// SPDX-FileCopyrightText: Copyright 2024 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later
#pragma once
#include "common/assert.h"
#include "common/common_funcs.h"
#include "common/common_types.h"
#include "common/scope_exit.h"
#include "core/file_sys/fs_directory.h"
#include "core/file_sys/fs_memory_management.h"
#include "core/file_sys/fs_string_util.h"
#include "core/hle/result.h"
namespace FileSys {
constexpr inline size_t MountNameLengthMax = 15;
namespace StringTraits {
constexpr inline char DirectorySeparator = '/';
constexpr inline char DriveSeparator = ':';
constexpr inline char Dot = '.';
constexpr inline char NullTerminator = '\x00';
constexpr inline char AlternateDirectorySeparator = '\\';
constexpr inline const char InvalidCharacters[6] = {':', '*', '?', '<', '>', '|'};
constexpr inline const char InvalidCharactersForHostName[6] = {':', '*', '<', '>', '|', '$'};
constexpr inline const char InvalidCharactersForMountName[5] = {'*', '?', '<', '>', '|'};
namespace impl {
template <const char* InvalidCharacterSet, size_t NumInvalidCharacters>
consteval u64 MakeInvalidCharacterMask(size_t n) {
u64 mask = 0;
for (size_t i = 0; i < NumInvalidCharacters; ++i) {
if ((static_cast<u64>(InvalidCharacterSet[i]) >> 6) == n) {
mask |= static_cast<u64>(1) << (static_cast<u64>(InvalidCharacterSet[i]) & 0x3F);
}
}
return mask;
}
template <const char* InvalidCharacterSet, size_t NumInvalidCharacters>
constexpr bool IsInvalidCharacterImpl(char c) {
constexpr u64 Masks[4] = {
MakeInvalidCharacterMask<InvalidCharacterSet, NumInvalidCharacters>(0),
MakeInvalidCharacterMask<InvalidCharacterSet, NumInvalidCharacters>(1),
MakeInvalidCharacterMask<InvalidCharacterSet, NumInvalidCharacters>(2),
MakeInvalidCharacterMask<InvalidCharacterSet, NumInvalidCharacters>(3)};
return (Masks[static_cast<u64>(c) >> 6] &
(static_cast<u64>(1) << (static_cast<u64>(c) & 0x3F))) != 0;
}
} // namespace impl
constexpr bool IsInvalidCharacter(char c) {
return impl::IsInvalidCharacterImpl<InvalidCharacters, Common::Size(InvalidCharacters)>(c);
}
constexpr bool IsInvalidCharacterForHostName(char c) {
return impl::IsInvalidCharacterImpl<InvalidCharactersForHostName,
Common::Size(InvalidCharactersForHostName)>(c);
}
constexpr bool IsInvalidCharacterForMountName(char c) {
return impl::IsInvalidCharacterImpl<InvalidCharactersForMountName,
Common::Size(InvalidCharactersForMountName)>(c);
}
} // namespace StringTraits
constexpr inline size_t WindowsDriveLength = 2;
constexpr inline size_t UncPathPrefixLength = 2;
constexpr inline size_t DosDevicePathPrefixLength = 4;
class PathFlags {
private:
static constexpr u32 WindowsPathFlag = (1 << 0);
static constexpr u32 RelativePathFlag = (1 << 1);
static constexpr u32 EmptyPathFlag = (1 << 2);
static constexpr u32 MountNameFlag = (1 << 3);
static constexpr u32 BackslashFlag = (1 << 4);
static constexpr u32 AllCharactersFlag = (1 << 5);
private:
u32 m_value;
public:
constexpr PathFlags() : m_value(0) { /* ... */
}
#define DECLARE_PATH_FLAG_HANDLER(__WHICH__) \
constexpr bool Is##__WHICH__##Allowed() const { return (m_value & __WHICH__##Flag) != 0; } \
constexpr void Allow##__WHICH__() { m_value |= __WHICH__##Flag; }
DECLARE_PATH_FLAG_HANDLER(WindowsPath)
DECLARE_PATH_FLAG_HANDLER(RelativePath)
DECLARE_PATH_FLAG_HANDLER(EmptyPath)
DECLARE_PATH_FLAG_HANDLER(MountName)
DECLARE_PATH_FLAG_HANDLER(Backslash)
DECLARE_PATH_FLAG_HANDLER(AllCharacters)
#undef DECLARE_PATH_FLAG_HANDLER
};
template <typename T>
requires(std::same_as<T, char> || std::same_as<T, wchar_t>)
constexpr inline bool IsDosDevicePath(const T* path) {
ASSERT(path != nullptr);
using namespace StringTraits;
return path[0] == AlternateDirectorySeparator && path[1] == AlternateDirectorySeparator &&
(path[2] == Dot || path[2] == '?') &&
(path[3] == DirectorySeparator || path[3] == AlternateDirectorySeparator);
}
template <typename T>
requires(std::same_as<T, char> || std::same_as<T, wchar_t>)
constexpr inline bool IsUncPath(const T* path, bool allow_forward_slash = true,
bool allow_back_slash = true) {
ASSERT(path != nullptr);
using namespace StringTraits;
return (allow_forward_slash && path[0] == DirectorySeparator &&
path[1] == DirectorySeparator) ||
(allow_back_slash && path[0] == AlternateDirectorySeparator &&
path[1] == AlternateDirectorySeparator);
}
constexpr inline bool IsWindowsDrive(const char* path) {
ASSERT(path != nullptr);
return (('a' <= path[0] && path[0] <= 'z') || ('A' <= path[0] && path[0] <= 'Z')) &&
path[1] == StringTraits::DriveSeparator;
}
constexpr inline bool IsWindowsPath(const char* path, bool allow_forward_slash_unc) {
return IsWindowsDrive(path) || IsDosDevicePath(path) ||
IsUncPath(path, allow_forward_slash_unc, true);
}
constexpr inline int GetWindowsSkipLength(const char* path) {
if (IsDosDevicePath(path)) {
return DosDevicePathPrefixLength;
} else if (IsWindowsDrive(path)) {
return WindowsDriveLength;
} else if (IsUncPath(path)) {
return UncPathPrefixLength;
} else {
return 0;
}
}
constexpr inline bool IsPathAbsolute(const char* path) {
return IsWindowsPath(path, false) || path[0] == StringTraits::DirectorySeparator;
}
constexpr inline bool IsPathRelative(const char* path) {
return path[0] && !IsPathAbsolute(path);
}
constexpr inline bool IsCurrentDirectory(const char* path) {
return path[0] == StringTraits::Dot &&
(path[1] == StringTraits::NullTerminator || path[1] == StringTraits::DirectorySeparator);
}
constexpr inline bool IsParentDirectory(const char* path) {
return path[0] == StringTraits::Dot && path[1] == StringTraits::Dot &&
(path[2] == StringTraits::NullTerminator || path[2] == StringTraits::DirectorySeparator);
}
constexpr inline bool IsPathStartWithCurrentDirectory(const char* path) {
return IsCurrentDirectory(path) || IsParentDirectory(path);
}
constexpr inline bool IsSubPath(const char* lhs, const char* rhs) {
// Check pre-conditions
ASSERT(lhs != nullptr);
ASSERT(rhs != nullptr);
// Import StringTraits names for current scope
using namespace StringTraits;
// Special case certain paths
if (IsUncPath(lhs) && !IsUncPath(rhs)) {
return false;
}
if (!IsUncPath(lhs) && IsUncPath(rhs)) {
return false;
}
if (lhs[0] == DirectorySeparator && lhs[1] == NullTerminator && rhs[0] == DirectorySeparator &&
rhs[1] != NullTerminator) {
return true;
}
if (rhs[0] == DirectorySeparator && rhs[1] == NullTerminator && lhs[0] == DirectorySeparator &&
lhs[1] != NullTerminator) {
return true;
}
// Check subpath
for (size_t i = 0; /* ... */; ++i) {
if (lhs[i] == NullTerminator) {
return rhs[i] == DirectorySeparator;
} else if (rhs[i] == NullTerminator) {
return lhs[i] == DirectorySeparator;
} else if (lhs[i] != rhs[i]) {
return false;
}
}
}
// Path utilities
constexpr inline void Replace(char* dst, size_t dst_size, char old_char, char new_char) {
ASSERT(dst != nullptr);
for (char* cur = dst; cur < dst + dst_size && *cur; ++cur) {
if (*cur == old_char) {
*cur = new_char;
}
}
}
constexpr inline Result CheckUtf8(const char* s) {
// Check pre-conditions
ASSERT(s != nullptr);
// Iterate, checking for utf8-validity
while (*s) {
char utf8_buf[4] = {};
const auto pick_res = PickOutCharacterFromUtf8String(utf8_buf, std::addressof(s));
R_UNLESS(pick_res == CharacterEncodingResult_Success, ResultInvalidPathFormat);
u32 dummy;
const auto cvt_res = ConvertCharacterUtf8ToUtf32(std::addressof(dummy), utf8_buf);
R_UNLESS(cvt_res == CharacterEncodingResult_Success, ResultInvalidPathFormat);
}
R_SUCCEED();
}
// Path formatting
class PathNormalizer {
private:
enum class PathState {
Start,
Normal,
FirstSeparator,
Separator,
CurrentDir,
ParentDir,
};
private:
static constexpr void ReplaceParentDirectoryPath(char* dst, const char* src) {
// Use StringTraits names for remainder of scope
using namespace StringTraits;
// Start with a dir-separator
dst[0] = DirectorySeparator;
auto i = 1;
while (src[i] != NullTerminator) {
if ((src[i - 1] == DirectorySeparator || src[i - 1] == AlternateDirectorySeparator) &&
src[i + 0] == Dot && src[i + 1] == Dot &&
(src[i + 2] == DirectorySeparator || src[i + 2] == AlternateDirectorySeparator)) {
dst[i - 1] = DirectorySeparator;
dst[i + 0] = Dot;
dst[i + 1] = Dot;
dst[i + 2] = DirectorySeparator;
i += 3;
} else {
if (src[i - 1] == AlternateDirectorySeparator && src[i + 0] == Dot &&
src[i + 1] == Dot && src[i + 2] == NullTerminator) {
dst[i - 1] = DirectorySeparator;
dst[i + 0] = Dot;
dst[i + 1] = Dot;
i += 2;
break;
}
dst[i] = src[i];
++i;
}
}
dst[i] = StringTraits::NullTerminator;
}
public:
static constexpr bool IsParentDirectoryPathReplacementNeeded(const char* path) {
// Use StringTraits names for remainder of scope
using namespace StringTraits;
if (path[0] != DirectorySeparator && path[0] != AlternateDirectorySeparator) {
return false;
}
// Check to find a parent reference using alternate separators
if (path[0] != NullTerminator && path[1] != NullTerminator && path[2] != NullTerminator) {
size_t i;
for (i = 0; path[i + 3] != NullTerminator; ++path) {
if (path[i + 1] != Dot || path[i + 2] != Dot) {
continue;
}
const char c0 = path[i + 0];
const char c3 = path[i + 3];
if (c0 == AlternateDirectorySeparator &&
(c3 == DirectorySeparator || c3 == AlternateDirectorySeparator ||
c3 == NullTerminator)) {
return true;
}
if (c3 == AlternateDirectorySeparator &&
(c0 == DirectorySeparator || c0 == AlternateDirectorySeparator)) {
return true;
}
}
if (path[i + 0] == AlternateDirectorySeparator && path[i + 1] == Dot &&
path[i + 2] == Dot /* && path[i + 3] == NullTerminator */) {
return true;
}
}
return false;
}
static constexpr Result IsNormalized(bool* out, size_t* out_len, const char* path,
bool allow_all_characters = false) {
// Use StringTraits names for remainder of scope
using namespace StringTraits;
// Parse the path
auto state = PathState::Start;
size_t len = 0;
while (path[len] != NullTerminator) {
// Get the current character
const char c = path[len++];
// Check the current character is valid
if (!allow_all_characters && state != PathState::Start) {
R_UNLESS(!IsInvalidCharacter(c), ResultInvalidCharacter);
}
// Process depending on current state
switch (state) {
// Import the PathState enums for convenience
using enum PathState;
case Start:
R_UNLESS(c == DirectorySeparator, ResultInvalidPathFormat);
state = FirstSeparator;
break;
case Normal:
if (c == DirectorySeparator) {
state = Separator;
}
break;
case FirstSeparator:
case Separator:
if (c == DirectorySeparator) {
*out = false;
R_SUCCEED();
}
if (c == Dot) {
state = CurrentDir;
} else {
state = Normal;
}
break;
case CurrentDir:
if (c == DirectorySeparator) {
*out = false;
R_SUCCEED();
}
if (c == Dot) {
state = ParentDir;
} else {
state = Normal;
}
break;
case ParentDir:
if (c == DirectorySeparator) {
*out = false;
R_SUCCEED();
}
state = Normal;
break;
default:
UNREACHABLE();
break;
}
}
// Check the final state
switch (state) {
// Import the PathState enums for convenience
using enum PathState;
case Start:
R_THROW(ResultInvalidPathFormat);
case Normal:
case FirstSeparator:
*out = true;
break;
case Separator:
case CurrentDir:
case ParentDir:
*out = false;
break;
default:
UNREACHABLE();
break;
}
// Set the output length
*out_len = len;
R_SUCCEED();
}
static constexpr Result Normalize(char* dst, size_t* out_len, const char* path,
size_t max_out_size, bool is_windows_path,
bool is_drive_relative_path,
bool allow_all_characters = false) {
// Use StringTraits names for remainder of scope
using namespace StringTraits;
// Prepare to iterate
const char* cur_path = path;
size_t total_len = 0;
// If path begins with a separator, check that we're not drive relative
if (cur_path[0] != DirectorySeparator) {
R_UNLESS(is_drive_relative_path, ResultInvalidPathFormat);
dst[total_len++] = DirectorySeparator;
}
// We're going to need to do path replacement, potentially
char* replacement_path = nullptr;
size_t replacement_path_size = 0;
SCOPE_EXIT {
if (replacement_path != nullptr) {
if (std::is_constant_evaluated()) {
delete[] replacement_path;
} else {
Deallocate(replacement_path, replacement_path_size);
}
}
};
// Perform path replacement, if necessary
if (IsParentDirectoryPathReplacementNeeded(cur_path)) {
if (std::is_constant_evaluated()) {
replacement_path_size = EntryNameLengthMax + 1;
replacement_path = new char[replacement_path_size];
} else {
replacement_path_size = EntryNameLengthMax + 1;
replacement_path = static_cast<char*>(Allocate(replacement_path_size));
}
ReplaceParentDirectoryPath(replacement_path, cur_path);
cur_path = replacement_path;
}
// Iterate, normalizing path components
bool skip_next_sep = false;
size_t i = 0;
while (cur_path[i] != NullTerminator) {
// Process a directory separator, if we run into one
if (cur_path[i] == DirectorySeparator) {
// Swallow separators
do {
++i;
} while (cur_path[i] == DirectorySeparator);
// Check if we hit end of string
if (cur_path[i] == NullTerminator) {
break;
}
// If we aren't skipping the separator, write it, checking that we remain in bounds.
if (!skip_next_sep) {
if (total_len + 1 == max_out_size) {
dst[total_len] = NullTerminator;
*out_len = total_len;
R_THROW(ResultTooLongPath);
}
dst[total_len++] = DirectorySeparator;
}
// Don't skip the next separator
skip_next_sep = false;
}
// Get the length of the current directory component
size_t dir_len = 0;
while (cur_path[i + dir_len] != DirectorySeparator &&
cur_path[i + dir_len] != NullTerminator) {
// Check for validity
if (!allow_all_characters) {
R_UNLESS(!IsInvalidCharacter(cur_path[i + dir_len]), ResultInvalidCharacter);
}
++dir_len;
}
// Handle the current dir component
if (IsCurrentDirectory(cur_path + i)) {
skip_next_sep = true;
} else if (IsParentDirectory(cur_path + i)) {
// We should have just written a separator
ASSERT(dst[total_len - 1] == DirectorySeparator);
// We should have started with a separator, for non-windows paths
if (!is_windows_path) {
ASSERT(dst[0] == DirectorySeparator);
}
// Remove the previous component
if (total_len == 1) {
R_UNLESS(is_windows_path, ResultDirectoryUnobtainable);
--total_len;
} else {
total_len -= 2;
do {
if (dst[total_len] == DirectorySeparator) {
break;
}
} while ((--total_len) != 0);
}
// We should be pointing to a directory separator, for non-windows paths
if (!is_windows_path) {
ASSERT(dst[total_len] == DirectorySeparator);
}
// We should remain in bounds
ASSERT(total_len < max_out_size);
} else {
// Copy, possibly truncating
if (total_len + dir_len + 1 > max_out_size) {
const size_t copy_len = max_out_size - (total_len + 1);
for (size_t j = 0; j < copy_len; ++j) {
dst[total_len++] = cur_path[i + j];
}
dst[total_len] = NullTerminator;
*out_len = total_len;
R_THROW(ResultTooLongPath);
}
for (size_t j = 0; j < dir_len; ++j) {
dst[total_len++] = cur_path[i + j];
}
}
// Advance past the current directory component
i += dir_len;
}
if (skip_next_sep) {
--total_len;
}
if (total_len == 0 && max_out_size != 0) {
total_len = 1;
dst[0] = DirectorySeparator;
}
// NOTE: Probable nintendo bug, as max_out_size must be at least total_len + 1 for the null
// terminator.
R_UNLESS(max_out_size >= total_len - 1, ResultTooLongPath);
dst[total_len] = NullTerminator;
// Check that the result path is normalized
bool is_normalized;
size_t dummy;
R_TRY(IsNormalized(std::addressof(is_normalized), std::addressof(dummy), dst,
allow_all_characters));
// Assert that the result path is normalized
ASSERT(is_normalized);
// Set the output length
*out_len = total_len;
R_SUCCEED();
}
};
class PathFormatter {
private:
static constexpr Result CheckSharedName(const char* name, size_t len) {
// Use StringTraits names for remainder of scope
using namespace StringTraits;
if (len == 1) {
R_UNLESS(name[0] != Dot, ResultInvalidPathFormat);
} else if (len == 2) {
R_UNLESS(name[0] != Dot || name[1] != Dot, ResultInvalidPathFormat);
}
for (size_t i = 0; i < len; ++i) {
R_UNLESS(!IsInvalidCharacter(name[i]), ResultInvalidCharacter);
}
R_SUCCEED();
}
static constexpr Result CheckHostName(const char* name, size_t len) {
// Use StringTraits names for remainder of scope
using namespace StringTraits;
if (len == 2) {
R_UNLESS(name[0] != Dot || name[1] != Dot, ResultInvalidPathFormat);
}
for (size_t i = 0; i < len; ++i) {
R_UNLESS(!IsInvalidCharacterForHostName(name[i]), ResultInvalidCharacter);
}
R_SUCCEED();
}
static constexpr Result CheckInvalidBackslash(bool* out_contains_backslash, const char* path,
bool allow_backslash) {
// Use StringTraits names for remainder of scope
using namespace StringTraits;
// Default to no backslashes, so we can just write if we see one
*out_contains_backslash = false;
while (*path != NullTerminator) {
if (*(path++) == AlternateDirectorySeparator) {
*out_contains_backslash = true;
R_UNLESS(allow_backslash, ResultInvalidCharacter);
}
}
R_SUCCEED();
}
public:
static constexpr Result CheckPathFormat(const char* path, const PathFlags& flags) {
bool normalized;
size_t len;
R_RETURN(IsNormalized(std::addressof(normalized), std::addressof(len), path, flags));
}
static constexpr Result SkipMountName(const char** out, size_t* out_len, const char* path) {
R_RETURN(ParseMountName(out, out_len, nullptr, 0, path));
}
static constexpr Result ParseMountName(const char** out, size_t* out_len, char* out_mount_name,
size_t out_mount_name_buffer_size, const char* path) {
// Check pre-conditions
ASSERT(path != nullptr);
ASSERT(out_len != nullptr);
ASSERT(out != nullptr);
ASSERT((out_mount_name == nullptr) == (out_mount_name_buffer_size == 0));
// Use StringTraits names for remainder of scope
using namespace StringTraits;
// Determine max mount length
const auto max_mount_len =
out_mount_name_buffer_size == 0
? MountNameLengthMax + 1
: std::min(MountNameLengthMax + 1, out_mount_name_buffer_size);
// Parse the path until we see a drive separator
size_t mount_len = 0;
for (/* ... */; mount_len < max_mount_len && path[mount_len]; ++mount_len) {
const char c = path[mount_len];
// If we see a drive separator, advance, then we're done with the pre-drive separator
// part of the mount.
if (c == DriveSeparator) {
++mount_len;
break;
}
// If we see a directory separator, we're not in a mount name
if (c == DirectorySeparator || c == AlternateDirectorySeparator) {
*out = path;
*out_len = 0;
R_SUCCEED();
}
}
// Check to be sure we're actually looking at a mount name
if (mount_len <= 2 || path[mount_len - 1] != DriveSeparator) {
*out = path;
*out_len = 0;
R_SUCCEED();
}
// Check that all characters in the mount name are allowable
for (size_t i = 0; i < mount_len; ++i) {
R_UNLESS(!IsInvalidCharacterForMountName(path[i]), ResultInvalidCharacter);
}
// Copy out the mount name
if (out_mount_name_buffer_size > 0) {
R_UNLESS(mount_len < out_mount_name_buffer_size, ResultTooLongPath);
for (size_t i = 0; i < mount_len; ++i) {
out_mount_name[i] = path[i];
}
out_mount_name[mount_len] = NullTerminator;
}
// Set the output
*out = path + mount_len;
*out_len = mount_len;
R_SUCCEED();
}
static constexpr Result SkipRelativeDotPath(const char** out, size_t* out_len,
const char* path) {
R_RETURN(ParseRelativeDotPath(out, out_len, nullptr, 0, path));
}
static constexpr Result ParseRelativeDotPath(const char** out, size_t* out_len,
char* out_relative,
size_t out_relative_buffer_size,
const char* path) {
// Check pre-conditions
ASSERT(path != nullptr);
ASSERT(out_len != nullptr);
ASSERT(out != nullptr);
ASSERT((out_relative == nullptr) == (out_relative_buffer_size == 0));
// Use StringTraits names for remainder of scope
using namespace StringTraits;
// Initialize the output buffer, if we have one
if (out_relative_buffer_size > 0) {
out_relative[0] = NullTerminator;
}
// Check if the path is relative
if (path[0] == Dot && (path[1] == NullTerminator || path[1] == DirectorySeparator ||
path[1] == AlternateDirectorySeparator)) {
if (out_relative_buffer_size > 0) {
R_UNLESS(out_relative_buffer_size >= 2, ResultTooLongPath);
out_relative[0] = Dot;
out_relative[1] = NullTerminator;
}
*out = path + 1;
*out_len = 1;
R_SUCCEED();
}
// Ensure the path isn't a parent directory
R_UNLESS(!(path[0] == Dot && path[1] == Dot), ResultDirectoryUnobtainable);
// There was no relative dot path
*out = path;
*out_len = 0;
R_SUCCEED();
}
static constexpr Result SkipWindowsPath(const char** out, size_t* out_len, bool* out_normalized,
const char* path, bool has_mount_name) {
// We're normalized if and only if the parsing doesn't throw ResultNotNormalized()
*out_normalized = true;
R_TRY_CATCH(ParseWindowsPath(out, out_len, nullptr, 0, path, has_mount_name)) {
R_CATCH(ResultNotNormalized) {
*out_normalized = false;
}
}
R_END_TRY_CATCH;
ON_RESULT_INCLUDED(ResultNotNormalized) {
*out_normalized = false;
};
R_SUCCEED();
}
static constexpr Result ParseWindowsPath(const char** out, size_t* out_len, char* out_win,
size_t out_win_buffer_size, const char* path,
bool has_mount_name) {
// Check pre-conditions
ASSERT(path != nullptr);
ASSERT(out_len != nullptr);
ASSERT(out != nullptr);
ASSERT((out_win == nullptr) == (out_win_buffer_size == 0));
// Use StringTraits names for remainder of scope
using namespace StringTraits;
// Initialize the output buffer, if we have one
if (out_win_buffer_size > 0) {
out_win[0] = NullTerminator;
}
// Handle path start
const char* cur_path = path;
if (has_mount_name && path[0] == DirectorySeparator) {
if (path[1] == AlternateDirectorySeparator && path[2] == AlternateDirectorySeparator) {
R_UNLESS(out_win_buffer_size > 0, ResultNotNormalized);
++cur_path;
} else if (IsWindowsDrive(path + 1)) {
R_UNLESS(out_win_buffer_size > 0, ResultNotNormalized);
++cur_path;
}
}
// Handle windows drive
if (IsWindowsDrive(cur_path)) {
// Parse up to separator
size_t win_path_len = WindowsDriveLength;
for (/* ... */; cur_path[win_path_len] != NullTerminator; ++win_path_len) {
R_UNLESS(!IsInvalidCharacter(cur_path[win_path_len]), ResultInvalidCharacter);
if (cur_path[win_path_len] == DirectorySeparator ||
cur_path[win_path_len] == AlternateDirectorySeparator) {
break;
}
}
// Ensure that we're normalized, if we're required to be
if (out_win_buffer_size == 0) {
for (size_t i = 0; i < win_path_len; ++i) {
R_UNLESS(cur_path[i] != AlternateDirectorySeparator, ResultNotNormalized);
}
} else {
// Ensure we can copy into the normalized buffer
R_UNLESS(win_path_len < out_win_buffer_size, ResultTooLongPath);
for (size_t i = 0; i < win_path_len; ++i) {
out_win[i] = cur_path[i];
}
out_win[win_path_len] = NullTerminator;
Replace(out_win, win_path_len, AlternateDirectorySeparator, DirectorySeparator);
}
*out = cur_path + win_path_len;
*out_len = win_path_len;
R_SUCCEED();
}
// Handle DOS device
if (IsDosDevicePath(cur_path)) {
size_t dos_prefix_len = DosDevicePathPrefixLength;
if (IsWindowsDrive(cur_path + dos_prefix_len)) {
dos_prefix_len += WindowsDriveLength;
} else {
--dos_prefix_len;
}
if (out_win_buffer_size > 0) {
// Ensure we can copy into the normalized buffer
R_UNLESS(dos_prefix_len < out_win_buffer_size, ResultTooLongPath);
for (size_t i = 0; i < dos_prefix_len; ++i) {
out_win[i] = cur_path[i];
}
out_win[dos_prefix_len] = NullTerminator;
Replace(out_win, dos_prefix_len, DirectorySeparator, AlternateDirectorySeparator);
}
*out = cur_path + dos_prefix_len;
*out_len = dos_prefix_len;
R_SUCCEED();
}
// Handle UNC path
if (IsUncPath(cur_path, false, true)) {
const char* final_path = cur_path;
R_UNLESS(cur_path[UncPathPrefixLength] != DirectorySeparator, ResultInvalidPathFormat);
R_UNLESS(cur_path[UncPathPrefixLength] != AlternateDirectorySeparator,
ResultInvalidPathFormat);
size_t cur_component_offset = 0;
size_t pos = UncPathPrefixLength;
for (/* ... */; cur_path[pos] != NullTerminator; ++pos) {
if (cur_path[pos] == DirectorySeparator ||
cur_path[pos] == AlternateDirectorySeparator) {
if (cur_component_offset != 0) {
R_TRY(CheckSharedName(cur_path + cur_component_offset,
pos - cur_component_offset));
final_path = cur_path + pos;
break;
}
R_UNLESS(cur_path[pos + 1] != DirectorySeparator, ResultInvalidPathFormat);
R_UNLESS(cur_path[pos + 1] != AlternateDirectorySeparator,
ResultInvalidPathFormat);
R_TRY(CheckHostName(cur_path + 2, pos - 2));
cur_component_offset = pos + 1;
}
}
R_UNLESS(cur_component_offset != pos, ResultInvalidPathFormat);
if (cur_component_offset != 0 && final_path == cur_path) {
R_TRY(CheckSharedName(cur_path + cur_component_offset, pos - cur_component_offset));
final_path = cur_path + pos;
}
size_t unc_prefix_len = final_path - cur_path;
// Ensure that we're normalized, if we're required to be
if (out_win_buffer_size == 0) {
for (size_t i = 0; i < unc_prefix_len; ++i) {
R_UNLESS(cur_path[i] != DirectorySeparator, ResultNotNormalized);
}
} else {
// Ensure we can copy into the normalized buffer
R_UNLESS(unc_prefix_len < out_win_buffer_size, ResultTooLongPath);
for (size_t i = 0; i < unc_prefix_len; ++i) {
out_win[i] = cur_path[i];
}
out_win[unc_prefix_len] = NullTerminator;
Replace(out_win, unc_prefix_len, DirectorySeparator, AlternateDirectorySeparator);
}
*out = cur_path + unc_prefix_len;
*out_len = unc_prefix_len;
R_SUCCEED();
}
// There's no windows path to parse
*out = path;
*out_len = 0;
R_SUCCEED();
}
static constexpr Result IsNormalized(bool* out, size_t* out_len, const char* path,
const PathFlags& flags = {}) {
// Ensure nothing is null
R_UNLESS(out != nullptr, ResultNullptrArgument);
R_UNLESS(out_len != nullptr, ResultNullptrArgument);
R_UNLESS(path != nullptr, ResultNullptrArgument);
// Verify that the path is valid utf-8
R_TRY(CheckUtf8(path));
// Use StringTraits names for remainder of scope
using namespace StringTraits;
// Handle the case where the path is empty
if (path[0] == NullTerminator) {
R_UNLESS(flags.IsEmptyPathAllowed(), ResultInvalidPathFormat);
*out = true;
*out_len = 0;
R_SUCCEED();
}
// All normalized paths start with a directory separator...unless they're windows paths,
// relative paths, or have mount names.
if (path[0] != DirectorySeparator) {
R_UNLESS(flags.IsWindowsPathAllowed() || flags.IsRelativePathAllowed() ||
flags.IsMountNameAllowed(),
ResultInvalidPathFormat);
}
// Check that the path is allowed to be a windows path, if it is
if (IsWindowsPath(path, false)) {
R_UNLESS(flags.IsWindowsPathAllowed(), ResultInvalidPathFormat);
}
// Skip past the mount name, if one is present
size_t total_len = 0;
size_t mount_name_len = 0;
R_TRY(SkipMountName(std::addressof(path), std::addressof(mount_name_len), path));
// If we had a mount name, check that that was allowed
if (mount_name_len > 0) {
R_UNLESS(flags.IsMountNameAllowed(), ResultInvalidPathFormat);
total_len += mount_name_len;
}
// Check that the path starts as a normalized path should
if (path[0] != DirectorySeparator && !IsPathStartWithCurrentDirectory(path) &&
!IsWindowsPath(path, false)) {
R_UNLESS(flags.IsRelativePathAllowed(), ResultInvalidPathFormat);
R_UNLESS(!IsInvalidCharacter(path[0]), ResultInvalidPathFormat);
*out = false;
R_SUCCEED();
}
// Process relative path
size_t relative_len = 0;
R_TRY(SkipRelativeDotPath(std::addressof(path), std::addressof(relative_len), path));
// If we have a relative path, check that was allowed
if (relative_len > 0) {
R_UNLESS(flags.IsRelativePathAllowed(), ResultInvalidPathFormat);
total_len += relative_len;
if (path[0] == NullTerminator) {
*out = true;
*out_len = total_len;
R_SUCCEED();
}
}
// Process windows path
size_t windows_len = 0;
bool normalized_win = false;
R_TRY(SkipWindowsPath(std::addressof(path), std::addressof(windows_len),
std::addressof(normalized_win), path, mount_name_len > 0));
// If the windows path wasn't normalized, we're not normalized
if (!normalized_win) {
R_UNLESS(flags.IsWindowsPathAllowed(), ResultInvalidPathFormat);
*out = false;
R_SUCCEED();
}
// If we had a windows path, check that was allowed
if (windows_len > 0) {
R_UNLESS(flags.IsWindowsPathAllowed(), ResultInvalidPathFormat);
total_len += windows_len;
// We can't have both a relative path and a windows path
R_UNLESS(relative_len == 0, ResultInvalidPathFormat);
// A path ending in a windows path isn't normalized
if (path[0] == NullTerminator) {
*out = false;
R_SUCCEED();
}
// Check that there are no windows directory separators in the path
for (size_t i = 0; path[i] != NullTerminator; ++i) {
if (path[i] == AlternateDirectorySeparator) {
*out = false;
R_SUCCEED();
}
}
}
// Check that parent directory replacement is not needed if backslashes are allowed
if (flags.IsBackslashAllowed() &&
PathNormalizer::IsParentDirectoryPathReplacementNeeded(path)) {
*out = false;
R_SUCCEED();
}
// Check that the backslash state is valid
bool is_backslash_contained = false;
R_TRY(CheckInvalidBackslash(std::addressof(is_backslash_contained), path,
flags.IsWindowsPathAllowed() || flags.IsBackslashAllowed()));
// Check that backslashes are contained only if allowed
if (is_backslash_contained && !flags.IsBackslashAllowed()) {
*out = false;
R_SUCCEED();
}
// Check that the final result path is normalized
size_t normal_len = 0;
R_TRY(PathNormalizer::IsNormalized(out, std::addressof(normal_len), path,
flags.IsAllCharactersAllowed()));
// Add the normal length
total_len += normal_len;
// Set the output length
*out_len = total_len;
R_SUCCEED();
}
static constexpr Result Normalize(char* dst, size_t dst_size, const char* path, size_t path_len,
const PathFlags& flags) {
// Use StringTraits names for remainder of scope
using namespace StringTraits;
// Prepare to iterate
const char* src = path;
size_t cur_pos = 0;
bool is_windows_path = false;
// Check if the path is empty
if (src[0] == NullTerminator) {
if (dst_size != 0) {
dst[0] = NullTerminator;
}
R_UNLESS(flags.IsEmptyPathAllowed(), ResultInvalidPathFormat);
R_SUCCEED();
}
// Handle a mount name
size_t mount_name_len = 0;
if (flags.IsMountNameAllowed()) {
R_TRY(ParseMountName(std::addressof(src), std::addressof(mount_name_len), dst + cur_pos,
dst_size - cur_pos, src));
cur_pos += mount_name_len;
}
// Handle a drive-relative prefix
bool is_drive_relative = false;
if (src[0] != DirectorySeparator && !IsPathStartWithCurrentDirectory(src) &&
!IsWindowsPath(src, false)) {
R_UNLESS(flags.IsRelativePathAllowed(), ResultInvalidPathFormat);
R_UNLESS(!IsInvalidCharacter(src[0]), ResultInvalidPathFormat);
dst[cur_pos++] = Dot;
is_drive_relative = true;
}
size_t relative_len = 0;
if (flags.IsRelativePathAllowed()) {
R_UNLESS(cur_pos < dst_size, ResultTooLongPath);
R_TRY(ParseRelativeDotPath(std::addressof(src), std::addressof(relative_len),
dst + cur_pos, dst_size - cur_pos, src));
cur_pos += relative_len;
if (src[0] == NullTerminator) {
R_UNLESS(cur_pos < dst_size, ResultTooLongPath);
dst[cur_pos] = NullTerminator;
R_SUCCEED();
}
}
// Handle a windows path
if (flags.IsWindowsPathAllowed()) {
const char* const orig = src;
R_UNLESS(cur_pos < dst_size, ResultTooLongPath);
size_t windows_len = 0;
R_TRY(ParseWindowsPath(std::addressof(src), std::addressof(windows_len), dst + cur_pos,
dst_size - cur_pos, src, mount_name_len != 0));
cur_pos += windows_len;
if (src[0] == NullTerminator) {
/* NOTE: Bug in original code here repeated, should be checking cur_pos + 2. */
R_UNLESS(cur_pos + 1 < dst_size, ResultTooLongPath);
dst[cur_pos + 0] = DirectorySeparator;
dst[cur_pos + 1] = NullTerminator;
R_SUCCEED();
}
if ((src - orig) > 0) {
is_windows_path = true;
}
}
// Check for invalid backslash
bool backslash_contained = false;
R_TRY(CheckInvalidBackslash(std::addressof(backslash_contained), src,
flags.IsWindowsPathAllowed() || flags.IsBackslashAllowed()));
// Handle backslash replacement as necessary
if (backslash_contained && flags.IsWindowsPathAllowed()) {
// Create a temporary buffer holding a slash-replaced version of the path.
// NOTE: Nintendo unnecessarily allocates and replaces here a fully copy of the path,
// despite having skipped some of it already.
const size_t replaced_src_len = path_len - (src - path);
char* replaced_src = nullptr;
SCOPE_EXIT {
if (replaced_src != nullptr) {
if (std::is_constant_evaluated()) {
delete[] replaced_src;
} else {
Deallocate(replaced_src, replaced_src_len);
}
}
};
if (std::is_constant_evaluated()) {
replaced_src = new char[replaced_src_len];
} else {
replaced_src = static_cast<char*>(Allocate(replaced_src_len));
}
Strlcpy<char>(replaced_src, src, replaced_src_len);
Replace(replaced_src, replaced_src_len, AlternateDirectorySeparator,
DirectorySeparator);
size_t dummy;
R_TRY(PathNormalizer::Normalize(dst + cur_pos, std::addressof(dummy), replaced_src,
dst_size - cur_pos, is_windows_path, is_drive_relative,
flags.IsAllCharactersAllowed()));
} else {
// We can just do normalization
size_t dummy;
R_TRY(PathNormalizer::Normalize(dst + cur_pos, std::addressof(dummy), src,
dst_size - cur_pos, is_windows_path, is_drive_relative,
flags.IsAllCharactersAllowed()));
}
R_SUCCEED();
}
};
} // namespace FileSys