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mirror of https://github.com/RPCS3/rpcs3.git synced 2024-11-22 10:42:36 +01:00
rpcs3/Utilities/StrFmt.h
Nekotekina 580bd2b25e Initial Linux Aarch64 support
* Update asmjit dependency (aarch64 branch)
* Disable USE_DISCORD_RPC by default
* Dump some JIT objects in rpcs3 cache dir
* Add SIGILL handler for all platforms
* Fix resetting zeroing denormals in thread pool
* Refactor most v128:: utils into global gv_** functions
* Refactor PPU interpreter (incomplete), remove "precise"
* - Instruction specializations with multiple accuracy flags
* - Adjust calling convention for speed
* - Removed precise/fast setting, replaced with static
* - Started refactoring interpreters for building at runtime JIT
*   (I got tired of poor compiler optimizations)
* - Expose some accuracy settings (SAT, NJ, VNAN, FPCC)
* - Add exec_bytes PPU thread variable (akin to cycle count)
* PPU LLVM: fix VCTUXS+VCTSXS instruction NaN results
* SPU interpreter: remove "precise" for now (extremely non-portable)
* - As with PPU, settings changed to static/dynamic for interpreters.
* - Precise options will be implemented later
* Fix termination after fatal error dialog
2022-01-15 06:48:04 +03:00

399 lines
9.2 KiB
C++

#pragma once // No BOM and only basic ASCII in this header, or a neko will die
#include "util/types.hpp"
#include <string>
namespace fmt
{
template <typename CharT, usz N, typename... Args>
static std::string format(const CharT(&)[N], const Args&...);
}
template <typename T, typename = void>
struct fmt_unveil
{
static_assert(sizeof(T) > 0, "fmt_unveil<> error: incomplete type");
using type = T;
static inline u64 get(const T& arg)
{
return reinterpret_cast<uptr>(&arg);
}
// Temporary value container (can possibly be created by other fmt_unveil<> specializations)
struct u64_wrapper
{
T arg;
// Allow implicit conversion
operator u64() const
{
return reinterpret_cast<uptr>(&arg);
}
};
// This overload resolution takes the precedence
static inline u64_wrapper get(T&& arg)
{
return u64_wrapper{std::move(arg)};
}
};
template <typename T>
struct fmt_unveil<T, std::enable_if_t<std::is_integral<T>::value && sizeof(T) <= 8 && alignof(T) <= 8>>
{
using type = T;
static inline u64 get(T arg)
{
return static_cast<T>(arg);
}
};
template <typename T>
struct fmt_unveil<T, std::enable_if_t<std::is_floating_point<T>::value && sizeof(T) <= 8 && alignof(T) <= 8>>
{
using type = T;
// Convert FP to f64 and reinterpret as u64
static inline u64 get(const f64& arg)
{
return std::bit_cast<u64>(arg);
}
};
template <typename T>
struct fmt_unveil<T, std::enable_if_t<std::is_enum<T>::value>>
{
using type = T;
static inline u64 get(T arg)
{
return static_cast<std::underlying_type_t<T>>(arg);
}
};
template <typename T>
struct fmt_unveil<T*, void>
{
using type = std::add_const_t<T>*;
static inline u64 get(type arg)
{
return reinterpret_cast<uptr>(arg);
}
};
namespace fmt
{
template <typename T>
concept CharT = (std::is_same_v<const T, const char> || std::is_same_v<const T, const char8_t>);
}
template <fmt::CharT T, usz N>
struct fmt_unveil<T[N], void>
{
using type = std::add_const_t<T>*;
static inline u64 get(type arg)
{
return reinterpret_cast<uptr>(arg);
}
};
template <typename T, bool Se, usz Align>
struct fmt_unveil<se_t<T, Se, Align>, void>
{
using type = typename fmt_unveil<T>::type;
static inline auto get(const se_t<T, Se, Align>& arg)
{
return fmt_unveil<T>::get(arg);
}
};
// String type format provider, also type classifier (format() called if an argument is formatted as "%s")
template <typename T, typename = void>
struct fmt_class_string
{
// Formatting function (must be explicitly specialized)
static void format(std::string& out, u64 arg);
// Helper typedef (visible in format())
using type = T;
// Helper function (converts arg to object reference)
static FORCE_INLINE SAFE_BUFFERS(const T&) get_object(u64 arg)
{
return *reinterpret_cast<const T*>(static_cast<uptr>(arg));
}
// Enum -> string function type
using convert_t = const char*(*)(T value);
// Helper function (safely converts arg to enum value)
static FORCE_INLINE SAFE_BUFFERS(void) format_enum(std::string& out, u64 arg, convert_t convert)
{
const auto value = static_cast<std::underlying_type_t<T>>(arg);
// Check narrowing
if (static_cast<u64>(value) == arg)
{
if (const char* str = convert(static_cast<T>(value)))
{
out += str;
return;
}
}
// Fallback to underlying type formatting
fmt_class_string<std::underlying_type_t<T>>::format(out, static_cast<u64>(value));
}
// Helper function (bitset formatting)
static FORCE_INLINE SAFE_BUFFERS(void) format_bitset(std::string& out, u64 arg, const char* prefix, const char* delim, const char* suffix, void (*fmt)(std::string&, u64))
{
// Start from raw value
fmt_class_string<u64>::format(out, arg);
out += prefix;
for (u64 i = 0; i < 63; i++)
{
const u64 mask = 1ull << i;
if (arg & mask)
{
fmt(out, i);
if (arg >> (i + 1))
{
out += delim;
}
}
}
if (arg & (1ull << 63))
{
fmt(out, 63);
}
out += suffix;
}
// Helper constant (may be used in format_enum as lambda return value)
static constexpr const char* unknown = nullptr;
};
template <>
struct fmt_class_string<const void*, void>
{
static void format(std::string& out, u64 arg);
};
template <typename T>
struct fmt_class_string<T*, void> : fmt_class_string<const void*, void>
{
// Classify all pointers as const void*
};
template <>
struct fmt_class_string<const char*, void>
{
static void format(std::string& out, u64 arg);
};
template <>
struct fmt_class_string<char*, void> : fmt_class_string<const char*>
{
// Classify char* as const char*
};
template <>
struct fmt_class_string<const char8_t*, void> : fmt_class_string<const char*>
{
};
template <>
struct fmt_class_string<char8_t*, void> : fmt_class_string<const char8_t*>
{
};
namespace fmt
{
// Both uchar and std::byte are allowed
template <typename T>
concept ByteArray = requires (T& t) { const_cast<std::conditional_t<std::is_same_v<decltype(std::as_const(t[0])), const std::byte&>, std::byte, uchar>&>(std::data(t)[0]); };
}
template <fmt::ByteArray T>
struct fmt_class_string<T, void>
{
static FORCE_INLINE SAFE_BUFFERS(const T&) get_object(u64 arg)
{
return *reinterpret_cast<const T*>(static_cast<uptr>(arg));
}
static void format(std::string& out, u64 arg)
{
const auto& obj = get_object(arg);
void format_byte_array(std::string&, const uchar*, usz);
format_byte_array(out, reinterpret_cast<const uchar*>(std::data(obj)), std::size(obj));
}
};
struct fmt_type_info
{
decltype(&fmt_class_string<int>::format) fmt_string;
template <typename T>
static constexpr fmt_type_info make()
{
return fmt_type_info
{
&fmt_class_string<T>::format,
};
}
};
// Argument array type (each element generated via fmt_unveil<>)
template <typename... Args>
using fmt_args_t = const u64(&&)[sizeof...(Args) + 1];
template <typename Arg>
using fmt_unveil_t = typename fmt_unveil<Arg>::type;
namespace fmt
{
// Base-57 format helper
struct base57
{
const uchar* data;
usz size;
template <typename T>
base57(const T& arg)
: data(reinterpret_cast<const uchar*>(&arg))
, size(sizeof(T))
{
}
base57(const uchar* data, usz size)
: data(data)
, size(size)
{
}
};
template <typename... Args>
constexpr const fmt_type_info type_info_v[sizeof...(Args) + 1]{fmt_type_info::make<fmt_unveil_t<Args>>()...};
// Internal formatting function
void raw_append(std::string& out, const char*, const fmt_type_info*, const u64*) noexcept;
// Formatting function
template <typename CharT, usz N, typename... Args>
FORCE_INLINE SAFE_BUFFERS(void) append(std::string& out, const CharT(&fmt)[N], const Args&... args)
{
raw_append(out, reinterpret_cast<const char*>(fmt), type_info_v<Args...>, fmt_args_t<Args...>{fmt_unveil<Args>::get(args)...});
}
// Formatting function
template <typename CharT, usz N, typename... Args>
FORCE_INLINE SAFE_BUFFERS(std::string) format(const CharT(&fmt)[N], const Args&... args)
{
std::string result;
append(result, fmt, args...);
return result;
}
// Internal exception message formatting template, must be explicitly specialized or instantiated in cpp to minimize code bloat
[[noreturn]] void raw_throw_exception(const src_loc&, const char*, const fmt_type_info*, const u64*);
// Throw exception with formatting
template <typename CharT, usz N, typename... Args>
struct throw_exception
{
[[noreturn]] FORCE_INLINE SAFE_BUFFERS() throw_exception(const CharT(&fmt)[N], const Args&... args,
u32 line = __builtin_LINE(),
u32 col = __builtin_COLUMN(),
const char* file = __builtin_FILE(),
const char* func = __builtin_FUNCTION())
{
raw_throw_exception({line, col, file, func}, reinterpret_cast<const char*>(fmt), type_info_v<Args...>, fmt_args_t<Args...>{fmt_unveil<Args>::get(args)...});
}
#ifndef _MSC_VER
[[noreturn]] ~throw_exception();
#endif
};
template <typename CharT, usz N, typename... Args>
throw_exception(const CharT(&)[N], const Args&...) -> throw_exception<CharT, N, Args...>;
// Helper template: pack format variables
template <typename Arg = void, typename... Args>
struct tie
{
// Universal reference
std::add_rvalue_reference_t<Arg> arg;
tie<Args...> next;
// Store only references, unveil op is postponed
tie(Arg&& arg, Args&&... args) noexcept
: arg(std::forward<Arg>(arg))
, next(std::forward<Args>(args)...)
{
}
using type = std::remove_cvref_t<Arg>;
// Storage for fmt_unveil (deferred initialization)
decltype(fmt_unveil<type>::get(std::declval<Arg>())) value;
void init(u64 to[])
{
value = fmt_unveil<type>::get(arg);
to[0] = value;
next.init(to + 1);
}
};
template <>
struct tie<void>
{
void init(u64 to[]) const
{
// Isn't really null terminated, this value has no meaning
to[0] = 0;
}
};
template <typename... Args>
tie(Args&&... args) -> tie<Args...>;
// Ensure with formatting
template <typename T, typename CharT, usz N, typename... Args>
decltype(auto) ensure(T&& arg, const CharT(&fmt)[N], tie<Args...> args,
u32 line = __builtin_LINE(),
u32 col = __builtin_COLUMN(),
const char* file = __builtin_FILE(),
const char* func = __builtin_FUNCTION()) noexcept
{
if (std::forward<T>(arg)) [[likely]]
{
return std::forward<T>(arg);
}
// Prepare u64 array
u64 data[sizeof...(Args) + 1];
args.init(data);
raw_throw_exception({line, col, file, func}, reinterpret_cast<const char*>(fmt), type_info_v<std::remove_cvref_t<Args>...>, +data);
}
}