStepLength() const { return timeStepLength; }
// Set the maximum length of a Time Step.
inline void SetTimeStepLength(float newStep) { timeStepLength = newStep; }
// TODO: Viewports
// Fetch the Section that is always present and loaded; be careful adding things to this.
EntitySection* GetPersistentSection() { return sections[0]; }
EntitySection const* GetPersistentSection() const { return sections[0]; }
// Get the first Section that is not persistent, if present.
EntitySection* GetFirstNonPersistentSection() { return sections.size() > 1 ? sections[1] : nullptr; }
EntitySection const* GetFirstNonPersistentSection() const { return sections.size() > 1 ? sections[1] : nullptr; }
// Create a transient (memory-resident) Section.
EntitySection* CreateTransientSection();
// Get a Section from memory.
EntitySection const* GetSection(EntitySectionID const& sID) const;
EntitySection* GetSection(EntitySectionID const& sID);
// Whether anything is loading into a Section
bool IsLoading() const;
// Whether a Section exists in this scene
bool HasSection(const EntitySectionID& eID) const;
// Whether the Section in this scene is loaded.
bool isSectionLoaded(const EntitySectionID& sID) const;
// Load a Section from the Scene file into memory.
EntitySectionID LoadSection(EntitySectionID& section);
// Unload a section from memory; delete every entity within.
void UnloadSection(EntitySectionID& section);
inline Entity* FindEntity(EntityID& entity) const {
Entity* e = nullptr;
for (auto const& section : sections) {
e = section->GetEntity(entity);
if (e != nullptr) break;
}
return e;
}
private:
// The ID of this Scene.
EntitySceneID id = UUID::Generate();
// The system that manages asynchronous background tasks for this Scene, such as Systems and Entity management.
// Tasks* tasks;
// The local Input State, which exists relative to the viewport, allowing for tri picking.
// Input input;
// TODO: Loading/Initialization
// TODO: Scene Systems
// The type of this Scene; default to game.
Type type = Type::GAME;
// Whether or not everything in the map is ready to start.
bool initialized = false;
// Whether or not everything in the map is paused; no logic runs, nothing updates.
bool suspended = false;
// TODO: Viewport
// The list of Sections in this Scene.
std::vector<EntitySection*> sections;
// Every entity that is eligible for updates.
// Ie. Every Initialized Entity in every Loaded Section.
std::vector<Entity*> entityUpdateList;
//TODO: Scene Systems 2
// The multiplier for the number of steps per second (1/timescale * stepInterval)
float timeScale = 1.0f;
// The maximum length of each time step; if a step goes over this, it is aborted and the next begins processing.
float timeStepLength = 1.0f/30;
// Whether or not a new Time Step should begin immediately. Only applicable to Scenes with Paused Time.
bool timeStepNeeded = false;
};
}

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#pragma once
#include <vector>
#include <map>
namespace SE {
// Forward declaration, see inc/entity/Entity.h
class Entity;
/**
* A section is a collection of Entities with linked runtime.
* ie. a game level could have one giant linked Section.
* a cell of an open-world game could represent one Region,
* and rooms of a BSP level could represent one Region.
*/
class EntitySection {
/**
* The possible statuses for this Section.
* Entities are not valid until the Loaded status is reached.
*/
enum class Status {
Failed = -1, // An error occurred during loading.
Unloaded = 0, // The Section is present, but none of the data is populated.
Loading, // The Section is being loaded with data.
Loaded, // The Section is present and contains valid data.
Unloading // The Section is present but preparing to unload.
};
/**
* Request the deletion of an entity, after ie. destruction or death.
*/
struct PendingRemoval {
PendingRemoval(Entity* entity, bool destroy)
: entity(entity), destroy(destroy) {}
Entity* entity = nullptr;
bool destroy = false;
};
public:
EntitySection();
EntitySection(EntitySection const& section);
EntitySection(EntitySection&& section);
~EntitySection();
EntitySection& operator=(EntitySection const& section);
EntitySection& operator=(EntitySection&& section);
// Get the ID of this Section
inline EntitySectionID GetID() const { return id; }
// Whether or not this Section was generated, without being loaded from disk.
inline bool IsTransient() const { return isTransient; }
// TODO: Contexts?
void Load();
void Unload();
// Check that everything went properly, and update state accordingly.
bool UpdateState();
// Whether there are any pending entity removals or additions.
inline bool HasPendingEntityChanges() const { return (entitiesPendingLoading.size() + entitiesPendingRemoval.size()) > 0; }
bool IsLoading() const { return status == Status::Loading; }
inline bool IsLoaded() const { return status == Status::Loaded; }
inline bool IsUnloaded() const { return status == Status::Unloaded; }
inline bool LoadingFailed() const { return status == Status::Failed; }
// Get the total number of entities in the section
inline size_t GetEntityCount() const { return entities.size(); }
// Get all entities in the region.
inline std::vector<Entity*> const& GetEntities() const { return entities; }
// Get a specific entity by its' ID.
inline Entity* GetEntity(const EntityID& eID) const {
auto i = entityLookup.find(eID);
return (i != entityLookup.end()) ? i->second : nullptr;
}
// Check whether this region contains the specified entity.
inline bool ContainsEntity(const EntityID& eID) const { return GetEntity(eID) != nullptr; }
// Add all of the specified entities to the region.
// Transfers ownership if already present.
// This operation takes time, but is guaranteed to be finished by the start of the next frame.
void AddEntities(const std::vector<Entity*>& entities);
// Add an entity to the region.
// Transfers ownership if already present.
void AddEntity(Entity* entity);
// Queue an entity for removal from this region.
// Transfers ownership to the caller.
// This operation takes time, and no guarantee is given for completion.
Entity* RemoveEntity(const EntityID& eID);
// Queue an entity for unloading from this region.
// This operation takes time, and no guarantee is given for completion.
void DestroyEntity(const EntityID& eID);
private:
// A callback for when an entity's state changes (ie. when loading)
void EntityStateUpdated(Entity* entity);
// TODO: Process Loading, Unloading, Entity Shutdown, Entity Removal, Entity Loading.
private:
EntitySectionID id = UUID::Generate();
Status status = Status::Unloaded;
// Transient = created on-the-fly, rather than existing on disk.
bool const isTransient = false;
// The list of every entity in the Section, including those that are not yet loaded, or those that are due to be unloaded.
std::vector<Entity*> entities;
// A fast map for looking up entities by ID.
std::map<EntityID, Entity*> entityLookup;
// The list of entities that are currently being initialized to be put into the Section.
std::vector<Entity*> entitiesLoading;
// The list of entities that are waiting to be loaded.
std::vector<Entity*> entitiesPendingLoading;
// The list of entities that are waiting to be removed.
std::vector<Entity*> entitiesPendingRemoval;
};
}

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#pragma once
#include <string>
namespace SE {
// Forward declaration.
class EntityComponent;
/**
* A System is a routine that operates over the Components in an Entity.
* A System may be local to a given Entity, or it may be glboal to the Scene.
*
* Components must be registered to the System that works over them.
*
* TODO: Think of better names for these functions
*/
class EntitySystem {
public:
virtual ~EntitySystem();
virtual std::string& GetName() const = 0;
// Pre-Component Register
virtual void Initialize() {}
// Post-Component Register
virtual void Initialized() {}
// Pre-Component Unregister
virtual void Uninitialize() {}
// Post-Component Unregister
virtual void Uninitialized() {}
protected:
// Register a Component with this System
virtual void RegisterComponent(EntityComponent* component) = 0;
// Unregister a Component from this system
virtual void UnregisterComponent(EntityComponent* component) = 0;
// Update over all Components. TODO: Context?
virtual void Update() = 0;
};
}

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#include <id/ID.h>
#include <atomic>
namespace SE {
static std::atomic<uint64_t> entityID = 1;
EntityID EntityID::Generate() {
EntityID id(entityID++);
return id;
}
static std::atomic<uint64_t> componentID = 1;
ComponentID ComponentID::Generate() {
ComponentID id(componentID++);
return id;
}
}

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set(CMAKE_CXX_STANDARD 20)
# Set up Catch2 testing
list(APPEND CMAKE_MODULE_PATH "cmake")
enable_testing()
# Set up asset sourceset
FILE(GLOB_RECURSE SOURCES src/*.cpp src/*.h)
FILE(GLOB_RECURSE TESTS test/*.cpp)
add_library(shadow-asset ${SOURCES})
# Set up test executable
add_executable(shadow-asset-test ${TESTS})
target_link_libraries(shadow-asset-test PRIVATE Catch2::Catch2 shadow-utils)
# Enable testing on the executable
include(CTest)
include(Catch)
catch_discover_tests(shadow-asset-test)