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construct/ircd/fmt.cc
2017-04-06 18:34:44 -07:00

798 lines
17 KiB
C++

/**
* Copyright (C) 2016 Charybdis Development Team
* Copyright (C) 2016 Jason Volk <jason@zemos.net>
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice is present in all copies.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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.
*/
#include <ircd/rfc1459_parse.h>
#include <ircd/rfc1459_gen.h>
#include <ircd/fmt.h>
BOOST_FUSION_ADAPT_STRUCT
(
ircd::fmt::spec,
( decltype(ircd::fmt::spec::sign), sign )
( decltype(ircd::fmt::spec::width), width )
( decltype(ircd::fmt::spec::name), name )
)
namespace ircd {
namespace fmt {
namespace qi = boost::spirit::qi;
namespace karma = boost::spirit::karma;
using qi::lit;
using qi::char_;
using qi::ushort_;
using qi::int_;
using qi::eps;
using qi::raw;
using qi::repeat;
using qi::omit;
using qi::unused_type;
std::map<string_view, specifier *, std::less<>> _specifiers;
bool is_specifier(const string_view &name);
void handle_specifier(char *&out, const size_t &max, const uint &idx, const spec &, const arg &);
template<class generator> bool generate_string(char *&out, const generator &gen, const arg &val);
template<class T, class lambda> bool visit_type(const arg &val, lambda&& closure);
struct parser
:qi::grammar<const char *, fmt::spec>
{
template<class R = unused_type> using rule = qi::rule<const char *, R>;
const rule<> specsym { lit(SPECIFIER) ,"format specifier" };
const rule<> specterm { lit(SPECIFIER_TERMINATOR) ,"specifier termination" };
const rule<string_view> name
{
raw[repeat(1,14)[char_("A-Za-z")]]
,"specifier name"
};
rule<fmt::spec> spec;
parser()
:parser::base_type{spec}
{
static const auto is_valid([]
(const auto &str, auto &, auto &valid)
{
valid = is_specifier(str);
});
spec %= specsym >> -(char_('+') | char_('-')) >> -ushort_ >> name[is_valid] >> -specterm;
}
}
const parser;
struct string_specifier
:specifier
{
static const std::tuple
<
const char *,
ircd::string_view,
std::string_view,
std::string
>
types;
bool operator()(char *&out, const size_t &max, const spec &, const arg &val) const override;
using specifier::specifier;
}
const string_specifier
{
"s"s
};
decltype(string_specifier::types)
string_specifier::types
{};
struct bool_specifier
:specifier
{
static const std::tuple
<
bool,
char, unsigned char,
short, unsigned short,
int, unsigned int,
long, unsigned long
>
types;
bool operator()(char *&out, const size_t &max, const spec &, const arg &val) const override;
using specifier::specifier;
}
const bool_specifier
{
{ "b"s }
};
decltype(bool_specifier::types)
bool_specifier::types
{};
struct signed_specifier
:specifier
{
static const std::tuple
<
bool,
char, unsigned char,
short, unsigned short,
int, unsigned int,
long, unsigned long
>
types;
bool operator()(char *&out, const size_t &max, const spec &, const arg &val) const override;
using specifier::specifier;
}
const signed_specifier
{
{ "d"s, "ld"s, "zd"s }
};
decltype(signed_specifier::types)
signed_specifier::types
{};
struct unsigned_specifier
:specifier
{
static const std::tuple
<
bool,
char, unsigned char,
short, unsigned short,
int, unsigned int,
long, unsigned long
>
types;
bool operator()(char *&out, const size_t &max, const spec &, const arg &val) const override;
using specifier::specifier;
}
const unsigned_specifier
{
{ "u"s, "lu"s, "zu"s }
};
struct hex_lowercase_specifier
:specifier
{
static const std::tuple
<
bool,
char, unsigned char,
short, unsigned short,
int, unsigned int,
long, unsigned long
>
types;
bool operator()(char *&out, const size_t &max, const spec &, const arg &val) const override;
using specifier::specifier;
}
const hex_lowercase_specifier
{
{ "x"s, "lx"s }
};
decltype(hex_lowercase_specifier::types)
hex_lowercase_specifier::types
{};
decltype(unsigned_specifier::types)
unsigned_specifier::types
{};
struct float_specifier
:specifier
{
static const std::tuple
<
char, unsigned char,
short, unsigned short,
int, unsigned int,
long, unsigned long,
float, double
>
types;
bool operator()(char *&out, const size_t &max, const spec &, const arg &val) const override;
using specifier::specifier;
}
const float_specifier
{
{ "f"s, "lf"s }
};
decltype(float_specifier::types)
float_specifier::types
{};
struct char_specifier
:specifier
{
bool operator()(char *&out, const size_t &max, const spec &, const arg &val) const override;
using specifier::specifier;
}
const char_specifier
{
"c"s
};
struct pointer_specifier
:specifier
{
bool operator()(char *&out, const size_t &max, const spec &, const arg &val) const override;
using specifier::specifier;
}
const pointer_specifier
{
"p"s
};
} // namespace fmt
} // namespace ircd
using namespace ircd;
fmt::snprintf::snprintf(internal_t,
char *const &out,
const size_t &max,
const char *const &fstr,
const va_rtti &v)
try
:fstart{strchr(fstr, SPECIFIER)}
,fstop{fstr}
,fend{fstr + strlen(fstr)}
,obeg{out}
,oend{out + max}
,out{out}
,idx{0}
{
if(unlikely(!max))
{
fstart = nullptr;
return;
}
if(!fstart)
{
append(fstr, fend);
return;
}
append(fstr, fstart);
auto it(begin(v));
for(size_t i(0); i < v.size(); ++it, i++)
{
const auto &ptr(get<0>(*it));
const auto &type(get<1>(*it));
argument(std::make_tuple(ptr, std::type_index(*type)));
}
}
catch(const std::out_of_range &e)
{
throw invalid_format("Format string requires more than %zu arguments.", v.size());
}
void
fmt::snprintf::argument(const arg &val)
{
if(finished())
return;
fmt::spec spec;
if(qi::parse(fstart, fend, parser, spec))
handle_specifier(out, remaining(), idx++, spec, val);
fstop = fstart;
if(fstart < fend)
{
fstart = strchr(fstart, SPECIFIER);
append(fstop, fstart?: fend);
}
else *out = '\0';
}
void
fmt::snprintf::append(const char *const &begin,
const char *const &end)
{
const size_t len(std::distance(begin, end));
const size_t &cpsz(std::min(len, size_t(remaining())));
memcpy(out, begin, cpsz);
out += cpsz;
*out = '\0';
}
const decltype(fmt::_specifiers) &
fmt::specifiers()
{
return _specifiers;
}
fmt::specifier::specifier(const std::string &name)
:specifier{{name}}
{
}
fmt::specifier::specifier(const std::initializer_list<std::string> &names)
:names{names}
{
for(const auto &name : this->names)
if(is_specifier(name))
throw error("Specifier '%s' already registered\n", name);
for(const auto &name : this->names)
_specifiers.emplace(name, this);
}
fmt::specifier::~specifier()
noexcept
{
for(const auto &name : names)
_specifiers.erase(name);
}
bool
fmt::is_specifier(const string_view &name)
{
return specifiers().count(name);
}
void
fmt::handle_specifier(char *&out,
const size_t &max,
const uint &idx,
const spec &spec,
const arg &val)
try
{
const auto &type(get<1>(val));
const auto &handler(*specifiers().at(spec.name));
if(!handler(out, max, spec, val))
throw invalid_type("`%s' for format specifier '%s' for argument #%u",
type.name(),
spec.name,
idx);
}
catch(const std::out_of_range &e)
{
throw invalid_format("Unhandled specifier `%s' for argument #%u in format string",
spec.name,
idx);
}
catch(const illegal &e)
{
throw illegal("Specifier `%s' for argument #%u: %s",
spec.name,
idx,
e.what());
}
template<class T,
class lambda>
bool
fmt::visit_type(const arg &val,
lambda&& closure)
{
const auto &ptr(get<0>(val));
const auto &type(get<1>(val));
return type == typeid(T)? closure(*static_cast<const T *>(ptr)) : false;
}
bool
fmt::pointer_specifier::operator()(char *&out,
const size_t &max,
const spec &,
const arg &val)
const
{
using karma::ulong_;
using karma::eps;
using karma::maxwidth;
static const auto throw_illegal([]
{
throw illegal("Not a pointer");
});
struct generator
:karma::grammar<char *, uintptr_t()>
{
karma::rule<char *, uintptr_t()> pointer_hex
{
lit("0x") << karma::hex
};
generator(): generator::base_type{pointer_hex} {}
}
static const generator;
const auto &ptr(get<0>(val));
const auto &type(get<1>(val));
const void *const p(*static_cast<const void *const *>(ptr));
return karma::generate(out, maxwidth(max)[generator] | eps[throw_illegal], uintptr_t(p));
}
bool
fmt::char_specifier::operator()(char *&out,
const size_t &max,
const spec &,
const arg &val)
const
{
using karma::eps;
using karma::maxwidth;
static const auto throw_illegal([]
{
throw illegal("Not a printable character");
});
struct generator
:karma::grammar<char *, char()>
{
karma::rule<char *, char()> printable
{
karma::print
,"character"
};
generator(): generator::base_type{printable} {}
}
static const generator;
const auto &ptr(get<0>(val));
const auto &type(get<1>(val));
if(type == typeid(const char))
{
const auto &c(*static_cast<const char *>(ptr));
karma::generate(out, maxwidth(max)[generator] | eps[throw_illegal], c);
return true;
}
else return false;
}
bool
fmt::bool_specifier::operator()(char *&out,
const size_t &max,
const spec &,
const arg &val)
const
{
using karma::eps;
using karma::maxwidth;
static const auto throw_illegal([]
{
throw illegal("Failed to print signed value");
});
const auto closure([&](const bool &boolean)
{
using karma::maxwidth;
struct generator
:karma::grammar<char *, bool()>
{
karma::rule<char *, bool()> rule
{
karma::bool_
,"boolean"
};
generator(): generator::base_type{rule} {}
}
static const generator;
return karma::generate(out, maxwidth(max)[generator] | eps[throw_illegal], boolean);
});
return !until(types, [&](auto type)
{
return !visit_type<decltype(type)>(val, closure);
});
}
bool
fmt::signed_specifier::operator()(char *&out,
const size_t &max,
const spec &s,
const arg &val)
const
{
static const auto throw_illegal([]
{
throw illegal("Failed to print signed value");
});
const auto closure([&](const long &integer)
{
using karma::long_;
using karma::maxwidth;
struct generator
:karma::grammar<char *, long()>
{
karma::rule<char *, long()> rule
{
long_
,"signed long integer"
};
generator(): generator::base_type{rule} {}
}
static const generator;
return karma::generate(out, maxwidth(max)[generator] | eps[throw_illegal], integer);
});
return !until(types, [&](auto type)
{
return !visit_type<decltype(type)>(val, closure);
});
}
bool
fmt::unsigned_specifier::operator()(char *&out,
const size_t &max,
const spec &s,
const arg &val)
const
{
static const auto throw_illegal([]
{
throw illegal("Failed to print unsigned value");
});
const auto closure([&](const ulong &integer)
{
using karma::ulong_;
using karma::maxwidth;
struct generator
:karma::grammar<char *, ulong()>
{
karma::rule<char *, ulong()> rule
{
ulong_
,"unsigned long integer"
};
generator(): generator::base_type{rule} {}
}
static const generator;
return karma::generate(out, maxwidth(max)[generator] | eps[throw_illegal], integer);
});
return !until(types, [&](auto type)
{
return !visit_type<decltype(type)>(val, closure);
});
}
bool
fmt::hex_lowercase_specifier::operator()(char *&out,
const size_t &max,
const spec &s,
const arg &val)
const
{
static const auto throw_illegal([]
{
throw illegal("Failed to print hexadecimal value");
});
const auto closure([&](const uint &integer)
{
using karma::maxwidth;
struct generator
:karma::grammar<char *, uint()>
{
karma::rule<char *, uint()> rule
{
karma::lower[karma::hex]
,"unsigned lowercase hexadecimal"
};
generator(): generator::base_type{rule} {}
}
static const generator;
return karma::generate(out, maxwidth(max)[generator] | eps[throw_illegal], integer);
});
return !until(types, [&](auto type)
{
return !visit_type<decltype(type)>(val, closure);
});
}
bool
fmt::float_specifier::operator()(char *&out,
const size_t &max,
const spec &s,
const arg &val)
const
{
static const auto throw_illegal([]
{
throw illegal("Failed to print floating point value");
});
const auto closure([&](const double &floating)
{
using karma::double_;
using karma::maxwidth;
struct generator
:karma::grammar<char *, double()>
{
karma::rule<char *, double()> rule
{
double_
,"floating point integer"
};
generator(): generator::base_type{rule} {}
}
static const generator;
return karma::generate(out, maxwidth(max)[generator] | eps[throw_illegal], floating);
});
return !until(types, [&](auto type)
{
return !visit_type<decltype(type)>(val, closure);
});
}
/*
if(type == typeid(const char[]))
{
const auto &i(reinterpret_cast<const char *>(ptr));
if(!try_lex_cast<ssize_t>(i))
throw illegal("The string literal value for integer specifier is not a valid integer");
const auto len(std::min(max, strlen(i)));
memcpy(out, i, len);
out += len;
return true;
}
if(type == typeid(const char *))
{
const auto &i(*reinterpret_cast<const char *const *>(ptr));
if(!try_lex_cast<ssize_t>(i))
throw illegal("The character buffer for integer specifier is not a valid integer");
const auto len(std::min(max, strlen(i)));
memcpy(out, i, len);
out += len;
return true;
}
if(type == typeid(const std::string))
{
const auto &i(*reinterpret_cast<const std::string *>(ptr));
if(!try_lex_cast<ssize_t>(i))
throw illegal("The string argument for integer specifier is not a valid integer");
const auto len(std::min(max, i.size()));
memcpy(out, i.data(), len);
out += len;
return true;
}
if(type == typeid(const string_view) || type == typeid(const std::string_view))
{
const auto &i(*reinterpret_cast<const std::string_view *>(ptr));
if(!try_lex_cast<ssize_t>(i))
throw illegal("The string argument for integer specifier is not a valid integer");
const auto len(std::min(max, i.size()));
memcpy(out, i.data(), len);
out += len;
return true;
}
*/
bool
fmt::string_specifier::operator()(char *&out,
const size_t &max,
const spec &,
const arg &val)
const
{
using karma::char_;
using karma::eps;
using karma::maxwidth;
using karma::unused_type;
static const auto throw_illegal([]
{
throw illegal("Not a printable string");
});
struct generator
:karma::grammar<char *, const string_view &>
{
karma::rule<char *, const string_view &> string
{
*(karma::print)
,"string"
};
generator() :generator::base_type{string} {}
}
static const generator;
return generate_string(out, maxwidth(max)[generator] | eps[throw_illegal], val);
}
template<class generator>
bool
fmt::generate_string(char *&out,
const generator &gen,
const arg &val)
{
using karma::eps;
const auto &ptr(get<0>(val));
const auto &type(get<1>(val));
if(type == typeid(ircd::string_view))
{
const auto &str(*static_cast<const ircd::string_view *>(ptr));
return karma::generate(out, gen, str);
}
else if(type == typeid(std::string_view))
{
const auto &str(*static_cast<const std::string_view *>(ptr));
return karma::generate(out, gen, str);
}
else if(type == typeid(std::string))
{
const auto &str(*static_cast<const std::string *>(ptr));
return karma::generate(out, gen, string_view{str});
}
else if(type == typeid(const char *))
{
const char *const &str{*static_cast<const char *const *const>(ptr)};
return karma::generate(out, gen, string_view{str});
}
// This for string literals which have unique array types depending on their size.
// There is no reasonable way to match them. The best that can be hoped for is the
// grammar will fail gracefully (most of the time) or not print something bogus when
// it happens to be legal.
const auto &str(static_cast<const char *>(ptr));
return karma::generate(out, gen, string_view{str});
}