#include <folly/json.h>
#include <algorithm>
-#include <cassert>
#include <functional>
+#include <type_traits>
-#include <boost/next_prior.hpp>
#include <boost/algorithm/string.hpp>
+#include <boost/next_prior.hpp>
+#include <folly/Portability.h>
+#include <folly/lang/Bits.h>
#include <folly/Conv.h>
#include <folly/Range.h>
}
}
-private:
+ private:
void printKV(const std::pair<const dynamic, dynamic>& p) const {
if (!opts_.allow_non_string_keys && !p.first.isString()) {
throw std::runtime_error("folly::toJson: JSON object key was not a "
out_ += ']';
}
-private:
+ private:
void outdent() const {
if (indentLevel_) {
--*indentLevel_;
out_ += indentLevel_ ? " : " : ":";
}
-private:
- std::string& out_;
- unsigned* const indentLevel_;
- serialization_opts const& opts_;
+ private:
+ std::string& out_;
+ unsigned* const indentLevel_;
+ serialization_opts const& opts_;
};
//////////////////////////////////////////////////////////////////////
// Parse ahead for as long as the supplied predicate is satisfied,
// returning a range of what was skipped.
- template<class Predicate>
+ template <class Predicate>
StringPiece skipWhile(const Predicate& p) {
std::size_t skipped = 0;
for (; skipped < range_.size(); ++skipped) {
storeCurrent();
}
- template<class T>
+ template <class T>
T extract() {
try {
return to<T>(&range_);
current_ = range_.empty() ? EOF : range_.front();
}
-private:
+ private:
StringPiece range_;
json::serialization_opts const& opts_;
unsigned lineNum_;
dynamic parseNumber(Input& in);
dynamic parseObject(Input& in) {
- assert(*in == '{');
+ DCHECK_EQ(*in, '{');
++in;
dynamic ret = dynamic::object;
}
dynamic parseArray(Input& in) {
- assert(*in == '[');
+ DCHECK_EQ(*in, '[');
++in;
dynamic ret = dynamic::array;
}
std::string parseString(Input& in) {
- assert(*in == '\"');
+ DCHECK_EQ(*in, '\"');
++in;
std::string ret;
in.error("expected json value");
}
-}
+} // namespace
//////////////////////////////////////////////////////////////////////
return ret;
}
+// Fast path to determine the longest prefix that can be left
+// unescaped in a string of sizeof(T) bytes packed in an integer of
+// type T.
+template <class T>
+size_t firstEscapableInWord(T s) {
+ static_assert(std::is_unsigned<T>::value, "Unsigned integer required");
+ static constexpr T kOnes = ~T() / 255; // 0x...0101
+ static constexpr T kMsbs = kOnes * 0x80; // 0x...8080
+
+ // Sets the MSB of bytes < b. Precondition: b < 128.
+ auto isLess = [](T w, uint8_t b) {
+ // A byte is < b iff subtracting b underflows, so we check that
+ // the MSB wasn't set before and it's set after the subtraction.
+ return (w - kOnes * b) & ~w & kMsbs;
+ };
+
+ auto isChar = [&](uint8_t c) {
+ // A byte is == c iff it is 0 if xored with c.
+ return isLess(s ^ (kOnes * c), 1);
+ };
+
+ // The following masks have the MSB set for each byte of the word
+ // that satisfies the corresponding condition.
+ auto isHigh = s & kMsbs; // >= 128
+ auto isLow = isLess(s, 0x20); // <= 0x1f
+ auto needsEscape = isHigh | isLow | isChar('\\') | isChar('"');
+
+ if (!needsEscape) {
+ return sizeof(T);
+ }
+
+ if (folly::kIsLittleEndian) {
+ return folly::findFirstSet(needsEscape) / 8 - 1;
+ } else {
+ return sizeof(T) - folly::findLastSet(needsEscape) / 8;
+ }
+}
+
// Escape a string so that it is legal to print it in JSON text.
void escapeString(
StringPiece input,
auto* e = reinterpret_cast<const unsigned char*>(input.end());
while (p < e) {
+ // Find the longest prefix that does not need escaping, and copy
+ // it literally into the output string.
+ auto firstEsc = p;
+ while (firstEsc < e) {
+ auto avail = e - firstEsc;
+ uint64_t word = 0;
+ if (avail >= 8) {
+ word = folly::loadUnaligned<uint64_t>(firstEsc);
+ } else {
+ memcpy(static_cast<void*>(&word), firstEsc, avail);
+ }
+ auto prefix = firstEscapableInWord(word);
+ DCHECK_LE(prefix, avail);
+ firstEsc += prefix;
+ if (prefix < 8) {
+ break;
+ }
+ }
+ if (firstEsc > p) {
+ out.append(reinterpret_cast<const char*>(p), firstEsc - p);
+ p = firstEsc;
+ // We can't be in the middle of a multibyte sequence, so we can reset q.
+ q = p;
+ if (p == e) {
+ break;
+ }
+ }
+
+ // Handle the next byte that may need escaping.
+
// Since non-ascii encoding inherently does utf8 validation
// we explicitly validate utf8 only if non-ascii encoding is disabled.
if ((opts.validate_utf8 || opts.skip_invalid_utf8)
&& !opts.encode_non_ascii) {
- // to achieve better spatial and temporal coherence
+ // To achieve better spatial and temporal coherence
// we do utf8 validation progressively along with the
- // string-escaping instead of two separate passes
+ // string-escaping instead of two separate passes.
- // as the encoding progresses, q will stay at or ahead of p
- CHECK(q >= p);
+ // As the encoding progresses, q will stay at or ahead of p.
+ CHECK_GE(q, p);
- // as p catches up with q, move q forward
+ // As p catches up with q, move q forward.
if (q == p) {
// calling utf8_decode has the side effect of
// checking that utf8 encodings are valid
// note that this if condition captures utf8 chars
// with value > 127, so size > 1 byte
char32_t v = utf8ToCodePoint(p, e, opts.skip_invalid_utf8);
- out.append("\\u");
- out.push_back(hexDigit(uint8_t(v >> 12)));
- out.push_back(hexDigit((v >> 8) & 0x0f));
- out.push_back(hexDigit((v >> 4) & 0x0f));
- out.push_back(hexDigit(v & 0x0f));
+ char buf[] = "\\u\0\0\0\0";
+ buf[2] = hexDigit(uint8_t(v >> 12));
+ buf[3] = hexDigit((v >> 8) & 0x0f);
+ buf[4] = hexDigit((v >> 4) & 0x0f);
+ buf[5] = hexDigit(v & 0x0f);
+ out.append(buf, 6);
} else if (*p == '\\' || *p == '\"') {
- out.push_back('\\');
- out.push_back(char(*p++));
+ char buf[] = "\\\0";
+ buf[1] = char(*p++);
+ out.append(buf, 2);
} else if (*p <= 0x1f) {
switch (*p) {
case '\b': out.append("\\b"); p++; break;
case '\r': out.append("\\r"); p++; break;
case '\t': out.append("\\t"); p++; break;
default:
- // note that this if condition captures non readable chars
+ // Note that this if condition captures non readable chars
// with value < 32, so size = 1 byte (e.g control chars).
- out.append("\\u00");
- out.push_back(hexDigit(uint8_t((*p & 0xf0) >> 4)));
- out.push_back(hexDigit(uint8_t(*p & 0xf)));
+ char buf[] = "\\u00\0\0";
+ buf[4] = hexDigit(uint8_t((*p & 0xf0) >> 4));
+ buf[5] = hexDigit(uint8_t(*p & 0xf));
+ out.append(buf, 6);
p++;
}
} else {
return result;
}
-}
+} // namespace json
//////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////
-}
+} // namespace folly