/*************************************************************************/
/*  codesign.cpp                                                         */
/*************************************************************************/
/*                       This file is part of:                           */
/*                           GODOT ENGINE                                */
/*                      https://godotengine.org                          */
/*************************************************************************/
/* Copyright (c) 2007-2022 Juan Linietsky, Ariel Manzur.                 */
/* Copyright (c) 2014-2022 Godot Engine contributors (cf. AUTHORS.md).   */
/*                                                                       */
/* Permission is hereby granted, free of charge, to any person obtaining */
/* a copy of this software and associated documentation files (the       */
/* "Software"), to deal in the Software without restriction, including   */
/* without limitation the rights to use, copy, modify, merge, publish,   */
/* distribute, sublicense, and/or sell copies of the Software, and to    */
/* permit persons to whom the Software is furnished to do so, subject to */
/* the following conditions:                                             */
/*                                                                       */
/* The above copyright notice and this permission notice shall be        */
/* included in all copies or substantial portions of the Software.       */
/*                                                                       */
/* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,       */
/* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF    */
/* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.*/
/* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY  */
/* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,  */
/* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE     */
/* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.                */
/*************************************************************************/

#include "codesign.h"

#include "lipo.h"
#include "macho.h"
#include "plist.h"

#include "core/os/os.h"
#include "editor/editor_settings.h"
#include "modules/modules_enabled.gen.h" // For regex.

#include <ctime>

#ifdef MODULE_REGEX_ENABLED

/*************************************************************************/
/* CodeSignCodeResources                                                 */
/*************************************************************************/

String CodeSignCodeResources::hash_sha1_base64(const String &p_path) {
	FileAccessRef fa = FileAccess::open(p_path, FileAccess::READ);
	ERR_FAIL_COND_V_MSG(!fa, String(), vformat("CodeSign/CodeResources: Can't open file: \"%s\".", p_path));

	CryptoCore::SHA1Context ctx;
	ctx.start();

	unsigned char step[4096];
	while (true) {
		uint64_t br = fa->get_buffer(step, 4096);
		if (br > 0) {
			ctx.update(step, br);
		}
		if (br < 4096) {
			break;
		}
	}

	unsigned char hash[0x14];
	ctx.finish(hash);
	fa->close();

	return CryptoCore::b64_encode_str(hash, 0x14);
}

String CodeSignCodeResources::hash_sha256_base64(const String &p_path) {
	FileAccessRef fa = FileAccess::open(p_path, FileAccess::READ);
	ERR_FAIL_COND_V_MSG(!fa, String(), vformat("CodeSign/CodeResources: Can't open file: \"%s\".", p_path));

	CryptoCore::SHA256Context ctx;
	ctx.start();

	unsigned char step[4096];
	while (true) {
		uint64_t br = fa->get_buffer(step, 4096);
		if (br > 0) {
			ctx.update(step, br);
		}
		if (br < 4096) {
			break;
		}
	}

	unsigned char hash[0x20];
	ctx.finish(hash);
	fa->close();

	return CryptoCore::b64_encode_str(hash, 0x20);
}

void CodeSignCodeResources::add_rule1(const String &p_rule, const String &p_key, int p_weight, bool p_store) {
	rules1.push_back(CRRule(p_rule, p_key, p_weight, p_store));
}

void CodeSignCodeResources::add_rule2(const String &p_rule, const String &p_key, int p_weight, bool p_store) {
	rules2.push_back(CRRule(p_rule, p_key, p_weight, p_store));
}

CodeSignCodeResources::CRMatch CodeSignCodeResources::match_rules1(const String &p_path) const {
	CRMatch found = CRMatch::CR_MATCH_NO;
	int weight = 0;
	for (int i = 0; i < rules1.size(); i++) {
		RegEx regex(rules1[i].file_pattern);
		if (regex.search(p_path).is_valid()) {
			if (rules1[i].key == "omit") {
				return CRMatch::CR_MATCH_NO;
			} else if (rules1[i].key == "nested") {
				if (weight <= rules1[i].weight) {
					found = CRMatch::CR_MATCH_NESTED;
					weight = rules1[i].weight;
				}
			} else if (rules1[i].key == "optional") {
				if (weight <= rules1[i].weight) {
					found = CRMatch::CR_MATCH_OPTIONAL;
					weight = rules1[i].weight;
				}
			} else {
				if (weight <= rules1[i].weight) {
					found = CRMatch::CR_MATCH_YES;
					weight = rules1[i].weight;
				}
			}
		}
	}
	return found;
}

CodeSignCodeResources::CRMatch CodeSignCodeResources::match_rules2(const String &p_path) const {
	CRMatch found = CRMatch::CR_MATCH_NO;
	int weight = 0;
	for (int i = 0; i < rules2.size(); i++) {
		RegEx regex(rules2[i].file_pattern);
		if (regex.search(p_path).is_valid()) {
			if (rules2[i].key == "omit") {
				return CRMatch::CR_MATCH_NO;
			} else if (rules2[i].key == "nested") {
				if (weight <= rules2[i].weight) {
					found = CRMatch::CR_MATCH_NESTED;
					weight = rules2[i].weight;
				}
			} else if (rules2[i].key == "optional") {
				if (weight <= rules2[i].weight) {
					found = CRMatch::CR_MATCH_OPTIONAL;
					weight = rules2[i].weight;
				}
			} else {
				if (weight <= rules2[i].weight) {
					found = CRMatch::CR_MATCH_YES;
					weight = rules2[i].weight;
				}
			}
		}
	}
	return found;
}

bool CodeSignCodeResources::add_file1(const String &p_root, const String &p_path) {
	CRMatch found = match_rules1(p_path);
	if (found != CRMatch::CR_MATCH_YES && found != CRMatch::CR_MATCH_OPTIONAL) {
		return true; // No match.
	}

	CRFile f;
	f.name = p_path;
	f.optional = (found == CRMatch::CR_MATCH_OPTIONAL);
	f.nested = false;
	f.hash = hash_sha1_base64(p_root.plus_file(p_path));
	print_verbose(vformat("CodeSign/CodeResources: File(V1) %s hash1:%s", f.name, f.hash));

	files1.push_back(f);
	return true;
}

bool CodeSignCodeResources::add_file2(const String &p_root, const String &p_path) {
	CRMatch found = match_rules2(p_path);
	if (found == CRMatch::CR_MATCH_NESTED) {
		return add_nested_file(p_root, p_path, p_root.plus_file(p_path));
	}
	if (found != CRMatch::CR_MATCH_YES && found != CRMatch::CR_MATCH_OPTIONAL) {
		return true; // No match.
	}

	CRFile f;
	f.name = p_path;
	f.optional = (found == CRMatch::CR_MATCH_OPTIONAL);
	f.nested = false;
	f.hash = hash_sha1_base64(p_root.plus_file(p_path));
	f.hash2 = hash_sha256_base64(p_root.plus_file(p_path));

	print_verbose(vformat("CodeSign/CodeResources: File(V2) %s hash1:%s hash2:%s", f.name, f.hash, f.hash2));

	files2.push_back(f);
	return true;
}

bool CodeSignCodeResources::add_nested_file(const String &p_root, const String &p_path, const String &p_exepath) {
#define CLEANUP()                                       \
	if (files_to_add.size() > 1) {                      \
		for (int j = 0; j < files_to_add.size(); j++) { \
			da->remove(files_to_add[j]);                \
		}                                               \
	}

	DirAccessRef da = DirAccess::create(DirAccess::ACCESS_FILESYSTEM);
	ERR_FAIL_COND_V(!da, false);

	Vector<String> files_to_add;
	if (LipO::is_lipo(p_exepath)) {
		String tmp_path_name = EditorSettings::get_singleton()->get_cache_dir().plus_file("_lipo");
		Error err = da->make_dir_recursive(tmp_path_name);
		if (err != OK) {
			ERR_FAIL_V_MSG(false, vformat("CodeSign/CodeResources: Failed to create \"%s\" subfolder.", tmp_path_name));
		}
		LipO lip;
		if (lip.open_file(p_exepath)) {
			for (int i = 0; i < lip.get_arch_count(); i++) {
				if (!lip.extract_arch(i, tmp_path_name.plus_file("_rqexe_" + itos(i)))) {
					CLEANUP();
					ERR_FAIL_V_MSG(false, "CodeSign/CodeResources: Failed to extract thin binary.");
				}
				files_to_add.push_back(tmp_path_name.plus_file("_rqexe_" + itos(i)));
			}
		}
	} else if (MachO::is_macho(p_exepath)) {
		files_to_add.push_back(p_exepath);
	}

	CRFile f;
	f.name = p_path;
	f.optional = false;
	f.nested = true;
	for (int i = 0; i < files_to_add.size(); i++) {
		MachO mh;
		if (!mh.open_file(files_to_add[i])) {
			CLEANUP();
			ERR_FAIL_V_MSG(false, "CodeSign/CodeResources: Invalid executable file.");
		}
		PoolByteArray hash = mh.get_cdhash_sha256(); // Use SHA-256 variant, if available.
		if (hash.size() != 0x20) {
			hash = mh.get_cdhash_sha1(); // Use SHA-1 instead.
			if (hash.size() != 0x14) {
				CLEANUP();
				ERR_FAIL_V_MSG(false, "CodeSign/CodeResources: Unsigned nested executable file.");
			}
		}
		hash.resize(0x14); // Always clamp to 0x14 size.
		f.hash = CryptoCore::b64_encode_str(hash.read().ptr(), hash.size());

		PoolByteArray rq_blob = mh.get_requirements();
		String req_string;
		if (rq_blob.size() > 8) {
			CodeSignRequirements rq(rq_blob);
			Vector<String> rqs = rq.parse_requirements();
			for (int j = 0; j < rqs.size(); j++) {
				if (rqs[j].begins_with("designated => ")) {
					req_string = rqs[j].replace("designated => ", "");
				}
			}
		}
		if (req_string.empty()) {
			req_string = "cdhash H\"" + String::hex_encode_buffer(hash.read().ptr(), hash.size()) + "\"";
		}
		print_verbose(vformat("CodeSign/CodeResources: Nested object %s (cputype: %d) cdhash:%s designated rq:%s", f.name, mh.get_cputype(), f.hash, req_string));
		if (f.requirements != req_string) {
			if (i != 0) {
				f.requirements += " or ";
			}
			f.requirements += req_string;
		}
	}
	files2.push_back(f);

	CLEANUP();
	return true;

#undef CLEANUP
}

bool CodeSignCodeResources::add_folder_recursive(const String &p_root, const String &p_path, const String &p_main_exe_path) {
	DirAccessRef da = DirAccess::create(DirAccess::ACCESS_FILESYSTEM);
	ERR_FAIL_COND_V(!da, false);
	Error err = da->change_dir(p_root.plus_file(p_path));
	ERR_FAIL_COND_V(err != OK, false);

	bool ret = true;
	da->list_dir_begin();
	String n = da->get_next();
	while (n != String()) {
		if (n != "." && n != "..") {
			String path = p_root.plus_file(p_path).plus_file(n);
			if (path == p_main_exe_path) {
				n = da->get_next();
				continue; // Skip main executable.
			}
			if (da->current_is_dir()) {
				CRMatch found = match_rules2(p_path.plus_file(n));
				String fmw_ver = "Current"; // Framework version (default).
				String info_path;
				String main_exe;
				String bundle_path;
				bool bundle = false;
				if (da->file_exists(path.plus_file("Contents/Info.plist"))) {
					info_path = path.plus_file("Contents/Info.plist");
					main_exe = path.plus_file("Contents/MacOS");
					bundle = true;
				} else if (da->file_exists(path.plus_file(vformat("Versions/%s/Resources/Info.plist", fmw_ver)))) {
					info_path = path.plus_file(vformat("Versions/%s/Resources/Info.plist", fmw_ver));
					main_exe = path.plus_file(vformat("Versions/%s", fmw_ver));
					bundle = true;
				} else if (da->file_exists(path.plus_file("Info.plist"))) {
					info_path = path.plus_file("Info.plist");
					main_exe = path;
					bundle = true;
				}
				if (bundle && found == CRMatch::CR_MATCH_NESTED && !info_path.empty()) {
					// Read Info.plist.
					PList info_plist;
					if (info_plist.load_file(info_path)) {
						if (info_plist.get_root()->data_type == PList::PLNodeType::PL_NODE_TYPE_DICT && info_plist.get_root()->data_dict.has("CFBundleExecutable")) {
							main_exe = main_exe.plus_file(String::utf8(info_plist.get_root()->data_dict["CFBundleExecutable"]->data_string.get_data()));
						} else {
							ERR_FAIL_V_MSG(false, "CodeSign/CodeResources: Invalid Info.plist, no exe name.");
						}
					} else {
						ERR_FAIL_V_MSG(false, "CodeSign/CodeResources: Invalid Info.plist, can't load.");
					}
					ret = ret && add_nested_file(p_root, p_path.plus_file(n), main_exe);
				} else {
					ret = ret && add_folder_recursive(p_root, p_path.plus_file(n), p_main_exe_path);
				}
			} else {
				ret = ret && add_file1(p_root, p_path.plus_file(n));
				ret = ret && add_file2(p_root, p_path.plus_file(n));
			}
		}

		n = da->get_next();
	}

	da->list_dir_end();
	return ret;
}

bool CodeSignCodeResources::save_to_file(const String &p_path) {
	PList pl;

	print_verbose(vformat("CodeSign/CodeResources: Writing to file: %s", p_path));

	// Write version 1 hashes.
	Ref<PListNode> files1_dict = PListNode::new_dict();
	pl.get_root()->push_subnode(files1_dict, "files");
	for (int i = 0; i < files1.size(); i++) {
		if (files1[i].optional) {
			Ref<PListNode> file_dict = PListNode::new_dict();
			files1_dict->push_subnode(file_dict, files1[i].name);

			file_dict->push_subnode(PListNode::new_data(files1[i].hash), "hash");
			file_dict->push_subnode(PListNode::new_bool(true), "optional");
		} else {
			files1_dict->push_subnode(PListNode::new_data(files1[i].hash), files1[i].name);
		}
	}

	// Write version 2 hashes.
	Ref<PListNode> files2_dict = PListNode::new_dict();
	pl.get_root()->push_subnode(files2_dict, "files2");
	for (int i = 0; i < files2.size(); i++) {
		Ref<PListNode> file_dict = PListNode::new_dict();
		files2_dict->push_subnode(file_dict, files2[i].name);

		if (files2[i].nested) {
			file_dict->push_subnode(PListNode::new_data(files2[i].hash), "cdhash");
			file_dict->push_subnode(PListNode::new_string(files2[i].requirements), "requirement");
		} else {
			file_dict->push_subnode(PListNode::new_data(files2[i].hash), "hash");
			file_dict->push_subnode(PListNode::new_data(files2[i].hash2), "hash2");
			if (files2[i].optional) {
				file_dict->push_subnode(PListNode::new_bool(true), "optional");
			}
		}
	}

	// Write version 1 rules.
	Ref<PListNode> rules1_dict = PListNode::new_dict();
	pl.get_root()->push_subnode(rules1_dict, "rules");
	for (int i = 0; i < rules1.size(); i++) {
		if (rules1[i].store) {
			if (rules1[i].key.empty() && rules1[i].weight <= 0) {
				rules1_dict->push_subnode(PListNode::new_bool(true), rules1[i].file_pattern);
			} else {
				Ref<PListNode> rule_dict = PListNode::new_dict();
				rules1_dict->push_subnode(rule_dict, rules1[i].file_pattern);
				if (!rules1[i].key.empty()) {
					rule_dict->push_subnode(PListNode::new_bool(true), rules1[i].key);
				}
				if (rules1[i].weight != 1) {
					rule_dict->push_subnode(PListNode::new_real(rules1[i].weight), "weight");
				}
			}
		}
	}

	// Write version 2 rules.
	Ref<PListNode> rules2_dict = PListNode::new_dict();
	pl.get_root()->push_subnode(rules2_dict, "rules2");
	for (int i = 0; i < rules2.size(); i++) {
		if (rules2[i].store) {
			if (rules2[i].key.empty() && rules2[i].weight <= 0) {
				rules2_dict->push_subnode(PListNode::new_bool(true), rules2[i].file_pattern);
			} else {
				Ref<PListNode> rule_dict = PListNode::new_dict();
				rules2_dict->push_subnode(rule_dict, rules2[i].file_pattern);
				if (!rules2[i].key.empty()) {
					rule_dict->push_subnode(PListNode::new_bool(true), rules2[i].key);
				}
				if (rules2[i].weight != 1) {
					rule_dict->push_subnode(PListNode::new_real(rules2[i].weight), "weight");
				}
			}
		}
	}
	String text = pl.save_text();
	ERR_FAIL_COND_V_MSG(text.empty(), false, "CodeSign/CodeResources: Generating resources PList failed.");

	FileAccessRef fa = FileAccess::open(p_path, FileAccess::WRITE);
	ERR_FAIL_COND_V_MSG(!fa, false, vformat("CodeSign/CodeResources: Can't open file: \"%s\".", p_path));

	CharString cs = text.utf8();
	fa->store_buffer((const uint8_t *)cs.ptr(), cs.length());
	fa->close();
	return true;
}

/*************************************************************************/
/* CodeSignRequirements                                                  */
/*************************************************************************/

CodeSignRequirements::CodeSignRequirements() {
#define _W(a, b, c, d) \
	blob.push_back(a); \
	blob.push_back(b); \
	blob.push_back(c); \
	blob.push_back(d);
	_W(0xFA, 0xDE, 0x0C, 0x01); // Requirement set magic.
	_W(0x00, 0x00, 0x00, 0x0C); // Length of requirements set (12 bytes).
	_W(0x00, 0x00, 0x00, 0x00); // Empty.
#undef _W
}

CodeSignRequirements::CodeSignRequirements(const PoolByteArray &p_data) {
	blob = p_data;
}

_FORCE_INLINE_ void CodeSignRequirements::_parse_certificate_slot(uint32_t &r_pos, String &r_out, uint32_t p_rq_size) const {
#define _R(x) BSWAP32(*(uint32_t *)(r.ptr() + x))
	PoolByteArray::Read r = blob.read();
	ERR_FAIL_COND_MSG(r_pos >= p_rq_size, "CodeSign/Requirements: Out of bounds.");
	r_out += "certificate ";
	uint32_t tag_slot = _R(r_pos);
	if (tag_slot == 0x00000000) {
		r_out += "leaf";
	} else if (tag_slot == 0xffffffff) {
		r_out += "root";
	} else {
		r_out += itos((int32_t)tag_slot);
	}
	r_pos += 4;
#undef _R
}

_FORCE_INLINE_ void CodeSignRequirements::_parse_key(uint32_t &r_pos, String &r_out, uint32_t p_rq_size) const {
#define _R(x) BSWAP32(*(uint32_t *)(r.ptr() + x))
	PoolByteArray::Read r = blob.read();
	ERR_FAIL_COND_MSG(r_pos >= p_rq_size, "CodeSign/Requirements: Out of bounds.");
	uint32_t key_size = _R(r_pos);
	ERR_FAIL_COND_MSG(r_pos + key_size > p_rq_size, "CodeSign/Requirements: Out of bounds.");
	CharString key;
	key.resize(key_size);
	memcpy((void *)key.ptrw(), blob.read().ptr() + r_pos + 4, key_size);
	r_pos += 4 + key_size + PAD(key_size, 4);
	r_out += "[" + String::utf8(key, key_size) + "]";
#undef _R
}

_FORCE_INLINE_ void CodeSignRequirements::_parse_oid_key(uint32_t &r_pos, String &r_out, uint32_t p_rq_size) const {
#define _R(x) BSWAP32(*(uint32_t *)(r.ptr() + x))
	PoolByteArray::Read r = blob.read();
	ERR_FAIL_COND_MSG(r_pos >= p_rq_size, "CodeSign/Requirements: Out of bounds.");
	uint32_t key_size = _R(r_pos);
	ERR_FAIL_COND_MSG(r_pos + key_size > p_rq_size, "CodeSign/Requirements: Out of bounds.");
	r_out += "[field.";
	r_out += itos(blob[r_pos + 4] / 40) + ".";
	r_out += itos(blob[r_pos + 4] % 40);
	uint32_t spos = r_pos + 5;
	while (spos < r_pos + 4 + key_size) {
		r_out += ".";
		if (blob[spos] <= 127) {
			r_out += itos(blob[spos]);
			spos += 1;
		} else {
			uint32_t x = (0x7F & blob[spos]) << 7;
			spos += 1;
			while (blob[spos] > 127) {
				x = (x + (0x7F & blob[spos])) << 7;
				spos += 1;
			}
			x = (x + (0x7F & blob[spos]));
			r_out += itos(x);
			spos += 1;
		}
	}
	r_out += "]";
	r_pos += 4 + key_size + PAD(key_size, 4);
#undef _R
}

_FORCE_INLINE_ void CodeSignRequirements::_parse_hash_string(uint32_t &r_pos, String &r_out, uint32_t p_rq_size) const {
#define _R(x) BSWAP32(*(uint32_t *)(r.ptr() + x))
	PoolByteArray::Read r = blob.read();
	ERR_FAIL_COND_MSG(r_pos >= p_rq_size, "CodeSign/Requirements: Out of bounds.");
	uint32_t tag_size = _R(r_pos);
	ERR_FAIL_COND_MSG(r_pos + tag_size > p_rq_size, "CodeSign/Requirements: Out of bounds.");
	PoolByteArray data;
	data.resize(tag_size);
	memcpy(data.write().ptr(), blob.read().ptr() + r_pos + 4, tag_size);
	r_out += "H\"" + String::hex_encode_buffer(data.read().ptr(), data.size()) + "\"";
	r_pos += 4 + tag_size + PAD(tag_size, 4);
#undef _R
}

_FORCE_INLINE_ void CodeSignRequirements::_parse_value(uint32_t &r_pos, String &r_out, uint32_t p_rq_size) const {
#define _R(x) BSWAP32(*(uint32_t *)(r.ptr() + x))
	PoolByteArray::Read r = blob.read();
	ERR_FAIL_COND_MSG(r_pos >= p_rq_size, "CodeSign/Requirements: Out of bounds.");
	uint32_t key_size = _R(r_pos);
	ERR_FAIL_COND_MSG(r_pos + key_size > p_rq_size, "CodeSign/Requirements: Out of bounds.");
	CharString key;
	key.resize(key_size);
	memcpy((void *)key.ptrw(), blob.read().ptr() + r_pos + 4, key_size);
	r_pos += 4 + key_size + PAD(key_size, 4);
	r_out += "\"" + String::utf8(key, key_size) + "\"";
#undef _R
}

_FORCE_INLINE_ void CodeSignRequirements::_parse_date(uint32_t &r_pos, String &r_out, uint32_t p_rq_size) const {
#define _R(x) BSWAP32(*(uint32_t *)(r.ptr() + x))
	PoolByteArray::Read r = blob.read();
	ERR_FAIL_COND_MSG(r_pos >= p_rq_size, "CodeSign/Requirements: Out of bounds.");
	uint32_t date = _R(r_pos);
	time_t t = 978307200 + date;
	struct tm lt;
#ifdef WINDOWS_ENABLED
	gmtime_s(&lt, &t);
#else
	gmtime_r(&t, &lt);
#endif
	r_out += vformat("<%04d-%02d-%02d ", (int)(1900 + lt.tm_year), (int)(lt.tm_mon + 1), (int)(lt.tm_mday)) + vformat("%02d:%02d:%02d +0000>", (int)(lt.tm_hour), (int)(lt.tm_min), (int)(lt.tm_sec));
#undef _R
}

_FORCE_INLINE_ bool CodeSignRequirements::_parse_match(uint32_t &r_pos, String &r_out, uint32_t p_rq_size) const {
#define _R(x) BSWAP32(*(uint32_t *)(r.ptr() + x))
	PoolByteArray::Read r = blob.read();
	ERR_FAIL_COND_V_MSG(r_pos >= p_rq_size, false, "CodeSign/Requirements: Out of bounds.");
	uint32_t match = _R(r_pos);
	r_pos += 4;
	switch (match) {
		case 0x00000000: {
			r_out += "exists";
		} break;
		case 0x00000001: {
			r_out += "= ";
			_parse_value(r_pos, r_out, p_rq_size);
		} break;
		case 0x00000002: {
			r_out += "~ ";
			_parse_value(r_pos, r_out, p_rq_size);
		} break;
		case 0x00000003: {
			r_out += "= *";
			_parse_value(r_pos, r_out, p_rq_size);
		} break;
		case 0x00000004: {
			r_out += "= ";
			_parse_value(r_pos, r_out, p_rq_size);
			r_out += "*";
		} break;
		case 0x00000005: {
			r_out += "< ";
			_parse_value(r_pos, r_out, p_rq_size);
		} break;
		case 0x00000006: {
			r_out += "> ";
			_parse_value(r_pos, r_out, p_rq_size);
		} break;
		case 0x00000007: {
			r_out += "<= ";
			_parse_value(r_pos, r_out, p_rq_size);
		} break;
		case 0x00000008: {
			r_out += ">= ";
			_parse_value(r_pos, r_out, p_rq_size);
		} break;
		case 0x00000009: {
			r_out += "= ";
			_parse_date(r_pos, r_out, p_rq_size);
		} break;
		case 0x0000000A: {
			r_out += "< ";
			_parse_date(r_pos, r_out, p_rq_size);
		} break;
		case 0x0000000B: {
			r_out += "> ";
			_parse_date(r_pos, r_out, p_rq_size);
		} break;
		case 0x0000000C: {
			r_out += "<= ";
			_parse_date(r_pos, r_out, p_rq_size);
		} break;
		case 0x0000000D: {
			r_out += ">= ";
			_parse_date(r_pos, r_out, p_rq_size);
		} break;
		case 0x0000000E: {
			r_out += "absent";
		} break;
		default: {
			return false;
		}
	}
	return true;
#undef _R
}

Vector<String> CodeSignRequirements::parse_requirements() const {
#define _R(x) BSWAP32(*(uint32_t *)(r.ptr() + x))
	PoolByteArray::Read r = blob.read();
	Vector<String> list;

	// Read requirements set header.
	ERR_FAIL_COND_V_MSG(blob.size() < 12, list, "CodeSign/Requirements: Blob is too small.");
	uint32_t magic = _R(0);
	ERR_FAIL_COND_V_MSG(magic != 0xfade0c01, list, "CodeSign/Requirements: Invalid set magic.");
	uint32_t size = _R(4);
	ERR_FAIL_COND_V_MSG(size != (uint32_t)blob.size(), list, "CodeSign/Requirements: Invalid set size.");
	uint32_t count = _R(8);

	for (uint32_t i = 0; i < count; i++) {
		String out;

		// Read requirement header.
		uint32_t rq_type = _R(12 + i * 8);
		uint32_t rq_offset = _R(12 + i * 8 + 4);
		ERR_FAIL_COND_V_MSG(rq_offset + 12 >= (uint32_t)blob.size(), list, "CodeSign/Requirements: Invalid requirement offset.");
		switch (rq_type) {
			case 0x00000001: {
				out += "host => ";
			} break;
			case 0x00000002: {
				out += "guest => ";
			} break;
			case 0x00000003: {
				out += "designated => ";
			} break;
			case 0x00000004: {
				out += "library => ";
			} break;
			case 0x00000005: {
				out += "plugin => ";
			} break;
			default: {
				ERR_FAIL_V_MSG(list, "CodeSign/Requirements: Invalid requirement type.");
			}
		}
		uint32_t rq_magic = _R(rq_offset);
		uint32_t rq_size = _R(rq_offset + 4);
		uint32_t rq_ver = _R(rq_offset + 8);
		uint32_t pos = rq_offset + 12;
		ERR_FAIL_COND_V_MSG(rq_magic != 0xfade0c00, list, "CodeSign/Requirements: Invalid requirement magic.");
		ERR_FAIL_COND_V_MSG(rq_ver != 0x00000001, list, "CodeSign/Requirements: Invalid requirement version.");

		// Read requirement tokens.
		List<String> tokens;
		while (pos < rq_offset + rq_size) {
			uint32_t rq_tag = _R(pos);
			pos += 4;
			String token;
			switch (rq_tag) {
				case 0x00000000: {
					token = "false";
				} break;
				case 0x00000001: {
					token = "true";
				} break;
				case 0x00000002: {
					token = "identifier ";
					_parse_value(pos, token, rq_offset + rq_size);
				} break;
				case 0x00000003: {
					token = "anchor apple";
				} break;
				case 0x00000004: {
					_parse_certificate_slot(pos, token, rq_offset + rq_size);
					token += " ";
					_parse_hash_string(pos, token, rq_offset + rq_size);
				} break;
				case 0x00000005: {
					token = "info";
					_parse_key(pos, token, rq_offset + rq_size);
					token += " = ";
					_parse_value(pos, token, rq_offset + rq_size);
				} break;
				case 0x00000006: {
					token = "and";
				} break;
				case 0x00000007: {
					token = "or";
				} break;
				case 0x00000008: {
					token = "cdhash ";
					_parse_hash_string(pos, token, rq_offset + rq_size);
				} break;
				case 0x00000009: {
					token = "!";
				} break;
				case 0x0000000A: {
					token = "info";
					_parse_key(pos, token, rq_offset + rq_size);
					token += " ";
					ERR_FAIL_COND_V_MSG(!_parse_match(pos, token, rq_offset + rq_size), list, "CodeSign/Requirements: Unsupported match suffix.");
				} break;
				case 0x0000000B: {
					_parse_certificate_slot(pos, token, rq_offset + rq_size);
					_parse_key(pos, token, rq_offset + rq_size);
					token += " ";
					ERR_FAIL_COND_V_MSG(!_parse_match(pos, token, rq_offset + rq_size), list, "CodeSign/Requirements: Unsupported match suffix.");
				} break;
				case 0x0000000C: {
					_parse_certificate_slot(pos, token, rq_offset + rq_size);
					token += " trusted";
				} break;
				case 0x0000000D: {
					token = "anchor trusted";
				} break;
				case 0x0000000E: {
					_parse_certificate_slot(pos, token, rq_offset + rq_size);
					_parse_oid_key(pos, token, rq_offset + rq_size);
					token += " ";
					ERR_FAIL_COND_V_MSG(!_parse_match(pos, token, rq_offset + rq_size), list, "CodeSign/Requirements: Unsupported match suffix.");
				} break;
				case 0x0000000F: {
					token = "anchor apple generic";
				} break;
				default: {
					ERR_FAIL_V_MSG(list, "CodeSign/Requirements: Invalid requirement token.");
				} break;
			}
			tokens.push_back(token);
		}

		// Polish to infix notation (w/o bracket optimization).
		for (List<String>::Element *E = tokens.back(); E; E = E->prev()) {
			if (E->get() == "and") {
				ERR_FAIL_COND_V_MSG(!E->next() || !E->next()->next(), list, "CodeSign/Requirements: Invalid token sequence.");
				String token = "(" + E->next()->get() + " and " + E->next()->next()->get() + ")";
				tokens.erase(E->next()->next());
				tokens.erase(E->next());
				E->get() = token;
			} else if (E->get() == "or") {
				ERR_FAIL_COND_V_MSG(!E->next() || !E->next()->next(), list, "CodeSign/Requirements: Invalid token sequence.");
				String token = "(" + E->next()->get() + " or " + E->next()->next()->get() + ")";
				tokens.erase(E->next()->next());
				tokens.erase(E->next());
				E->get() = token;
			}
		}

		if (tokens.size() == 1) {
			list.push_back(out + tokens.front()->get());
		} else {
			ERR_FAIL_V_MSG(list, "CodeSign/Requirements: Invalid token sequence.");
		}
	}

	return list;
#undef _R
}

PoolByteArray CodeSignRequirements::get_hash_sha1() const {
	PoolByteArray hash;
	hash.resize(0x14);

	CryptoCore::SHA1Context ctx;
	ctx.start();
	ctx.update(blob.read().ptr(), blob.size());
	ctx.finish(hash.write().ptr());

	return hash;
}

PoolByteArray CodeSignRequirements::get_hash_sha256() const {
	PoolByteArray hash;
	hash.resize(0x20);

	CryptoCore::SHA256Context ctx;
	ctx.start();
	ctx.update(blob.read().ptr(), blob.size());
	ctx.finish(hash.write().ptr());

	return hash;
}

int CodeSignRequirements::get_size() const {
	return blob.size();
}

void CodeSignRequirements::write_to_file(FileAccess *p_file) const {
	ERR_FAIL_COND_MSG(!p_file, "CodeSign/Requirements: Invalid file handle.");
	p_file->store_buffer(blob.read().ptr(), blob.size());
}

/*************************************************************************/
/* CodeSignEntitlementsText                                             */
/*************************************************************************/

CodeSignEntitlementsText::CodeSignEntitlementsText() {
#define _W(a, b, c, d) \
	blob.push_back(a); \
	blob.push_back(b); \
	blob.push_back(c); \
	blob.push_back(d);
	_W(0xFA, 0xDE, 0x71, 0x71); // Text Entitlements set magic.
	_W(0x00, 0x00, 0x00, 0x08); // Length (8 bytes).
#undef _W
}

CodeSignEntitlementsText::CodeSignEntitlementsText(const String &p_string) {
	CharString utf8 = p_string.utf8();
#define _W(a, b, c, d) \
	blob.push_back(a); \
	blob.push_back(b); \
	blob.push_back(c); \
	blob.push_back(d);
	_W(0xFA, 0xDE, 0x71, 0x71); // Text Entitlements set magic.
	for (int i = 3; i >= 0; i--) {
		uint8_t x = ((utf8.length() + 8) >> i * 8) & 0xFF; // Size.
		blob.push_back(x);
	}
	for (int i = 0; i < utf8.length(); i++) { // Write data.
		blob.push_back(utf8[i]);
	}
#undef _W
}

PoolByteArray CodeSignEntitlementsText::get_hash_sha1() const {
	PoolByteArray hash;
	hash.resize(0x14);

	CryptoCore::SHA1Context ctx;
	ctx.start();
	ctx.update(blob.read().ptr(), blob.size());
	ctx.finish(hash.write().ptr());

	return hash;
}

PoolByteArray CodeSignEntitlementsText::get_hash_sha256() const {
	PoolByteArray hash;
	hash.resize(0x20);

	CryptoCore::SHA256Context ctx;
	ctx.start();
	ctx.update(blob.read().ptr(), blob.size());
	ctx.finish(hash.write().ptr());

	return hash;
}

int CodeSignEntitlementsText::get_size() const {
	return blob.size();
}

void CodeSignEntitlementsText::write_to_file(FileAccess *p_file) const {
	ERR_FAIL_COND_MSG(!p_file, "CodeSign/EntitlementsText: Invalid file handle.");
	p_file->store_buffer(blob.read().ptr(), blob.size());
}

/*************************************************************************/
/* CodeSignEntitlementsBinary                                           */
/*************************************************************************/

CodeSignEntitlementsBinary::CodeSignEntitlementsBinary() {
#define _W(a, b, c, d) \
	blob.push_back(a); \
	blob.push_back(b); \
	blob.push_back(c); \
	blob.push_back(d);
	_W(0xFA, 0xDE, 0x71, 0x72); // Binary Entitlements magic.
	_W(0x00, 0x00, 0x00, 0x08); // Length (8 bytes).
#undef _W
}

CodeSignEntitlementsBinary::CodeSignEntitlementsBinary(const String &p_string) {
	PList pl(p_string);

	PoolByteArray asn1 = pl.save_asn1();
#define _W(a, b, c, d) \
	blob.push_back(a); \
	blob.push_back(b); \
	blob.push_back(c); \
	blob.push_back(d);
	_W(0xFA, 0xDE, 0x71, 0x72); // Binary Entitlements magic.
	uint32_t size = asn1.size() + 8;
	for (int i = 3; i >= 0; i--) {
		uint8_t x = (size >> i * 8) & 0xFF; // Size.
		blob.push_back(x);
	}
	blob.append_array(asn1); // Write data.
#undef _W
}

PoolByteArray CodeSignEntitlementsBinary::get_hash_sha1() const {
	PoolByteArray hash;
	hash.resize(0x14);

	CryptoCore::SHA1Context ctx;
	ctx.start();
	ctx.update(blob.read().ptr(), blob.size());
	ctx.finish(hash.write().ptr());

	return hash;
}

PoolByteArray CodeSignEntitlementsBinary::get_hash_sha256() const {
	PoolByteArray hash;
	hash.resize(0x20);

	CryptoCore::SHA256Context ctx;
	ctx.start();
	ctx.update(blob.read().ptr(), blob.size());
	ctx.finish(hash.write().ptr());

	return hash;
}

int CodeSignEntitlementsBinary::get_size() const {
	return blob.size();
}

void CodeSignEntitlementsBinary::write_to_file(FileAccess *p_file) const {
	ERR_FAIL_COND_MSG(!p_file, "CodeSign/EntitlementsBinary: Invalid file handle.");
	p_file->store_buffer(blob.read().ptr(), blob.size());
}

/*************************************************************************/
/* CodeSignCodeDirectory                                                 */
/*************************************************************************/

CodeSignCodeDirectory::CodeSignCodeDirectory() {
#define _W(a, b, c, d) \
	blob.push_back(a); \
	blob.push_back(b); \
	blob.push_back(c); \
	blob.push_back(d);
	_W(0xFA, 0xDE, 0x0C, 0x02); // Code Directory magic.
	_W(0x00, 0x00, 0x00, 0x00); // Size (8 bytes).
#undef _W
}

CodeSignCodeDirectory::CodeSignCodeDirectory(uint8_t p_hash_size, uint8_t p_hash_type, bool p_main, const CharString &p_id, const CharString &p_team_id, uint32_t p_page_size, uint64_t p_exe_limit, uint64_t p_code_limit) {
	pages = p_code_limit / (uint64_t(1) << p_page_size);
	remain = p_code_limit % (uint64_t(1) << p_page_size);
	code_slots = pages + (remain > 0 ? 1 : 0);
	special_slots = 7;

	int cd_size = 8 + sizeof(CodeDirectoryHeader) + (code_slots + special_slots) * p_hash_size + p_id.size() + p_team_id.size();
	int cd_off = 8 + sizeof(CodeDirectoryHeader);
#define _W(a, b, c, d) \
	blob.push_back(a); \
	blob.push_back(b); \
	blob.push_back(c); \
	blob.push_back(d);
	_W(0xFA, 0xDE, 0x0C, 0x02); // Code Directory magic.
	for (int i = 3; i >= 0; i--) {
		uint8_t x = (cd_size >> i * 8) & 0xFF; // Size.
		blob.push_back(x);
	}
#undef _W
	blob.resize(cd_size);
	memset(blob.write().ptr() + 8, 0x00, cd_size - 8);
	CodeDirectoryHeader *cd = (CodeDirectoryHeader *)(blob.write().ptr() + 8);

	bool is_64_cl = (p_code_limit >= std::numeric_limits<uint32_t>::max());

	// Version and options.
	cd->version = BSWAP32(0x20500);
	cd->flags = BSWAP32(SIGNATURE_ADHOC | SIGNATURE_RUNTIME);
	cd->special_slots = BSWAP32(special_slots);
	cd->code_slots = BSWAP32(code_slots);
	if (is_64_cl) {
		cd->code_limit_64 = BSWAP64(p_code_limit);
	} else {
		cd->code_limit = BSWAP32(p_code_limit);
	}
	cd->hash_size = p_hash_size;
	cd->hash_type = p_hash_type;
	cd->page_size = p_page_size;
	cd->exec_seg_base = 0x00;
	cd->exec_seg_limit = BSWAP64(p_exe_limit);
	cd->exec_seg_flags = 0;
	if (p_main) {
		cd->exec_seg_flags |= EXECSEG_MAIN_BINARY;
	}
	cd->exec_seg_flags = BSWAP64(cd->exec_seg_flags);
	uint32_t version = (11 << 16) + (3 << 8) + 0; // Version 11.3.0
	cd->runtime = BSWAP32(version);

	// Copy ID.
	cd->ident_offset = BSWAP32(cd_off);
	memcpy(blob.write().ptr() + cd_off, p_id.get_data(), p_id.size());
	cd_off += p_id.size();

	// Copy Team ID.
	if (p_team_id.length() > 0) {
		cd->team_offset = BSWAP32(cd_off);
		memcpy(blob.write().ptr() + cd_off, p_team_id.get_data(), p_team_id.size());
		cd_off += p_team_id.size();
	} else {
		cd->team_offset = 0;
	}

	// Scatter vector.
	cd->scatter_vector_offset = 0; // Not used.

	// Executable hashes offset.
	cd->hash_offset = BSWAP32(cd_off + special_slots * cd->hash_size);
}

bool CodeSignCodeDirectory::set_hash_in_slot(const PoolByteArray &p_hash, int p_slot) {
	ERR_FAIL_COND_V_MSG((p_slot < -special_slots) || (p_slot >= code_slots), false, vformat("CodeSign/CodeDirectory: Invalid hash slot index: %d.", p_slot));
	CodeDirectoryHeader *cd = reinterpret_cast<CodeDirectoryHeader *>(blob.write().ptr() + 8);
	for (int i = 0; i < cd->hash_size; i++) {
		blob.write()[BSWAP32(cd->hash_offset) + p_slot * cd->hash_size + i] = p_hash[i];
	}
	return true;
}

int32_t CodeSignCodeDirectory::get_page_count() {
	return pages;
}

int32_t CodeSignCodeDirectory::get_page_remainder() {
	return remain;
}

PoolByteArray CodeSignCodeDirectory::get_hash_sha1() const {
	PoolByteArray hash;
	hash.resize(0x14);

	CryptoCore::SHA1Context ctx;
	ctx.start();
	ctx.update(blob.read().ptr(), blob.size());
	ctx.finish(hash.write().ptr());

	return hash;
}

PoolByteArray CodeSignCodeDirectory::get_hash_sha256() const {
	PoolByteArray hash;
	hash.resize(0x20);

	CryptoCore::SHA256Context ctx;
	ctx.start();
	ctx.update(blob.read().ptr(), blob.size());
	ctx.finish(hash.write().ptr());

	return hash;
}

int CodeSignCodeDirectory::get_size() const {
	return blob.size();
}

void CodeSignCodeDirectory::write_to_file(FileAccess *p_file) const {
	ERR_FAIL_COND_MSG(!p_file, "CodeSign/CodeDirectory: Invalid file handle.");
	p_file->store_buffer(blob.read().ptr(), blob.size());
}

/*************************************************************************/
/* CodeSignSignature                                                     */
/*************************************************************************/

CodeSignSignature::CodeSignSignature() {
#define _W(a, b, c, d) \
	blob.push_back(a); \
	blob.push_back(b); \
	blob.push_back(c); \
	blob.push_back(d);
	_W(0xFA, 0xDE, 0x0B, 0x01); // Signature magic.
	uint32_t sign_size = 8; // Ad-hoc signature is empty.
	for (int i = 3; i >= 0; i--) {
		uint8_t x = (sign_size >> i * 8) & 0xFF; // Size.
		blob.push_back(x);
	}
#undef _W
}

PoolByteArray CodeSignSignature::get_hash_sha1() const {
	PoolByteArray hash;
	hash.resize(0x14);

	CryptoCore::SHA1Context ctx;
	ctx.start();
	ctx.update(blob.read().ptr(), blob.size());
	ctx.finish(hash.write().ptr());

	return hash;
}

PoolByteArray CodeSignSignature::get_hash_sha256() const {
	PoolByteArray hash;
	hash.resize(0x20);

	CryptoCore::SHA256Context ctx;
	ctx.start();
	ctx.update(blob.read().ptr(), blob.size());
	ctx.finish(hash.write().ptr());

	return hash;
}

int CodeSignSignature::get_size() const {
	return blob.size();
}

void CodeSignSignature::write_to_file(FileAccess *p_file) const {
	ERR_FAIL_COND_MSG(!p_file, "CodeSign/Signature: Invalid file handle.");
	p_file->store_buffer(blob.read().ptr(), blob.size());
}

/*************************************************************************/
/* CodeSignSuperBlob                                                     */
/*************************************************************************/

bool CodeSignSuperBlob::add_blob(const Ref<CodeSignBlob> &p_blob) {
	if (p_blob.is_valid()) {
		blobs.push_back(p_blob);
		return true;
	} else {
		return false;
	}
}

int CodeSignSuperBlob::get_size() const {
	int size = 12 + blobs.size() * 8;
	for (int i = 0; i < blobs.size(); i++) {
		if (blobs[i].is_null()) {
			return 0;
		}
		size += blobs[i]->get_size();
	}
	return size;
}

void CodeSignSuperBlob::write_to_file(FileAccess *p_file) const {
	ERR_FAIL_COND_MSG(!p_file, "CodeSign/SuperBlob: Invalid file handle.");
	uint32_t size = get_size();
	uint32_t data_offset = 12 + blobs.size() * 8;

	// Write header.
	p_file->store_32(BSWAP32(0xfade0cc0));
	p_file->store_32(BSWAP32(size));
	p_file->store_32(BSWAP32(blobs.size()));

	// Write index.
	for (int i = 0; i < blobs.size(); i++) {
		if (blobs[i].is_null()) {
			return;
		}
		p_file->store_32(BSWAP32(blobs[i]->get_index_type()));
		p_file->store_32(BSWAP32(data_offset));
		data_offset += blobs[i]->get_size();
	}

	// Write blobs.
	for (int i = 0; i < blobs.size(); i++) {
		blobs[i]->write_to_file(p_file);
	}
}

/*************************************************************************/
/* CodeSign                                                              */
/*************************************************************************/

PoolByteArray CodeSign::file_hash_sha1(const String &p_path) {
	PoolByteArray file_hash;
	FileAccessRef f = FileAccess::open(p_path, FileAccess::READ);
	ERR_FAIL_COND_V_MSG(!f, PoolByteArray(), vformat("CodeSign: Can't open file: \"%s\".", p_path));

	CryptoCore::SHA1Context ctx;
	ctx.start();

	unsigned char step[4096];
	while (true) {
		uint64_t br = f->get_buffer(step, 4096);
		if (br > 0) {
			ctx.update(step, br);
		}
		if (br < 4096) {
			break;
		}
	}

	file_hash.resize(0x14);
	ctx.finish(file_hash.write().ptr());
	return file_hash;
}

PoolByteArray CodeSign::file_hash_sha256(const String &p_path) {
	PoolByteArray file_hash;
	FileAccessRef f = FileAccess::open(p_path, FileAccess::READ);
	ERR_FAIL_COND_V_MSG(!f, PoolByteArray(), vformat("CodeSign: Can't open file: \"%s\".", p_path));

	CryptoCore::SHA256Context ctx;
	ctx.start();

	unsigned char step[4096];
	while (true) {
		uint64_t br = f->get_buffer(step, 4096);
		if (br > 0) {
			ctx.update(step, br);
		}
		if (br < 4096) {
			break;
		}
	}

	file_hash.resize(0x20);
	ctx.finish(file_hash.write().ptr());
	return file_hash;
}

Error CodeSign::_codesign_file(bool p_use_hardened_runtime, bool p_force, const String &p_info, const String &p_exe_path, const String &p_bundle_path, const String &p_ent_path, bool p_ios_bundle, String &r_error_msg) {
#define CLEANUP()                                        \
	if (files_to_sign.size() > 1) {                      \
		for (int j = 0; j < files_to_sign.size(); j++) { \
			da->remove(files_to_sign[j]);                \
		}                                                \
	}

	print_verbose(vformat("CodeSign: Signing executable: %s, bundle: %s with entitlements %s", p_exe_path, p_bundle_path, p_ent_path));

	PoolByteArray info_hash1, info_hash2;
	PoolByteArray res_hash1, res_hash2;
	String id;
	String main_exe = p_exe_path;

	DirAccess *da = DirAccess::create(DirAccess::ACCESS_FILESYSTEM);
	if (!da) {
		r_error_msg = TTR("Can't get filesystem access.");
		ERR_FAIL_V_MSG(ERR_CANT_CREATE, "CodeSign: Can't get filesystem access.");
	}

	// Read Info.plist.
	if (!p_info.empty()) {
		print_verbose(vformat("CodeSign: Reading bundle info..."));
		PList info_plist;
		if (info_plist.load_file(p_info)) {
			info_hash1 = file_hash_sha1(p_info);
			info_hash2 = file_hash_sha256(p_info);
			if (info_hash1.empty() || info_hash2.empty()) {
				r_error_msg = TTR("Failed to get Info.plist hash.");
				ERR_FAIL_V_MSG(FAILED, "CodeSign: Failed to get Info.plist hash.");
			}

			if (info_plist.get_root()->data_type == PList::PLNodeType::PL_NODE_TYPE_DICT && info_plist.get_root()->data_dict.has("CFBundleExecutable")) {
				main_exe = p_exe_path.plus_file(String::utf8(info_plist.get_root()->data_dict["CFBundleExecutable"]->data_string.get_data()));
			} else {
				r_error_msg = TTR("Invalid Info.plist, no exe name.");
				ERR_FAIL_V_MSG(FAILED, "CodeSign: Invalid Info.plist, no exe name.");
			}

			if (info_plist.get_root()->data_type == PList::PLNodeType::PL_NODE_TYPE_DICT && info_plist.get_root()->data_dict.has("CFBundleIdentifier")) {
				id = info_plist.get_root()->data_dict["CFBundleIdentifier"]->data_string.get_data();
			} else {
				r_error_msg = TTR("Invalid Info.plist, no bundle id.");
				ERR_FAIL_V_MSG(FAILED, "CodeSign: Invalid Info.plist, no bundle id.");
			}
		} else {
			r_error_msg = TTR("Invalid Info.plist, can't load.");
			ERR_FAIL_V_MSG(FAILED, "CodeSign: Invalid Info.plist, can't load.");
		}
	}

	// Extract fat binary.
	PoolStringArray files_to_sign;
	if (LipO::is_lipo(main_exe)) {
		print_verbose(vformat("CodeSign: Executable is fat, extracting..."));
		String tmp_path_name = EditorSettings::get_singleton()->get_cache_dir().plus_file("_lipo");
		Error err = da->make_dir_recursive(tmp_path_name);
		if (err != OK) {
			r_error_msg = vformat(TTR("Failed to create \"%s\" subfolder."), tmp_path_name);
			ERR_FAIL_V_MSG(FAILED, vformat("CodeSign: Failed to create \"%s\" subfolder.", tmp_path_name));
		}
		LipO lip;
		if (lip.open_file(main_exe)) {
			for (int i = 0; i < lip.get_arch_count(); i++) {
				if (!lip.extract_arch(i, tmp_path_name.plus_file("_exe_" + itos(i)))) {
					CLEANUP();
					r_error_msg = TTR("Failed to extract thin binary.");
					ERR_FAIL_V_MSG(FAILED, "CodeSign: Failed to extract thin binary.");
				}
				files_to_sign.push_back(tmp_path_name.plus_file("_exe_" + itos(i)));
			}
		}
	} else if (MachO::is_macho(main_exe)) {
		print_verbose(vformat("CodeSign: Executable is thin..."));
		files_to_sign.push_back(main_exe);
	} else {
		r_error_msg = TTR("Invalid binary format.");
		ERR_FAIL_V_MSG(FAILED, "CodeSign: Invalid binary format.");
	}

	// Check if it's already signed.
	if (!p_force) {
		for (int i = 0; i < files_to_sign.size(); i++) {
			MachO mh;
			mh.open_file(files_to_sign[i]);
			if (mh.is_signed()) {
				CLEANUP();
				r_error_msg = TTR("Already signed!");
				ERR_FAIL_V_MSG(FAILED, "CodeSign: Already signed!");
			}
		}
	}

	// Generate core resources.
	if (!p_bundle_path.empty()) {
		print_verbose(vformat("CodeSign: Generating bundle CodeResources..."));
		CodeSignCodeResources cr;

		if (p_ios_bundle) {
			cr.add_rule1("^.*");
			cr.add_rule1("^.*\\.lproj/", "optional", 100);
			cr.add_rule1("^.*\\.lproj/locversion.plist$", "omit", 1100);
			cr.add_rule1("^Base\\.lproj/", "", 1010);
			cr.add_rule1("^version.plist$");

			cr.add_rule2(".*\\.dSYM($|/)", "", 11);
			cr.add_rule2("^(.*/)?\\.DS_Store$", "omit", 2000);
			cr.add_rule2("^.*");
			cr.add_rule2("^.*\\.lproj/", "optional", 1000);
			cr.add_rule2("^.*\\.lproj/locversion.plist$", "omit", 1100);
			cr.add_rule2("^Base\\.lproj/", "", 1010);
			cr.add_rule2("^Info\\.plist$", "omit", 20);
			cr.add_rule2("^PkgInfo$", "omit", 20);
			cr.add_rule2("^embedded\\.provisionprofile$", "", 10);
			cr.add_rule2("^version\\.plist$", "", 20);

			cr.add_rule2("^_MASReceipt", "omit", 2000, false);
			cr.add_rule2("^_CodeSignature", "omit", 2000, false);
			cr.add_rule2("^CodeResources", "omit", 2000, false);
		} else {
			cr.add_rule1("^Resources/");
			cr.add_rule1("^Resources/.*\\.lproj/", "optional", 1000);
			cr.add_rule1("^Resources/.*\\.lproj/locversion.plist$", "omit", 1100);
			cr.add_rule1("^Resources/Base\\.lproj/", "", 1010);
			cr.add_rule1("^version.plist$");

			cr.add_rule2(".*\\.dSYM($|/)", "", 11);
			cr.add_rule2("^(.*/)?\\.DS_Store$", "omit", 2000);
			cr.add_rule2("^(Frameworks|SharedFrameworks|PlugIns|Plug-ins|XPCServices|Helpers|MacOS|Library/(Automator|Spotlight|LoginItems))/", "nested", 10);
			cr.add_rule2("^.*");
			cr.add_rule2("^Info\\.plist$", "omit", 20);
			cr.add_rule2("^PkgInfo$", "omit", 20);
			cr.add_rule2("^Resources/", "", 20);
			cr.add_rule2("^Resources/.*\\.lproj/", "optional", 1000);
			cr.add_rule2("^Resources/.*\\.lproj/locversion.plist$", "omit", 1100);
			cr.add_rule2("^Resources/Base\\.lproj/", "", 1010);
			cr.add_rule2("^[^/]+$", "nested", 10);
			cr.add_rule2("^embedded\\.provisionprofile$", "", 10);
			cr.add_rule2("^version\\.plist$", "", 20);
			cr.add_rule2("^_MASReceipt", "omit", 2000, false);
			cr.add_rule2("^_CodeSignature", "omit", 2000, false);
			cr.add_rule2("^CodeResources", "omit", 2000, false);
		}

		if (!cr.add_folder_recursive(p_bundle_path, "", main_exe)) {
			CLEANUP();
			r_error_msg = TTR("Failed to process nested resources.");
			ERR_FAIL_V_MSG(FAILED, "CodeSign: Failed to process nested resources.");
		}
		Error err = da->make_dir_recursive(p_bundle_path.plus_file("_CodeSignature"));
		if (err != OK) {
			CLEANUP();
			r_error_msg = TTR("Failed to create _CodeSignature subfolder.");
			ERR_FAIL_V_MSG(FAILED, "CodeSign: Failed to create _CodeSignature subfolder.");
		}
		cr.save_to_file(p_bundle_path.plus_file("_CodeSignature").plus_file("CodeResources"));
		res_hash1 = file_hash_sha1(p_bundle_path.plus_file("_CodeSignature").plus_file("CodeResources"));
		res_hash2 = file_hash_sha256(p_bundle_path.plus_file("_CodeSignature").plus_file("CodeResources"));
		if (res_hash1.empty() || res_hash2.empty()) {
			CLEANUP();
			r_error_msg = TTR("Failed to get CodeResources hash.");
			ERR_FAIL_V_MSG(FAILED, "CodeSign: Failed to get CodeResources hash.");
		}
	}

	// Generate common signature structures.
	if (id.empty()) {
		Ref<Crypto> crypto = Ref<Crypto>(Crypto::create());
		PoolByteArray uuid = crypto->generate_random_bytes(16);
		id = (String("a-55554944") /*a-UUID*/ + String::hex_encode_buffer(uuid.read().ptr(), 16));
	}
	CharString uuid_str = id.utf8();
	print_verbose(vformat("CodeSign: Used bundle ID: %s", id));

	print_verbose(vformat("CodeSign: Processing entitlements..."));

	Ref<CodeSignEntitlementsText> cet;
	Ref<CodeSignEntitlementsBinary> ceb;
	if (!p_ent_path.empty()) {
		String entitlements = FileAccess::get_file_as_string(p_ent_path);
		if (entitlements.empty()) {
			CLEANUP();
			r_error_msg = TTR("Invalid entitlements file.");
			ERR_FAIL_V_MSG(FAILED, "CodeSign: Invalid entitlements file.");
		}
		cet = Ref<CodeSignEntitlementsText>(memnew(CodeSignEntitlementsText(entitlements)));
		ceb = Ref<CodeSignEntitlementsBinary>(memnew(CodeSignEntitlementsBinary(entitlements)));
	}

	print_verbose(vformat("CodeSign: Generating requirements..."));
	Ref<CodeSignRequirements> rq;
	String team_id = "";
	rq = Ref<CodeSignRequirements>(memnew(CodeSignRequirements()));

	// Sign executables.
	for (int i = 0; i < files_to_sign.size(); i++) {
		MachO mh;
		if (!mh.open_file(files_to_sign[i])) {
			CLEANUP();
			r_error_msg = TTR("Invalid executable file.");
			ERR_FAIL_V_MSG(FAILED, "CodeSign: Invalid executable file.");
		}
		print_verbose(vformat("CodeSign: Signing executable for cputype: %d ...", mh.get_cputype()));

		print_verbose(vformat("CodeSign: Generating CodeDirectory..."));
		Ref<CodeSignCodeDirectory> cd1 = memnew(CodeSignCodeDirectory(0x14, 0x01, true, uuid_str, team_id.utf8(), 12, mh.get_exe_limit(), mh.get_code_limit()));
		Ref<CodeSignCodeDirectory> cd2 = memnew(CodeSignCodeDirectory(0x20, 0x02, true, uuid_str, team_id.utf8(), 12, mh.get_exe_limit(), mh.get_code_limit()));
		print_verbose(vformat("CodeSign: Calculating special slot hashes..."));
		if (info_hash2.size() == 0x20) {
			cd2->set_hash_in_slot(info_hash2, CodeSignCodeDirectory::SLOT_INFO_PLIST);
		}
		if (info_hash1.size() == 0x14) {
			cd1->set_hash_in_slot(info_hash1, CodeSignCodeDirectory::SLOT_INFO_PLIST);
		}
		cd1->set_hash_in_slot(rq->get_hash_sha1(), CodeSignCodeDirectory::Slot::SLOT_REQUIREMENTS);
		cd2->set_hash_in_slot(rq->get_hash_sha256(), CodeSignCodeDirectory::Slot::SLOT_REQUIREMENTS);
		if (res_hash2.size() == 0x20) {
			cd2->set_hash_in_slot(res_hash2, CodeSignCodeDirectory::SLOT_RESOURCES);
		}
		if (res_hash1.size() == 0x14) {
			cd1->set_hash_in_slot(res_hash1, CodeSignCodeDirectory::SLOT_RESOURCES);
		}
		if (cet.is_valid()) {
			cd1->set_hash_in_slot(cet->get_hash_sha1(), CodeSignCodeDirectory::Slot::SLOT_ENTITLEMENTS); //Text variant.
			cd2->set_hash_in_slot(cet->get_hash_sha256(), CodeSignCodeDirectory::Slot::SLOT_ENTITLEMENTS);
		}
		if (ceb.is_valid()) {
			cd1->set_hash_in_slot(ceb->get_hash_sha1(), CodeSignCodeDirectory::Slot::SLOT_DER_ENTITLEMENTS); //ASN.1 variant.
			cd2->set_hash_in_slot(ceb->get_hash_sha256(), CodeSignCodeDirectory::Slot::SLOT_DER_ENTITLEMENTS);
		}

		// Calculate signature size.
		int sign_size = 12; // SuperBlob header.
		sign_size += cd1->get_size() + 8;
		sign_size += cd2->get_size() + 8;
		sign_size += rq->get_size() + 8;
		if (cet.is_valid()) {
			sign_size += cet->get_size() + 8;
		}
		if (ceb.is_valid()) {
			sign_size += ceb->get_size() + 8;
		}
		sign_size += 16; // Empty signature size.

		// Alloc/resize signature load command.
		print_verbose(vformat("CodeSign: Reallocating space for the signature superblob (%d)...", sign_size));
		if (!mh.set_signature_size(sign_size)) {
			CLEANUP();
			r_error_msg = TTR("Can't resize signature load command.");
			ERR_FAIL_V_MSG(FAILED, "CodeSign: Can't resize signature load command.");
		}

		print_verbose(vformat("CodeSign: Calculating executable code hashes..."));
		// Calculate executable code hashes.
		PoolByteArray buffer;
		PoolByteArray hash1, hash2;
		hash1.resize(0x14);
		hash2.resize(0x20);
		buffer.resize(1 << 12);
		mh.get_file()->seek(0);
		for (int32_t j = 0; j < cd2->get_page_count(); j++) {
			mh.get_file()->get_buffer(buffer.write().ptr(), (1 << 12));
			CryptoCore::SHA256Context ctx2;
			ctx2.start();
			ctx2.update(buffer.read().ptr(), (1 << 12));
			ctx2.finish(hash2.write().ptr());
			cd2->set_hash_in_slot(hash2, j);

			CryptoCore::SHA1Context ctx1;
			ctx1.start();
			ctx1.update(buffer.read().ptr(), (1 << 12));
			ctx1.finish(hash1.write().ptr());
			cd1->set_hash_in_slot(hash1, j);
		}
		if (cd2->get_page_remainder() > 0) {
			mh.get_file()->get_buffer(buffer.write().ptr(), cd2->get_page_remainder());
			CryptoCore::SHA256Context ctx2;
			ctx2.start();
			ctx2.update(buffer.read().ptr(), cd2->get_page_remainder());
			ctx2.finish(hash2.write().ptr());
			cd2->set_hash_in_slot(hash2, cd2->get_page_count());

			CryptoCore::SHA1Context ctx1;
			ctx1.start();
			ctx1.update(buffer.read().ptr(), cd1->get_page_remainder());
			ctx1.finish(hash1.write().ptr());
			cd1->set_hash_in_slot(hash1, cd1->get_page_count());
		}

		print_verbose(vformat("CodeSign: Generating signature..."));
		Ref<CodeSignSignature> cs;
		cs = Ref<CodeSignSignature>(memnew(CodeSignSignature()));

		print_verbose(vformat("CodeSign: Writing signature superblob..."));
		// Write signature data to the executable.
		CodeSignSuperBlob sb = CodeSignSuperBlob();
		sb.add_blob(cd2);
		sb.add_blob(cd1);
		sb.add_blob(rq);
		if (cet.is_valid()) {
			sb.add_blob(cet);
		}
		if (ceb.is_valid()) {
			sb.add_blob(ceb);
		}
		sb.add_blob(cs);
		mh.get_file()->seek(mh.get_signature_offset());
		sb.write_to_file(mh.get_file());
	}
	if (files_to_sign.size() > 1) {
		print_verbose(vformat("CodeSign: Rebuilding fat executable..."));
		LipO lip;
		if (!lip.create_file(main_exe, files_to_sign)) {
			CLEANUP();
			r_error_msg = TTR("Failed to create fat binary.");
			ERR_FAIL_V_MSG(FAILED, "CodeSign: Failed to create fat binary.");
		}
		CLEANUP();
	}
	FileAccess::set_unix_permissions(main_exe, 0755); // Restore unix permissions.
	return OK;
#undef CLEANUP
}

Error CodeSign::codesign(bool p_use_hardened_runtime, bool p_force, const String &p_path, const String &p_ent_path, String &r_error_msg) {
	DirAccess *da = DirAccess::create(DirAccess::ACCESS_FILESYSTEM);
	if (!da) {
		r_error_msg = TTR("Can't get filesystem access.");
		ERR_FAIL_V_MSG(ERR_CANT_CREATE, "CodeSign: Can't get filesystem access.");
	}

	if (da->dir_exists(p_path)) {
		String fmw_ver = "Current"; // Framework version (default).
		String info_path;
		String main_exe;
		String bundle_path;
		bool bundle = false;
		bool ios_bundle = false;
		if (da->file_exists(p_path.plus_file("Contents/Info.plist"))) {
			info_path = p_path.plus_file("Contents/Info.plist");
			main_exe = p_path.plus_file("Contents/MacOS");
			bundle_path = p_path.plus_file("Contents");
			bundle = true;
		} else if (da->file_exists(p_path.plus_file(vformat("Versions/%s/Resources/Info.plist", fmw_ver)))) {
			info_path = p_path.plus_file(vformat("Versions/%s/Resources/Info.plist", fmw_ver));
			main_exe = p_path.plus_file(vformat("Versions/%s", fmw_ver));
			bundle_path = p_path.plus_file(vformat("Versions/%s", fmw_ver));
			bundle = true;
		} else if (da->file_exists(p_path.plus_file("Info.plist"))) {
			info_path = p_path.plus_file("Info.plist");
			main_exe = p_path;
			bundle_path = p_path;
			bundle = true;
			ios_bundle = true;
		}
		if (bundle) {
			return _codesign_file(p_use_hardened_runtime, p_force, info_path, main_exe, bundle_path, p_ent_path, ios_bundle, r_error_msg);
		} else {
			r_error_msg = TTR("Unknown bundle type.");
			ERR_FAIL_V_MSG(FAILED, "CodeSign: Unknown bundle type.");
		}
	} else if (da->file_exists(p_path)) {
		return _codesign_file(p_use_hardened_runtime, p_force, "", p_path, "", p_ent_path, false, r_error_msg);
	} else {
		r_error_msg = TTR("Unknown object type.");
		ERR_FAIL_V_MSG(FAILED, "CodeSign: Unknown object type.");
	}
}

#endif // MODULE_REGEX_ENABLED