Rocket.Chat.ReactNative/ios/Pods/Folly/folly/dynamic-inl.h

1237 lines
34 KiB
C++

/*
* Copyright 2011-present Facebook, Inc.
*
* 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.
*/
#pragma once
#include <functional>
#include <folly/CPortability.h>
#include <folly/Conv.h>
#include <folly/Format.h>
#include <folly/Likely.h>
#include <folly/detail/Iterators.h>
#include <folly/lang/Exception.h>
namespace folly {
namespace detail {
struct DynamicHasher {
using is_transparent = void;
size_t operator()(dynamic const& d) const {
return d.hash();
}
template <typename T>
std::enable_if_t<std::is_convertible<T, StringPiece>::value, size_t>
operator()(T const& val) const {
// keep consistent with dynamic::hash() for strings
return Hash()(static_cast<StringPiece>(val));
}
};
struct DynamicKeyEqual {
using is_transparent = void;
bool operator()(const dynamic& lhs, const dynamic& rhs) const {
return std::equal_to<dynamic>()(lhs, rhs);
}
// Dynamic objects contains a map<dynamic, dynamic>. At least one of the
// operands should be a dynamic. Hence, an operator() where both operands are
// convertible to StringPiece is unnecessary.
template <typename A, typename B>
std::enable_if_t<
std::is_convertible<A, StringPiece>::value &&
std::is_convertible<B, StringPiece>::value,
bool>
operator()(A const& lhs, B const& rhs) const = delete;
template <typename A>
std::enable_if_t<std::is_convertible<A, StringPiece>::value, bool> operator()(
A const& lhs,
dynamic const& rhs) const {
return FOLLY_LIKELY(rhs.type() == dynamic::Type::STRING) &&
std::equal_to<StringPiece>()(lhs, rhs.stringPiece());
}
template <typename B>
std::enable_if_t<std::is_convertible<B, StringPiece>::value, bool> operator()(
dynamic const& lhs,
B const& rhs) const {
return FOLLY_LIKELY(lhs.type() == dynamic::Type::STRING) &&
std::equal_to<StringPiece>()(lhs.stringPiece(), rhs);
}
};
} // namespace detail
} // namespace folly
//////////////////////////////////////////////////////////////////////
namespace std {
template <>
struct hash<::folly::dynamic> {
size_t operator()(::folly::dynamic const& d) const {
return d.hash();
}
};
} // namespace std
//////////////////////////////////////////////////////////////////////
// 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)
//////////////////////////////////////////////////////////////////////
namespace folly {
struct FOLLY_EXPORT TypeError : std::runtime_error {
explicit TypeError(const std::string& expected, dynamic::Type actual);
explicit TypeError(
const std::string& expected,
dynamic::Type actual1,
dynamic::Type actual2);
// TODO: noexcept calculation required through gcc-v4.9; remove once upgrading
// to gcc-v5.
TypeError(const TypeError&) noexcept(
std::is_nothrow_copy_constructible<std::runtime_error>::value);
TypeError& operator=(const TypeError&) noexcept(
std::is_nothrow_copy_assignable<std::runtime_error>::value);
TypeError(TypeError&&) noexcept(
std::is_nothrow_move_constructible<std::runtime_error>::value);
TypeError& operator=(TypeError&&) noexcept(
std::is_nothrow_move_assignable<std::runtime_error>::value);
~TypeError() override;
};
//////////////////////////////////////////////////////////////////////
namespace detail {
// This helper is used in destroy() to be able to run destructors on
// types like "int64_t" without a compiler error.
struct Destroy {
template <class T>
static void destroy(T* t) {
t->~T();
}
};
/*
* Helper for implementing numeric conversions in operators on
* numbers. Just promotes to double when one of the arguments is
* double, or throws if either is not a numeric type.
*/
template <template <class> class Op>
dynamic numericOp(dynamic const& a, dynamic const& b) {
if (!a.isNumber() || !b.isNumber()) {
throw_exception<TypeError>("numeric", a.type(), b.type());
}
if (a.type() != b.type()) {
auto& integ = a.isInt() ? a : b;
auto& nonint = a.isInt() ? b : a;
return Op<double>()(to<double>(integ.asInt()), nonint.asDouble());
}
if (a.isDouble()) {
return Op<double>()(a.asDouble(), b.asDouble());
}
return Op<int64_t>()(a.asInt(), b.asInt());
}
} // namespace detail
//////////////////////////////////////////////////////////////////////
/*
* We're doing this instead of a simple member typedef to avoid the
* undefined behavior of parameterizing F14NodeMap<> with an
* incomplete type.
*
* Note: Later we may add separate order tracking here (a multi-index
* type of thing.)
*/
struct dynamic::ObjectImpl : F14NodeMap<
dynamic,
dynamic,
detail::DynamicHasher,
detail::DynamicKeyEqual> {};
//////////////////////////////////////////////////////////////////////
// Helper object for creating objects conveniently. See object and
// the dynamic::dynamic(ObjectMaker&&) ctor.
struct dynamic::ObjectMaker {
friend struct dynamic;
explicit ObjectMaker() : val_(dynamic::object) {}
explicit ObjectMaker(dynamic key, dynamic val) : val_(dynamic::object) {
val_.insert(std::move(key), std::move(val));
}
// Make sure no one tries to save one of these into an lvalue with
// auto or anything like that.
ObjectMaker(ObjectMaker&&) = default;
ObjectMaker(ObjectMaker const&) = delete;
ObjectMaker& operator=(ObjectMaker const&) = delete;
ObjectMaker& operator=(ObjectMaker&&) = delete;
// This returns an rvalue-reference instead of an lvalue-reference
// to allow constructs like this to moved instead of copied:
// dynamic a = dynamic::object("a", "b")("c", "d")
ObjectMaker&& operator()(dynamic key, dynamic val) {
val_.insert(std::move(key), std::move(val));
return std::move(*this);
}
private:
dynamic val_;
};
inline void dynamic::array(EmptyArrayTag) {}
template <class... Args>
inline dynamic dynamic::array(Args&&... args) {
return dynamic(Array{std::forward<Args>(args)...});
}
inline dynamic::ObjectMaker dynamic::object() {
return ObjectMaker();
}
inline dynamic::ObjectMaker dynamic::object(dynamic a, dynamic b) {
return ObjectMaker(std::move(a), std::move(b));
}
//////////////////////////////////////////////////////////////////////
struct dynamic::item_iterator : detail::IteratorAdaptor<
dynamic::item_iterator,
dynamic::ObjectImpl::iterator,
std::pair<dynamic const, dynamic>> {
using Super = detail::IteratorAdaptor<
dynamic::item_iterator,
dynamic::ObjectImpl::iterator,
std::pair<dynamic const, dynamic>>;
/* implicit */ item_iterator(dynamic::ObjectImpl::iterator b) : Super(b) {}
using object_type = dynamic::ObjectImpl;
};
struct dynamic::value_iterator : detail::IteratorAdaptor<
dynamic::value_iterator,
dynamic::ObjectImpl::iterator,
dynamic> {
using Super = detail::IteratorAdaptor<
dynamic::value_iterator,
dynamic::ObjectImpl::iterator,
dynamic>;
/* implicit */ value_iterator(dynamic::ObjectImpl::iterator b) : Super(b) {}
using object_type = dynamic::ObjectImpl;
dynamic& dereference() const {
return base()->second;
}
};
struct dynamic::const_item_iterator
: detail::IteratorAdaptor<
dynamic::const_item_iterator,
dynamic::ObjectImpl::const_iterator,
std::pair<dynamic const, dynamic> const> {
using Super = detail::IteratorAdaptor<
dynamic::const_item_iterator,
dynamic::ObjectImpl::const_iterator,
std::pair<dynamic const, dynamic> const>;
/* implicit */ const_item_iterator(dynamic::ObjectImpl::const_iterator b)
: Super(b) {}
/* implicit */ const_item_iterator(const_item_iterator const& i)
: Super(i.base()) {}
/* implicit */ const_item_iterator(item_iterator i) : Super(i.base()) {}
using object_type = dynamic::ObjectImpl const;
};
struct dynamic::const_key_iterator : detail::IteratorAdaptor<
dynamic::const_key_iterator,
dynamic::ObjectImpl::const_iterator,
dynamic const> {
using Super = detail::IteratorAdaptor<
dynamic::const_key_iterator,
dynamic::ObjectImpl::const_iterator,
dynamic const>;
/* implicit */ const_key_iterator(dynamic::ObjectImpl::const_iterator b)
: Super(b) {}
using object_type = dynamic::ObjectImpl const;
dynamic const& dereference() const {
return base()->first;
}
};
struct dynamic::const_value_iterator : detail::IteratorAdaptor<
dynamic::const_value_iterator,
dynamic::ObjectImpl::const_iterator,
dynamic const> {
using Super = detail::IteratorAdaptor<
dynamic::const_value_iterator,
dynamic::ObjectImpl::const_iterator,
dynamic const>;
/* implicit */ const_value_iterator(dynamic::ObjectImpl::const_iterator b)
: Super(b) {}
/* implicit */ const_value_iterator(value_iterator i) : Super(i.base()) {}
/* implicit */ const_value_iterator(dynamic::ObjectImpl::iterator i)
: Super(i) {}
using object_type = dynamic::ObjectImpl const;
dynamic const& dereference() const {
return base()->second;
}
};
//////////////////////////////////////////////////////////////////////
inline dynamic::dynamic() : dynamic(nullptr) {}
inline dynamic::dynamic(std::nullptr_t) : type_(NULLT) {}
inline dynamic::dynamic(void (*)(EmptyArrayTag)) : type_(ARRAY) {
new (&u_.array) Array();
}
inline dynamic::dynamic(ObjectMaker (*)()) : type_(OBJECT) {
new (getAddress<ObjectImpl>()) ObjectImpl();
}
inline dynamic::dynamic(StringPiece s) : type_(STRING) {
new (&u_.string) std::string(s.data(), s.size());
}
inline dynamic::dynamic(char const* s) : type_(STRING) {
new (&u_.string) std::string(s);
}
inline dynamic::dynamic(std::string s) : type_(STRING) {
new (&u_.string) std::string(std::move(s));
}
inline dynamic::dynamic(ObjectMaker&& maker) : type_(OBJECT) {
new (getAddress<ObjectImpl>())
ObjectImpl(std::move(*maker.val_.getAddress<ObjectImpl>()));
}
inline dynamic::dynamic(dynamic const& o) : type_(NULLT) {
*this = o;
}
inline dynamic::dynamic(dynamic&& o) noexcept : type_(NULLT) {
*this = std::move(o);
}
inline dynamic::~dynamic() noexcept {
destroy();
}
// Integral types except bool convert to int64_t, float types to double.
template <class T>
struct dynamic::NumericTypeHelper<
T,
typename std::enable_if<std::is_integral<T>::value>::type> {
static_assert(
!kIsObjC || sizeof(T) > sizeof(char),
"char-sized types are ambiguous in objc; cast to bool or wider type");
using type = int64_t;
};
template <>
struct dynamic::NumericTypeHelper<bool> {
using type = bool;
};
template <>
struct dynamic::NumericTypeHelper<float> {
using type = double;
};
template <>
struct dynamic::NumericTypeHelper<double> {
using type = double;
};
inline dynamic::dynamic(std::vector<bool>::reference b)
: dynamic(static_cast<bool>(b)) {}
inline dynamic::dynamic(VectorBoolConstRefCtorType b)
: dynamic(static_cast<bool>(b)) {}
template <
class T,
class NumericType /* = typename NumericTypeHelper<T>::type */>
dynamic::dynamic(T t) {
type_ = TypeInfo<NumericType>::type;
new (getAddress<NumericType>()) NumericType(NumericType(t));
}
template <class Iterator>
dynamic::dynamic(Iterator first, Iterator last) : type_(ARRAY) {
new (&u_.array) Array(first, last);
}
//////////////////////////////////////////////////////////////////////
inline dynamic::const_iterator dynamic::begin() const {
return get<Array>().begin();
}
inline dynamic::const_iterator dynamic::end() const {
return get<Array>().end();
}
inline dynamic::iterator dynamic::begin() {
return get<Array>().begin();
}
inline dynamic::iterator dynamic::end() {
return get<Array>().end();
}
template <class It>
struct dynamic::IterableProxy {
typedef It iterator;
typedef typename It::value_type value_type;
typedef typename It::object_type object_type;
/* implicit */ IterableProxy(object_type* o) : o_(o) {}
It begin() const {
return o_->begin();
}
It end() const {
return o_->end();
}
private:
object_type* o_;
};
inline dynamic::IterableProxy<dynamic::const_key_iterator> dynamic::keys()
const {
return &(get<ObjectImpl>());
}
inline dynamic::IterableProxy<dynamic::const_value_iterator> dynamic::values()
const {
return &(get<ObjectImpl>());
}
inline dynamic::IterableProxy<dynamic::const_item_iterator> dynamic::items()
const {
return &(get<ObjectImpl>());
}
inline dynamic::IterableProxy<dynamic::value_iterator> dynamic::values() {
return &(get<ObjectImpl>());
}
inline dynamic::IterableProxy<dynamic::item_iterator> dynamic::items() {
return &(get<ObjectImpl>());
}
inline bool dynamic::isString() const {
return get_nothrow<std::string>() != nullptr;
}
inline bool dynamic::isObject() const {
return get_nothrow<ObjectImpl>() != nullptr;
}
inline bool dynamic::isBool() const {
return get_nothrow<bool>() != nullptr;
}
inline bool dynamic::isArray() const {
return get_nothrow<Array>() != nullptr;
}
inline bool dynamic::isDouble() const {
return get_nothrow<double>() != nullptr;
}
inline bool dynamic::isInt() const {
return get_nothrow<int64_t>() != nullptr;
}
inline bool dynamic::isNull() const {
return get_nothrow<std::nullptr_t>() != nullptr;
}
inline bool dynamic::isNumber() const {
return isInt() || isDouble();
}
inline dynamic::Type dynamic::type() const {
return type_;
}
inline std::string dynamic::asString() const {
return asImpl<std::string>();
}
inline double dynamic::asDouble() const {
return asImpl<double>();
}
inline int64_t dynamic::asInt() const {
return asImpl<int64_t>();
}
inline bool dynamic::asBool() const {
return asImpl<bool>();
}
inline const std::string& dynamic::getString() const& {
return get<std::string>();
}
inline double dynamic::getDouble() const& {
return get<double>();
}
inline int64_t dynamic::getInt() const& {
return get<int64_t>();
}
inline bool dynamic::getBool() const& {
return get<bool>();
}
inline std::string& dynamic::getString() & {
return get<std::string>();
}
inline double& dynamic::getDouble() & {
return get<double>();
}
inline int64_t& dynamic::getInt() & {
return get<int64_t>();
}
inline bool& dynamic::getBool() & {
return get<bool>();
}
inline std::string&& dynamic::getString() && {
return std::move(get<std::string>());
}
inline double dynamic::getDouble() && {
return get<double>();
}
inline int64_t dynamic::getInt() && {
return get<int64_t>();
}
inline bool dynamic::getBool() && {
return get<bool>();
}
inline const char* dynamic::data() const& {
return get<std::string>().data();
}
inline const char* dynamic::c_str() const& {
return get<std::string>().c_str();
}
inline StringPiece dynamic::stringPiece() const {
return get<std::string>();
}
template <class T>
struct dynamic::CompareOp {
static bool comp(T const& a, T const& b) {
return a < b;
}
};
template <>
struct dynamic::CompareOp<dynamic::ObjectImpl> {
static bool comp(ObjectImpl const&, ObjectImpl const&) {
// This code never executes; it is just here for the compiler.
return false;
}
};
template <>
struct dynamic::CompareOp<std::nullptr_t> {
static bool comp(std::nullptr_t const&, std::nullptr_t const&) {
return true;
}
};
inline dynamic& dynamic::operator+=(dynamic const& o) {
if (type() == STRING && o.type() == STRING) {
*getAddress<std::string>() += *o.getAddress<std::string>();
return *this;
}
*this = detail::numericOp<std::plus>(*this, o);
return *this;
}
inline dynamic& dynamic::operator-=(dynamic const& o) {
*this = detail::numericOp<std::minus>(*this, o);
return *this;
}
inline dynamic& dynamic::operator*=(dynamic const& o) {
*this = detail::numericOp<std::multiplies>(*this, o);
return *this;
}
inline dynamic& dynamic::operator/=(dynamic const& o) {
*this = detail::numericOp<std::divides>(*this, o);
return *this;
}
#define FB_DYNAMIC_INTEGER_OP(op) \
inline dynamic& dynamic::operator op(dynamic const& o) { \
if (!isInt() || !o.isInt()) { \
throw_exception<TypeError>("int64", type(), o.type()); \
} \
*getAddress<int64_t>() op o.asInt(); \
return *this; \
}
FB_DYNAMIC_INTEGER_OP(%=)
FB_DYNAMIC_INTEGER_OP(|=)
FB_DYNAMIC_INTEGER_OP(&=)
FB_DYNAMIC_INTEGER_OP(^=)
#undef FB_DYNAMIC_INTEGER_OP
inline dynamic& dynamic::operator++() {
++get<int64_t>();
return *this;
}
inline dynamic& dynamic::operator--() {
--get<int64_t>();
return *this;
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic const&> dynamic::operator[](
K&& idx) const& {
return at(std::forward<K>(idx));
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic&> dynamic::operator[](
K&& idx) & {
if (!isObject() && !isArray()) {
throw_exception<TypeError>("object/array", type());
}
if (isArray()) {
return at(std::forward<K>(idx));
}
auto& obj = get<ObjectImpl>();
auto ret = obj.emplace(std::forward<K>(idx), nullptr);
return ret.first->second;
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic&&> dynamic::operator[](
K&& idx) && {
return std::move((*this)[std::forward<K>(idx)]);
}
inline dynamic const& dynamic::operator[](StringPiece k) const& {
return at(k);
}
inline dynamic&& dynamic::operator[](StringPiece k) && {
return std::move((*this)[k]);
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic> dynamic::getDefault(
K&& k,
const dynamic& v) const& {
auto& obj = get<ObjectImpl>();
auto it = obj.find(std::forward<K>(k));
return it == obj.end() ? v : it->second;
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic> dynamic::getDefault(
K&& k,
dynamic&& v) const& {
auto& obj = get<ObjectImpl>();
auto it = obj.find(std::forward<K>(k));
// Avoid clang bug with ternary
if (it == obj.end()) {
return std::move(v);
} else {
return it->second;
}
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic> dynamic::getDefault(
K&& k,
const dynamic& v) && {
auto& obj = get<ObjectImpl>();
auto it = obj.find(std::forward<K>(k));
// Avoid clang bug with ternary
if (it == obj.end()) {
return v;
} else {
return std::move(it->second);
}
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic> dynamic::getDefault(
K&& k,
dynamic&& v) && {
auto& obj = get<ObjectImpl>();
auto it = obj.find(std::forward<K>(k));
return std::move(it == obj.end() ? v : it->second);
}
template <typename K, typename V>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic&> dynamic::setDefault(
K&& k,
V&& v) {
auto& obj = get<ObjectImpl>();
return obj.emplace(std::forward<K>(k), std::forward<V>(v)).first->second;
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic&> dynamic::setDefault(
K&& k,
dynamic&& v) {
auto& obj = get<ObjectImpl>();
return obj.emplace(std::forward<K>(k), std::move(v)).first->second;
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic&> dynamic::setDefault(
K&& k,
const dynamic& v) {
auto& obj = get<ObjectImpl>();
return obj.emplace(std::forward<K>(k), v).first->second;
}
template <typename V>
dynamic& dynamic::setDefault(StringPiece k, V&& v) {
auto& obj = get<ObjectImpl>();
return obj.emplace(k, std::forward<V>(v)).first->second;
}
inline dynamic& dynamic::setDefault(StringPiece k, dynamic&& v) {
auto& obj = get<ObjectImpl>();
return obj.emplace(k, std::move(v)).first->second;
}
inline dynamic& dynamic::setDefault(StringPiece k, const dynamic& v) {
auto& obj = get<ObjectImpl>();
return obj.emplace(k, v).first->second;
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic const*> dynamic::get_ptr(
K&& k) const& {
return get_ptrImpl(std::forward<K>(k));
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic*> dynamic::get_ptr(
K&& idx) & {
return const_cast<dynamic*>(const_cast<dynamic const*>(this)->get_ptr(idx));
}
inline dynamic* dynamic::get_ptr(StringPiece idx) & {
return const_cast<dynamic*>(const_cast<dynamic const*>(this)->get_ptr(idx));
}
inline dynamic* dynamic::get_ptr(json_pointer const& jsonPtr) & {
return const_cast<dynamic*>(
const_cast<dynamic const*>(this)->get_ptr(jsonPtr));
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic const&> dynamic::at(
K&& k) const& {
return atImpl(std::forward<K>(k));
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic&> dynamic::at(K&& idx) & {
return const_cast<dynamic&>(const_cast<dynamic const*>(this)->at(idx));
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic&&> dynamic::at(K&& idx) && {
return std::move(at(idx));
}
inline dynamic& dynamic::at(StringPiece idx) & {
return const_cast<dynamic&>(const_cast<dynamic const*>(this)->at(idx));
}
inline dynamic&& dynamic::at(StringPiece idx) && {
return std::move(at(idx));
}
inline bool dynamic::empty() const {
if (isNull()) {
return true;
}
return !size();
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic::const_item_iterator>
dynamic::find(K&& key) const {
return get<ObjectImpl>().find(std::forward<K>(key));
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, dynamic::item_iterator>
dynamic::find(K&& key) {
return get<ObjectImpl>().find(std::forward<K>(key));
}
inline dynamic::const_item_iterator dynamic::find(StringPiece key) const {
return get<ObjectImpl>().find(key);
}
inline dynamic::item_iterator dynamic::find(StringPiece key) {
return get<ObjectImpl>().find(key);
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, std::size_t> dynamic::count(
K&& key) const {
return find(std::forward<K>(key)) != items().end() ? 1u : 0u;
}
inline std::size_t dynamic::count(StringPiece key) const {
return find(key) != items().end() ? 1u : 0u;
}
template <class K, class V>
inline void dynamic::insert(K&& key, V&& val) {
auto& obj = get<ObjectImpl>();
obj[std::forward<K>(key)] = std::forward<V>(val);
}
inline void dynamic::update(const dynamic& mergeObj) {
if (!isObject() || !mergeObj.isObject()) {
throw_exception<TypeError>("object", type(), mergeObj.type());
}
for (const auto& pair : mergeObj.items()) {
(*this)[pair.first] = pair.second;
}
}
inline void dynamic::update_missing(const dynamic& mergeObj1) {
if (!isObject() || !mergeObj1.isObject()) {
throw_exception<TypeError>("object", type(), mergeObj1.type());
}
// Only add if not already there
for (const auto& pair : mergeObj1.items()) {
if ((*this).find(pair.first) == (*this).items().end()) {
(*this)[pair.first] = pair.second;
}
}
}
inline void dynamic::merge_patch(const dynamic& patch) {
auto& self = *this;
if (!patch.isObject()) {
self = patch;
return;
}
// if we are not an object, erase all contents, reset to object
if (!isObject()) {
self = object;
}
for (const auto& pair : patch.items()) {
if (pair.second.isNull()) {
// if name could be found in current object, remove it
auto it = self.find(pair.first);
if (it != self.items().end()) {
self.erase(it);
}
} else {
self[pair.first].merge_patch(pair.second);
}
}
}
inline dynamic dynamic::merge(
const dynamic& mergeObj1,
const dynamic& mergeObj2) {
// No checks on type needed here because they are done in update_missing
// Note that we do update_missing here instead of update() because
// it will prevent the extra writes that would occur with update()
auto ret = mergeObj2;
ret.update_missing(mergeObj1);
return ret;
}
template <typename K>
dynamic::IfIsNonStringDynamicConvertible<K, std::size_t> dynamic::erase(
K&& key) {
auto& obj = get<ObjectImpl>();
return obj.erase(std::forward<K>(key));
}
inline std::size_t dynamic::erase(StringPiece key) {
auto& obj = get<ObjectImpl>();
return obj.erase(key);
}
inline dynamic::iterator dynamic::erase(const_iterator it) {
auto& arr = get<Array>();
// std::vector doesn't have an erase method that works on const iterators,
// even though the standard says it should, so this hack converts to a
// non-const iterator before calling erase.
return get<Array>().erase(arr.begin() + (it - arr.begin()));
}
inline dynamic::const_key_iterator dynamic::erase(const_key_iterator it) {
return const_key_iterator(get<ObjectImpl>().erase(it.base()));
}
inline dynamic::const_key_iterator dynamic::erase(
const_key_iterator first,
const_key_iterator last) {
return const_key_iterator(get<ObjectImpl>().erase(first.base(), last.base()));
}
inline dynamic::value_iterator dynamic::erase(const_value_iterator it) {
return value_iterator(get<ObjectImpl>().erase(it.base()));
}
inline dynamic::value_iterator dynamic::erase(
const_value_iterator first,
const_value_iterator last) {
return value_iterator(get<ObjectImpl>().erase(first.base(), last.base()));
}
inline dynamic::item_iterator dynamic::erase(const_item_iterator it) {
return item_iterator(get<ObjectImpl>().erase(it.base()));
}
inline dynamic::item_iterator dynamic::erase(
const_item_iterator first,
const_item_iterator last) {
return item_iterator(get<ObjectImpl>().erase(first.base(), last.base()));
}
inline void dynamic::resize(std::size_t sz, dynamic const& c) {
auto& arr = get<Array>();
arr.resize(sz, c);
}
inline void dynamic::push_back(dynamic const& v) {
auto& arr = get<Array>();
arr.push_back(v);
}
inline void dynamic::push_back(dynamic&& v) {
auto& arr = get<Array>();
arr.push_back(std::move(v));
}
inline void dynamic::pop_back() {
auto& arr = get<Array>();
arr.pop_back();
}
//////////////////////////////////////////////////////////////////////
inline dynamic::dynamic(Array&& r) : type_(ARRAY) {
new (&u_.array) Array(std::move(r));
}
#define FOLLY_DYNAMIC_DEC_TYPEINFO(T, str, val) \
template <> \
struct dynamic::TypeInfo<T> { \
static constexpr const char* name = str; \
static constexpr dynamic::Type type = val; \
}; \
//
FOLLY_DYNAMIC_DEC_TYPEINFO(std::nullptr_t, "null", dynamic::NULLT)
FOLLY_DYNAMIC_DEC_TYPEINFO(bool, "boolean", dynamic::BOOL)
FOLLY_DYNAMIC_DEC_TYPEINFO(std::string, "string", dynamic::STRING)
FOLLY_DYNAMIC_DEC_TYPEINFO(dynamic::Array, "array", dynamic::ARRAY)
FOLLY_DYNAMIC_DEC_TYPEINFO(double, "double", dynamic::DOUBLE)
FOLLY_DYNAMIC_DEC_TYPEINFO(int64_t, "int64", dynamic::INT64)
FOLLY_DYNAMIC_DEC_TYPEINFO(dynamic::ObjectImpl, "object", dynamic::OBJECT)
#undef FOLLY_DYNAMIC_DEC_TYPEINFO
template <class T>
T dynamic::asImpl() const {
switch (type()) {
case INT64:
return to<T>(*get_nothrow<int64_t>());
case DOUBLE:
return to<T>(*get_nothrow<double>());
case BOOL:
return to<T>(*get_nothrow<bool>());
case STRING:
return to<T>(*get_nothrow<std::string>());
default:
throw_exception<TypeError>("int/double/bool/string", type());
}
}
// Return a T* to our type, or null if we're not that type.
// clang-format off
template <class T>
T* dynamic::get_nothrow() & noexcept {
if (type_ != TypeInfo<T>::type) {
return nullptr;
}
return getAddress<T>();
}
// clang-format on
template <class T>
T const* dynamic::get_nothrow() const& noexcept {
return const_cast<dynamic*>(this)->get_nothrow<T>();
}
// Return T* for where we can put a T, without type checking. (Memory
// might be uninitialized, even.)
template <class T>
T* dynamic::getAddress() noexcept {
return GetAddrImpl<T>::get(u_);
}
template <class T>
T const* dynamic::getAddress() const noexcept {
return const_cast<dynamic*>(this)->getAddress<T>();
}
template <class T>
struct dynamic::GetAddrImpl {};
template <>
struct dynamic::GetAddrImpl<std::nullptr_t> {
static std::nullptr_t* get(Data& d) noexcept {
return &d.nul;
}
};
template <>
struct dynamic::GetAddrImpl<dynamic::Array> {
static Array* get(Data& d) noexcept {
return &d.array;
}
};
template <>
struct dynamic::GetAddrImpl<bool> {
static bool* get(Data& d) noexcept {
return &d.boolean;
}
};
template <>
struct dynamic::GetAddrImpl<int64_t> {
static int64_t* get(Data& d) noexcept {
return &d.integer;
}
};
template <>
struct dynamic::GetAddrImpl<double> {
static double* get(Data& d) noexcept {
return &d.doubl;
}
};
template <>
struct dynamic::GetAddrImpl<std::string> {
static std::string* get(Data& d) noexcept {
return &d.string;
}
};
template <>
struct dynamic::GetAddrImpl<dynamic::ObjectImpl> {
static_assert(
sizeof(ObjectImpl) <= sizeof(Data::objectBuffer),
"In your implementation, F14NodeMap<> apparently takes different"
" amount of space depending on its template parameters. This is "
"weird. Make objectBuffer bigger if you want to compile dynamic.");
static ObjectImpl* get(Data& d) noexcept {
void* data = &d.objectBuffer;
return static_cast<ObjectImpl*>(data);
}
};
template <class T>
T& dynamic::get() {
if (auto* p = get_nothrow<T>()) {
return *p;
}
throw_exception<TypeError>(TypeInfo<T>::name, type());
}
template <class T>
T const& dynamic::get() const {
return const_cast<dynamic*>(this)->get<T>();
}
//////////////////////////////////////////////////////////////////////
/*
* Helper for implementing operator<<. Throws if the type shouldn't
* support it.
*/
template <class T>
struct dynamic::PrintImpl {
static void print(dynamic const&, std::ostream& out, T const& t) {
out << t;
}
};
// Otherwise, null, being (void*)0, would print as 0.
template <>
struct dynamic::PrintImpl<std::nullptr_t> {
static void
print(dynamic const& /* d */, std::ostream& out, std::nullptr_t const&) {
out << "null";
}
};
template <>
struct dynamic::PrintImpl<dynamic::ObjectImpl> {
static void
print(dynamic const& d, std::ostream& out, dynamic::ObjectImpl const&) {
d.print_as_pseudo_json(out);
}
};
template <>
struct dynamic::PrintImpl<dynamic::Array> {
static void
print(dynamic const& d, std::ostream& out, dynamic::Array const&) {
d.print_as_pseudo_json(out);
}
};
inline void dynamic::print(std::ostream& out) const {
#define FB_X(T) PrintImpl<T>::print(*this, out, *getAddress<T>())
FB_DYNAMIC_APPLY(type_, FB_X);
#undef FB_X
}
inline std::ostream& operator<<(std::ostream& out, dynamic const& d) {
d.print(out);
return out;
}
//////////////////////////////////////////////////////////////////////
// Secialization of FormatValue so dynamic objects can be formatted
template <>
class FormatValue<dynamic> {
public:
explicit FormatValue(const dynamic& val) : val_(val) {}
template <class FormatCallback>
void format(FormatArg& arg, FormatCallback& cb) const {
switch (val_.type()) {
case dynamic::NULLT:
FormatValue<std::nullptr_t>(nullptr).format(arg, cb);
break;
case dynamic::BOOL:
FormatValue<bool>(val_.asBool()).format(arg, cb);
break;
case dynamic::INT64:
FormatValue<int64_t>(val_.asInt()).format(arg, cb);
break;
case dynamic::STRING:
FormatValue<std::string>(val_.asString()).format(arg, cb);
break;
case dynamic::DOUBLE:
FormatValue<double>(val_.asDouble()).format(arg, cb);
break;
case dynamic::ARRAY:
FormatValue(val_.at(arg.splitIntKey())).format(arg, cb);
break;
case dynamic::OBJECT:
FormatValue(val_.at(arg.splitKey().toString())).format(arg, cb);
break;
}
}
private:
const dynamic& val_;
};
template <class V>
class FormatValue<detail::DefaultValueWrapper<dynamic, V>> {
public:
explicit FormatValue(const detail::DefaultValueWrapper<dynamic, V>& val)
: val_(val) {}
template <class FormatCallback>
void format(FormatArg& arg, FormatCallback& cb) const {
auto& c = val_.container;
switch (c.type()) {
case dynamic::NULLT:
case dynamic::BOOL:
case dynamic::INT64:
case dynamic::STRING:
case dynamic::DOUBLE:
FormatValue<dynamic>(c).format(arg, cb);
break;
case dynamic::ARRAY: {
int key = arg.splitIntKey();
if (key >= 0 && size_t(key) < c.size()) {
FormatValue<dynamic>(c.at(key)).format(arg, cb);
} else {
FormatValue<V>(val_.defaultValue).format(arg, cb);
}
break;
}
case dynamic::OBJECT: {
auto pos = c.find(arg.splitKey());
if (pos != c.items().end()) {
FormatValue<dynamic>(pos->second).format(arg, cb);
} else {
FormatValue<V>(val_.defaultValue).format(arg, cb);
}
break;
}
}
}
private:
const detail::DefaultValueWrapper<dynamic, V>& val_;
};
} // namespace folly
#undef FB_DYNAMIC_APPLY