verdnatura-chat/ios/Pods/Flipper-Folly/folly/dynamic.cpp

474 lines
14 KiB
C++

/*
* Copyright (c) Facebook, Inc. and its affiliates.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <folly/dynamic.h>
#include <numeric>
#include <glog/logging.h>
#include <folly/Format.h>
#include <folly/container/Enumerate.h>
#include <folly/hash/Hash.h>
#include <folly/lang/Assume.h>
#include <folly/lang/Exception.h>
namespace folly {
//////////////////////////////////////////////////////////////////////
#define FOLLY_DYNAMIC_DEF_TYPEINFO(T, str) \
const char* const dynamic::TypeInfo<T>::name = str; \
//
FOLLY_DYNAMIC_DEF_TYPEINFO(std::nullptr_t, "null")
FOLLY_DYNAMIC_DEF_TYPEINFO(bool, "boolean")
FOLLY_DYNAMIC_DEF_TYPEINFO(std::string, "string")
FOLLY_DYNAMIC_DEF_TYPEINFO(dynamic::Array, "array")
FOLLY_DYNAMIC_DEF_TYPEINFO(double, "double")
FOLLY_DYNAMIC_DEF_TYPEINFO(int64_t, "int64")
FOLLY_DYNAMIC_DEF_TYPEINFO(dynamic::ObjectImpl, "object")
#undef FOLLY_DYNAMIC_DEF_TYPEINFO
const char* dynamic::typeName() const {
return typeName(type_);
}
TypeError::TypeError(const std::string& expected, dynamic::Type actual)
: std::runtime_error(sformat(
"TypeError: expected dynamic type `{}', but had type `{}'",
expected,
dynamic::typeName(actual))) {}
TypeError::TypeError(
const std::string& expected,
dynamic::Type actual1,
dynamic::Type actual2)
: std::runtime_error(sformat(
"TypeError: expected dynamic types `{}, but had types `{}' and `{}'",
expected,
dynamic::typeName(actual1),
dynamic::typeName(actual2))) {}
// This is a higher-order preprocessor macro to aid going from runtime
// types to the compile time type system.
#define FB_DYNAMIC_APPLY(type, apply) \
do { \
switch ((type)) { \
case NULLT: \
apply(std::nullptr_t); \
break; \
case ARRAY: \
apply(Array); \
break; \
case BOOL: \
apply(bool); \
break; \
case DOUBLE: \
apply(double); \
break; \
case INT64: \
apply(int64_t); \
break; \
case OBJECT: \
apply(ObjectImpl); \
break; \
case STRING: \
apply(std::string); \
break; \
default: \
CHECK(0); \
abort(); \
} \
} while (0)
bool dynamic::operator<(dynamic const& o) const {
if (UNLIKELY(type_ == OBJECT || o.type_ == OBJECT)) {
throw_exception<TypeError>("object", type_);
}
if (type_ != o.type_) {
return type_ < o.type_;
}
#define FB_X(T) return CompareOp<T>::comp(*getAddress<T>(), *o.getAddress<T>())
FB_DYNAMIC_APPLY(type_, FB_X);
#undef FB_X
}
bool dynamic::operator==(dynamic const& o) const {
if (type() != o.type()) {
if (isNumber() && o.isNumber()) {
auto& integ = isInt() ? *this : o;
auto& doubl = isInt() ? o : *this;
return integ.asInt() == doubl.asDouble();
}
return false;
}
#define FB_X(T) return *getAddress<T>() == *o.getAddress<T>();
FB_DYNAMIC_APPLY(type_, FB_X);
#undef FB_X
}
dynamic& dynamic::operator=(dynamic const& o) {
if (&o != this) {
if (type_ == o.type_) {
#define FB_X(T) *getAddress<T>() = *o.getAddress<T>()
FB_DYNAMIC_APPLY(type_, FB_X);
#undef FB_X
} else {
destroy();
#define FB_X(T) new (getAddress<T>()) T(*o.getAddress<T>())
FB_DYNAMIC_APPLY(o.type_, FB_X);
#undef FB_X
type_ = o.type_;
}
}
return *this;
}
dynamic& dynamic::operator=(dynamic&& o) noexcept {
if (&o != this) {
if (type_ == o.type_) {
#define FB_X(T) *getAddress<T>() = std::move(*o.getAddress<T>())
FB_DYNAMIC_APPLY(type_, FB_X);
#undef FB_X
} else {
destroy();
#define FB_X(T) new (getAddress<T>()) T(std::move(*o.getAddress<T>()))
FB_DYNAMIC_APPLY(o.type_, FB_X);
#undef FB_X
type_ = o.type_;
}
}
return *this;
}
dynamic const& dynamic::atImpl(dynamic const& idx) const& {
if (auto* parray = get_nothrow<Array>()) {
if (!idx.isInt()) {
throw_exception<TypeError>("int64", idx.type());
}
if (idx < 0 || idx >= parray->size()) {
throw_exception<std::out_of_range>("out of range in dynamic array");
}
return (*parray)[size_t(idx.asInt())];
} else if (auto* pobject = get_nothrow<ObjectImpl>()) {
auto it = pobject->find(idx);
if (it == pobject->end()) {
throw_exception<std::out_of_range>(
sformat("couldn't find key {} in dynamic object", idx.asString()));
}
return it->second;
} else {
throw_exception<TypeError>("object/array", type());
}
}
dynamic const& dynamic::at(StringPiece idx) const& {
auto* pobject = get_nothrow<ObjectImpl>();
if (!pobject) {
throw_exception<TypeError>("object", type());
}
auto it = pobject->find(idx);
if (it == pobject->end()) {
throw_exception<std::out_of_range>(
sformat("couldn't find key {} in dynamic object", idx));
}
return it->second;
}
dynamic& dynamic::operator[](StringPiece k) & {
auto& obj = get<ObjectImpl>();
auto ret = obj.emplace(k, nullptr);
return ret.first->second;
}
dynamic dynamic::getDefault(StringPiece k, const dynamic& v) const& {
auto& obj = get<ObjectImpl>();
auto it = obj.find(k);
return it == obj.end() ? v : it->second;
}
dynamic dynamic::getDefault(StringPiece k, dynamic&& v) const& {
auto& obj = get<ObjectImpl>();
auto it = obj.find(k);
// Avoid clang bug with ternary
if (it == obj.end()) {
return std::move(v);
} else {
return it->second;
}
}
dynamic dynamic::getDefault(StringPiece k, const dynamic& v) && {
auto& obj = get<ObjectImpl>();
auto it = obj.find(k);
// Avoid clang bug with ternary
if (it == obj.end()) {
return v;
} else {
return std::move(it->second);
}
}
dynamic dynamic::getDefault(StringPiece k, dynamic&& v) && {
auto& obj = get<ObjectImpl>();
auto it = obj.find(k);
return std::move(it == obj.end() ? v : it->second);
}
const dynamic* dynamic::get_ptrImpl(dynamic const& idx) const& {
if (auto* parray = get_nothrow<Array>()) {
if (!idx.isInt()) {
throw_exception<TypeError>("int64", idx.type());
}
if (idx < 0 || idx >= parray->size()) {
return nullptr;
}
return &(*parray)[size_t(idx.asInt())];
} else if (auto* pobject = get_nothrow<ObjectImpl>()) {
auto it = pobject->find(idx);
if (it == pobject->end()) {
return nullptr;
}
return &it->second;
} else {
throw_exception<TypeError>("object/array", type());
}
}
const dynamic* dynamic::get_ptr(StringPiece idx) const& {
auto* pobject = get_nothrow<ObjectImpl>();
if (!pobject) {
throw_exception<TypeError>("object", type());
}
auto it = pobject->find(idx);
if (it == pobject->end()) {
return nullptr;
}
return &it->second;
}
std::size_t dynamic::size() const {
if (auto* ar = get_nothrow<Array>()) {
return ar->size();
}
if (auto* obj = get_nothrow<ObjectImpl>()) {
return obj->size();
}
if (auto* str = get_nothrow<std::string>()) {
return str->size();
}
throw_exception<TypeError>("array/object/string", type());
}
dynamic::iterator dynamic::erase(const_iterator first, const_iterator last) {
auto& arr = get<Array>();
return get<Array>().erase(
arr.begin() + (first - arr.begin()), arr.begin() + (last - arr.begin()));
}
std::size_t dynamic::hash() const {
switch (type()) {
case NULLT:
return 0xBAAAAAAD;
case OBJECT: {
// Accumulate using addition instead of using hash_range (as in the ARRAY
// case), as we need a commutative hash operation since unordered_map's
// iteration order is unspecified.
auto h = std::hash<std::pair<dynamic const, dynamic>>{};
return std::accumulate(
items().begin(),
items().end(),
size_t{0x0B1EC7},
[&](auto acc, auto const& item) { return acc + h(item); });
}
case ARRAY:
return folly::hash::hash_range(begin(), end());
case INT64:
return std::hash<int64_t>()(getInt());
case DOUBLE:
return std::hash<double>()(getDouble());
case BOOL:
return std::hash<bool>()(getBool());
case STRING:
// keep consistent with detail::DynamicHasher
return Hash()(getString());
}
assume_unreachable();
}
char const* dynamic::typeName(Type t) {
#define FB_X(T) return TypeInfo<T>::name
FB_DYNAMIC_APPLY(t, FB_X);
#undef FB_X
}
void dynamic::destroy() noexcept {
// This short-circuit speeds up some microbenchmarks.
if (type_ == NULLT) {
return;
}
#define FB_X(T) detail::Destroy::destroy(getAddress<T>())
FB_DYNAMIC_APPLY(type_, FB_X);
#undef FB_X
type_ = NULLT;
u_.nul = nullptr;
}
dynamic dynamic::merge_diff(const dynamic& source, const dynamic& target) {
if (!source.isObject() || source.type() != target.type()) {
return target;
}
dynamic diff = object;
// added/modified keys
for (const auto& pair : target.items()) {
auto it = source.find(pair.first);
if (it == source.items().end()) {
diff[pair.first] = pair.second;
} else {
diff[pair.first] = merge_diff(source[pair.first], target[pair.first]);
}
}
// removed keys
for (const auto& pair : source.items()) {
auto it = target.find(pair.first);
if (it == target.items().end()) {
diff[pair.first] = nullptr;
}
}
return diff;
}
// clang-format off
dynamic::resolved_json_pointer<dynamic const>
// clang-format on
dynamic::try_get_ptr(json_pointer const& jsonPtr) const& {
using err_code = json_pointer_resolution_error_code;
using error = json_pointer_resolution_error<dynamic const>;
auto const& tokens = jsonPtr.tokens();
if (tokens.empty()) {
return json_pointer_resolved_value<dynamic const>{
nullptr, this, {nullptr, nullptr}, 0};
}
dynamic const* curr = this;
dynamic const* prev = nullptr;
size_t curr_idx{0};
StringPiece curr_key{};
for (auto it : enumerate(tokens)) {
// hit bottom but pointer not exhausted yet
if (!curr) {
return makeUnexpected(
error{err_code::json_pointer_out_of_bounds, it.index, prev});
}
prev = curr;
// handle lookup in array
if (auto const* parray = curr->get_nothrow<dynamic::Array>()) {
if (it->size() > 1 && it->at(0) == '0') {
return makeUnexpected(
error{err_code::index_has_leading_zero, it.index, prev});
}
// if last element of pointer is '-', this is an append operation
if (it->size() == 1 && it->at(0) == '-') {
// was '-' the last token in pointer?
if (it.index == tokens.size() - 1) {
return makeUnexpected(
error{err_code::append_requested, it.index, prev});
}
// Cannot resolve past '-' in an array
curr = nullptr;
continue;
}
auto const idx = tryTo<size_t>(*it);
if (!idx.hasValue()) {
return makeUnexpected(
error{err_code::index_not_numeric, it.index, prev});
}
if (idx.value() < parray->size()) {
curr = &(*parray)[idx.value()];
curr_idx = idx.value();
} else {
return makeUnexpected(
error{err_code::index_out_of_bounds, it.index, prev});
}
continue;
}
// handle lookup in object
if (auto const* pobject = curr->get_nothrow<dynamic::ObjectImpl>()) {
auto const sub_it = pobject->find(*it);
if (sub_it == pobject->end()) {
return makeUnexpected(error{err_code::key_not_found, it.index, prev});
}
curr = &sub_it->second;
curr_key = *it;
continue;
}
return makeUnexpected(
error{err_code::element_not_object_or_array, it.index, prev});
}
return json_pointer_resolved_value<dynamic const>{
prev, curr, curr_key, curr_idx};
}
const dynamic* dynamic::get_ptr(json_pointer const& jsonPtr) const& {
using err_code = json_pointer_resolution_error_code;
auto ret = try_get_ptr(jsonPtr);
if (ret.hasValue()) {
return ret.value().value;
}
auto const ctx = ret.error().context;
auto const objType = ctx ? ctx->type() : Type::NULLT;
switch (ret.error().error_code) {
case err_code::key_not_found:
return nullptr;
case err_code::index_out_of_bounds:
return nullptr;
case err_code::append_requested:
return nullptr;
case err_code::index_not_numeric:
throw std::invalid_argument("array index is not numeric");
case err_code::index_has_leading_zero:
throw std::invalid_argument(
"leading zero not allowed when indexing arrays");
case err_code::element_not_object_or_array:
throw_exception<TypeError>("object/array", objType);
case err_code::json_pointer_out_of_bounds:
return nullptr;
case err_code::other:
default:
return nullptr;
}
assume_unreachable();
}
//////////////////////////////////////////////////////////////////////
} // namespace folly