GSL/include/gsl.h
2015-09-27 23:28:18 -05:00

302 lines
9.4 KiB
C++

///////////////////////////////////////////////////////////////////////////////
//
// Copyright (c) 2015 Microsoft Corporation. All rights reserved.
//
// This code is licensed under the MIT License (MIT).
//
// 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.
//
///////////////////////////////////////////////////////////////////////////////
#pragma once
#ifndef GSL_GSL_H
#define GSL_GSL_H
#include "array_view.h" // array_view, strided_array_view...
#include "fail_fast.h" // fail_fast_assert
#include "string_view.h" // zstring, string_view, zstring_builder...
#include <memory>
namespace Guide
{
//
// GSL.owner: ownership pointers
//
using std::unique_ptr;
using std::shared_ptr;
template <class T>
using owner = T;
//
// GSL.assert: assertions
//
inline void Expects(bool cond) { Guide::fail_fast_assert(cond); }
inline void Ensures(bool cond) { Guide::fail_fast_assert(cond); }
//
// GSL.util: utilities
//
// Final_act allows you to ensure something gets run at the end of a scope
template <class F>
class Final_act
{
public:
explicit Final_act(F f) : f_(std::move(f)) {}
Final_act(const Final_act&& other) : f_(other.f_) {}
Final_act(const Final_act&) = delete;
Final_act& operator=(const Final_act&) = delete;
~Final_act() { f_(); }
private:
F f_;
};
// finally() - convenience function to generate a Final_act
template <class F>
Final_act<F> finally(const F &f) { return Final_act<F>(f); }
template <class F>
Final_act<F> finally(F &&f) { return Final_act<F>(std::forward<F>(f)); }
// narrow_cast(): a searchable way to do narrowing casts of values
template<class T, class U>
T narrow_cast(U u) { return static_cast<T>(u); }
struct narrowing_error : public std::exception {};
// narrow() : a checked version of narrow_cast() that throws if the cast changed the value
template<class T, class U>
T narrow(U u) { T t = narrow_cast<T>(u); if (static_cast<U>(t) != u) throw narrowing_error(); return t; }
//
// at() - Bounds-checked way of accessing static arrays, std::array, std::vector
//
template <class T, size_t N>
T& at(T(&arr)[N], size_t index) { fail_fast_assert(index < N); return arr[index]; }
template <class T, size_t N>
T& at(std::array<T, N>& arr, size_t index) { fail_fast_assert(index < N); return arr[index]; }
template <class Cont>
typename Cont::value_type& at(Cont& cont, size_t index) { fail_fast_assert(index < cont.size()); return cont[index]; }
//
// not_null
//
// Restricts a pointer or smart pointer to only hold non-null values.
//
// Has zero size overhead over T.
//
// If T is a pointer (i.e. T == U*) then
// - allow construction from U* or U&
// - disallow construction from nullptr_t
// - disallow default construction
// - ensure construction from U* fails with nullptr
// - allow implicit conversion to U*
//
template<class T>
class not_null
{
static_assert(std::is_assignable<T&, std::nullptr_t>::value, "T cannot be assigned nullptr.");
public:
not_null(T t) : ptr_(t) { ensure_invariant(); }
// deleting these two prevents compilation when initialized with a nullptr or literal 0
not_null(std::nullptr_t) = delete;
not_null(int) = delete;
not_null(const not_null &other) = default;
template <typename U, typename Dummy = std::enable_if_t<std::is_convertible<U, T>::value>>
not_null(const not_null<U> &other) : ptr_(other.get())
{
}
not_null<T>& operator=(const T& t) { ptr_ = t; ensure_invariant(); return *this; }
// prevents compilation when someone attempts to assign a nullptr
not_null<T>& operator=(std::nullptr_t) = delete;
not_null<T>& operator=(int) = delete;
T get() const {
#ifdef _MSC_VER
__assume(ptr_ != nullptr);
#endif
return ptr_;
} // the assume() should help the optimizer
operator T() const { return get(); }
T operator->() const { return get(); }
bool operator==(const T& rhs) const { return ptr_ == rhs; }
bool operator!=(const T& rhs) const { return !(*this == rhs); }
private:
T ptr_;
// we assume that the compiler can hoist/prove away most of the checks inlined from this function
// if not, we could make them optional via conditional compilation
void ensure_invariant() const { fail_fast_assert(ptr_ != nullptr); }
// unwanted operators...pointers only point to single objects!
// TODO ensure all arithmetic ops on this type are unavailable
not_null<T>& operator++() = delete;
not_null<T>& operator--() = delete;
not_null<T> operator++(int) = delete;
not_null<T> operator--(int) = delete;
not_null<T>& operator+(size_t) = delete;
not_null<T>& operator+=(size_t) = delete;
not_null<T>& operator-(size_t) = delete;
not_null<T>& operator-=(size_t) = delete;
};
//
// maybe_null
//
// Describes an optional pointer - provides symmetry with not_null
//
template<class T>
class maybe_null_dbg
{
static_assert(std::is_assignable<T&, std::nullptr_t>::value, "T cannot be assigned nullptr.");
public:
maybe_null_dbg() : ptr_(nullptr), tested_(false) {}
maybe_null_dbg(const T& p) : ptr_(p), tested_(false) {}
maybe_null_dbg(const maybe_null_dbg& rhs) : ptr_(rhs.ptr_), tested_(false) {}
template <typename U, typename Dummy = std::enable_if_t<std::is_convertible<U, T>::value>>
maybe_null_dbg(const not_null<U> &other) : ptr_(other.get()), tested_(false)
{
}
template <typename U, typename Dummy = std::enable_if_t<std::is_convertible<U, T>::value>>
maybe_null_dbg(const maybe_null_dbg<U> &other) : ptr_(other.get()), tested_(false)
{
}
maybe_null_dbg& operator=(const T& p)
{
if (ptr_ != p)
{
ptr_ = p;
tested_ = false;
}
return *this;
}
maybe_null_dbg& operator=(const maybe_null_dbg& rhs)
{
if (this != &rhs)
{
ptr_ = rhs.ptr_;
tested_ = false;
}
return *this;
}
bool present() const { tested_ = true; return ptr_ != nullptr; }
bool operator==(const T& rhs) const { tested_ = true; return ptr_ == rhs; }
bool operator!=(const T& rhs) const { return !(*this == rhs); }
bool operator==(const maybe_null_dbg& rhs) const { tested_ = true; rhs.tested_ = true; return ptr_ == rhs.ptr_; }
bool operator!=(const maybe_null_dbg& rhs) const { return !(*this == rhs); }
T get() const {
fail_fast_assert(tested_);
#ifdef _MSC_VER
__assume(ptr_ != nullptr);
#endif
return ptr_;
}
operator T() const { return get(); }
T operator->() const { return get(); }
private:
const size_t ptee_size_ = sizeof(*ptr_); // T must be a pointer type
// unwanted operators...pointers only point to single objects!
// TODO ensure all arithmetic ops on this type are unavailable
maybe_null_dbg<T>& operator++() = delete;
maybe_null_dbg<T>& operator--() = delete;
maybe_null_dbg<T> operator++(int) = delete;
maybe_null_dbg<T> operator--(int) = delete;
maybe_null_dbg<T>& operator+(size_t) = delete;
maybe_null_dbg<T>& operator+=(size_t) = delete;
maybe_null_dbg<T>& operator-(size_t) = delete;
maybe_null_dbg<T>& operator-=(size_t) = delete;
T ptr_;
mutable bool tested_;
};
template<class T>
class maybe_null_ret
{
static_assert(std::is_assignable<T&, std::nullptr_t>::value, "T cannot be assigned nullptr.");
public:
maybe_null_ret() : ptr_(nullptr) {}
maybe_null_ret(std::nullptr_t) : ptr_(nullptr) {}
maybe_null_ret(const T& p) : ptr_(p) {}
maybe_null_ret(const maybe_null_ret& rhs) = default;
template <typename U, typename Dummy = std::enable_if_t<std::is_convertible<U, T>::value>>
maybe_null_ret(const not_null<U> &other) : ptr_(other.get())
{
}
template <typename U, typename Dummy = std::enable_if_t<std::is_convertible<U, T>::value>>
maybe_null_ret(const maybe_null_ret<U> &other) : ptr_(other.get())
{
}
template <typename U, typename Dummy = std::enable_if_t<std::is_convertible<U, T>::value>>
maybe_null_ret(const maybe_null_dbg<U> &other) : ptr_(other.get())
{
}
maybe_null_ret& operator=(const T& p) { if (ptr_ != p) { ptr_ = p; } return *this; }
maybe_null_ret& operator=(const maybe_null_ret& rhs) = default;
bool present() const { return ptr_ != nullptr; }
T get() const { return ptr_; }
operator T() const { return get(); }
T operator->() const { return get(); }
private:
// unwanted operators...pointers only point to single objects!
// TODO ensure all arithmetic ops on this type are unavailable
maybe_null_ret<T>& operator++() = delete;
maybe_null_ret<T>& operator--() = delete;
maybe_null_ret<T> operator++(int) = delete;
maybe_null_ret<T> operator--(int) = delete;
maybe_null_ret<T>& operator+(size_t) = delete;
maybe_null_ret<T>& operator+=(size_t) = delete;
maybe_null_ret<T>& operator-(size_t) = delete;
maybe_null_ret<T>& operator-=(size_t) = delete;
const size_t ptee_size_ = sizeof(*ptr_); // T must be a pointer type
T ptr_;
};
template<class T> using maybe_null = maybe_null_ret<T>;
} // namespace Guide
#endif // GSL_GSL_H