#ifndef ABSL_STRINGS_INTERNAL_STR_FORMAT_BIND_H_
#define ABSL_STRINGS_INTERNAL_STR_FORMAT_BIND_H_
#include <array>
#include <cstdio>
#include <sstream>
#include <string>
#include "absl/base/port.h"
#include "absl/strings/internal/str_format/arg.h"
#include "absl/strings/internal/str_format/checker.h"
#include "absl/strings/internal/str_format/parser.h"
#include "absl/types/span.h"
namespace absl {
class UntypedFormatSpec;
namespace str_format_internal {
class BoundConversion : public ConversionSpec {
public:
const FormatArgImpl* arg() const { return arg_; }
void set_arg(const FormatArgImpl* a) { arg_ = a; }
private:
const FormatArgImpl* arg_;
};
// This is the type-erased class that the implementation uses.
class UntypedFormatSpecImpl {
public:
UntypedFormatSpecImpl() = delete;
explicit UntypedFormatSpecImpl(string_view s)
: data_(s.data()), size_(s.size()) {}
explicit UntypedFormatSpecImpl(
const str_format_internal::ParsedFormatBase* pc)
: data_(pc), size_(~size_t{}) {}
bool has_parsed_conversion() const { return size_ == ~size_t{}; }
string_view str() const {
assert(!has_parsed_conversion());
return string_view(static_cast<const char*>(data_), size_);
}
const str_format_internal::ParsedFormatBase* parsed_conversion() const {
assert(has_parsed_conversion());
return static_cast<const str_format_internal::ParsedFormatBase*>(data_);
}
template <typename T>
static const UntypedFormatSpecImpl& Extract(const T& s) {
return s.spec_;
}
private:
const void* data_;
size_t size_;
};
template <typename T, typename...>
struct MakeDependent {
using type = T;
};
// Implicitly convertible from `const char*`, `string_view`, and the
// `ExtendedParsedFormat` type. This abstraction allows all format functions to
// operate on any without providing too many overloads.
template <typename... Args>
class FormatSpecTemplate
: public MakeDependent<UntypedFormatSpec, Args...>::type {
using Base = typename MakeDependent<UntypedFormatSpec, Args...>::type;
public:
#if ABSL_INTERNAL_ENABLE_FORMAT_CHECKER
// Honeypot overload for when the std::string is not constexpr.
// We use the 'unavailable' attribute to give a better compiler error than
// just 'method is deleted'.
FormatSpecTemplate(...) // NOLINT
__attribute__((unavailable("Format std::string is not constexpr.")));
// Honeypot overload for when the format is constexpr and invalid.
// We use the 'unavailable' attribute to give a better compiler error than
// just 'method is deleted'.
// To avoid checking the format twice, we just check that the format is
// constexpr. If is it valid, then the overload below will kick in.
// We add the template here to make this overload have lower priority.
template <typename = void>
FormatSpecTemplate(const char* s) // NOLINT
__attribute__((
enable_if(str_format_internal::EnsureConstexpr(s), "constexpr trap"),
unavailable(
"Format specified does not match the arguments passed.")));
template <typename T = void>
FormatSpecTemplate(string_view s) // NOLINT
__attribute__((enable_if(str_format_internal::EnsureConstexpr(s),
"constexpr trap"))) {
static_assert(sizeof(T*) == 0,
"Format specified does not match the arguments passed.");
}
// Good format overload.
FormatSpecTemplate(const char* s) // NOLINT
__attribute__((enable_if(ValidFormatImpl<ArgumentToConv<Args>()...>(s),
"bad format trap")))
: Base(s) {}
FormatSpecTemplate(string_view s) // NOLINT
__attribute__((enable_if(ValidFormatImpl<ArgumentToConv<Args>()...>(s),
"bad format trap")))
: Base(s) {}
#else // ABSL_INTERNAL_ENABLE_FORMAT_CHECKER
FormatSpecTemplate(const char* s) : Base(s) {} // NOLINT
FormatSpecTemplate(string_view s) : Base(s) {} // NOLINT
#endif // ABSL_INTERNAL_ENABLE_FORMAT_CHECKER
template <Conv... C, typename = typename std::enable_if<
sizeof...(C) == sizeof...(Args) &&
AllOf(Contains(ArgumentToConv<Args>(),
C)...)>::type>
FormatSpecTemplate(const ExtendedParsedFormat<C...>& pc) // NOLINT
: Base(&pc) {}
};
template <typename... Args>
struct FormatSpecDeductionBarrier {
using type = FormatSpecTemplate<Args...>;
};
class Streamable {
public:
Streamable(const UntypedFormatSpecImpl& format,
absl::Span<const FormatArgImpl> args)
: format_(format) {
if (args.size() <= ABSL_ARRAYSIZE(few_args_)) {
for (size_t i = 0; i < args.size(); ++i) {
few_args_[i] = args[i];
}
args_ = absl::MakeSpan(few_args_, args.size());
} else {
many_args_.assign(args.begin(), args.end());
args_ = many_args_;
}
}
std::ostream& Print(std::ostream& os) const;
friend std::ostream& operator<<(std::ostream& os, const Streamable& l) {
return l.Print(os);
}
private:
const UntypedFormatSpecImpl& format_;
absl::Span<const FormatArgImpl> args_;
// if args_.size() is 4 or less:
FormatArgImpl few_args_[4] = {FormatArgImpl(0), FormatArgImpl(0),
FormatArgImpl(0), FormatArgImpl(0)};
// if args_.size() is more than 4:
std::vector<FormatArgImpl> many_args_;
};
// for testing
std::string Summarize(UntypedFormatSpecImpl format,
absl::Span<const FormatArgImpl> args);
bool BindWithPack(const UnboundConversion* props,
absl::Span<const FormatArgImpl> pack, BoundConversion* bound);
bool FormatUntyped(FormatRawSinkImpl raw_sink,
UntypedFormatSpecImpl format,
absl::Span<const FormatArgImpl> args);
std::string& AppendPack(std::string* out, UntypedFormatSpecImpl format,
absl::Span<const FormatArgImpl> args);
inline std::string FormatPack(const UntypedFormatSpecImpl format,
absl::Span<const FormatArgImpl> args) {
std::string out;
AppendPack(&out, format, args);
return out;
}
int FprintF(std::FILE* output, UntypedFormatSpecImpl format,
absl::Span<const FormatArgImpl> args);
int SnprintF(char* output, size_t size, UntypedFormatSpecImpl format,
absl::Span<const FormatArgImpl> args);
// Returned by Streamed(v). Converts via '%s' to the std::string created
// by std::ostream << v.
template <typename T>
class StreamedWrapper {
public:
explicit StreamedWrapper(const T& v) : v_(v) { }
private:
template <typename S>
friend ConvertResult<Conv::s> FormatConvertImpl(const StreamedWrapper<S>& v,
ConversionSpec conv,
FormatSinkImpl* out);
const T& v_;
};
} // namespace str_format_internal
} // namespace absl
#endif // ABSL_STRINGS_INTERNAL_STR_FORMAT_BIND_H_