// Matrix Construct // // Copyright (C) Matrix Construct Developers, Authors & Contributors // Copyright (C) 2016-2018 Jason Volk // // 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. The // full license for this software is available in the LICENSE file. #pragma GCC visibility push(internal) namespace ircd::json { using namespace ircd::spirit; // Instantiations of the grammars struct parser extern const parser; struct printer extern const printer; } #pragma GCC visibility pop #pragma GCC visibility push(internal) BOOST_FUSION_ADAPT_STRUCT ( ircd::json::member, ( decltype(ircd::json::member::first), first ) ( decltype(ircd::json::member::second), second ) ) #pragma GCC visibility pop #pragma GCC visibility push(internal) BOOST_FUSION_ADAPT_STRUCT ( ircd::json::object::member, ( decltype(ircd::json::object::member::first), first ) ( decltype(ircd::json::object::member::second), second ) ) #pragma GCC visibility pop #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wuninitialized" struct [[gnu::visibility("internal")]] ircd::json::parser :qi::grammar { using it = const char *; template using rule = qi::rule; const rule<> NUL { lit('\0') ,"nul" }; // insignificant whitespaces const rule<> SP { lit('\x20') ,"space" }; const rule<> HT { lit('\x09') ,"horizontal tab" }; const rule<> CR { lit('\x0D') ,"carriage return" }; const rule<> LF { lit('\x0A') ,"line feed" }; // whitespace skipping const rule<> WS { SP | HT | CR | LF ,"whitespace" }; const rule<> ws { *(WS) ,"whitespace monoid" }; const rule<> wsp { +(WS) ,"whitespace semigroup" }; // structural const rule<> object_begin { lit('{') ,"object begin" }; const rule<> object_end { lit('}') ,"object end" }; const rule<> array_begin { lit('[') ,"array begin" }; const rule<> array_end { lit(']') ,"array end" }; const rule<> name_sep { lit(':') ,"name sep" }; const rule<> value_sep { lit(',') ,"value sep" }; const rule<> escape { lit('\\') ,"escape" }; const rule<> quote { lit('"') ,"quote" }; // literal const rule<> lit_false { lit("false") ,"literal false" }; const rule<> lit_true { lit("true") ,"literal true" }; const rule<> lit_null { lit("null") ,"null" }; const rule<> boolean { lit_true | lit_false ,"boolean" }; const rule<> literal { lit_true | lit_false | lit_null ,"literal" }; // numerical const rule<> number_int { (char_("1-9") >> repeat(0, 18)[char_("0-9")]) | lit('0') ,"integer" }; const rule<> number_frac { lit('.') >> repeat(1, 18)[char_("0-9")] >> -char_("1-9") ,"fraction" }; const rule<> number_exp { char_("eE") >> -char_("+-") >> repeat(1, 4)[char_("0-9")] ,"exponent" }; const rule<> number { -lit('-') >> number_int >> -number_frac >> -number_exp ,"number" }; // string const rule<> utf16_surrogate { qi::uint_parser < uint16_t, // 16 bit width 16U, // base-16 (hex) 4U, // minimum digits 4U // maximum digits >{} ,"UTF-16 surrogate" }; const rule<> unicode { lit('u') >> utf16_surrogate ,"escaped unicode" }; const rule<> control { char_('\x00', '\x1F') ,"control character" }; // characters that must be escaped const rule<> escaped { quote | escape | control ,"escaped character" }; // characters that should appear after an escaping solidus const rule<> escaper { char_("btnfr0\"\\") | unicode ,"escaper" }; // cscapers supersetting the rule above with addl non-canonical chars const rule<> escaper_nc { escaper | lit('/') ,"escaper" }; const rule<> escape_sequence { escape >> escaper_nc ,"escape sequence" }; const rule chars { //raw[*((char_ - escaped) | (escape >> escaper_nc))] raw[*((~char_('\x00', '\x1F') - char_("\x22\x5C")) | (escape >> escaper_nc))] ,"characters" }; template static u64x2 string_content_block(const block_t, const block_t) noexcept; const custom_parser string_content{}; const rule string { //quote >> chars >> (!escape >> quote) string_content ,"string" }; // container const rule name { string.alias() ,"name" }; // recursion depth _r1_type depth; [[noreturn]] static void throws_exceeded(); rule member { name >> -ws >> name_sep >> -ws >> value(depth) ,"member" }; rule object { (eps(depth < json::object::max_recursion_depth) | eps[throws_exceeded]) >> object_begin >> -((-ws >> member(depth)) % (-ws >> value_sep)) >> -ws >> object_end ,"object" }; rule array { (eps(depth < json::array::max_recursion_depth) | eps[throws_exceeded]) >> array_begin >> -((-ws >> value(depth)) % (-ws >> value_sep)) >> -ws >> array_end ,"array" }; // primary recursive rule rule value { ("e >> string) | (&object_begin >> object(depth + 1)) | (&array_begin >> array(depth + 1)) | number | lit_true | lit_false | lit_null ,"value" }; template bool operator()(const char *&start, const char *const &stop, gen&&, attr&&...) const; template bool operator()(const char *const &start, const char *const &stop, gen&&, attr&&...) const; parser() noexcept :parser::base_type{rule<>{}} // required by spirit { // synthesized repropagation of recursive rules value %= ("e >> string) | (&object_begin >> object(depth + 1)) | (&array_begin >> array(depth + 1)) | number | lit_true | lit_false | lit_null ; } } const ircd::json::parser; #pragma GCC diagnostic pop struct [[gnu::visibility("internal")]] ircd::json::printer :karma::grammar { using it = char *; template using rule = karma::rule; const rule<> NUL { lit('\0') ,"nul" }; // insignificant whitespaces const rule<> SP { lit('\x20') ,"space" }; const rule<> HT { lit('\x09') ,"horizontal tab" }; const rule<> CR { lit('\x0D') ,"carriage return" }; const rule<> LF { lit('\x0A') ,"line feed" }; // whitespace skipping const rule<> WS { SP | HT | CR | LF ,"whitespace" }; const rule<> ws { *(WS) ,"whitespace monoid" }; const rule<> wsp { +(WS) ,"whitespace semigroup" }; // structural const rule<> object_begin { lit('{') ,"object begin" }; const rule<> object_end { lit('}') ,"object end" }; const rule<> array_begin { lit('[') ,"array begin" }; const rule<> array_end { lit(']') ,"array end" }; const rule<> name_sep { lit(':') ,"name separator" }; const rule<> value_sep { lit(',') ,"value separator" }; const rule<> quote { lit('"') ,"quote" }; const rule<> escape { lit('\\') ,"escape" }; // literal const rule lit_true { karma::string("true") ,"literal true" }; const rule lit_false { karma::string("false") ,"literal false" }; const rule lit_null { karma::string("null") ,"literal null" }; const rule boolean { lit_true | lit_false ,"boolean" }; const rule literal { lit_true | lit_false | lit_null ,"literal" }; // number const rule number { double_ ,"number" }; // string using string_context = boost::spirit::context, fusion::vector<>>; static void string_generate(unused_type, string_context &, bool &) noexcept; const rule string { quote << eps[std::bind(&printer::string_generate, ph::_1, ph::_2, ph::_3)] << quote ,"string" }; const rule name { string.alias() ,"name" }; // primary recursive rule rule value { rule{} ,"value" }; rule member { rule{} ,"member" }; rule object { rule{} ,"object" }; rule array { rule{} ,"array" }; template static void list_protocol(mutable_buffer &, it_a begin, const it_b &end, closure&&); template void operator()(mutable_buffer &out, gen&&, attr&&...) const; printer() noexcept :printer::base_type{rule<>{}} { // synthesized repropagation of recursive rules member %= name << name_sep << value; object %= object_begin << -(member % value_sep) << object_end; array %= array_begin << -(value % value_sep) << array_end; value %= (&object << object) | (&array << array) | (&literal << literal) | (&number << number) | string ; } } const ircd::json::printer; decltype(ircd::json::stats) ircd::json::stats; template [[gnu::always_inline]] inline void ircd::json::printer::operator()(mutable_buffer &out, gen&& g, attr&&... a) const { #ifdef IRCD_JSON_PRINTER_STATS ++stats.print_calls; const prof::scope_cycles timer{stats.print_cycles}; #endif if(unlikely(!ircd::generate(out, std::forward(g), std::forward(a)...))) throw print_error { "Failed to generate JSON" }; } template [[gnu::always_inline]] inline void ircd::json::printer::list_protocol(mutable_buffer &out, it_a it, const it_b &end, closure&& lambda) { if(likely(it != end)) { lambda(out, *it); for(++it; it != end; ++it) { const auto &printer(json::printer); printer(out, printer.value_sep); lambda(out, *it); } } } inline void ircd::json::printer::string_generate(unused_type, string_context &g, bool &ret) noexcept { #if __has_builtin(__builtin_assume) __builtin_assume(ret == true); #endif assert(generator_state); auto &state { *generator_state }; const string_view &input { attr_at<0>(g) }; const size_t output_length { json::string::stringify(state.out, input) }; const size_t consumed { std::min(output_length, size(state.out)) }; state.consumed += consume(state.out, consumed); state.generated += output_length; ret = state.generated == state.consumed; } template [[gnu::always_inline]] inline bool ircd::json::parser::operator()(const char *const &start_, const char *const &stop, gen&& g, attr&&...a) const { const char *start(start_); return operator()(start, stop, std::forward(g), std::forward(a)...); } template [[gnu::always_inline]] inline bool ircd::json::parser::operator()(const char *&start, const char *const &stop, gen&& g, attr&&...a) const { #ifdef IRCD_JSON_PARSER_STATS ++stats.parse_calls; const prof::scope_cycles timer{stats.parse_cycles}; #endif return ircd::parse(start, stop, std::forward(g), std::forward(a)...); } /// The input covers everything from the alleged start of our alleged string /// to the end of whatever the user provided. Returns true if successful and /// the result string_view is set in the context attribute; the iterator is /// advanced. template inline bool ircd::json::custom_parser::parse(iterator &__restrict__ start, const iterator &__restrict__ stop, context &g, const skipper &, attr &) const { // Clang scales between 128bit and 256bit systems when we use the 256 bit // type (note that performance even improves on some 128 bit systems). GCC // falls back to scalar instead, so we have to case 128bit systems on GCC. #if defined(__AVX__) || defined(__clang__) using block_t = u8x32; using block_t_u = u256x1_u; #else using block_t = u8x16; using block_t_u = u128x1_u; #endif assert(start <= stop); const size_t input_max { size_t(std::distance(start, stop)) }; // The input is a priori invalid if the length is not greater than "" or // the first character is not quote. const bool input_valid { input_max >= 2 && start[0] == '"' }; // When the input is valid subtract one for the new max length. Otherwise // we mask this length to zero to void the remainder of this frame. const u64x2 max { 0, (input_max - 1) & boolmask(input_valid) }; static const auto each_block { json::parser::string_content_block }; const auto count { simd::stream(start + 1, max, each_block) }; const bool ok { count[0] == 1 }; // Set the result in the context attribute. This covers the string content // without surrounding quotes. attr_at<0>(g) = string_view { start + ok, count[1] & boolmask(ok) }; // Advance the iterator the length of the full string including quotes // iff this parser was successful. start += (1 + count[1] + 1) & boolmask(ok); return ok; } template inline ircd::u64x2 ircd::json::parser::string_content_block(const block_t block, const block_t block_mask) noexcept { assert(block_mask[0] == 0xff); const block_t is_esc ( block == '\\' ); const block_t is_quote ( block == '"' ); const block_t is_ctrl ( block < 0x20 ); const block_t is_special { is_esc | is_quote | is_ctrl }; const block_t is_regular { simd::lateral(~is_special) }; if(likely(is_regular[0])) return u64x2 { 0, sizeof(block) }; const u64 regular_prefix_count { simd::lzcnt(is_special | ~block_mask) / 8 }; if(likely(regular_prefix_count)) return u64x2 { 0, regular_prefix_count }; const u64 err { popmask(is_quote[0]) | boolmask(is_ctrl[0]) | boolmask(is_esc[0] & ~block_mask[1]) }; const u64 add { 1UL + popmask(is_esc[0] & (is_quote[1] | is_esc[1]) & block_mask[1]) }; return u64x2 { err, add & boolmask(err == 0) }; } [[gnu::noinline]] void ircd::json::parser::throws_exceeded() { throw recursion_limit { "Maximum recursion depth exceeded" }; } /////////////////////////////////////////////////////////////////////////////// // // json/tool.h // ircd::json::strung ircd::json::replace(const strung &s, const json::members &r) { static const auto in { [](const json::members &r, const object::member &m) { return std::any_of(begin(r), end(r), [&m] (const json::member &r) { return string_view{r.first} == m.first; }); } }; if(!empty(s) && type(s) != type::OBJECT) throw type_error { "Cannot replace member into JSON of type %s", reflect(type(s)) }; size_t mctr {0}; thread_local std::array mb; for(const object::member &m : object{s}) if(!in(r, m)) mb.at(mctr++) = member{m}; for(const json::member &m : r) mb.at(mctr++) = m; return strung { mb.data(), mb.data() + mctr }; } ircd::json::strung ircd::json::replace(const strung &s, const json::member &m_) { if(!empty(s) && type(s) != type::OBJECT) throw type_error { "Cannot replace member into JSON of type %s", reflect(type(s)) }; size_t mctr {0}; thread_local std::array mb; for(const object::member &m : object{s}) if(m.first != string_view{m_.first}) mb.at(mctr++) = member{m}; mb.at(mctr++) = m_; return strung { mb.data(), mb.data() + mctr }; } ircd::json::strung ircd::json::insert(const strung &s, const json::member &m) { if(!empty(s) && type(s) != type::OBJECT) throw type_error { "Cannot insert member into JSON of type %s", reflect(type(s)) }; size_t mctr {0}; thread_local std::array mb; for(const object::member &m : object{s}) mb.at(mctr++) = member{m}; mb.at(mctr++) = m; return strung { mb.data(), mb.data() + mctr }; } ircd::json::strung ircd::json::remove(const strung &s, const string_view &key) { if(empty(s)) return s; if(type(s) != type::OBJECT) throw type_error { "Cannot remove object member '%s' from JSON of type %s", key, reflect(type(s)) }; size_t mctr {0}; thread_local std::array mb; for(const object::member &m : object{s}) if(m.first != key) mb.at(mctr++) = m; return strung { mb.data(), mb.data() + mctr }; } ircd::json::strung ircd::json::remove(const strung &s, const size_t &idx) { if(empty(s)) return s; if(type(s) != type::ARRAY) throw type_error { "Cannot remove array element [%zu] from JSON of type %s", idx, reflect(type(s)) }; size_t mctr{0}, i{0}; thread_local std::array mb; for(const string_view &m : array{s}) if(i++ != idx) mb.at(mctr++) = m; return strung { mb.data(), mb.data() + mctr }; } void ircd::json::merge(stack::object &out, const vector &v) { struct val { //TODO: optimize with std::pmr::monotonic_buffer_resource et al std::map> o; std::vector a; string_view v; void _merge_object(const json::object &o) { for(const auto &m : o) { val &v(this->o[m.first]); v.merge(m.second); } } void _merge_array(const json::array &a) { for(const auto &v : a) this->a.emplace_back(v); } void merge(const string_view &v) { switch(json::type(v)) { case json::OBJECT: _merge_object(v); break; case json::ARRAY: _merge_array(v); break; default: this->v = v; break; } } void _compose_object(json::stack &out, json::stack::object &object) const { for(const auto &m : o) { json::stack::member member{object, m.first}; m.second.compose(out); } } void _compose_object(json::stack &out, json::stack::member &member) const { json::stack::object object{member}; _compose_object(out, object); } void _compose_object(json::stack &out) const { json::stack::chase c{out, true}; if(c.m) _compose_object(out, *c.m); else if(c.o) _compose_object(out, *c.o); } void _compose_array(json::stack &out) const { json::stack::array array{out}; for(const auto &v : a) array.append(v); } void _compose_value(json::stack &out) const { json::stack::chase c{out, true}; if(c.a) c.a->append(v); else if(c.m) c.m->append(v); else assert(0); } void compose(json::stack &out) const { if(!o.empty()) _compose_object(out); else if(!a.empty()) _compose_array(out); else if(!v.empty()) _compose_value(out); } val() = default; val(const string_view &v) { merge(v); } }; val top; for(const auto &o : v) top.merge(o); assert(out.s); top.compose(*out.s); } /////////////////////////////////////////////////////////////////////////////// // // json/stack.h // ircd::json::stack::stack(const mutable_buffer &buf, flush_callback flusher, const size_t &hiwat, const size_t &lowat) :buf{buf} ,flusher{std::move(flusher)} ,hiwat{hiwat} ,lowat{lowat} { } ircd::json::stack::stack(stack &&other) noexcept :buf{std::move(other.buf)} ,flusher{std::move(other.flusher)} ,eptr{std::move(other.eptr)} ,cp{std::move(other.cp)} ,appended{std::move(other.appended)} ,flushed{std::move(other.flushed)} ,level{std::move(other.level)} ,hiwat{std::move(other.hiwat)} ,lowat{std::move(other.lowat)} ,co{std::move(other.co)} ,ca{std::move(other.ca)} { other.cp = nullptr; other.co = nullptr; other.ca = nullptr; if(cp) { assert(cp->s == &other); cp->s = this; } if(co) { assert(co->s == &other); co->s = this; } if(ca) { assert(ca->s == &other); ca->s = this; } } ircd::json::stack::~stack() noexcept { assert(closed()); if(buf.consumed()) flush(true); assert(clean() || done()); } void ircd::json::stack::append(const char &c) noexcept { append(1, [&c] (const mutable_buffer &buf) noexcept { buf[0] = c; return 1; }); } void ircd::json::stack::append(const string_view &s) noexcept { append(s.size(), [&s] (const mutable_buffer &buf) noexcept { assert(ircd::size(buf) >= s.size()); return ircd::copy(buf, s); }); } void ircd::json::stack::append(const size_t &expect, const window_buffer::closure &closure) noexcept try { if(!expect || failed()) return; // Minimum bytes we keep available all times to allow the JSON to close // correctly without complication on the user's stack unwind; hinted by // the recursion level. const size_t buf_min { level + 8 }; // Calculated buffer bytes required. const size_t buf_req { expect + buf_min }; // Since all appends are atomic, we need to have buffer available to print // the JSON without having to flush while doing so. If we're low on buffer, // this branch triggers a flush. Afterward, if there is still not enough // buffer that's an error so the user needs to flush enough when called. if(buf_req > buf.remaining()) { if(unlikely(!flusher)) throw print_panic { "Insufficient buffer. I need %zu more bytes; you only have %zu left (of %zu).", buf_req, buf.remaining(), size(buf.base) }; if(!flush(true)) return; if(unlikely(buf_req > buf.remaining())) throw print_error { "Insufficient flush. I still need %zu more bytes to buffer.", buf_req - buf.remaining(), }; } // Print the JSON to the buffer and advance the window pointer const const_buffer appended { buf([&expect, &closure](const mutable_buffer &buf) { const size_t appended { closure(buf) }; assert(appended <= size(buf)); assert(appended == expect); return const_buffer { data(buf), appended }; }) }; this->appended += expect; assert(size(appended) >= expect); assert(this->appended >= size(appended)); // Conditions to courtesy flush after a sufficiently large dump; when // there's no buffer remaining we'll inevitably have to flush; the call // is force=true so the flusher must accomplish something. if(!buf.remaining()) flush(true); // The high-watermark feature triggers a flush when the buffer has exceeded // the threshold from accumulated writes; force is not set to true. else if(buf.consumed() >= hiwat) flush(); } catch(...) { assert(!this->eptr); this->eptr = std::current_exception(); } void ircd::json::stack::rethrow_exception() { if(unlikely(eptr)) std::rethrow_exception(eptr); } bool ircd::json::stack::flush(const bool &force) noexcept try { if(!flusher) return false; if(unlikely(failed())) return false; if(!force && buf.consumed() < lowat) return false; if(!force && cp) return false; if(unlikely(cp)) { const size_t invalidated { invalidate_checkpoints() }; log::dwarning { "Flushing json::stack(%p) bytes:%zu level:%zu checkpoints:%zu", this, size(buf.completed()), level, invalidated, }; } // The user returns the portion of the buffer they were able to flush // rather than forcing them to wait on their sink to flush the whole // thing, they can continue with us for a little while more. const const_buffer flushed { flusher(buf.completed()) }; assert(data(flushed) == data(buf.completed())); // Can only flush front sry this->flushed += size(flushed); buf.shift(size(flushed)); return true; } catch(...) { assert(!this->eptr); this->eptr = std::current_exception(); return false; } size_t ircd::json::stack::invalidate_checkpoints() { size_t ret(0); for(auto cp(this->cp); cp; cp = cp->pc, ++ret) cp->s = nullptr; this->cp = nullptr; return ret; } void ircd::json::stack::clear() { const size_t rewound { rewind(buf.consumed()) }; this->eptr = std::exception_ptr{}; } size_t ircd::json::stack::rewind(const size_t &bytes) { const size_t before { buf.consumed() }; assert(appended >= before); const size_t &amount { std::min(bytes, before) }; assert(appended >= amount); const size_t after { size(buf.rewind(amount)) }; assert(before >= after); assert(before - after == amount); appended -= amount; assert(appended >= after); return amount; } ircd::string_view ircd::json::stack::completed() const { return buf.completed(); } size_t ircd::json::stack::remaining() const { return buf.remaining(); } bool ircd::json::stack::failed() const { return bool(eptr); } bool ircd::json::stack::done() const { assert((opened() && level) || !level); return closed() && buf.consumed(); } bool ircd::json::stack::clean() const { return closed() && !buf.consumed(); } bool ircd::json::stack::closed() const { return !opened(); } bool ircd::json::stack::opened() const { return co || ca; } // // object // ircd::json::stack::object & ircd::json::stack::object::top(stack &s) { const chase t{s, true}; if(unlikely(!t.o)) throw type_error { "Top of stack is not of type object. (o:%b a:%b m:%b)", bool(t.o), bool(t.a), bool(t.m), }; return *t.o; } const ircd::json::stack::object & ircd::json::stack::object::top(const stack &s) { const const_chase t{s, true}; if(unlikely(!t.o)) throw type_error { "Top of stack is not of type object. (o:%b a:%b m:%b)", bool(t.o), bool(t.a), bool(t.m), }; return *t.o; } ircd::json::stack::object::object(object &&other) noexcept :m{std::move(other.m)} ,s{std::move(other.s)} ,pm{std::move(other.pm)} ,pa{std::move(other.pa)} ,cm{std::move(other.cm)} ,mc{std::move(other.mc)} { other.s = nullptr; if(s) { assert(s->co == &other); s->co = this; } if(pm) { assert(pm->co == &other); pm->co = this; } else if(pa) { assert(pa->co == &other); pa->co = this; } if(cm) { assert(cm->po == &other); cm->po = this; } } ircd::json::stack::object::object(stack &s) :s{&s} { const chase t{s, true}; if(t.a) { new (this) object{*t.a}; return; } else if(t.m) { new (this) object{*t.m}; return; } else if(t.o) { assert(0); return; } assert(s.clean()); s.co = this; s.append('{'); s.level++; } ircd::json::stack::object::object(stack &s, const string_view &name) :object{object::top(s), name} { } ircd::json::stack::object::object(object &po, const string_view &name) :m{po, name} ,s{po.s} ,pm{&m} { assert(s->opened()); s->rethrow_exception(); assert(pm->co == nullptr); assert(pm->ca == nullptr); pm->co = this; s->append('{'); pm->vc |= true; s->level++; } ircd::json::stack::object::object(member &pm) :s{pm.s} ,pm{&pm} { assert(s->opened()); s->rethrow_exception(); assert(pm.co == nullptr); assert(pm.ca == nullptr); pm.co = this; s->append('{'); pm.vc |= true; s->level++; } ircd::json::stack::object::object(array &pa) :s{pa.s} ,pa{&pa} { assert(s->opened()); s->rethrow_exception(); assert(pa.co == nullptr); assert(pa.ca == nullptr); pa.co = this; if(pa.vc) s->append(','); s->append('{'); s->level++; } void ircd::json::stack::object::append(const json::object &object) { for(const auto &kv : object) json::stack::member { *this, kv.first, kv.second }; } #if defined(__GNUC__) && !defined(__clang__) __attribute__((optimize("no-lifetime-dse"))) #endif ircd::json::stack::object::~object() noexcept { if(!s) { assert(!m.s); return; // std::move()'ed away } const unwind _{[this] { // Allows ~dtor to be called to close the JSON manually s = nullptr; }}; assert(cm == nullptr); s->append('}'); s->level--; if(pm) // branch taken if member of object { assert(pa == nullptr); assert(pm->ca == nullptr); assert(pm->co == this); pm->co = nullptr; return; } if(pa) // branch taken if value in array { assert(pm == nullptr); assert(pa->ca == nullptr); assert(pa->co == this); pa->vc++; pa->co = nullptr; return; } // branch taken if top of stack:: assert(s->co == this); assert(s->ca == nullptr); assert(pm == nullptr && pa == nullptr); s->co = nullptr; assert(s->closed()); } // // array // ircd::json::stack::array & ircd::json::stack::array::top(stack &s) { const chase t{s, true}; if(unlikely(!t.a)) throw type_error { "Top of stack is not of type array. (o:%b a:%b m:%b)", bool(t.o), bool(t.a), bool(t.m), }; return *t.a; } const ircd::json::stack::array & ircd::json::stack::array::top(const stack &s) { const const_chase t{s, true}; if(unlikely(!t.a)) throw type_error { "Top of stack is not of type array. (o:%b a:%b m:%b)", bool(t.o), bool(t.a), bool(t.m), }; return *t.a; } ircd::json::stack::array::array(array &&other) noexcept :m{std::move(other.m)} ,s{std::move(other.s)} ,pm{std::move(other.pm)} ,pa{std::move(other.pa)} ,co{std::move(other.co)} ,ca{std::move(other.ca)} ,vc{std::move(other.vc)} { other.s = nullptr; if(s) { assert(s->ca == &other); s->ca = this; } if(pm) { assert(pm->ca == &other); pm->ca = this; } else if(pa) { assert(pa->ca == &other); pa->ca = this; } if(co) { assert(co->pa == &other); co->pa = this; } else if(ca) { assert(ca->pa == &other); ca->pa = this; } } ircd::json::stack::array::array(stack &s) :s{&s} { const chase t{s, true}; if(t.a) { new (this) array{*t.a}; return; } else if(t.m) { new (this) array{*t.m}; return; } else if(t.o) { assert(0); return; } assert(s.clean()); s.ca = this; s.append('['); s.level++; } ircd::json::stack::array::array(stack &s, const string_view &name) :array{object::top(s), name} { } ircd::json::stack::array::array(object &po, const string_view &name) :m{po, name} ,s{po.s} ,pm{&m} { assert(s->opened()); s->rethrow_exception(); assert(pm->co == nullptr); assert(pm->ca == nullptr); pm->ca = this; s->append('['); pm->vc |= true; s->level++; } ircd::json::stack::array::array(array &pa) :s{pa.s} ,pa{&pa} { assert(s->opened()); s->rethrow_exception(); assert(pa.co == nullptr); assert(pa.ca == nullptr); pa.ca = this; if(pa.vc) s->append(','); s->append('['); s->level++; } ircd::json::stack::array::array(member &pm) :s{pm.s} ,pm{&pm} { assert(s->opened()); s->rethrow_exception(); assert(pm.co == nullptr); assert(pm.ca == nullptr); pm.ca = this; s->append('['); pm.vc |= true; s->level++; } #if defined(__GNUC__) && !defined(__clang__) __attribute__((optimize("no-lifetime-dse"))) #endif ircd::json::stack::array::~array() noexcept { if(!s) { assert(!m.s); return; // std::move()'ed away } const unwind _{[this] { // Allows ~dtor to be called to close the JSON manually s = nullptr; }}; assert(co == nullptr); assert(ca == nullptr); s->append(']'); s->level--; if(pm) // branch taken if member of object { assert(pa == nullptr); assert(pm->ca == this); assert(pm->co == nullptr); pm->ca = nullptr; return; } if(pa) // branch taken if value in array { assert(pm == nullptr); assert(pa->ca == this); assert(pa->co == nullptr); pa->vc++; pa->ca = nullptr; return; } // branch taken if top of stack:: assert(s->ca == this); assert(s->co == nullptr); assert(pm == nullptr && pa == nullptr); s->ca = nullptr; assert(s->closed()); } void ircd::json::stack::array::append(const json::value &value) { assert(s); _pre_append(); const unwind_nominal post{[this] { _post_append(); }}; s->append(serialized(value), [&value] (mutable_buffer buf) { return size(stringify(buf, value)); }); } void ircd::json::stack::array::_pre_append() { if(vc) s->append(','); s->rethrow_exception(); } void ircd::json::stack::array::_post_append() { ++vc; } // // member // ircd::json::stack::member & ircd::json::stack::member::top(stack &s) { const chase t{s, true}; if(unlikely(!t.m)) throw type_error { "Top of stack is not of type member. (o:%b a:%b m:%b)", bool(t.o), bool(t.a), bool(t.m), }; return *t.m; } const ircd::json::stack::member & ircd::json::stack::member::top(const stack &s) { const const_chase t{s, true}; if(unlikely(!t.m)) throw type_error { "Top of stack is not of type member. (o:%b a:%b m:%b)", bool(t.o), bool(t.a), bool(t.m), }; return *t.m; } ircd::json::stack::member::member(member &&other) noexcept :s{std::move(other.s)} ,po{std::move(other.po)} ,name{std::move(other.name)} ,co{std::move(other.co)} ,ca{std::move(other.ca)} ,vc{std::move(other.vc)} { other.s = nullptr; if(po) { assert(po->cm == &other); po->cm = this; } if(co) { assert(co->pm == &other); co->pm = this; } else if(ca) { assert(ca->pm == &other); ca->pm = this; } } ircd::json::stack::member::member(stack &s, const string_view &name) :member { object::top(s), name } { } ircd::json::stack::member::member(object &po, const string_view &name) :s{po.s} ,po{&po} ,name{name} { assert(s->opened()); s->rethrow_exception(); assert(po.cm == nullptr); po.cm = this; if(po.mc) s->append(','); static const printer::rule rule { printer.name << printer.name_sep }; char tmp[512]; mutable_buffer buf{tmp}; printer(buf, rule, name); assert(data(buf) >= tmp); s->append(string_view{tmp, size_t(data(buf) - tmp)}); } ircd::json::stack::member::member(stack &s, const string_view &name, const json::value &value) :member { object::top(s), name, value } { } ircd::json::stack::member::member(object &po, const string_view &name, const json::value &value) :member{po, name} { append(value); } #if defined(__GNUC__) && !defined(__clang__) __attribute__((optimize("no-lifetime-dse"))) #endif ircd::json::stack::member::~member() noexcept { if(!s) return; // std::move()'ed away const unwind _{[this] { // Allows ~dtor to be called to close the JSON manually s = nullptr; }}; if(!vc) s->append("null"); assert(co == nullptr); assert(ca == nullptr); assert(po); assert(po->cm == this); po->mc++; po->cm = nullptr; } void ircd::json::stack::member::append(const json::value &value) { assert(s); _pre_append(); const unwind_nominal post{[this] { _post_append(); }}; s->append(serialized(value), [&value] (mutable_buffer buf) { return size(stringify(buf, value)); }); } void ircd::json::stack::member::_pre_append() { assert(!vc); } void ircd::json::stack::member::_post_append() { vc |= true; } // // stack::checkpoint // ircd::json::stack::checkpoint::checkpoint(stack &s, const bool &committed, const bool &exception_rollback) :s{&s} ,pc{s.cp} ,point { s.buf.consumed() } ,vc{[&s] { const chase top { s, true }; return top.o? top.o->mc: top.a? top.a->vc: top.m? top.m->vc: 0; }()} ,committed { committed } ,exception_rollback { exception_rollback } { s.cp = this; } ircd::json::stack::checkpoint::~checkpoint() noexcept { if(std::uncaught_exceptions() && exception_rollback) committing(false); if(!committing()) rollback(); if(!s) return; assert(s->cp == this); s->cp = pc; // Certain uses of json::stack in loops might create and destroy // checkpoints without any appends between their lifetimes. This results // in the buffer filling up and inevitably force-flushing under an unlucky // checkpoint (which is bad). This non-forced flush here prevents that once // the buffer reaches the low-watermark and there is no parent checkpoint. if(committing()) s->flush(); } bool ircd::json::stack::checkpoint::rollback() { if(!s) { log::dwarning { "Attempting rollback of invalidated checkpoint(%p).", this, }; return false; } assert(point <= s->buf.consumed()); s->rewind(s->buf.consumed() - point); const chase top { *s, true }; if(top.o) top.o->mc = vc; else if(top.a) top.a->vc = vc; else if(top.m) top.m->vc = vc; committing(true); return true; } // // chase // namespace ircd::json { template static bool _next(chase &); template static bool _prev(chase &); } ircd::json::stack::chase::chase(stack &s, const bool &prechase) :a{s.ca} ,o{s.co} ,m{nullptr} { if(prechase) while(next()); } bool ircd::json::stack::chase::next() { return _next(*this); } bool ircd::json::stack::chase::prev() { return _prev(*this); } // // const_chase // ircd::json::stack::const_chase::const_chase(const stack &s, const bool &prechase) :a{s.ca} ,o{s.co} ,m{nullptr} { if(prechase) while(next()); } bool ircd::json::stack::const_chase::next() { return _next(*this); } bool ircd::json::stack::const_chase::prev() { return _prev(*this); } // // chase internal // template bool ircd::json::_next(chase &c) { if(c.o) { if(!c.o->cm) return false; c.m = c.o->cm; c.a = nullptr; c.o = nullptr; return true; } else if(c.a) { if(!c.a->co && !c.a->ca) return false; c.m = nullptr; c.o = c.a->co; c.a = c.a->ca; return true; } else if(c.m) { if(!c.m->co && !c.m->ca) return false; c.o = c.m->co; c.a = c.m->ca; c.m = nullptr; return true; } else return false; } template bool ircd::json::_prev(chase &c) { if(c.o) { if(!c.o->pa && !c.o->pm) return false; c.a = c.o->pa; c.m = c.o->pm; c.o = nullptr; return true; } else if(c.a) { if(!c.a->pa && !c.a->pm) return false; c.m = c.a->pm; c.a = c.a->pa; c.o = nullptr; return true; } else if(c.m) { assert(c.m->po); c.o = c.m->po; c.a = nullptr; c.m = nullptr; return true; } else return false; } /////////////////////////////////////////////////////////////////////////////// // // json/iov.h // decltype(ircd::json::iov::max_size) ircd::json::iov::max_size; std::ostream & ircd::json::operator<<(std::ostream &s, const iov &iov) { s << json::strung(iov); return s; } ircd::string_view ircd::json::stringify(mutable_buffer &buf, const iov &iov) { static const auto addressof //TODO: XXX { [](const member &m) noexcept { return std::addressof(m); } }; static const auto less_member { [](const member *const &a, const member *const &b) noexcept { return *a < *b; } }; static const auto print_member { [](mutable_buffer &buf, const member *const &m) { printer(buf, printer.name << printer.name_sep, m->first); stringify(buf, m->second); } }; thread_local const member *m[iov::max_size]; const ctx::critical_assertion ca; if(unlikely(size_t(iov.size()) > iov.max_size)) throw iov::oversize { "IOV has %zd members but maximum is %zu", iov.size(), iov.max_size }; const auto start(begin(buf)); std::transform(std::begin(iov), std::end(iov), m, addressof); std::sort(m, m + iov.size(), less_member); printer(buf, printer.object_begin); printer::list_protocol(buf, m, m + iov.size(), print_member); printer(buf, printer.object_end); const string_view ret { start, begin(buf) }; assert(serialized(iov) == size(ret)); return ret; } size_t ircd::json::serialized(const iov &iov) { const size_t ret { 1U + iov.empty() }; return std::accumulate(std::begin(iov), std::end(iov), ret, [] (auto ret, const auto &member) { return ret += serialized(member) + 1; }); } ircd::json::value & ircd::json::iov::at(const string_view &key) { const auto it { std::find_if(std::begin(*this), std::end(*this), [&key] (const auto &member) { return string_view{member.first} == key; }) }; if(it == std::end(*this)) throw not_found { "key '%s' not found", key }; return it->second; } const ircd::json::value & ircd::json::iov::at(const string_view &key) const { const auto it { std::find_if(std::begin(*this), std::end(*this), [&key] (const auto &member) { return string_view{member.first} == key; }) }; if(it == std::end(*this)) throw not_found { "key '%s' not found", key }; return it->second; } bool ircd::json::iov::has(const string_view &key) const { return std::any_of(std::begin(*this), std::end(*this), [&key] (const auto &member) { return string_view{member.first} == key; }); } ircd::json::iov::push::push(iov &iov, member member) :node { iov, std::move(member) } { } ircd::json::iov::push::push(iov &iov, const bool &b, const conditional_member &cp) :node { b? &iov: nullptr, b? member{cp.first, cp.second()}: member{} } { } ircd::json::iov::add::add(iov &iov, member member) :node { iov, [&iov, &member] { if(iov.has(member.first)) throw exists { "failed to add member '%s': already exists", string_view{member.first} }; return std::move(member); }() } { } ircd::json::iov::add::add(iov &iov, const bool &b, const conditional_member &cp) :node { b? &iov: nullptr, [&iov, &b, &cp] { if(!b) return member{}; if(iov.has(cp.first)) throw exists { "failed to add member '%s': already exists", string_view{cp.first} }; return member { cp.first, cp.second() }; }() } { } ircd::json::iov::set::set(iov &iov, member member) :node { iov, [&iov, &member] { iov.remove_if([&member](const auto &existing) { return string_view{existing.first} == string_view{member.first}; }); return std::move(member); }() } { } ircd::json::iov::set::set(iov &iov, const bool &b, const conditional_member &cp) :node { b? &iov: nullptr, [&iov, &b, &cp] { if(!b) return member{}; iov.remove_if([&cp](const auto &existing) { return string_view{existing.first} == cp.first; }); return member { cp.first, cp.second() }; }() } { } ircd::json::iov::defaults::defaults(iov &iov, member member) :node { !iov.has(member.first)? &iov: nullptr, std::move(member) } { } ircd::json::iov::defaults::defaults(iov &iov, bool b, const conditional_member &cp) :node { [&iov, &b, &cp]() -> json::iov * { if(!b) return nullptr; if(!iov.has(cp.first)) return &iov; b = false; return nullptr; }(), [&iov, &b, &cp] { if(!b) return member{}; return member { cp.first, cp.second() }; }() } { } /////////////////////////////////////////////////////////////////////////////// // // json/strung.h // ircd::json::strung::operator json::array() const { return string_view{*this}; } ircd::json::strung::operator json::object() const { return string_view{*this}; } /////////////////////////////////////////////////////////////////////////////// // // json/vector.h // namespace ircd::json { [[gnu::visibility("internal")]] extern const parser::rule vector_object, vector_next_parse, vector_begin_parse; } decltype(ircd::json::vector_object) ircd::json::vector_object { raw[parser.object(0)] ,"vector object" }; decltype(ircd::json::vector_next_parse) ircd::json::vector_next_parse { expect[eoi | (vector_object >> -parser.ws)] ,"next object vector element or end" }; decltype(ircd::json::vector_begin_parse) ircd::json::vector_begin_parse { expect[-parser.ws >> (eoi | (vector_object >> -parser.ws))] ,"object vector element" }; bool ircd::json::operator!(const vector &v) { return v.empty(); } size_t ircd::json::size(const vector &v) { return v.size(); } bool ircd::json::empty(const vector &v) { return v.empty(); } // // vector::vector // size_t ircd::json::vector::size() const { return count(); } size_t ircd::json::vector::count() const { return std::distance(begin(), end()); } ircd::json::vector::operator bool() const { return !empty(); } bool ircd::json::vector::empty() const { const string_view &sv { *static_cast(this) }; return sv.empty(); } ircd::json::vector::value_type ircd::json::vector::operator[](const size_t &i) const { const auto it(find(i)); return it != end()? *it : object{}; } ircd::json::vector::value_type ircd::json::vector::at(const size_t &i) const { const auto it(find(i)); if(it == end()) throw not_found { "indice %zu", i }; return *it; } ircd::json::vector::const_iterator ircd::json::vector::find(size_t i) const { auto it(begin()); for(; it != end() && i; ++it, i--); return it; } ircd::json::vector::const_iterator ircd::json::vector::begin() const { const_iterator ret { string_view::begin(), string_view::end() }; string_view &state(ret.state); parser(ret.start, ret.stop, vector_begin_parse, state); return ret; } // // vector::const_iterator::const_iterator // ircd::json::vector::const_iterator & ircd::json::vector::const_iterator::operator++() { this->state = {}; string_view &state(this->state); parser(start, stop, vector_next_parse, state); return *this; } /////////////////////////////////////////////////////////////////////////////// // // json/object.h // decltype(ircd::json::object::max_recursion_depth) ircd::json::object::max_recursion_depth { 96 }; decltype(ircd::json::object::max_sorted_members) ircd::json::object::max_sorted_members { iov::max_size }; namespace ircd::json { [[gnu::visibility("internal")]] extern const parser::rule object_member, object_next, object_begin, object_next_parse, object_begin_parse; using object_member_array_type = std::array; using object_member_arrays_type = std::array; static_assert(sizeof(object_member_arrays_type) == 3_MiB); // yay reentrance .. joy :/ static thread_local object_member_arrays_type object_member_arrays; static thread_local size_t object_member_arrays_ctr; static string_view _stringify(mutable_buffer &buf, const object::member *const &b, const object::member *const &e); } decltype(ircd::json::object_member) ircd::json::object_member { parser.name >> -parser.ws >> parser.name_sep >> -parser.ws >> raw[parser.value(0)] ,"object member" }; decltype(ircd::json::object_next) ircd::json::object_next { (parser.value_sep >> -parser.ws >> object_member) | (parser.object_end >> -parser.ws >> eoi) ,"object member" }; decltype(ircd::json::object_begin) ircd::json::object_begin { parser.object_begin >> -parser.ws >> (parser.object_end | object_member) ,"object" }; decltype(ircd::json::object_next_parse) ircd::json::object_next_parse { expect[object_next >> -parser.ws] ,"object increment" }; decltype(ircd::json::object_begin_parse) ircd::json::object_begin_parse { expect[-parser.ws >> (eoi | (object_begin >> -parser.ws))] ,"object begin" }; std::ostream & ircd::json::operator<<(std::ostream &s, const object &object) { s << json::strung(object); return s; } ircd::string_view ircd::json::stringify(mutable_buffer &buf, const object &object) try { const size_t mc(object_member_arrays_ctr); assert(mc < object_member_arrays.size()); const scope_count _mc(object_member_arrays_ctr); auto &m(object_member_arrays.at(object_member_arrays_ctr)); size_t i(0); for(auto it(begin(object)); it != end(object); ++it, ++i) m.at(i) = *it; std::sort(begin(m), begin(m) + i, [] (const object::member &a, const object::member &b) noexcept { return a.first < b.first; }); return _stringify(buf, m.data(), m.data() + i); } catch(const std::out_of_range &e) { throw print_error { "Too many members (%zu) for stringifying JSON object", size(object) }; } size_t ircd::json::serialized(const object &object) { const auto b(begin(object)); const auto e(end(object)); assert(!empty(object) || b == e); const size_t ret(1 + (b == e)); return std::accumulate(b, e, ret, [] (auto ret, const object::member &member) { return ret += serialized(member) + 1; }); } bool ircd::json::sorted(const object &object) { auto it(begin(object)); if(it == end(object)) return true; string_view last{it->first}; for(++it; it != end(object); last = it->first, ++it) if(it->first < last) return false; return true; } size_t ircd::json::size(const object &object) { return object.size(); } bool ircd::json::operator!(const object &object) { return empty(object); } bool ircd::json::empty(const object &object) { return object.empty(); } // // object // ircd::string_view ircd::json::object::operator[](const string_view &key) const { const auto it(find(key)); return it != end()? it->second : string_view{}; } ircd::string_view ircd::json::object::get(const string_view &key, const string_view &def) const { return get(key, def); } ircd::json::object::operator std::string() const { return json::strung(*this); } bool ircd::json::object::has(const string_view &key) const { return find(key) != end(); } size_t ircd::json::object::size() const { return count(); } size_t ircd::json::object::count() const { return std::distance(begin(), end()); } bool ircd::json::object::empty() const { const string_view &sv{*this}; assert(sv.size() > 2 || (sv.empty() || sv == empty_object)); return sv.size() <= 2; } ircd::json::object::const_iterator ircd::json::object::find(const name_hash_t &key) const { return std::find_if(begin(), end(), [&key] (const auto &member) { return name_hash(member.first) == key; }); } ircd::json::object::const_iterator ircd::json::object::find(const string_view &key) const { return std::find_if(begin(), end(), [&key] (const auto &member) { return member.first == key; }); } ircd::json::object::const_iterator ircd::json::object::begin() const try { const_iterator ret { string_view::begin(), string_view::end() }; parser(ret.start, ret.stop, object_begin_parse, ret.state); return ret; } catch(const expectation_failure &e) { const auto type { json::type(*this) }; if(type != type::OBJECT) throw type_error { "Expected JSON type OBJECT, not %s.", reflect(type) }; throw; } // // object::const_iterator // ircd::json::object::const_iterator & ircd::json::object::const_iterator::operator++() { assert(start != stop); state = {}; parser(start, stop, object_next_parse, state); return *this; } // // object::member // std::ostream & ircd::json::operator<<(std::ostream &s, const object::member &member) { s << json::strung(member); return s; } ircd::string_view ircd::json::stringify(mutable_buffer &buf, const object::member &member) { char *const start(begin(buf)); assert(!surrounds(member.first, '"')); printer(buf, printer.name << printer.name_sep, member.first); stringify(buf, member.second); const string_view ret { start, begin(buf) }; assert(serialized(member) == size(ret)); return ret; } size_t ircd::json::serialized(const object::member &member) { return 1 + size(member.first) + 1 + 1 + serialized(member.second); } ircd::string_view ircd::json::stringify(mutable_buffer &buf, const object::member *const &b, const object::member *const &e) { const size_t mc(object_member_arrays_ctr); assert(mc < object_member_arrays.size()); const scope_count _mc(object_member_arrays_ctr); auto &m(object_member_arrays.at(object_member_arrays_ctr)); size_t i(0); for(auto it(b); it != e; ++it, ++i) m.at(i) = *it; std::sort(begin(m), begin(m) + i, [] (const object::member &a, const object::member &b) noexcept { return a.first < b.first; }); return _stringify(buf, begin(m), begin(m) + i); } ircd::string_view ircd::json::_stringify(mutable_buffer &buf, const object::member *const &b, const object::member *const &e) { static const auto stringify_member { [](mutable_buffer &buf, const object::member &member) { stringify(buf, member); } }; char *const start(begin(buf)); printer(buf, printer.object_begin); printer::list_protocol(buf, b, e, stringify_member); printer(buf, printer.object_end); const string_view ret { start, begin(buf) }; assert(serialized(b, e) == size(ret)); return ret; } size_t ircd::json::serialized(const object::member *const &begin, const object::member *const &end) { const size_t ret(1 + (begin == end)); return std::accumulate(begin, end, ret, [] (auto ret, const object::member &member) { return ret += serialized(member) + 1; }); } bool ircd::json::sorted(const object::member *const &begin, const object::member *const &end) { return std::is_sorted(begin, end, [] (const object::member &a, const object::member &b) { return a.first < b.first; }); } /////////////////////////////////////////////////////////////////////////////// // // json/array.h // namespace ircd::json { [[gnu::visibility("internal")]] extern const parser::rule array_value, array_next, array_begin, array_next_parse, array_begin_parse; } decltype(ircd::json::array::max_recursion_depth) ircd::json::array::max_recursion_depth { 96 }; decltype(ircd::json::array_value) ircd::json::array_value { raw[parser.value(0)] ,"array element" }; decltype(ircd::json::array_next) ircd::json::array_next { parser.array_end | (parser.value_sep >> -parser.ws >> array_value) ,"next array element" }; decltype(ircd::json::array_begin) ircd::json::array_begin { parser.array_begin >> -parser.ws >> (parser.array_end | array_value) ,"array begin element" }; decltype(ircd::json::array_next_parse) ircd::json::array_next_parse { expect[array_next >> -parser.ws] ,"array next" }; decltype(ircd::json::array_begin_parse) ircd::json::array_begin_parse { expect[-parser.ws >> (eoi | (array_begin >> -parser.ws))] ,"array begin" }; std::ostream & ircd::json::operator<<(std::ostream &s, const array &a) { s << json::strung(a); return s; } ircd::string_view ircd::json::stringify(mutable_buffer &buf, const array &v) { if(likely(!string_view{v}.empty())) return array::stringify(buf, begin(v), end(v)); const char *const start{begin(buf)}; consume(buf, copy(buf, empty_array)); const string_view ret{start, begin(buf)}; assert(serialized(v) == size(ret)); return ret; } size_t ircd::json::serialized(const array &v) { assert(!empty(v) || (begin(v) == end(v))); return array::serialized(begin(v), end(v)); } ircd::string_view ircd::json::stringify(mutable_buffer &buf, const std::string *const &b, const std::string *const &e) { return array::stringify(buf, b, e); } size_t ircd::json::serialized(const std::string *const &b, const std::string *const &e) { return array::serialized(b, e); } ircd::string_view ircd::json::stringify(mutable_buffer &buf, const string_view *const &b, const string_view *const &e) { return array::stringify(buf, b, e); } size_t ircd::json::serialized(const string_view *const &b, const string_view *const &e) { return array::serialized(b, e); } size_t ircd::json::size(const array &array) { return array.size(); } bool ircd::json::operator!(const array &array) { return empty(array); } bool ircd::json::empty(const array &array) { return array.empty(); } // // array::array // template ircd::string_view ircd::json::array::stringify(mutable_buffer &buf, const it &b, const it &e) { static const auto print_element { [](mutable_buffer &buf, const string_view &element) { json::stringify(buf, element); } }; using ircd::buffer::begin; char *const start(begin(buf)); printer(buf, printer.array_begin); printer::list_protocol(buf, b, e, print_element); printer(buf, printer.array_end); const string_view ret { start, begin(buf) }; using ircd::buffer::size; assert(serialized(b, e) == size(ret)); return ret; } template size_t ircd::json::array::serialized(const it &b, const it &e) { const size_t ret(1 + (b == e)); return std::accumulate(b, e, ret, [] (auto ret, const string_view &value) { return ret += json::serialized(value) + 1; }); } ircd::json::array::operator std::string() const { return json::strung(*this); } ircd::json::array::const_iterator ircd::json::array::begin() const { const_iterator ret { string_view::begin(), string_view::end() }; parser(ret.start, ret.stop, array_begin_parse, ret.state); return ret; } ircd::string_view ircd::json::array::operator[](const size_t &i) const { const auto it(find(i)); return it != end()? *it : string_view{}; } ircd::string_view ircd::json::array::at(const size_t &i) const { const auto it(find(i)); if(it == end()) throw not_found { "indice %zu", i }; return *it; } ircd::json::array::const_iterator ircd::json::array::find(size_t i) const { auto it(begin()); for(; it != end() && i; ++it, i--); return it; } size_t ircd::json::array::size() const { return count(); } size_t ircd::json::array::count() const { return std::distance(begin(), end()); } bool ircd::json::array::empty() const { const string_view &sv{*this}; // Allow empty objects '{}' to pass this assertion; this function is not // a type-check. Some serializers (like browser JS) might give an empty // object before it has any context that the set is an array; it doesn't // matter here for us. assert(sv.size() > 2 || sv.empty() || sv == empty_array || sv == empty_object); return sv.size() <= 2; } // // array::const_iterator // ircd::json::array::const_iterator & ircd::json::array::const_iterator::operator++() { assert(start != stop); state = string_view{}; parser(start, stop, array_next_parse, state); return *this; } /////////////////////////////////////////////////////////////////////////////// // // json/member.h // ircd::string_view ircd::json::stringify(mutable_buffer &buf, const members &list) { return stringify(buf, std::begin(list), std::end(list)); } ircd::string_view ircd::json::stringify(mutable_buffer &buf, const member &m) { return stringify(buf, &m, &m + 1); } ircd::string_view ircd::json::stringify(mutable_buffer &buf, const member *const &b, const member *const &e) { using member_array = std::array; using member_arrays = std::array; static_assert(sizeof(member_arrays) == 768_KiB); static const auto less_member { [](const member *const &a, const member *const &b) noexcept { return *a < *b; } }; static const auto print_member { [](mutable_buffer &buf, const member *const &m) { assert(type(m->first) == STRING); stringify(buf, m->first); printer(buf, printer.name_sep); stringify(buf, m->second); } }; const size_t count(std::distance(b, e)); if(unlikely(count > object::max_sorted_members)) throw print_error { "json::member vector of %zu exceeds maximum %zu.", count, object::max_sorted_members, }; thread_local member_arrays ma; thread_local size_t mctr; const size_t mc{mctr}; const scope_count _mc{mctr}; assert(mc < ma.size()); auto &m(ma.at(mc)); for(size_t i(0); i < count; ++i) m[i] = b + i; std::sort(begin(m), begin(m) + count, less_member); const char *const start(begin(buf)); printer(buf, printer.object_begin); printer::list_protocol(buf, begin(m), begin(m) + count, print_member); printer(buf, printer.object_end); const string_view ret { start, begin(buf) }; assert(serialized(b, e) == size(ret)); return ret; } size_t ircd::json::serialized(const members &m) { return serialized(std::begin(m), std::end(m)); } size_t ircd::json::serialized(const member *const &begin, const member *const &end) { const size_t ret(1 + (begin == end)); return std::accumulate(begin, end, ret, [] (auto ret, const auto &member) { return ret += serialized(member) + 1; }); } size_t ircd::json::serialized(const member &member) { return serialized(member.first) + 1 + serialized(member.second); } bool ircd::json::sorted(const member *const &begin, const member *const &end) { return std::is_sorted(begin, end, [] (const member &a, const member &b) { return a < b; }); } bool ircd::json::operator<(const member &a, const member &b) { return a.first < b.first; } bool ircd::json::operator!=(const member &a, const member &b) { return a.first != b.first; } bool ircd::json::operator==(const member &a, const member &b) { return a.first == b.first; } bool ircd::json::operator<(const member &a, const string_view &b) { return string_view{a.first.string, a.first.len} < b; } bool ircd::json::operator!=(const member &a, const string_view &b) { return string_view{a.first.string, a.first.len} != b; } bool ircd::json::operator==(const member &a, const string_view &b) { return string_view{a.first.string, a.first.len} == b; } /////////////////////////////////////////////////////////////////////////////// // // json/string.h // namespace ircd::json { extern const char ctrl_tab[0x20][16]; extern const int32_t ctrl_tab_len[0x20]; static u8x16 lookup_ctrl_tab_len(const u8x16 block); static u64x2 string_serialized_ctrl(const u8x16 block, const u8x16 mask, const u8x16 ctrl_mask); static u64x2 string_serialized_utf16(const u8x16 block, const u8x16 mask); static u64x2 string_serialized(const u8x16 block, const u8x16 mask); static u64x2 string_stringify_utf16(u8x16 &block, const u8x16 mask); static u64x2 string_stringify(u8x16 &block, const u8x16 mask); } /// Escaped control character LUT. decltype(ircd::json::ctrl_tab) ircd::json::ctrl_tab alignas(32) { "\\u0000", "\\u0001", "\\u0002", "\\u0003", "\\u0004", "\\u0005", "\\u0006", "\\u0007", "\\b", "\\t", "\\n", "\\u000B", "\\f", "\\r", "\\u000E", "\\u000F", "\\u0010", "\\u0011", "\\u0012", "\\u0013", "\\u0014", "\\u0015", "\\u0016", "\\u0017", "\\u0018", "\\u0019", "\\u001A", "\\u001B", "\\u001C", "\\u001D", "\\u001E", "\\u001F", }; /// Escaped control character LUT length hints decltype(ircd::json::ctrl_tab_len) ircd::json::ctrl_tab_len alignas(32) { 6, 6, 6, 6, 6, 6, 6, 6, 2, 2, 2, 6, 2, 2, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, }; ircd::const_buffer ircd::json::unescape(const mutable_buffer &buf, const string &in) { throw ircd::not_implemented{}; } ircd::json::string ircd::json::escape(const mutable_buffer &buf, const string_view &in) { mutable_buffer out{buf}; printer(out, printer.string, in); const string_view ret { data(buf), data(out) }; return ret; } /// Streaming transform for canonical JSON strings. This function takes /// virtually any input and "always makes it right" i.e. always outputs /// the application's so-called canonical JSON. /// /// This involves a variable-length transformation where the output might /// end up as significantly longer or shorter than the input; neither will /// have any hope for aligned access, and most of the inputs are short and /// already canonical. This is all tricky. /// size_t ircd::json::string::stringify(const mutable_buffer &buf, const string_view &input) noexcept { using block_t = u8x16; using block_t_u = u128x1_u; const u64x2 max { ircd::size(buf), ircd::size(input), }; const auto consumed { simd::stream(ircd::data(buf), ircd::data(input), max, string_stringify) }; return consumed[0]; // output pos (bytes written) } /// Returns two addends to the outer loop. The second advances the input string /// pointer any number of bytes; the block for the next invocation will start /// at the new offset. This function may want to advance the input less than /// the full block width if there's a possibility something important is being /// split between blocks (i.e. an escaped utf-16 surrogate pair of 12 chars); /// next invocation will then encounter the contiguous sequence without issue. /// The first value is added to the final return count to indicate the length /// of the input string in serialized form after correction. Partial sequences /// trailing off the block are not counted here so they can be pushed over to /// the next invocation. /// /// The input is a block of characters from the original string. When the block /// cannot be filled at the end of a string (or a short string) the block_mask /// will indicate 0 for any bytes past the end, otherwise -1 for valid chars; /// note that null characters in the string are valid which we will escape. /// ircd::u64x2 ircd::json::string_stringify(u8x16 &block, const u8x16 block_mask) { const u8x16 is_esc ( block == '\\' ); const u8x16 is_quote ( block == '"' ); const u8x16 is_ctrl ( block < 0x20 ); const u8x16 is_special { is_esc | is_quote | is_ctrl }; const u8x16 any_special { simd::lateral(is_special | ~block_mask) }; // Fastest-path; backward branch to count and consume all of the input. if(likely(!any_special[0])) return u64x2 { sizeof(u8x16), sizeof(u8x16) }; // Count the number of uninteresting characters from the front of the // block. With the special characters masked, we count leading zeroes. // The inverted block_mask generates non-zero bits to terminate any // counting past the end of the string. const u64 regular_prefix_count { simd::lzcnt(is_special | ~block_mask) / 8 }; // Fast-path; backward branch to count and consume uninteresting characters // from the front of the input. if(likely(regular_prefix_count)) return u64x2 { regular_prefix_count, regular_prefix_count, }; // Unescaped quote case if(is_quote[0]) { block[0] = '\\'; block[1] = '"'; return u64x2 { 2, 1 }; } // Control character case if(is_ctrl[0]) { const u8 idx{block[0]}; block = *reinterpret_cast(ctrl_tab + idx); return u64x2 { u64(ctrl_tab_len[idx]), 1 }; } // Escape sequence case assert(block[0] == '\\'); // Legitimately escaped sequence bank const u8x16 cases { 'b', 't', 'n', 'f', 'r', '"', '\\', 'u' }; const u8x16 subject { simd::broad_cast(block, block[1]) & simd::broad_cast(block_mask, block_mask[1]) }; const u8x16 match ( subject == cases ); const u64 match_depth { simd::lzcnt(match) / 8 }; // Legitimately escaped single char if(match_depth < 7) return u64x2 { 2, 2 }; // Unnecessary escape; unless it's the last char. if(match_depth > 7) { block[0] = '\\'; block[1] = '\\'; return u64x2 { block_mask[1]? 0UL: 2UL, 1 }; } // Possible utf-16 surrogate(s) assert(block[1] == 'u'); return string_stringify_utf16(block, block_mask); } ircd::u64x2 ircd::json::string_stringify_utf16(u8x16 &block, const u8x16 block_mask) { const u32x4 unicode { utf16::decode_surrogate_aligned_next(block & block_mask) }; const u32x4 is_surrogate ( utf16::find_surrogate(block & block_mask) ); const u32x4 surrogate_mask ( is_surrogate != 0U ); const u32x4 is_ctrl ( unicode < 0x20 ); const u32x4 length_encoded { utf8::length(unicode) }; const u32x4 ctrl_idx { unicode & is_ctrl }; const u32x4 length_surrogate { u32(ctrl_tab_len[ctrl_idx[0]]), u32(ctrl_tab_len[ctrl_idx[1]]), }; const u32x4 is_non_bmp ( unicode >= 0x10000U ); const u32x4 is_surrogate_pair { (is_non_bmp | shl<32>(is_non_bmp)) & (surrogate_mask | shr<32>(surrogate_mask)) }; // Determine the utf-8 encoding length for each codepoint... // Supplement the escaped surrogate length for excluded codepoints. const u32x4 length { (length_encoded & ~is_ctrl) | (length_surrogate & is_ctrl & ~is_surrogate_pair & surrogate_mask) }; const u32x4 encoded_sparse { utf8::encode(unicode) }; const u8x16 encoded ( encoded_sparse ); size_t di(0); for(size_t i(0); i < 2; ++i) for(size_t j(0); j < length[i]; ++j) block[di++] = is_ctrl[i]? ctrl_tab[ctrl_idx[i]][j]: encoded[i * 4 + j]; const auto surrogates { simd::popcnt(u64x2(simd::popmask(u8x16(is_surrogate)))) }; assert(di == length[0] + length[1]); return u64x2 { di, std::max(6U * surrogates, 1U) }; } /// Determine the length of the JSON string value after canonization by /// string::stringify() on the input. See the docs for string::stringify() /// as most details are the same here, except this has no output stream /// or transformation logic. size_t ircd::json::string::serialized(const string_view &input) noexcept { using block_t = u8x16; using block_t_u = u128x1_u; const u64x2 max { 0, ircd::size(input) }; const auto count { simd::stream(ircd::data(input), max, string_serialized) }; return count[0]; } ircd::u64x2 ircd::json::string_serialized(const u8x16 block, const u8x16 block_mask) { assert(block_mask[0] == 0xff); const u8x16 is_esc ( block == '\\' ); const u8x16 is_quote ( block == '"' ); const u8x16 is_ctrl ( block < 0x20 ); const u8x16 is_special { is_esc | is_quote | is_ctrl }; const u8x16 any_special { simd::lateral(is_special | ~block_mask) }; // Fastest-path; backward branch to count and consume all of the input. if(likely(!any_special[0])) return u64x2 { sizeof(u8x16), sizeof(u8x16) }; const u64 regular_prefix_count { simd::lzcnt(is_special | ~block_mask) / 8 }; // Fast-path; backward branch to count and consume uninteresting characters // from the front of the input. if(likely(regular_prefix_count)) return u64x2 { regular_prefix_count, regular_prefix_count, }; // Unescaped quote: +1 if(is_quote[0]) return u64x2 { 2, 1 }; // Covers the ctrl 0x00-0x20 range only; no other character here. if(is_ctrl[0]) return string_serialized_ctrl(block, block_mask, is_ctrl); // Escape sequence assert(block[0] == '\\'); // Legitimate escape bank const u8x16 cases { 'b', 't', 'n', 'f', 'r', '"', '\\', 'u' }; const u8x16 subject { simd::broad_cast(block, block[1]) & simd::broad_cast(block_mask, block_mask[1]) }; const u8x16 match ( subject == cases ); const u64 match_depth { simd::lzcnt(match) / 8 }; // Legitimately escaped single char if(match_depth < 7) return u64x2 { 2, 2 }; // Unnecessary escape; unless it's the last char: -1 if(match_depth > 7) return u64x2 { block_mask[1]? 0UL: 2UL, 1 }; // Possible utf-16 surrogate(s) assert(block[1] == 'u'); return string_serialized_utf16(block, block_mask); } ircd::u64x2 ircd::json::string_serialized_utf16(const u8x16 block, const u8x16 block_mask) { const u32x4 is_surrogate ( utf16::find_surrogate(block & block_mask) ); const u32x4 surrogate_mask ( is_surrogate != 0U ); const u32x4 unicode { utf16::decode_surrogate_aligned_next(block & block_mask) }; const u32x4 is_ctrl ( unicode < 0x20 ); const u32x4 length_encoded { utf8::length(unicode) }; const u32x4 ctrl_idx { unicode & is_ctrl }; const i32x4 length_surrogate { ctrl_tab_len[ctrl_idx[0]], ctrl_tab_len[ctrl_idx[1]], }; const u32x4 is_non_bmp ( unicode >= 0x10000U ); const u32x4 is_surrogate_pair { (is_non_bmp | shl<32>(is_non_bmp)) & (surrogate_mask | shr<32>(surrogate_mask)) }; // Determine the utf-8 encoding length for each codepoint... // Supplement the escaped surrogate length for excluded codepoints. const u32x4 length { (length_encoded & ~is_ctrl) | (length_surrogate & is_ctrl & ~is_surrogate_pair & surrogate_mask) }; const auto total_length { length[0] + length[1] }; const auto surrogates { simd::popcnt(u64x2(simd::popmask(u8x16(is_surrogate)))) }; return u64x2 { total_length, std::max(6U * surrogates, 1U) }; } ircd::u64x2 ircd::json::string_serialized_ctrl(const u8x16 block, const u8x16 block_mask, const u8x16 is_ctrl) { assert(block[0] < 0x20); const u8x16 ctrl_esc_len { lookup_ctrl_tab_len(block & is_ctrl) }; const u64 ctrl_prefix_count { simd::lzcnt(~is_ctrl | ~block_mask) / 8 }; u64 ret(0); for(size_t i(0); i < ctrl_prefix_count; ++i) ret += ctrl_esc_len[i]; return u64x2 { ret, ctrl_prefix_count }; } /// Performs a parallel transform of control characters in the input into /// the length of their escape surrogate. The input character must be in /// the control character range. ircd::u8x16 ircd::json::lookup_ctrl_tab_len(const u8x16 in) { static const int32_t *const tab { ctrl_tab_len }; size_t k(0); i32x4 idx[4] { { in[k++], in[k++], in[k++], in[k++] }, { in[k++], in[k++], in[k++], in[k++] }, { in[k++], in[k++], in[k++], in[k++] }, { in[k++], in[k++], in[k++], in[k++] }, }; size_t i, j; i32x8 res[2]; for(i = 0; i < 2; ++i) for(j = 0; j < 8; ++j) res[i][j] = tab[idx[i][j]]; i8x16 ret; k = 0; for(i = 0; i < 2; ++i) for(j = 0; j < 8; ++j) ret[k++] = res[i][j]; return ret; } /////////////////////////////////////////////////////////////////////////////// // // json/value.h // decltype(ircd::json::value::max_string_size) ircd::json::value::max_string_size; std::ostream & ircd::json::operator<<(std::ostream &s, const value &v) { s << json::strung(v); return s; } ircd::string_view ircd::json::stringify(mutable_buffer &buf, const value *const &b, const value *const &e) { static const auto print_value { [](mutable_buffer &buf, const value &value) { stringify(buf, value); } }; char *const start(begin(buf)); printer(buf, printer.array_begin); printer::list_protocol(buf, b, e, print_value); printer(buf, printer.array_end); const string_view ret { start, begin(buf) }; assert(serialized(b, e) == size(ret)); return ret; } ircd::string_view ircd::json::stringify(mutable_buffer &buf, const value &v) { const auto start { begin(buf) }; switch(v.type) { case STRING: { if(!v.string) { consume(buf, copy(buf, empty_string)); break; } if(unlikely(v.len > value::max_string_size)) throw print_error { "String value cannot have length:%zu which exceeds limit:%zu", v.len, value::max_string_size, }; const string_view sv { v.string, v.len }; if(v.serial) printer(buf, printer.string, json::string(sv)); else printer(buf, printer.string, sv); break; } case LITERAL: { if(v.serial) printer(buf, printer.literal, string_view{v}); else if(v.integer) consume(buf, copy(buf, "true"_sv)); else consume(buf, copy(buf, "false"_sv)); break; } case OBJECT: { if(v.serial) stringify(buf, json::object{string_view{v}}); else if(v.object) stringify(buf, v.object, v.object + v.len); else consume(buf, copy(buf, empty_object)); break; } case ARRAY: { if(v.serial) stringify(buf, json::array{string_view{v}}); else if(v.array) stringify(buf, v.array, v.array + v.len); else consume(buf, copy(buf, empty_array)); break; } case NUMBER: { if(v.serial) //printer(buf, printer.number, string_view{v}); consume(buf, copy(buf, strip(string_view{v}, ' '))); else if(v.floats) consume(buf, copy(buf, lex_cast(v.floating))); else consume(buf, copy(buf, lex_cast(v.integer))); break; } } const string_view ret { start, begin(buf) }; assert(serialized(v) == size(ret)); return ret; } size_t ircd::json::serialized(const values &v) { return serialized(std::begin(v), std::end(v)); } size_t ircd::json::serialized(const value *const &begin, const value *const &end) { // One opening '[' and either one ']' or comma count. const size_t ret(1 + (begin == end)); return std::accumulate(begin, end, size_t(ret), [] (auto ret, const value &v) { return ret += serialized(v) + 1; // 1 comma }); } size_t ircd::json::serialized(const value &v) { switch(v.type) { case OBJECT: return v.serial? serialized(json::object{v}): serialized(v.object, v.object + v.len); case ARRAY: return v.serial? serialized(json::array{v}): serialized(v.array, v.array + v.len); case LITERAL: return v.serial? v.len: v.integer? size(literal_true): size(literal_false); case NUMBER: { thread_local char test_buffer[256]; mutable_buffer buf{test_buffer}; if(v.serial) //printer(buf, printer.number, string_view{v}); return size(strip(string_view{v}, ' ')); else if(v.floats) return size(lex_cast(v.floating)); else return size(lex_cast(v.integer)); return begin(buf) - test_buffer; } case STRING: { if(!v.string) return size(empty_string); const string_view sv { v.string, v.len }; const auto ret { v.serial? json::string::serialized(json::string(sv)): json::string::serialized(sv) }; return 1 + ret + 1; } }; throw type_error { "deciding the size of a type[%u] is undefined", int(v.type) }; } size_t ircd::json::serialized(const bool &b) { static constexpr const size_t t { _constexpr_strlen("true") }; static constexpr const size_t f { _constexpr_strlen("false") }; return b? t : f; } // // value::value // ircd::json::value::value(const std::string &s, const enum type &type) :string{nullptr} ,len{0} ,type{type} ,serial{type == STRING? surrounds(s, '"') : true} ,alloc{true} ,floats{false} { const string_view sv{s}; create_string(serialized(sv), [&sv] (mutable_buffer &buffer) { json::stringify(buffer, sv); }); } ircd::json::value::value(const json::members &members) :string{nullptr} ,len{serialized(members)} ,type{OBJECT} ,serial{true} ,alloc{true} ,floats{false} { create_string(len, [&members] (mutable_buffer &buffer) { json::stringify(buffer, members); }); } ircd::json::value::value(const value &other) :integer{other.integer} ,len{other.len} ,type{other.type} ,serial{other.serial} ,alloc{other.alloc} ,floats{other.floats} { if(serial) { create_string(len, [&other] (mutable_buffer &buffer) { json::stringify(buffer, other); }); } else switch(type) { case OBJECT: { if(!object) break; const size_t count(this->len); create_string(serialized(object, object + count), [this, &count] (mutable_buffer &buffer) { json::stringify(buffer, object, object + count); }); break; } case ARRAY: { if(!array) break; const size_t count(this->len); create_string(serialized(array, array + count), [this, &count] (mutable_buffer &buffer) { json::stringify(buffer, array, array + count); }); break; } case STRING: { if(!string) break; create_string(serialized(other), [&other] (mutable_buffer &buffer) { json::stringify(buffer, other); }); break; } case LITERAL: case NUMBER: break; } } ircd::json::value & ircd::json::value::operator=(value &&other) noexcept { this->~value(); new (this) value(std::move(other)); assert(other.alloc == false); return *this; } ircd::json::value & ircd::json::value::operator=(const value &other) { this->~value(); new (this) value(other); return *this; } [[gnu::hot]] ircd::json::value::~value() noexcept { if(alloc) switch(serial? STRING : static_cast(type)) { case STRING: delete[] string; break; case OBJECT: delete[] object; break; case ARRAY: delete[] array; break; default: break; } } ircd::json::value::operator std::string() const { return json::strung(*this); } ircd::json::value::operator string_view() const { switch(type) { case STRING: return unquote(string_view{string, len}); case NUMBER: return serial? string_view{string, len}: floats? byte_view{floating}: byte_view{integer}; case ARRAY: case OBJECT: case LITERAL: if(likely(serial)) return string_view{string, len}; else break; } throw type_error { "value type[%d] is not a string", int(type) }; } ircd::json::value::operator int64_t() const { switch(type) { case NUMBER: return likely(!floats)? integer : floating; case STRING: return lex_cast(string_view{*this}); case ARRAY: case OBJECT: case LITERAL: break; } throw type_error { "value type[%d] is not an int64_t", int(type) }; } ircd::json::value::operator double() const { switch(type) { case NUMBER: return likely(floats)? floating : integer; case STRING: return lex_cast(string_view{*this}); case ARRAY: case OBJECT: case LITERAL: break; } throw type_error { "value type[%d] is not a float", int(type) }; } bool ircd::json::value::operator!() const { switch(type) { case NUMBER: return floats? !(floating > 0.0 || floating < 0.0): !bool(integer); case STRING: return string? !len || (serial && string_view{string, len} == empty_string): true; case OBJECT: return serial? !len || string_view{*this} == empty_object: object? !len: true; case ARRAY: return serial? !len || (string_view{*this} == empty_array): array? !len: true; case LITERAL: if(serial) return string == nullptr || string_view{*this} == literal_false || string_view{*this} == literal_null; else return !bool(integer); }; throw type_error { "deciding if a type[%u] is falsy is undefined", int(type) }; } bool ircd::json::value::empty() const { switch(type) { case NUMBER: return serial? !len: floats? !(floating > 0.0 || floating < 0.0): !bool(integer); case STRING: return !string || !len || (serial && string_view{string, len} == empty_string); case OBJECT: return serial? !len || string_view{*this} == empty_object: object? !len: true; case ARRAY: return serial? !len || string_view{*this} == empty_array: array? !len: true; case LITERAL: return serial? !len: false; }; throw type_error { "deciding if a type[%u] is empty is undefined", int(type) }; } bool ircd::json::value::null() const { switch(type) { case NUMBER: return floats? !(floating > 0.0 || floating < 0.0): !bool(integer); case STRING: return string == nullptr || string_view{string, len}.null(); case OBJECT: return serial? string == nullptr: object? false: true; case ARRAY: return serial? string == nullptr: array? false: true; case LITERAL: return serial? string == nullptr: string? literal_null == string: false; }; throw type_error { "deciding if a type[%u] is null is undefined", int(type) }; } bool ircd::json::value::undefined() const { switch(type) { case NUMBER: return integer == undefined_number; case STRING: return string_view{string, len}.undefined(); case OBJECT: return serial? string == nullptr: object? false: true; case ARRAY: return serial? string == nullptr: array? false: true; case LITERAL: return serial? string == nullptr: false; }; throw type_error { "deciding if a type[%u] is undefined is undefined", int(type) }; } void ircd::json::value::create_string(const size_t &len, const create_string_closure &closure) { const size_t max { len + 1 }; if(unlikely(max > max_string_size)) throw print_panic { "Value cannot have string length:%zu which exceeds limit:%zu", max, max_string_size, }; std::unique_ptr string { new char[max] }; mutable_buffer buffer { string.get(), len }; closure(buffer); (string.get())[len] = '\0'; this->alloc = true; this->serial = true; this->len = len; this->string = string.release(); } bool ircd::json::operator<(const value &a, const value &b) { if(type(a) == type(b)) switch(type(b)) { case NUMBER: assert(!a.serial && !b.serial); assert(a.floats == b.floats); return b.floats? a.floating < b.floating: a.integer < b.integer; case STRING: return static_cast(a) < static_cast(b); default: break; } throw type_error { "Cannot compare type[%u] %s to type[%u] %s", uint(type(a)), reflect(type(a)), uint(type(b)), reflect(type(b)), }; } bool ircd::json::operator==(const value &a, const value &b) { if(a.serial && b.serial) return string_view(a) == string_view(b); if(type(a) == type(b)) switch(type(b)) { case NUMBER: assert(!a.serial && !b.serial); assert(!a.floats && !b.floats); if(unlikely(a.floats || b.floats)) break; return a.integer == b.integer; case STRING: return static_cast(a) == static_cast(b); default: break; } throw type_error { "Cannot compare type[%u] %s to type[%u] %s", uint(type(a)), reflect(type(a)), uint(type(b)), reflect(type(b)), }; } /////////////////////////////////////////////////////////////////////////////// // // json/util.h // namespace ircd::json { [[gnu::visibility("internal")]] extern const parser::rule<> validation, validation_expect; } decltype(ircd::json::validation) ircd::json::validation { parser.value(0) >> eoi }; decltype(ircd::json::validation_expect) ircd::json::validation_expect { expect[validation] }; const ircd::string_view ircd::json::literal_null { "null" }, ircd::json::literal_true { "true" }, ircd::json::literal_false { "false" }, ircd::json::empty_string { "\"\"" }, ircd::json::empty_object { "{}" }, ircd::json::empty_array { "[]" }; decltype(ircd::json::undefined_number) ircd::json::undefined_number { std::numeric_limits::min() }; static_assert ( ircd::json::undefined_number != 0 ); std::string ircd::json::why(const string_view &s) try { valid(s); return {}; } catch(const std::exception &e) { return e.what(); } bool ircd::json::valid(const string_view &s, std::nothrow_t) noexcept try { const char *start(begin(s)), *const stop(end(s)); return parser(start, stop, validation); } catch(...) { assert(false); return false; } void ircd::json::valid(const string_view &s) { const char *start(begin(s)), *const stop(end(s)); const bool ret { parser(start, stop, validation_expect) }; assert(ret); } void ircd::json::valid_output(const string_view &sv, const size_t &expected) { if(unlikely(size(sv) != expected)) throw print_panic { "stringified:%zu != serialized:%zu :%s", size(sv), expected, sv }; if(unlikely(!valid(sv, std::nothrow))) //note: false alarm when T=json::member throw print_panic { "strung %zu bytes :%s :%s", size(sv), why(sv), sv }; } ircd::string_view ircd::json::stringify(mutable_buffer &buf, const string_view &v) { const json::value value(v); if(v.empty() && defined(value)) { const char *const start{begin(buf)}; consume(buf, copy(buf, empty_string)); const string_view ret{start, begin(buf)}; assert(serialized(v) == size(ret)); return ret; } return stringify(buf, value); } size_t ircd::json::serialized(const string_view &v) { if(v.empty() && defined(v)) return size(empty_string); // Query the json::type of the input string here in relaxed mode. The // json::value ctor uses strict_t by default which is a full validation; // we don't care about that for the serialized() suite. const json::value value { v, json::type(v, std::nothrow) }; return serialized(value); } /////////////////////////////////////////////////////////////////////////////// // // json/type.h // namespace ircd::json { [[gnu::visibility("internal")]] extern const parser::rule<> type_parse_is[5], type_parse_is_strict[5]; [[gnu::visibility("internal")]] extern const parser::rule type_parse, type_parse_strict; } //TODO: XXX array designated initializers decltype(ircd::json::type_parse_is) ircd::json::type_parse_is { { -parser.ws >> parser.quote }, { -parser.ws >> parser.object_begin }, { -parser.ws >> parser.array_begin }, { -parser.ws >> parser.number >> -parser.ws >> eoi }, { -parser.ws >> parser.literal >> -parser.ws >> eoi }, }; //TODO: XXX array designated initializers decltype(ircd::json::type_parse_is_strict) ircd::json::type_parse_is_strict { { -parser.ws >> &parser.quote >> parser.string >> -parser.ws >> eoi }, { -parser.ws >> &parser.object_begin >> parser.object(0) >> -parser.ws >> eoi }, { -parser.ws >> &parser.array_begin >> parser.array(0) >> -parser.ws >> eoi }, { -parser.ws >> parser.number >> -parser.ws >> eoi }, { -parser.ws >> parser.literal >> -parser.ws >> eoi }, }; decltype(ircd::json::type_parse) ircd::json::type_parse { (omit[type_parse_is[json::STRING]] >> attr(json::STRING)) | (omit[type_parse_is[json::OBJECT]] >> attr(json::OBJECT)) | (omit[type_parse_is[json::ARRAY]] >> attr(json::ARRAY)) | (omit[type_parse_is[json::NUMBER]] >> attr(json::NUMBER)) | (omit[type_parse_is[json::LITERAL]] >> attr(json::LITERAL)) ,"type check" }; decltype(ircd::json::type_parse_strict) ircd::json::type_parse_strict { (omit[type_parse_is_strict[json::STRING]] >> attr(json::STRING)) | (omit[type_parse_is_strict[json::OBJECT]] >> attr(json::OBJECT)) | (omit[type_parse_is_strict[json::ARRAY]] >> attr(json::ARRAY)) | (omit[type_parse_is_strict[json::NUMBER]] >> attr(json::NUMBER)) | (omit[type_parse_is_strict[json::LITERAL]] >> attr(json::LITERAL)) ,"type check strict" }; bool ircd::json::type(const string_view &buf, const enum type &type) { const bool ret { parser(begin(buf), end(buf), type_parse_is[type]) }; return ret; } bool ircd::json::type(const string_view &buf, const enum type &type, strict_t) { const bool ret { parser(begin(buf), end(buf), type_parse_is_strict[type]) }; return ret; } enum ircd::json::type ircd::json::type(const string_view &buf) { enum type ret; if(!parser(begin(buf), end(buf), type_parse, ret)) throw type_error { "Failed to derive JSON value type from input buffer." }; return ret; } enum ircd::json::type ircd::json::type(const string_view &buf, std::nothrow_t) { enum type ret; if(!parser(begin(buf), end(buf), type_parse, ret)) return STRING; return ret; } enum ircd::json::type ircd::json::type(const string_view &buf, strict_t) { enum type ret; if(!parser(begin(buf), end(buf), type_parse_strict, ret)) throw type_error { "Failed to derive JSON value type from input buffer." }; return ret; } enum ircd::json::type ircd::json::type(const string_view &buf, strict_t, std::nothrow_t) { enum type ret; if(!parser(begin(buf), end(buf), type_parse_strict, ret)) return STRING; return ret; } ircd::string_view ircd::json::reflect(const enum type &type) { switch(type) { case NUMBER: return "NUMBER"; case OBJECT: return "OBJECT"; case ARRAY: return "ARRAY"; case LITERAL: return "LITERAL"; case STRING: return "STRING"; } throw type_error { "Unknown type %x", uint(type) }; }