ladybird/AK/Format.h

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/*
* Copyright (c) 2020, the SerenityOS developers.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
* SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
* CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#pragma once
#include <AK/AllOf.h>
#include <AK/AnyOf.h>
#include <AK/Array.h>
#include <AK/GenericLexer.h>
#include <AK/Optional.h>
#include <AK/StringView.h>
#ifndef KERNEL
# include <stdio.h>
#endif
#ifndef DBGLN_NO_COMPILETIME_FORMAT_CHECK
// Note: Clang 12 adds support for CTAD, but still fails to build the dbgln() checks, so they're disabled altogether for now.
// See https://oss-fuzz-build-logs.storage.googleapis.com/log-79750138-f41e-4f39-8812-7c536f1d2e35.txt, for example.
# if defined(__clang__)
# define DBGLN_NO_COMPILETIME_FORMAT_CHECK
# endif
#endif
#ifndef DBGLN_NO_COMPILETIME_FORMAT_CHECK
namespace {
template<size_t N>
consteval auto extract_used_argument_index(const char (&fmt)[N], size_t specifier_start_index, size_t specifier_end_index, size_t& next_implicit_argument_index)
{
struct {
size_t index_value { 0 };
bool saw_explicit_index { false };
} state;
for (size_t i = specifier_start_index; i < specifier_end_index; ++i) {
auto c = fmt[i];
if (c > '9' || c < '0')
break;
state.index_value *= 10;
state.index_value += c - '0';
state.saw_explicit_index = true;
}
if (!state.saw_explicit_index)
return next_implicit_argument_index++;
return state.index_value;
}
// FIXME: We should rather parse these format strings at compile-time if possible.
template<size_t N>
consteval auto count_fmt_params(const char (&fmt)[N])
{
struct {
// FIXME: Switch to variable-sized storage whenever we can come up with one :)
Array<size_t, 128> used_arguments { 0 };
size_t total_used_argument_count { 0 };
size_t next_implicit_argument_index { 0 };
bool has_explicit_argument_references { false };
size_t unclosed_braces { 0 };
size_t extra_closed_braces { 0 };
Array<size_t, 4> last_format_specifier_start { 0 };
size_t total_used_last_format_specifier_start_count { 0 };
StringLiteral<128> internal_error { { 0 } };
} result;
for (size_t i = 0; i < N; ++i) {
auto ch = fmt[i];
switch (ch) {
case '{':
if (i + 1 < N && fmt[i + 1] == '{') {
++i;
continue;
}
// Note: There's no compile-time throw, so we have to abuse a compile-time string to store errors.
if (result.total_used_last_format_specifier_start_count >= result.last_format_specifier_start.size() - 1)
result.internal_error = "Format-String Checker internal error: Format specifier nested too deep";
result.last_format_specifier_start[result.total_used_last_format_specifier_start_count++] = i + 1;
++result.unclosed_braces;
break;
case '}':
if (i + 1 < N && fmt[i + 1] == '}') {
++i;
continue;
}
if (result.unclosed_braces) {
--result.unclosed_braces;
if (result.total_used_last_format_specifier_start_count == 0)
result.internal_error = "Format-String Checker internal error: Expected location information";
const auto specifier_start_index = result.last_format_specifier_start[--result.total_used_last_format_specifier_start_count];
if (result.total_used_argument_count >= result.used_arguments.size())
result.internal_error = "Format-String Checker internal error: Too many format arguments in format string";
auto used_argument_index = extract_used_argument_index<N>(fmt, specifier_start_index, i, result.next_implicit_argument_index);
if (used_argument_index + 1 != result.next_implicit_argument_index)
result.has_explicit_argument_references = true;
result.used_arguments[result.total_used_argument_count++] = used_argument_index;
} else {
++result.extra_closed_braces;
}
break;
default:
continue;
}
}
return result;
}
}
template<size_t N, StringLiteral<N> fmt, size_t param_count, auto check = count_fmt_params<N>(fmt.data)>
constexpr bool check_format_parameter_consistency()
{
static_assert(check.internal_error.data[0] == 0, "Some internal error occured, try looking at the check function type for the error");
static_assert(check.unclosed_braces == 0, "Extra unclosed braces in format string");
static_assert(check.extra_closed_braces == 0, "Extra closing braces in format string");
{
constexpr auto begin = check.used_arguments.begin();
constexpr auto end = check.used_arguments.begin() + check.total_used_argument_count;
constexpr auto has_all_referenced_arguments = !AK::any_of(begin, end, [](auto& entry) { return entry >= param_count; });
static_assert(has_all_referenced_arguments, "Format string references nonexistent parameter");
}
if constexpr (!check.has_explicit_argument_references)
static_assert(check.total_used_argument_count == param_count, "Format string does not reference all passed parameters");
// Ensure that no passed parameter is ignored or otherwise not referenced in the format
// As this check is generally pretty expensive, try to avoid it where it cannot fail.
// We will only do this check if the format string has explicit argument refs
// otherwise, the check above covers this check too, as implicit refs
// monotonically increase, and cannot have 'gaps'.
if constexpr (check.has_explicit_argument_references) {
constexpr auto all_parameters = iota_array<size_t, param_count>(0);
auto contains = [](auto begin, auto end, auto entry) {
for (; begin != end; begin++) {
if (*begin == entry)
return true;
}
return false;
};
constexpr auto references_all_arguments = AK::all_of(
all_parameters.begin(),
all_parameters.end(),
[&](auto& entry) {
return contains(
check.used_arguments.begin(),
check.used_arguments.begin() + check.total_used_argument_count,
entry);
});
static_assert(references_all_arguments, "Format string does not reference all passed parameters");
}
return true;
}
template<auto fmt, auto param_count>
concept ConsistentFormatParameters = check_format_parameter_consistency<fmt.size, fmt, param_count>();
#endif
namespace AK {
class TypeErasedFormatParams;
class FormatParser;
class FormatBuilder;
template<typename T, typename = void>
struct Formatter {
using __no_formatter_defined = void;
};
constexpr size_t max_format_arguments = 256;
struct TypeErasedParameter {
enum class Type {
UInt8,
UInt16,
UInt32,
UInt64,
Int8,
Int16,
Int32,
Int64,
Custom
};
static Type get_type_from_size(size_t size, bool is_unsigned)
{
if (is_unsigned) {
if (size == 1)
return Type::UInt8;
if (size == 2)
return Type::UInt16;
if (size == 4)
return Type::UInt32;
if (size == 8)
return Type::UInt64;
} else {
if (size == 1)
return Type::Int8;
if (size == 2)
return Type::Int16;
if (size == 4)
return Type::Int32;
if (size == 8)
return Type::Int64;
}
ASSERT_NOT_REACHED();
}
template<typename T>
static Type get_type()
{
if (IsIntegral<T>::value)
return get_type_from_size(sizeof(T), IsUnsigned<T>::value);
return Type::Custom;
}
size_t to_size() const;
// FIXME: Getters and setters.
const void* value;
Type type;
void (*formatter)(TypeErasedFormatParams&, FormatBuilder&, FormatParser&, const void* value);
};
class FormatParser : public GenericLexer {
public:
struct FormatSpecifier {
StringView flags;
size_t index;
};
explicit FormatParser(StringView input);
StringView consume_literal();
bool consume_number(size_t& value);
bool consume_specifier(FormatSpecifier& specifier);
bool consume_replacement_field(size_t& index);
};
class FormatBuilder {
public:
enum class Align {
Default,
Left,
Center,
Right,
};
enum class SignMode {
OnlyIfNeeded,
Always,
Reserved,
Default = OnlyIfNeeded,
};
explicit FormatBuilder(StringBuilder& builder)
: m_builder(builder)
{
}
void put_padding(char fill, size_t amount);
void put_literal(StringView value);
void put_string(
StringView value,
Align align = Align::Left,
size_t min_width = 0,
size_t max_width = NumericLimits<size_t>::max(),
char fill = ' ');
void put_u64(
u64 value,
u8 base = 10,
bool prefix = false,
bool upper_case = false,
bool zero_pad = false,
Align align = Align::Right,
size_t min_width = 0,
char fill = ' ',
SignMode sign_mode = SignMode::OnlyIfNeeded,
bool is_negative = false);
void put_i64(
i64 value,
u8 base = 10,
bool prefix = false,
bool upper_case = false,
bool zero_pad = false,
Align align = Align::Right,
size_t min_width = 0,
char fill = ' ',
SignMode sign_mode = SignMode::OnlyIfNeeded);
#ifndef KERNEL
void put_f64(
double value,
u8 base = 10,
bool upper_case = false,
Align align = Align::Right,
size_t min_width = 0,
size_t precision = 6,
char fill = ' ',
SignMode sign_mode = SignMode::OnlyIfNeeded);
#endif
const StringBuilder& builder() const
{
return m_builder;
}
StringBuilder& builder() { return m_builder; }
private:
StringBuilder& m_builder;
};
class TypeErasedFormatParams {
public:
Span<const TypeErasedParameter> parameters() const { return m_parameters; }
void set_parameters(Span<const TypeErasedParameter> parameters) { m_parameters = parameters; }
size_t take_next_index() { return m_next_index++; }
private:
Span<const TypeErasedParameter> m_parameters;
size_t m_next_index { 0 };
};
template<typename T>
void __format_value(TypeErasedFormatParams& params, FormatBuilder& builder, FormatParser& parser, const void* value)
{
Formatter<T> formatter;
formatter.parse(params, parser);
formatter.format(builder, *static_cast<const T*>(value));
}
template<typename... Parameters>
class VariadicFormatParams : public TypeErasedFormatParams {
public:
static_assert(sizeof...(Parameters) <= max_format_arguments);
explicit VariadicFormatParams(const Parameters&... parameters)
: m_data({ TypeErasedParameter { &parameters, TypeErasedParameter::get_type<Parameters>(), __format_value<Parameters> }... })
{
this->set_parameters(m_data);
}
private:
Array<TypeErasedParameter, sizeof...(Parameters)> m_data;
};
// We use the same format for most types for consistency. This is taken directly from
// std::format. One difference is that we are not counting the width or sign towards the
// total width when calculating zero padding for numbers.
// https://en.cppreference.com/w/cpp/utility/format/formatter#Standard_format_specification
struct StandardFormatter {
enum class Mode {
Default,
Binary,
BinaryUppercase,
Decimal,
Octal,
Hexadecimal,
HexadecimalUppercase,
Character,
String,
Pointer,
Float,
Hexfloat,
HexfloatUppercase,
};
FormatBuilder::Align m_align = FormatBuilder::Align::Default;
FormatBuilder::SignMode m_sign_mode = FormatBuilder::SignMode::OnlyIfNeeded;
Mode m_mode = Mode::Default;
bool m_alternative_form = false;
char m_fill = ' ';
bool m_zero_pad = false;
Optional<size_t> m_width;
Optional<size_t> m_precision;
void parse(TypeErasedFormatParams&, FormatParser&);
};
template<typename T>
struct Formatter<T, typename EnableIf<IsIntegral<T>::value>::Type> : StandardFormatter {
Formatter() = default;
explicit Formatter(StandardFormatter formatter)
: StandardFormatter(formatter)
{
}
void format(FormatBuilder&, T value);
};
template<>
struct Formatter<StringView> : StandardFormatter {
Formatter() = default;
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explicit Formatter(StandardFormatter formatter)
: StandardFormatter(formatter)
{
}
void format(FormatBuilder&, StringView value);
};
template<>
struct Formatter<const char*> : Formatter<StringView> {
void format(FormatBuilder& builder, const char* value)
{
if (m_mode == Mode::Pointer) {
Formatter<FlatPtr> formatter { *this };
formatter.format(builder, reinterpret_cast<FlatPtr>(value));
} else {
Formatter<StringView>::format(builder, value);
}
}
};
template<>
struct Formatter<char*> : Formatter<const char*> {
};
template<size_t Size>
struct Formatter<char[Size]> : Formatter<const char*> {
};
template<>
struct Formatter<String> : Formatter<StringView> {
};
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template<>
struct Formatter<FlyString> : Formatter<StringView> {
};
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template<typename T>
struct Formatter<T*> : StandardFormatter {
void format(FormatBuilder& builder, T* value)
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{
if (m_mode == Mode::Default)
m_mode = Mode::Pointer;
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Formatter<FlatPtr> formatter { *this };
formatter.format(builder, reinterpret_cast<FlatPtr>(value));
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}
};
template<>
struct Formatter<char> : StandardFormatter {
void format(FormatBuilder&, char value);
};
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template<>
struct Formatter<bool> : StandardFormatter {
void format(FormatBuilder&, bool value);
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};
#ifndef KERNEL
template<>
struct Formatter<float> : StandardFormatter {
void format(FormatBuilder&, float value);
};
template<>
struct Formatter<double> : StandardFormatter {
Formatter() = default;
explicit Formatter(StandardFormatter formatter)
: StandardFormatter(formatter)
{
}
void format(FormatBuilder&, double value);
};
#endif
template<>
struct Formatter<std::nullptr_t> : Formatter<FlatPtr> {
void format(FormatBuilder& builder, std::nullptr_t)
{
if (m_mode == Mode::Default)
m_mode = Mode::Pointer;
return Formatter<FlatPtr>::format(builder, 0);
}
};
void vformat(StringBuilder&, StringView fmtstr, TypeErasedFormatParams);
void vformat(const LogStream& stream, StringView fmtstr, TypeErasedFormatParams);
#ifndef KERNEL
void vout(FILE*, StringView fmtstr, TypeErasedFormatParams, bool newline = false);
template<typename... Parameters>
void out(FILE* file, StringView fmtstr, const Parameters&... parameters) { vout(file, fmtstr, VariadicFormatParams { parameters... }); }
template<typename... Parameters>
void outln(FILE* file, StringView fmtstr, const Parameters&... parameters) { vout(file, fmtstr, VariadicFormatParams { parameters... }, true); }
template<typename... Parameters>
void outln(FILE* file, const char* fmtstr, const Parameters&... parameters) { vout(file, fmtstr, VariadicFormatParams { parameters... }, true); }
inline void outln(FILE* file) { fputc('\n', file); }
template<typename... Parameters>
void out(StringView fmtstr, const Parameters&... parameters) { out(stdout, fmtstr, parameters...); }
template<typename... Parameters>
void outln(StringView fmtstr, const Parameters&... parameters) { outln(stdout, fmtstr, parameters...); }
template<typename... Parameters>
void outln(const char* fmtstr, const Parameters&... parameters) { outln(stdout, fmtstr, parameters...); }
inline void outln() { outln(stdout); }
template<typename... Parameters>
void warn(StringView fmtstr, const Parameters&... parameters) { out(stderr, fmtstr, parameters...); }
template<typename... Parameters>
void warnln(StringView fmtstr, const Parameters&... parameters) { outln(stderr, fmtstr, parameters...); }
template<typename... Parameters>
void warnln(const char* fmtstr, const Parameters&... parameters) { outln(stderr, fmtstr, parameters...); }
inline void warnln() { outln(stderr); }
#endif
void vdbgln(StringView fmtstr, TypeErasedFormatParams);
#ifndef DBGLN_NO_COMPILETIME_FORMAT_CHECK
template<StringLiteral fmt, bool enabled = true, typename... Parameters>
void dbgln(const Parameters&... parameters) requires ConsistentFormatParameters<fmt, sizeof...(Parameters)>
{
dbgln<enabled>(StringView { fmt.data }, parameters...);
}
#endif
template<bool enabled = true, typename... Parameters>
void dbgln(StringView fmtstr, const Parameters&... parameters)
{
if constexpr (enabled)
vdbgln(fmtstr, VariadicFormatParams { parameters... });
}
template<bool enabled = true, typename... Parameters>
void dbgln(const char* fmtstr, const Parameters&... parameters) { dbgln<enabled>(StringView { fmtstr }, parameters...); }
template<bool enabled = true>
void dbgln() { dbgln<enabled>(""); }
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void set_debug_enabled(bool);
#ifdef KERNEL
void vdmesgln(StringView fmtstr, TypeErasedFormatParams);
template<typename... Parameters>
void dmesgln(StringView fmtstr, const Parameters&... parameters) { vdmesgln(fmtstr, VariadicFormatParams { parameters... }); }
template<typename... Parameters>
void dmesgln(const char* fmtstr, const Parameters&... parameters) { vdmesgln(fmtstr, VariadicFormatParams { parameters... }); }
inline void dmesgln() { dmesgln(""); }
#endif
template<typename T, typename = void>
struct HasFormatter : TrueType {
};
template<typename T>
struct HasFormatter<T, typename Formatter<T>::__no_formatter_defined> : FalseType {
};
template<typename T>
class FormatIfSupported {
public:
explicit FormatIfSupported(const T& value)
: m_value(value)
{
}
const T& value() const { return m_value; }
private:
const T& m_value;
};
template<typename T, bool Supported = false>
struct __FormatIfSupported : Formatter<StringView> {
void format(FormatBuilder& builder, const FormatIfSupported<T>&)
{
Formatter<StringView>::format(builder, "?");
}
};
template<typename T>
struct __FormatIfSupported<T, true> : Formatter<T> {
void format(FormatBuilder& builder, const FormatIfSupported<T>& value)
{
Formatter<T>::format(builder, value.value());
}
};
template<typename T>
struct Formatter<FormatIfSupported<T>> : __FormatIfSupported<T, HasFormatter<T>::value> {
};
// This is a helper class, the idea is that if you want to implement a formatter you can inherit
// from this class to "break down" the formatting.
struct FormatString {
};
template<>
struct Formatter<FormatString> : Formatter<String> {
template<typename... Parameters>
void format(FormatBuilder& builder, StringView fmtstr, const Parameters&... parameters)
{
vformat(builder, fmtstr, VariadicFormatParams { parameters... });
}
void vformat(FormatBuilder& builder, StringView fmtstr, TypeErasedFormatParams params);
};
} // namespace AK
#ifdef KERNEL
using AK::dmesgln;
#else
using AK::out;
using AK::outln;
using AK::warn;
using AK::warnln;
#endif
using AK::dbgln;
using AK::FormatIfSupported;
using AK::FormatString;
#ifdef DBGLN_NO_COMPILETIME_FORMAT_CHECK
# define dbgln(fmt, ...) dbgln(fmt, ##__VA_ARGS__)
# define dbgln_if(flag, fmt, ...) dbgln<flag>(fmt, ##__VA_ARGS__)
#else
# define dbgln(fmt, ...) dbgln<fmt>(__VA_ARGS__)
# define dbgln_if(flag, fmt, ...) dbgln<fmt, flag>(__VA_ARGS__)
#endif