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ImHex/plugins/libimhex/include/hex/helpers/utils.hpp

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#pragma once
#include <hex.hpp>
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#include <hex/helpers/concepts.hpp>
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#include <array>
#include <bit>
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#include <cstring>
#include <cctype>
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#include <functional>
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#include <limits>
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#include <memory>
#include <optional>
#include <string>
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#include <type_traits>
#include <variant>
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#include <vector>
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#include <nfd.hpp>
#define TOKEN_CONCAT_IMPL(x, y) x ## y
#define TOKEN_CONCAT(x, y) TOKEN_CONCAT_IMPL(x, y)
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#define ANONYMOUS_VARIABLE(prefix) TOKEN_CONCAT(prefix, __COUNTER__)
struct ImVec2;
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namespace hex {
long double operator""_scaled(long double value);
long double operator""_scaled(unsigned long long value);
ImVec2 scaled(const ImVec2 &vector);
std::string to_string(u128 value);
std::string to_string(s128 value);
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std::string toByteString(u64 bytes);
std::string makePrintable(u8 c);
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void runCommand(const std::string &command);
void openWebpage(std::string url);
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[[nodiscard]] constexpr inline u64 extract(u8 from, u8 to, const hex::unsigned_integral auto &value) {
using ValueType = std::remove_cvref_t<decltype(value)>;
ValueType mask = (std::numeric_limits<ValueType>::max() >> (((sizeof(value) * 8) - 1) - (from - to))) << to;
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return (value & mask) >> to;
}
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[[nodiscard]] inline u64 extract(u32 from, u32 to, const std::vector<u8> &bytes) {
u8 index = 0;
while(from > 32 && to > 32) {
if (from - 8 < 0 || to - 8 < 0)
return 0;
from -= 8;
to -= 8;
index++;
}
u64 value = 0;
std::memcpy(&value, &bytes[index], std::min(sizeof(value), bytes.size() - index));
u64 mask = (std::numeric_limits<u64>::max() >> (64 - (from + 1)));
return (value & mask) >> to;
}
constexpr inline s128 signExtend(size_t numBits, s128 value) {
s128 mask = 1U << (numBits - 1);
return (value ^ mask) - mask;
}
template<class... Ts> struct overloaded : Ts... { using Ts::operator()...; };
template<class... Ts> overloaded(Ts...) -> overloaded<Ts...>;
template<size_t Size>
struct SizeTypeImpl { };
template<> struct SizeTypeImpl<1> { using Type = u8; };
template<> struct SizeTypeImpl<2> { using Type = u16; };
template<> struct SizeTypeImpl<4> { using Type = u32; };
template<> struct SizeTypeImpl<8> { using Type = u64; };
template<> struct SizeTypeImpl<16> { using Type = u128; };
template<size_t Size>
using SizeType = typename SizeTypeImpl<Size>::Type;
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template<typename T>
constexpr T changeEndianess(const T &value, std::endian endian) {
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if (endian == std::endian::native)
return value;
constexpr auto Size = sizeof(T);
SizeType<Size> unswapped;
std::memcpy(&unswapped, &value, Size);
SizeType<Size> swapped;
if constexpr (!std::has_single_bit(Size) || Size > 16)
static_assert(always_false<T>::value, "Invalid type provided!");
switch (Size) {
case 1: swapped = unswapped; break;
case 2: swapped = __builtin_bswap16(unswapped); break;
case 4: swapped = __builtin_bswap32(unswapped); break;
case 8: swapped = __builtin_bswap64(unswapped); break;
case 16: swapped = (u128(__builtin_bswap64(unswapped & 0xFFFF'FFFF'FFFF'FFFF)) << 64) | __builtin_bswap64(u128(unswapped) >> 64); break;
default: __builtin_unreachable();
}
T result;
std::memcpy(&result, &swapped, Size);
return result;
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}
[[nodiscard]]
constexpr uint64_t bitmask(uint8_t bits) {
return (uint64_t(1) << (bits)) - 1;
}
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template<typename T>
constexpr T changeEndianess(T value, size_t size, std::endian endian) {
if (endian == std::endian::native)
return value;
u128 unswapped = 0;
std::memcpy(&unswapped, &value, size);
u128 swapped;
switch (size) {
case 1: swapped = unswapped; break;
case 2: swapped = __builtin_bswap16(unswapped); break;
case 4: swapped = __builtin_bswap32(unswapped); break;
case 8: swapped = __builtin_bswap64(unswapped); break;
case 16: swapped = (u128(__builtin_bswap64(unswapped & 0xFFFF'FFFF'FFFF'FFFF)) << 64) | __builtin_bswap64(u128(unswapped) >> 64); break;
default: __builtin_unreachable();
}
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T result = 0;
std::memcpy(&result, &swapped, size);
return result;
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}
template< class T >
constexpr T bit_width(T x) noexcept {
return std::numeric_limits<T>::digits - std::countl_zero(x);
}
template<typename T>
constexpr T bit_ceil(T x) noexcept {
if (x <= 1u)
return T(1);
return T(1) << bit_width(T(x - 1));
}
std::vector<std::string> splitString(const std::string &string, const std::string &delimiter);
std::string combineStrings(const std::vector<std::string> &strings, const std::string &delimiter = "");
std::string toEngineeringString(double value);
template<typename T>
std::vector<u8> toBytes(T value) {
std::vector<u8> bytes(sizeof(T));
std::memcpy(bytes.data(), &value, sizeof(T));
return bytes;
}
inline std::vector<u8> parseByteString(const std::string &string) {
auto byteString = std::string(string);
byteString.erase(std::remove(byteString.begin(), byteString.end(), ' '), byteString.end());
if ((byteString.length() % 2) != 0) return { };
std::vector<u8> result;
for (u32 i = 0; i < byteString.length(); i += 2) {
if (!std::isxdigit(byteString[i]) || !std::isxdigit(byteString[i + 1]))
return { };
result.push_back(std::strtoul(byteString.substr(i, 2).c_str(), nullptr, 16));
}
return result;
}
inline std::string toBinaryString(hex::unsigned_integral auto number) {
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if (number == 0) return "0";
std::string result;
for (s16 bit = hex::bit_width(number) - 1; bit >= 0; bit--)
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result += (number & (0b1 << bit)) == 0 ? '0' : '1';
return result;
}
inline void trimLeft(std::string &s) {
s.erase(s.begin(), std::find_if(s.begin(), s.end(), [](unsigned char ch) {
return !std::isspace(ch) && ch >= 0x20;
}));
}
inline void trimRight(std::string &s) {
s.erase(std::find_if(s.rbegin(), s.rend(), [](unsigned char ch) {
return !std::isspace(ch) && ch >= 0x20;
}).base(), s.end());
}
inline void trim(std::string &s) {
trimLeft(s);
trimRight(s);
}
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enum class DialogMode {
Open,
Save,
Folder
};
void openFileBrowser(const std::string &title, DialogMode mode, const std::vector<nfdfilteritem_t> &validExtensions, const std::function<void(std::string)> &callback, const std::string &defaultPath = {});
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float float16ToFloat32(u16 float16);
inline bool equalsIgnoreCase(const std::string &left, const std::string &right) {
return std::equal(left.begin(), left.end(), right.begin(), right.end(), [](char a, char b) {
return tolower(a) == tolower(b);
});
}
inline bool containsIgnoreCase(const std::string &a, const std::string &b) {
auto iter = std::search(a.begin(), a.end(), b.begin(), b.end(), [](char ch1, char ch2) {
return std::toupper(ch1) == std::toupper(ch2);
});
return iter != a.end();
}
template<typename T, typename ... VariantTypes>
T get_or(const std::variant<VariantTypes...> &variant, T alt) {
const T *value = std::get_if<T>(&variant);
if (value == nullptr)
return alt;
else
return *value;
}
bool isProcessElevated();
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namespace scope_guard {
#define SCOPE_GUARD ::hex::scope_guard::ScopeGuardOnExit() + [&]()
#define ON_SCOPE_EXIT auto ANONYMOUS_VARIABLE(SCOPE_EXIT_) = SCOPE_GUARD
template<class F>
class ScopeGuard {
private:
F m_func;
bool m_active;
public:
constexpr ScopeGuard(F func) : m_func(std::move(func)), m_active(true) { }
~ScopeGuard() { if (this->m_active) { this->m_func(); } }
void release() { this->m_active = false; }
ScopeGuard(ScopeGuard &&other) noexcept : m_func(std::move(other.m_func)), m_active(other.m_active) {
other.cancel();
}
ScopeGuard& operator=(ScopeGuard &&) = delete;
};
enum class ScopeGuardOnExit { };
template <typename F>
constexpr ScopeGuard<F> operator+(ScopeGuardOnExit, F&& f) {
return ScopeGuard<F>(std::forward<F>(f));
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}
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}
namespace first_time_exec {
#define FIRST_TIME static auto ANONYMOUS_VARIABLE(FIRST_TIME_) = ::hex::first_time_exec::FirstTimeExecutor() + [&]()
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template<class F>
class FirstTimeExecute {
public:
constexpr FirstTimeExecute(F func) { func(); }
FirstTimeExecute& operator=(FirstTimeExecute &&) = delete;
};
enum class FirstTimeExecutor { };
template <typename F>
constexpr FirstTimeExecute<F> operator+(FirstTimeExecutor, F&& f) {
return FirstTimeExecute<F>(std::forward<F>(f));
}
}
namespace final_cleanup {
#define FINAL_CLEANUP static auto ANONYMOUS_VARIABLE(ON_EXIT_) = ::hex::final_cleanup::FinalCleanupExecutor() + [&]()
template<class F>
class FinalCleanupExecute {
F m_func;
public:
constexpr FinalCleanupExecute(F func) : m_func(func) { }
constexpr ~FinalCleanupExecute() { this->m_func(); }
FinalCleanupExecute& operator=(FinalCleanupExecute &&) = delete;
};
enum class FinalCleanupExecutor { };
template <typename F>
constexpr FinalCleanupExecute<F> operator+(FinalCleanupExecutor, F&& f) {
return FinalCleanupExecute<F>(std::forward<F>(f));
}
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}
}