//
// Copyright 2017 The Abseil Authors.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// https://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//
#ifndef ABSL_STRINGS_INTERNAL_STR_FORMAT_EXTENSION_H_
#define ABSL_STRINGS_INTERNAL_STR_FORMAT_EXTENSION_H_
#include <limits.h>
#include <cstddef>
#include <cstring>
#include <ostream>
#include "absl/base/port.h"
#include "absl/strings/internal/str_format/output.h"
#include "absl/strings/string_view.h"
namespace absl {
class Cord;
namespace str_format_internal {
class FormatRawSinkImpl {
public:
// Implicitly convert from any type that provides the hook function as
// described above.
template <typename T, decltype(str_format_internal::InvokeFlush(
std::declval<T*>(), string_view()))* = nullptr>
FormatRawSinkImpl(T* raw) // NOLINT
: sink_(raw), write_(&FormatRawSinkImpl::Flush<T>) {}
void Write(string_view s) { write_(sink_, s); }
template <typename T>
static FormatRawSinkImpl Extract(T s) {
return s.sink_;
}
private:
template <typename T>
static void Flush(void* r, string_view s) {
str_format_internal::InvokeFlush(static_cast<T*>(r), s);
}
void* sink_;
void (*write_)(void*, string_view);
};
// An abstraction to which conversions write their string data.
class FormatSinkImpl {
public:
explicit FormatSinkImpl(FormatRawSinkImpl raw) : raw_(raw) {}
~FormatSinkImpl() { Flush(); }
void Flush() {
raw_.Write(string_view(buf_, pos_ - buf_));
pos_ = buf_;
}
void Append(size_t n, char c) {
if (n == 0) return;
size_ += n;
auto raw_append = [&](size_t count) {
memset(pos_, c, count);
pos_ += count;
};
while (n > Avail()) {
n -= Avail();
if (Avail() > 0) {
raw_append(Avail());
}
Flush();
}
raw_append(n);
}
void Append(string_view v) {
size_t n = v.size();
if (n == 0) return;
size_ += n;
if (n >= Avail()) {
Flush();
raw_.Write(v);
return;
}
memcpy(pos_, v.data(), n);
pos_ += n;
}
size_t size() const { return size_; }
// Put 'v' to 'sink' with specified width, precision, and left flag.
bool PutPaddedString(string_view v, int w, int p, bool l);
template <typename T>
T Wrap() {
return T(this);
}
template <typename T>
static FormatSinkImpl* Extract(T* s) {
return s->sink_;
}
private:
size_t Avail() const { return buf_ + sizeof(buf_) - pos_; }
FormatRawSinkImpl raw_;
size_t size_ = 0;
char* pos_ = buf_;
char buf_[1024];
};
struct Flags {
bool basic : 1; // fastest conversion: no flags, width, or precision
bool left : 1; // "-"
bool show_pos : 1; // "+"
bool sign_col : 1; // " "
bool alt : 1; // "#"
bool zero : 1; // "0"
std::string ToString() const;
friend std::ostream& operator<<(std::ostream& os, const Flags& v) {
return os << v.ToString();
}
};
struct LengthMod {
public:
enum Id : uint8_t {
h, hh, l, ll, L, j, z, t, q, none
};
static const size_t kNumValues = none + 1;
LengthMod() : id_(none) {}
// Index into the opaque array of LengthMod enums.
// Requires: i < kNumValues
static LengthMod FromIndex(size_t i) {
return LengthMod(kSpecs[i].value);
}
static LengthMod FromId(Id id) { return LengthMod(id); }
// The length modifier std::string associated with a specified LengthMod.
string_view name() const {
const Spec& spec = kSpecs[id_];
return {spec.name, spec.name_length};
}
Id id() const { return id_; }
friend bool operator==(const LengthMod& a, const LengthMod& b) {
return a.id() == b.id();
}
friend bool operator!=(const LengthMod& a, const LengthMod& b) {
return !(a == b);
}
friend std::ostream& operator<<(std::ostream& os, const LengthMod& v) {
return os << v.name();
}
private:
struct Spec {
Id value;
const char *name;
size_t name_length;
};
static const Spec kSpecs[];
explicit LengthMod(Id id) : id_(id) {}
Id id_;
};
// clang-format off
#define ABSL_CONVERSION_CHARS_EXPAND_(X_VAL, X_SEP) \
/* text */ \
X_VAL(c) X_SEP X_VAL(C) X_SEP X_VAL(s) X_SEP X_VAL(S) X_SEP \
/* ints */ \
X_VAL(d) X_SEP X_VAL(i) X_SEP X_VAL(o) X_SEP \
X_VAL(u) X_SEP X_VAL(x) X_SEP X_VAL(X) X_SEP \
/* floats */ \
X_VAL(f) X_SEP X_VAL(F) X_SEP X_VAL(e) X_SEP X_VAL(E) X_SEP \
X_VAL(g) X_SEP X_VAL(G) X_SEP X_VAL(a) X_SEP X_VAL(A) X_SEP \
/* misc */ \
X_VAL(n) X_SEP X_VAL(p)
// clang-format on
struct ConversionChar {
public:
enum Id : uint8_t {
c, C, s, S, // text
d, i, o, u, x, X, // int
f, F, e, E, g, G, a, A, // float
n, p, // misc
none
};
static const size_t kNumValues = none + 1;
ConversionChar() : id_(none) {}
public:
// Index into the opaque array of ConversionChar enums.
// Requires: i < kNumValues
static ConversionChar FromIndex(size_t i) {
return ConversionChar(kSpecs[i].value);
}
static ConversionChar FromChar(char c) {
ConversionChar::Id out_id = ConversionChar::none;
switch (c) {
#define X_VAL(id) \
case #id[0]: \
out_id = ConversionChar::id; \
break;
ABSL_CONVERSION_CHARS_EXPAND_(X_VAL, )
#undef X_VAL
default:
break;
}
return ConversionChar(out_id);
}
static ConversionChar FromId(Id id) { return ConversionChar(id); }
Id id() const { return id_; }
int radix() const {
switch (id()) {
case x: case X: case a: case A: case p: return 16;
case o: return 8;
default: return 10;
}
}
bool upper() const {
switch (id()) {
case X: case F: case E: case G: case A: return true;
default: return false;
}
}
bool is_signed() const {
switch (id()) {
case d: case i: return true;
default: return false;
}
}
bool is_integral() const {
switch (id()) {
case d: case i: case u: case o: case x: case X:
return true;
default: return false;
}
}
bool is_float() const {
switch (id()) {
case a: case e: case f: case g: case A: case E: case F: case G:
return true;
default: return false;
}
}
bool IsValid() const { return id() != none; }
// The associated char.
char Char() const { return kSpecs[id_].name; }
friend bool operator==(const ConversionChar& a, const ConversionChar& b) {
return a.id() == b.id();
}
friend bool operator!=(const ConversionChar& a, const ConversionChar& b) {
return !(a == b);
}
friend std::ostream& operator<<(std::ostream& os, const ConversionChar& v) {
char c = v.Char();
if (!c) c = '?';
return os << c;
}
private:
struct Spec {
Id value;
char name;
};
static const Spec kSpecs[];
explicit ConversionChar(Id id) : id_(id) {}
Id id_;
};
class ConversionSpec {
public:
Flags flags() const { return flags_; }
LengthMod length_mod() const { return length_mod_; }
ConversionChar conv() const {
// Keep this field first in the struct . It generates better code when
// accessing it when ConversionSpec is passed by value in registers.
static_assert(offsetof(ConversionSpec, conv_) == 0, "");
return conv_;
}
// Returns the specified width. If width is unspecfied, it returns a negative
// value.
int width() const { return width_; }
// Returns the specified precision. If precision is unspecfied, it returns a
// negative value.
int precision() const { return precision_; }
void set_flags(Flags f) { flags_ = f; }
void set_length_mod(LengthMod lm) { length_mod_ = lm; }
void set_conv(ConversionChar c) { conv_ = c; }
void set_width(int w) { width_ = w; }
void set_precision(int p) { precision_ = p; }
void set_left(bool b) { flags_.left = b; }
private:
ConversionChar conv_;
Flags flags_;
LengthMod length_mod_;
int width_;
int precision_;
};
constexpr uint64_t ConversionCharToConvValue(char conv) {
return
#define CONV_SET_CASE(c) \
conv == #c[0] ? (uint64_t{1} << (1 + ConversionChar::Id::c)):
ABSL_CONVERSION_CHARS_EXPAND_(CONV_SET_CASE, )
#undef CONV_SET_CASE
conv == '*'
? 1
: 0;
}
enum class Conv : uint64_t {
#define CONV_SET_CASE(c) c = ConversionCharToConvValue(#c[0]),
ABSL_CONVERSION_CHARS_EXPAND_(CONV_SET_CASE, )
#undef CONV_SET_CASE
// Used for width/precision '*' specification.
star = ConversionCharToConvValue('*'),
// Some predefined values:
integral = d | i | u | o | x | X,
floating = a | e | f | g | A | E | F | G,
numeric = integral | floating,
string = s,
pointer = p
};
// Type safe OR operator.
// We need this for two reasons:
// 1. operator| on enums makes them decay to integers and the result is an
// integer. We need the result to stay as an enum.
// 2. We use "enum class" which would not work even if we accepted the decay.
constexpr Conv operator|(Conv a, Conv b) {
return Conv(static_cast<uint64_t>(a) | static_cast<uint64_t>(b));
}
// Get a conversion with a single character in it.
constexpr Conv ConversionCharToConv(char c) {
return Conv(ConversionCharToConvValue(c));
}
// Checks whether `c` exists in `set`.
constexpr bool Contains(Conv set, char c) {
return (static_cast<uint64_t>(set) & ConversionCharToConvValue(c)) != 0;
}
// Checks whether all the characters in `c` are contained in `set`
constexpr bool Contains(Conv set, Conv c) {
return (static_cast<uint64_t>(set) & static_cast<uint64_t>(c)) ==
static_cast<uint64_t>(c);
}
// Return type of the AbslFormatConvert() functions.
// The Conv template parameter is used to inform the framework of what
// conversion characters are supported by that AbslFormatConvert routine.
template <Conv C>
struct ConvertResult {
static constexpr Conv kConv = C;
bool value;
};
template <Conv C>
constexpr Conv ConvertResult<C>::kConv;
// Return capacity - used, clipped to a minimum of 0.
inline size_t Excess(size_t used, size_t capacity) {
return used < capacity ? capacity - used : 0;
}
} // namespace str_format_internal
} // namespace absl
#endif // ABSL_STRINGS_INTERNAL_STR_FORMAT_EXTENSION_H_