kakoune/src/utils.hh

#ifndef utils_hh_INCLUDED
#define utils_hh_INCLUDED

#include "exception.hh"
#include "assert.hh"

#include <memory>
#include <algorithm>
#include <vector>

namespace Kakoune
{
// *** Singleton ***
//
// Singleton helper class, every singleton type T should inherit
// from Singleton<T> to provide a consistent interface.
template<typename T>
class Singleton
{
public:
    Singleton(const Singleton&) = delete;
    Singleton& operator=(const Singleton&) = delete;

    static T& instance()
    {
        assert (ms_instance);
        return *ms_instance;
    }

    static void delete_instance()
    {
        delete ms_instance;
        ms_instance = nullptr;
    }

protected:
    Singleton()
    {
        assert(not ms_instance);
        ms_instance = static_cast<T*>(this);
    }

    ~Singleton()
    {
        assert(ms_instance == this);
        ms_instance = nullptr;
    }

private:
    static T* ms_instance;
};

template<typename T>
T* Singleton<T>::ms_instance = nullptr;

// *** safe_ptr: objects that assert nobody references them when they die ***

template<typename T>
class safe_ptr
{
public:
    safe_ptr() : m_ptr(nullptr) {}
    explicit safe_ptr(T* ptr) : m_ptr(ptr) { if (ptr) ptr->inc_safe_count(); }
    safe_ptr(const safe_ptr& other) : safe_ptr(other.m_ptr) {}
    safe_ptr(safe_ptr&& other) : m_ptr(other.m_ptr) { other.m_ptr = nullptr; }
    ~safe_ptr() { if (m_ptr) m_ptr->dec_safe_count(); }

    safe_ptr& operator=(const safe_ptr& other)
    {
        if (m_ptr != other.m_ptr)
        {
            if (m_ptr)
                m_ptr->dec_safe_count();
            m_ptr = other.m_ptr;
            if (m_ptr)
                m_ptr->inc_safe_count();
        }
        return *this;
   }

   safe_ptr& operator=(safe_ptr&& other)
   {
       if (m_ptr != other.m_ptr)
       {
           if (m_ptr)
               m_ptr->dec_safe_count();
           m_ptr = other.m_ptr;
           other.m_ptr = nullptr;
       }
       return *this;
   }

   void reset(T* ptr)
   {
       *this = safe_ptr(ptr);
   }

   bool operator== (const safe_ptr& other) const { return m_ptr == other.m_ptr; }
   bool operator!= (const safe_ptr& other) const { return m_ptr != other.m_ptr; }
   bool operator== (T* ptr) const { return m_ptr == ptr; }
   bool operator!= (T* ptr) const { return m_ptr != ptr; }

   T& operator*  () const { return *m_ptr; }
   T* operator-> () const { return m_ptr; }

   T* get() const { return m_ptr; }

   explicit operator bool() const { return m_ptr; }

private:
   T* m_ptr;
};

class SafeCountable
{
public:
   SafeCountable() : m_count(0) {}
   ~SafeCountable() { assert(m_count == 0); }

   void inc_safe_count() const { ++m_count; }
   void dec_safe_count() const { --m_count; assert(m_count >= 0); }

private:
   mutable int m_count;
};

// *** Containers helpers ***

template<typename Container>
struct ReversedContainer
{
    ReversedContainer(Container& container) : container(container) {}
    Container& container;

    decltype(container.rbegin()) begin() { return container.rbegin(); }
    decltype(container.rend())   end()   { return container.rend(); }
};

template<typename Container>
ReversedContainer<Container> reversed(Container& container)
{
    return ReversedContainer<Container>(container);
}


template<typename Container, typename T>
auto find(Container& container, const T& value) -> decltype(container.begin())
{
    return std::find(container.begin(), container.end(), value);
}

template<typename Container, typename T>
auto find_if(Container& container, T op) -> decltype(container.begin())
{
    return std::find_if(container.begin(), container.end(), op);
}


template<typename Container, typename T>
bool contains(const Container& container, const T& value)
{
    return (not container.empty()) and find(container, value) != container.end();
}

// *** On scope end ***
//
// on_scope_end provides a way to register some code to be
// executed when current scope closes.
//
// usage:
// auto cleaner = on_scope_end([]() { ... });
//
// This permits to cleanup c-style resources without implementing
// a wrapping class
template<typename T>
class OnScopeEnd
{
public:
    OnScopeEnd(T func) : m_func(func) {}
    ~OnScopeEnd() { m_func(); }
private:
    T m_func;
};

template<typename T>
OnScopeEnd<T> on_scope_end(T t)
{
    return OnScopeEnd<T>(t);
}

// *** Misc helper functions ***

template<typename T>
bool operator== (const std::unique_ptr<T>& lhs, T* rhs)
{
    return lhs.get() == rhs;
}

inline String escape(const String& name)
{
    return name.replace("([ \\t;])", R"(\\\1)");
}

template<typename T>
const T& clamp(const T& val, const T& min, const T& max)
{
    return (val < min ? min : (val > max ? max : val));
}

}

#endif // utils_hh_INCLUDED
LineAndColumn: segregate into WindowCoord and BufferCoord Having the same type to specify coordinates in window space or buffer space is error prone, now the compiler will tell if we use one for another. 2011-09-05 21:06:31 +02:00			`#ifndef utils_hh_INCLUDED`
			`#define utils_hh_INCLUDED`

assert: custom implementation 2011-09-09 21:24:18 +02:00			`#include "exception.hh"`
Utils: Singleton template and migration of the BufferManager Singletons are not autocreating, the application needs to create exactly one instance (I want to avoid implicit initialization order hell) 2011-09-23 16:26:53 +02:00			`#include "assert.hh"`
assert: custom implementation 2011-09-09 21:24:18 +02:00
utils: add operator== (const std::unique_ptr<T>&, T*) 2011-09-08 02:08:55 +02:00			`#include <memory>`
utils: add contains function 2011-10-17 23:05:22 +02:00			`#include <algorithm>`
Add and use a Set template class for recuring small sets 2013-01-11 14:28:13 +01:00			`#include <vector>`
utils: add operator== (const std::unique_ptr<T>&, T*) 2011-09-08 02:08:55 +02:00
LineAndColumn: segregate into WindowCoord and BufferCoord Having the same type to specify coordinates in window space or buffer space is error prone, now the compiler will tell if we use one for another. 2011-09-05 21:06:31 +02:00			`namespace Kakoune`
			`{`
Cleanup utils.hh, remove auto_raii in favor of on_scope_end 2012-06-12 20:45:13 +02:00			`// * Singleton *`
			`//`
			`// Singleton helper class, every singleton type T should inherit`
			`// from Singleton<T> to provide a consistent interface.`
Utils: Singleton template and migration of the BufferManager Singletons are not autocreating, the application needs to create exactly one instance (I want to avoid implicit initialization order hell) 2011-09-23 16:26:53 +02:00			`template<typename T>`
			`class Singleton`
			`{`
			`public:`
			`Singleton(const Singleton&) = delete;`
			`Singleton& operator=(const Singleton&) = delete;`

			`static T& instance()`
			`{`
			`assert (ms_instance);`
			`return *ms_instance;`
			`}`

			`static void delete_instance()`
			`{`
Cleanup utils.hh, remove auto_raii in favor of on_scope_end 2012-06-12 20:45:13 +02:00			`delete ms_instance;`
			`ms_instance = nullptr;`
Utils: Singleton template and migration of the BufferManager Singletons are not autocreating, the application needs to create exactly one instance (I want to avoid implicit initialization order hell) 2011-09-23 16:26:53 +02:00			`}`

			`protected:`
			`Singleton()`
			`{`
			`assert(not ms_instance);`
			`ms_instance = static_cast<T*>(this);`
			`}`

			`~Singleton()`
			`{`
			`assert(ms_instance == this);`
			`ms_instance = nullptr;`
			`}`

			`private:`
			`static T* ms_instance;`
			`};`

			`template<typename T>`
			`T* Singleton<T>::ms_instance = nullptr;`

Add SafeCountable and safe_ptr classes safe_ptr is a smart pointer which manage a safe count in pointed objects. SafeCountable provides the interface needed for safe_ptr and assert the safe count is zero in destructor. This permits to have pointers that guarantees their pointed object is alive. 2012-06-28 13:42:55 +02:00			`// * safe_ptr: objects that assert nobody references them when they die *`

			`template<typename T>`
			`class safe_ptr`
			`{`
			`public:`
			`safe_ptr() : m_ptr(nullptr) {}`
			`explicit safe_ptr(T* ptr) : m_ptr(ptr) { if (ptr) ptr->inc_safe_count(); }`
			`safe_ptr(const safe_ptr& other) : safe_ptr(other.m_ptr) {}`
			`safe_ptr(safe_ptr&& other) : m_ptr(other.m_ptr) { other.m_ptr = nullptr; }`
			`~safe_ptr() { if (m_ptr) m_ptr->dec_safe_count(); }`

			`safe_ptr& operator=(const safe_ptr& other)`
			`{`
			`if (m_ptr != other.m_ptr)`
			`{`
			`if (m_ptr)`
			`m_ptr->dec_safe_count();`
			`m_ptr = other.m_ptr;`
			`if (m_ptr)`
			`m_ptr->inc_safe_count();`
			`}`
			`return *this;`
			`}`

add safe_ptr::operator=(safe_ptr&&) and safe_ptr::reset(T*) 2012-06-30 00:33:36 +02:00			`safe_ptr& operator=(safe_ptr&& other)`
			`{`
			`if (m_ptr != other.m_ptr)`
			`{`
			`if (m_ptr)`
			`m_ptr->dec_safe_count();`
			`m_ptr = other.m_ptr;`
			`other.m_ptr = nullptr;`
			`}`
			`return *this;`
			`}`

			`void reset(T* ptr)`
			`{`
			`*this = safe_ptr(ptr);`
			`}`

Add SafeCountable and safe_ptr classes safe_ptr is a smart pointer which manage a safe count in pointed objects. SafeCountable provides the interface needed for safe_ptr and assert the safe count is zero in destructor. This permits to have pointers that guarantees their pointed object is alive. 2012-06-28 13:42:55 +02:00			`bool operator== (const safe_ptr& other) const { return m_ptr == other.m_ptr; }`
			`bool operator!= (const safe_ptr& other) const { return m_ptr != other.m_ptr; }`
			`bool operator== (T* ptr) const { return m_ptr == ptr; }`
			`bool operator!= (T* ptr) const { return m_ptr != ptr; }`

			`T& operator* () const { return *m_ptr; }`
			`T* operator-> () const { return m_ptr; }`

			`T* get() const { return m_ptr; }`

do not use our broken safe bool, c++11 explicit bool conversion is better 2012-10-02 14:18:34 +02:00			`explicit operator bool() const { return m_ptr; }`
Add SafeCountable and safe_ptr classes safe_ptr is a smart pointer which manage a safe count in pointed objects. SafeCountable provides the interface needed for safe_ptr and assert the safe count is zero in destructor. This permits to have pointers that guarantees their pointed object is alive. 2012-06-28 13:42:55 +02:00
			`private:`
			`T* m_ptr;`
			`};`

			`class SafeCountable`
			`{`
			`public:`
			`SafeCountable() : m_count(0) {}`
			`~SafeCountable() { assert(m_count == 0); }`

SafeCountable::m_count is mutable so that we can have safe_ptr<const T> 2012-11-12 20:07:05 +01:00			`void inc_safe_count() const { ++m_count; }`
			`void dec_safe_count() const { --m_count; assert(m_count >= 0); }`
Add SafeCountable and safe_ptr classes safe_ptr is a smart pointer which manage a safe count in pointed objects. SafeCountable provides the interface needed for safe_ptr and assert the safe count is zero in destructor. This permits to have pointers that guarantees their pointed object is alive. 2012-06-28 13:42:55 +02:00
			`private:`
SafeCountable::m_count is mutable so that we can have safe_ptr<const T> 2012-11-12 20:07:05 +01:00			`mutable int m_count;`
Add SafeCountable and safe_ptr classes safe_ptr is a smart pointer which manage a safe count in pointed objects. SafeCountable provides the interface needed for safe_ptr and assert the safe count is zero in destructor. This permits to have pointers that guarantees their pointed object is alive. 2012-06-28 13:42:55 +02:00			`};`

Cleanup utils.hh, remove auto_raii in favor of on_scope_end 2012-06-12 20:45:13 +02:00			`// * Containers helpers *`

			`template<typename Container>`
			`struct ReversedContainer`
			`{`
			`ReversedContainer(Container& container) : container(container) {}`
			`Container& container;`

			`decltype(container.rbegin()) begin() { return container.rbegin(); }`
			`decltype(container.rend()) end() { return container.rend(); }`
			`};`

			`template<typename Container>`
			`ReversedContainer<Container> reversed(Container& container)`
			`{`
			`return ReversedContainer<Container>(container);`
			`}`


add a find(container, value) utility function 2012-01-25 23:31:47 +01:00			`template<typename Container, typename T>`
			`auto find(Container& container, const T& value) -> decltype(container.begin())`
			`{`
			`return std::find(container.begin(), container.end(), value);`
			`}`

ClientManager: support naming clients and accessing client's context by name 2012-12-03 18:56:53 +01:00			`template<typename Container, typename T>`
			`auto find_if(Container& container, T op) -> decltype(container.begin())`
			`{`
			`return std::find_if(container.begin(), container.end(), op);`
			`}`


utils: add contains function 2011-10-17 23:05:22 +02:00			`template<typename Container, typename T>`
			`bool contains(const Container& container, const T& value)`
			`{`
fix contains for empty containers 2013-01-29 18:55:32 +01:00			`return (not container.empty()) and find(container, value) != container.end();`
utils: add contains function 2011-10-17 23:05:22 +02:00			`}`

Cleanup utils.hh, remove auto_raii in favor of on_scope_end 2012-06-12 20:45:13 +02:00			`// * On scope end *`
			`//`
			`// on_scope_end provides a way to register some code to be`
			`// executed when current scope closes.`
			`//`
			`// usage:`
			`// auto cleaner = on_scope_end([]() { ... });`
			`//`
			`// This permits to cleanup c-style resources without implementing`
			`// a wrapping class`
Utils: add on_scope_end utility on_scope_end permits to register a functor to be called at scope end (either exception thrown or normal scope end). this is usefull for cleanup code that must be run. usage: auto cleaner = on_scope_end([]() { cleanup(); }); 2011-12-20 20:18:00 +01:00			`template<typename T>`
			`class OnScopeEnd`
			`{`
			`public:`
			`OnScopeEnd(T func) : m_func(func) {}`
			`~OnScopeEnd() { m_func(); }`
			`private:`
			`T m_func;`
			`};`

			`template<typename T>`
			`OnScopeEnd<T> on_scope_end(T t)`
			`{`
			`return OnScopeEnd<T>(t);`
			`}`
Window: use an idvaluemap to store highlighters 2011-12-02 15:20:11 +01:00
Cleanup utils.hh, remove auto_raii in favor of on_scope_end 2012-06-12 20:45:13 +02:00			`// * Misc helper functions *`

			`template<typename T>`
			`bool operator== (const std::unique_ptr<T>& lhs, T* rhs)`
			`{`
			`return lhs.get() == rhs;`
			`}`

escape whitespaces in filename or buffername completions 2012-08-29 21:52:17 +02:00			`inline String escape(const String& name)`
			`{`
			`return name.replace("([ \\t;])", R"(\\\1)");`
			`}`

move clamp to utils.hh 2012-10-02 14:08:09 +02:00			`template<typename T>`
			`const T& clamp(const T& val, const T& min, const T& max)`
			`{`
			`return (val < min ? min : (val > max ? max : val));`
			`}`

LineAndColumn: segregate into WindowCoord and BufferCoord Having the same type to specify coordinates in window space or buffer space is error prone, now the compiler will tell if we use one for another. 2011-09-05 21:06:31 +02:00			`}`

			`#endif // utils_hh_INCLUDED`