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openpilot is an open source driver assistance system. openpilot performs the functions of Automated Lane Centering and Adaptive Cruise Control for over 200 supported car makes and models.
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openpilot_comma/phonelibs/capnp-cpp/include/capnp/list.h

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openpilot v0.4.6 release
7 years ago
// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors
// Licensed under the MIT License:
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to deal
// in the Software without restriction, including without limitation the rights
// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
// copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in
// all copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
// THE SOFTWARE.
#ifndef CAPNP_LIST_H_
#define CAPNP_LIST_H_
#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS)
#pragma GCC system_header
#endif
#include "layout.h"
#include "orphan.h"
#include <initializer_list>
#ifdef KJ_STD_COMPAT
#include <iterator>
#endif // KJ_STD_COMPAT
namespace capnp {
namespace _ { // private
template <typename T>
class TemporaryPointer {
// This class is a little hack which lets us define operator->() in cases where it needs to
// return a pointer to a temporary value. We instead construct a TemporaryPointer and return that
// (by value). The compiler then invokes operator->() on the TemporaryPointer, which itself is
// able to return a real pointer to its member.
public:
TemporaryPointer(T&& value): value(kj::mv(value)) {}
TemporaryPointer(const T& value): value(value) {}
inline T* operator->() { return &value; }
private:
T value;
};
template <typename Container, typename Element>
class IndexingIterator {
public:
IndexingIterator() = default;
inline Element operator*() const { return (*container)[index]; }
inline TemporaryPointer<Element> operator->() const {
return TemporaryPointer<Element>((*container)[index]);
}
inline Element operator[]( int off) const { return (*container)[index]; }
inline Element operator[](uint off) const { return (*container)[index]; }
inline IndexingIterator& operator++() { ++index; return *this; }
inline IndexingIterator operator++(int) { IndexingIterator other = *this; ++index; return other; }
inline IndexingIterator& operator--() { --index; return *this; }
inline IndexingIterator operator--(int) { IndexingIterator other = *this; --index; return other; }
inline IndexingIterator operator+(uint amount) const { return IndexingIterator(container, index + amount); }
inline IndexingIterator operator-(uint amount) const { return IndexingIterator(container, index - amount); }
inline IndexingIterator operator+( int amount) const { return IndexingIterator(container, index + amount); }
inline IndexingIterator operator-( int amount) const { return IndexingIterator(container, index - amount); }
inline int operator-(const IndexingIterator& other) const { return index - other.index; }
inline IndexingIterator& operator+=(uint amount) { index += amount; return *this; }
inline IndexingIterator& operator-=(uint amount) { index -= amount; return *this; }
inline IndexingIterator& operator+=( int amount) { index += amount; return *this; }
inline IndexingIterator& operator-=( int amount) { index -= amount; return *this; }
// STL says comparing iterators of different containers is not allowed, so we only compare
// indices here.
inline bool operator==(const IndexingIterator& other) const { return index == other.index; }
inline bool operator!=(const IndexingIterator& other) const { return index != other.index; }
inline bool operator<=(const IndexingIterator& other) const { return index <= other.index; }
inline bool operator>=(const IndexingIterator& other) const { return index >= other.index; }
inline bool operator< (const IndexingIterator& other) const { return index < other.index; }
inline bool operator> (const IndexingIterator& other) const { return index > other.index; }
private:
Container* container;
uint index;
friend Container;
inline IndexingIterator(Container* container, uint index)
: container(container), index(index) {}
};
} // namespace _ (private)
template <typename T>
struct List<T, Kind::PRIMITIVE> {
// List of primitives.
List() = delete;
class Reader {
public:
typedef List<T> Reads;
inline Reader(): reader(_::elementSizeForType<T>()) {}
inline explicit Reader(_::ListReader reader): reader(reader) {}
inline uint size() const { return unbound(reader.size() / ELEMENTS); }
inline T operator[](uint index) const {
KJ_IREQUIRE(index < size());
return reader.template getDataElement<T>(bounded(index) * ELEMENTS);
}
typedef _::IndexingIterator<const Reader, T> Iterator;
inline Iterator begin() const { return Iterator(this, 0); }
inline Iterator end() const { return Iterator(this, size()); }
private:
_::ListReader reader;
template <typename U, Kind K>
friend struct _::PointerHelpers;
template <typename U, Kind K>
friend struct List;
friend class Orphanage;
template <typename U, Kind K>
friend struct ToDynamic_;
};
class Builder {
public:
typedef List<T> Builds;
inline Builder(): builder(_::elementSizeForType<T>()) {}
inline Builder(decltype(nullptr)): Builder() {}
inline explicit Builder(_::ListBuilder builder): builder(builder) {}
inline operator Reader() const { return Reader(builder.asReader()); }
inline Reader asReader() const { return Reader(builder.asReader()); }
inline uint size() const { return unbound(builder.size() / ELEMENTS); }
inline T operator[](uint index) {
KJ_IREQUIRE(index < size());
return builder.template getDataElement<T>(bounded(index) * ELEMENTS);
}
inline void set(uint index, T value) {
// Alas, it is not possible to make operator[] return a reference to which you can assign,
// since the encoded representation does not necessarily match the compiler's representation
// of the type. We can't even return a clever class that implements operator T() and
// operator=() because it will lead to surprising behavior when using type inference (e.g.
// calling a template function with inferred argument types, or using "auto" or "decltype").
builder.template setDataElement<T>(bounded(index) * ELEMENTS, value);
}
typedef _::IndexingIterator<Builder, T> Iterator;
inline Iterator begin() { return Iterator(this, 0); }
inline Iterator end() { return Iterator(this, size()); }
private:
_::ListBuilder builder;
template <typename U, Kind K>
friend struct _::PointerHelpers;
friend class Orphanage;
template <typename U, Kind K>
friend struct ToDynamic_;
};
class Pipeline {};
private:
inline static _::ListBuilder initPointer(_::PointerBuilder builder, uint size) {
return builder.initList(_::elementSizeForType<T>(), bounded(size) * ELEMENTS);
}
inline static _::ListBuilder getFromPointer(_::PointerBuilder builder, const word* defaultValue) {
return builder.getList(_::elementSizeForType<T>(), defaultValue);
}
inline static _::ListReader getFromPointer(
const _::PointerReader& reader, const word* defaultValue) {
return reader.getList(_::elementSizeForType<T>(), defaultValue);
}
template <typename U, Kind k>
friend struct List;
template <typename U, Kind K>
friend struct _::PointerHelpers;
};
template <typename T>
struct List<T, Kind::ENUM>: public List<T, Kind::PRIMITIVE> {};
template <typename T>
struct List<T, Kind::STRUCT> {
// List of structs.
List() = delete;
class Reader {
public:
typedef List<T> Reads;
inline Reader(): reader(ElementSize::INLINE_COMPOSITE) {}
inline explicit Reader(_::ListReader reader): reader(reader) {}
inline uint size() const { return unbound(reader.size() / ELEMENTS); }
inline typename T::Reader operator[](uint index) const {
KJ_IREQUIRE(index < size());
return typename T::Reader(reader.getStructElement(bounded(index) * ELEMENTS));
}
typedef _::IndexingIterator<const Reader, typename T::Reader> Iterator;
inline Iterator begin() const { return Iterator(this, 0); }
inline Iterator end() const { return Iterator(this, size()); }
private:
_::ListReader reader;
template <typename U, Kind K>
friend struct _::PointerHelpers;
template <typename U, Kind K>
friend struct List;
friend class Orphanage;
template <typename U, Kind K>
friend struct ToDynamic_;
};
class Builder {
public:
typedef List<T> Builds;
inline Builder(): builder(ElementSize::INLINE_COMPOSITE) {}
inline Builder(decltype(nullptr)): Builder() {}
inline explicit Builder(_::ListBuilder builder): builder(builder) {}
inline operator Reader() const { return Reader(builder.asReader()); }
inline Reader asReader() const { return Reader(builder.asReader()); }
inline uint size() const { return unbound(builder.size() / ELEMENTS); }
inline typename T::Builder operator[](uint index) {
KJ_IREQUIRE(index < size());
return typename T::Builder(builder.getStructElement(bounded(index) * ELEMENTS));
}
inline void adoptWithCaveats(uint index, Orphan<T>&& orphan) {
// Mostly behaves like you'd expect `adopt` to behave, but with two caveats originating from
// the fact that structs in a struct list are allocated inline rather than by pointer:
// * This actually performs a shallow copy, effectively adopting each of the orphan's
// children rather than adopting the orphan itself. The orphan ends up being discarded,
// possibly wasting space in the message object.
// * If the orphan is larger than the target struct -- say, because the orphan was built
// using a newer version of the schema that has additional fields -- it will be truncated,
// losing data.
KJ_IREQUIRE(index < size());
// We pass a zero-valued StructSize to asStruct() because we do not want the struct to be
// expanded under any circumstances. We're just going to throw it away anyway, and
// transferContentFrom() already carefully compares the struct sizes before transferring.
builder.getStructElement(bounded(index) * ELEMENTS).transferContentFrom(
orphan.builder.asStruct(_::StructSize(ZERO * WORDS, ZERO * POINTERS)));
}
inline void setWithCaveats(uint index, const typename T::Reader& reader) {
// Mostly behaves like you'd expect `set` to behave, but with a caveat originating from
// the fact that structs in a struct list are allocated inline rather than by pointer:
// If the source struct is larger than the target struct -- say, because the source was built
// using a newer version of the schema that has additional fields -- it will be truncated,
// losing data.
//
// Note: If you are trying to concatenate some lists, use Orphanage::newOrphanConcat() to
// do it without losing any data in case the source lists come from a newer version of the
// protocol. (Plus, it's easier to use anyhow.)
KJ_IREQUIRE(index < size());
builder.getStructElement(bounded(index) * ELEMENTS).copyContentFrom(reader._reader);
}
// There are no init(), set(), adopt(), or disown() methods for lists of structs because the
// elements of the list are inlined and are initialized when the list is initialized. This
// means that init() would be redundant, and set() would risk data loss if the input struct
// were from a newer version of the protocol.
typedef _::IndexingIterator<Builder, typename T::Builder> Iterator;
inline Iterator begin() { return Iterator(this, 0); }
inline Iterator end() { return Iterator(this, size()); }
private:
_::ListBuilder builder;
template <typename U, Kind K>
friend struct _::PointerHelpers;
friend class Orphanage;
template <typename U, Kind K>
friend struct ToDynamic_;
};
class Pipeline {};
private:
inline static _::ListBuilder initPointer(_::PointerBuilder builder, uint size) {
return builder.initStructList(bounded(size) * ELEMENTS, _::structSize<T>());
}
inline static _::ListBuilder getFromPointer(_::PointerBuilder builder, const word* defaultValue) {
return builder.getStructList(_::structSize<T>(), defaultValue);
}
inline static _::ListReader getFromPointer(
const _::PointerReader& reader, const word* defaultValue) {
return reader.getList(ElementSize::INLINE_COMPOSITE, defaultValue);
}
template <typename U, Kind k>
friend struct List;
template <typename U, Kind K>
friend struct _::PointerHelpers;
};
template <typename T>
struct List<List<T>, Kind::LIST> {
// List of lists.
List() = delete;
class Reader {
public:
typedef List<List<T>> Reads;
inline Reader(): reader(ElementSize::POINTER) {}
inline explicit Reader(_::ListReader reader): reader(reader) {}
inline uint size() const { return unbound(reader.size() / ELEMENTS); }
inline typename List<T>::Reader operator[](uint index) const {
KJ_IREQUIRE(index < size());
return typename List<T>::Reader(_::PointerHelpers<List<T>>::get(
reader.getPointerElement(bounded(index) * ELEMENTS)));
}
typedef _::IndexingIterator<const Reader, typename List<T>::Reader> Iterator;
inline Iterator begin() const { return Iterator(this, 0); }
inline Iterator end() const { return Iterator(this, size()); }
private:
_::ListReader reader;
template <typename U, Kind K>
friend struct _::PointerHelpers;
template <typename U, Kind K>
friend struct List;
friend class Orphanage;
template <typename U, Kind K>
friend struct ToDynamic_;
};
class Builder {
public:
typedef List<List<T>> Builds;
inline Builder(): builder(ElementSize::POINTER) {}
inline Builder(decltype(nullptr)): Builder() {}
inline explicit Builder(_::ListBuilder builder): builder(builder) {}
inline operator Reader() const { return Reader(builder.asReader()); }
inline Reader asReader() const { return Reader(builder.asReader()); }
inline uint size() const { return unbound(builder.size() / ELEMENTS); }
inline typename List<T>::Builder operator[](uint index) {
KJ_IREQUIRE(index < size());
return typename List<T>::Builder(_::PointerHelpers<List<T>>::get(
builder.getPointerElement(bounded(index) * ELEMENTS)));
}
inline typename List<T>::Builder init(uint index, uint size) {
KJ_IREQUIRE(index < this->size());
return typename List<T>::Builder(_::PointerHelpers<List<T>>::init(
builder.getPointerElement(bounded(index) * ELEMENTS), size));
}
inline void set(uint index, typename List<T>::Reader value) {
KJ_IREQUIRE(index < size());
builder.getPointerElement(bounded(index) * ELEMENTS).setList(value.reader);
}
void set(uint index, std::initializer_list<ReaderFor<T>> value) {
KJ_IREQUIRE(index < size());
auto l = init(index, value.size());
uint i = 0;
for (auto& element: value) {
l.set(i++, element);
}
}
inline void adopt(uint index, Orphan<T>&& value) {
KJ_IREQUIRE(index < size());
builder.getPointerElement(bounded(index) * ELEMENTS).adopt(kj::mv(value.builder));
}
inline Orphan<T> disown(uint index) {
KJ_IREQUIRE(index < size());
return Orphan<T>(builder.getPointerElement(bounded(index) * ELEMENTS).disown());
}
typedef _::IndexingIterator<Builder, typename List<T>::Builder> Iterator;
inline Iterator begin() { return Iterator(this, 0); }
inline Iterator end() { return Iterator(this, size()); }
private:
_::ListBuilder builder;
template <typename U, Kind K>
friend struct _::PointerHelpers;
friend class Orphanage;
template <typename U, Kind K>
friend struct ToDynamic_;
};
class Pipeline {};
private:
inline static _::ListBuilder initPointer(_::PointerBuilder builder, uint size) {
return builder.initList(ElementSize::POINTER, bounded(size) * ELEMENTS);
}
inline static _::ListBuilder getFromPointer(_::PointerBuilder builder, const word* defaultValue) {
return builder.getList(ElementSize::POINTER, defaultValue);
}
inline static _::ListReader getFromPointer(
const _::PointerReader& reader, const word* defaultValue) {
return reader.getList(ElementSize::POINTER, defaultValue);
}
template <typename U, Kind k>
friend struct List;
template <typename U, Kind K>
friend struct _::PointerHelpers;
};
template <typename T>
struct List<T, Kind::BLOB> {
List() = delete;
class Reader {
public:
typedef List<T> Reads;
inline Reader(): reader(ElementSize::POINTER) {}
inline explicit Reader(_::ListReader reader): reader(reader) {}
inline uint size() const { return unbound(reader.size() / ELEMENTS); }
inline typename T::Reader operator[](uint index) const {
KJ_IREQUIRE(index < size());
return reader.getPointerElement(bounded(index) * ELEMENTS)
.template getBlob<T>(nullptr, ZERO * BYTES);
}
typedef _::IndexingIterator<const Reader, typename T::Reader> Iterator;
inline Iterator begin() const { return Iterator(this, 0); }
inline Iterator end() const { return Iterator(this, size()); }
private:
_::ListReader reader;
template <typename U, Kind K>
friend struct _::PointerHelpers;
template <typename U, Kind K>
friend struct List;
friend class Orphanage;
template <typename U, Kind K>
friend struct ToDynamic_;
};
class Builder {
public:
typedef List<T> Builds;
inline Builder(): builder(ElementSize::POINTER) {}
inline Builder(decltype(nullptr)): Builder() {}
inline explicit Builder(_::ListBuilder builder): builder(builder) {}
inline operator Reader() const { return Reader(builder.asReader()); }
inline Reader asReader() const { return Reader(builder.asReader()); }
inline uint size() const { return unbound(builder.size() / ELEMENTS); }
inline typename T::Builder operator[](uint index) {
KJ_IREQUIRE(index < size());
return builder.getPointerElement(bounded(index) * ELEMENTS)
.template getBlob<T>(nullptr, ZERO * BYTES);
}
inline void set(uint index, typename T::Reader value) {
KJ_IREQUIRE(index < size());
builder.getPointerElement(bounded(index) * ELEMENTS).template setBlob<T>(value);
}
inline typename T::Builder init(uint index, uint size) {
KJ_IREQUIRE(index < this->size());
return builder.getPointerElement(bounded(index) * ELEMENTS)
.template initBlob<T>(bounded(size) * BYTES);
}
inline void adopt(uint index, Orphan<T>&& value) {
KJ_IREQUIRE(index < size());
builder.getPointerElement(bounded(index) * ELEMENTS).adopt(kj::mv(value.builder));
}
inline Orphan<T> disown(uint index) {
KJ_IREQUIRE(index < size());
return Orphan<T>(builder.getPointerElement(bounded(index) * ELEMENTS).disown());
}
typedef _::IndexingIterator<Builder, typename T::Builder> Iterator;
inline Iterator begin() { return Iterator(this, 0); }
inline Iterator end() { return Iterator(this, size()); }
private:
_::ListBuilder builder;
template <typename U, Kind K>
friend struct _::PointerHelpers;
friend class Orphanage;
template <typename U, Kind K>
friend struct ToDynamic_;
};
class Pipeline {};
private:
inline static _::ListBuilder initPointer(_::PointerBuilder builder, uint size) {
return builder.initList(ElementSize::POINTER, bounded(size) * ELEMENTS);
}
inline static _::ListBuilder getFromPointer(_::PointerBuilder builder, const word* defaultValue) {
return builder.getList(ElementSize::POINTER, defaultValue);
}
inline static _::ListReader getFromPointer(
const _::PointerReader& reader, const word* defaultValue) {
return reader.getList(ElementSize::POINTER, defaultValue);
}
template <typename U, Kind k>
friend struct List;
template <typename U, Kind K>
friend struct _::PointerHelpers;
};
} // namespace capnp
#ifdef KJ_STD_COMPAT
namespace std {
template <typename Container, typename Element>
struct iterator_traits<capnp::_::IndexingIterator<Container, Element>>
: public std::iterator<std::random_access_iterator_tag, Element, int> {};
} // namespace std
#endif // KJ_STD_COMPAT
#endif // CAPNP_LIST_H_