Document number:  

N3508
Date: 2013-01-11
Project: Programming Language C++
Reply-to: Beman Dawes <bdawes at acm dot org>
Kevlin Henney <kevlin at curbralan dot com>

Any Library Proposal (Revision 2)

Introduction
Revision History
Motivation and Design
Design paths not taken
Examples
FAQ
Do list
Acknowledgements
Proposed Wording
    ValueType Requirements
    Header <any> synopsis
    Class bad_any_cast
    Class any
    Non-member functions
 

Introduction

This paper proposes a type-safe container for single values of value types. The C++ standards committee's Library Working Group reviewed the proposal at the October, 2012, meeting and is tentatively targeting the proposal for the C++ Standard update referred to as C++14. The proposal would also be suitable for a Library Technical Specification (TS).

The proposal is based on the Boost Any Library (see www.boost.org/libs/any). The Boost version of library has been in wide use for over a decade, and the library has been implemented at least twice in addition to the Boost implementation. The proposal is a pure addition to the standard library, requires no modifications to any C++11 standard library components, requires no compiler support, and will have no effect on existing namespace-disciplined code.

Revision History

N3508 - Revision 2

N3390 - Revision 1

N1939 - Initial paper

Motivation and Design

There are times when a generic (in the sense of general as opposed to template-based programming) type is needed: variables that are truly variable, accommodating values of many other more specific types rather than C++'s normal strict and static types. We can distinguish three basic kinds of generic type:

  1. Converting types that can hold one of a number of possible value types, e.g. int and string, and freely convert between them, for instance interpreting 5 as "5" or vice-versa. Such types are common in scripting and other interpreted languages. boost::lexical_cast supports such conversion functionality.
     
  2. Discriminated types that contain values of different types but do not attempt conversion between them, i.e. 5 is held strictly as an int and is not implicitly convertible either to "5" or to 5.0. Their indifference to interpretation but awareness of type effectively makes them safe, generic containers of single values, with no scope for surprises from ambiguous conversions.
     
  3. Indiscriminate types that can refer to anything but are oblivious to the actual underlying type, entrusting all forms of access and interpretation to the programmer. This niche is dominated by void *, which offers plenty of scope for surprising, undefined behavior.

The proposed any class (based on the class of the same name described in "Valued Conversions" by Kevlin Henney, C++ Report 12(7), July/August 2000) is a variant value type based on the second category. It supports copying of any value type and safe checked extraction of that value strictly against its type.

Design paths not taken

A similar design, offering more appropriate operators, could be used for a generalized function adaptor, a generalized iterator adaptor, and other object types that need uniform runtime treatment but support only compile-time template parameter conformance. Such components are not proposed here.

Examples

The following code demonstrates the syntax for using implicit conversions to and copying of any objects:

#include <list>
#include <any>

using std::tbd::any_cast;
using std::tbd::any;

typedef std::list<any> many;

void append_int(many& values, int value)
{
    any to_append = value;
    values.push_back(to_append);
}

void append_string(many& values, const std::string& value)
{
    values.push_back(value);
}

void append_char_ptr(many& values, const char* value)
{
    values.push_back(value);
}

void append_any(many& values, const any& value)
{
    values.push_back(value);
}

void append_nothing(many& values)
{
    values.push_back(any());
}

The following predicates follow from the previous definitions and demonstrate the use of queries on any objects:

bool is_empty(const any& operand)
{
    return operand.empty();
}

bool is_int(const any& operand)
{
    return operand.type() == typeid(int);
}

bool is_char_ptr(const any& operand)
{
    try
    {
        any_cast<const char *>(operand);
        return true;
    }
    catch(const std::tbd::bad_any_cast&)
    {
        return false;
    }
}

bool is_string(const any& operand)
{
    return any_cast<std::string*>(&operand);
}

void count_all(many& values, std::ostream& out)
{
    out << "#empty == "
        << std::count_if(values.begin(), values.end(), is_empty) << std::endl;
    out << "#int == "
        << std::count_if(values.begin(), values.end(), is_int) << std::endl;
    out << "#const char * == "
        << std::count_if(values.begin(), values.end(), is_char_ptr) << std::endl;
    out << "#string == "
        << std::count_if(values.begin(), values.end(), is_string) << std::endl;
}

The following type, patterned after the OMG's Property Service, defines name-value pairs for arbitrary value types:

struct property
{
    property();
    property(const std::string&, const any&);

    std::string name;
    any value;
};

typedef std::list<property> properties;

The following base class demonstrates one approach to runtime polymorphism based callbacks that also require arbitrary argument types. The absence of virtual member templates requires that different solutions have different trade-offs in terms of efficiency, safety, and generality. Using a checked variant type offers one approach:

class consumer
{
public:
    virtual void notify(const any&) = 0;
    ...
};

FAQ

What is the relationship between Boost.any and Boost.variant?

Boost::any is like a "typesafe void*", while Boost::variant is a "typesafe union".

Do list

Acknowledgements

Sean Parent and Daniel Krügler provided numerous comments, corrections, and suggestions, and were particularly helpful applying C++11 features to the library. Sean also provided a copy of his C++ implementation. Sean has done extensive experiments with real C++11 compilers on issues such as pass-by-value versus pass-by-reference. Daniel's expertise with library standardese markedly improved the proposed wording.

Proposed Wording

Add the following section to the working paper at a location to be determined by the project editor:

Any

This clause describes components that C++ programs may use to perform operations on objects of a discriminated type.

[Note: The discriminated type may contain values of different types but does not attempt conversion between them, i.e. 5 is held strictly as an int and is not implicitly convertible either to "5" or to 5.0. This indifference to interpretation but awareness of type effectively allows safe, generic containers of single values, with no scope for surprises from ambiguous conversions. -- end note.]

ValueType Requirements

A ValueType type shall meet the requirements for CopyConstructible [copyconstructible]. 

[Note: Values are strongly informational objects for which identity is not significant, i.e. the focus is principally on their state content and any behavior organized around that. Another distinguishing feature of values is their granularity: normally fine-grained objects representing simple concepts in the system such as quantities.

As the emphasis of a value lies in its state not its identity, values can be copied and typically assigned one to another, requiring the explicit or implicit definition of a public copy constructor. Values typically live within other scopes, i.e. within objects or blocks, rather than on the heap. Values are therefore normally passed around and manipulated directly as variables or through references, but not as pointers that emphasize identity and indirection. --end note]

Header <any> synopsis

Synopsis additions from the prior version are in green with underscores, deletions are in red with strikethroughs.

namespace std { namespace tbd {
  class bad_any_cast : public std::bad_cast
  {
  public:
    virtual const char* what() const;
  };

  class any
  {
  public:
    // construct/destruct
    any() noexcept;

    any(const any& other);
    any(any&& x) noexcept;

    template <typename ValueType>
      any(ValueType value);

    template <class Allocator>
      any(allocator_arg_t, const Allocator& a);

    template <class Allocator, typename ValueType>
      any(allocator_arg_t, const Allocator& a, ValueType value);

   ~any() noexcept;
  
    // assignments
    any& operator=(any rhs);
    any& operator=(const any& rhs);
    any& operator=(any&& rhs) noexcept;

    template <typename ValueType>
      any& operator=(ValueType rhs);

    // modifiers
    any& void swap(any& rhs) noexcept;

    // observers
    bool empty() const noexcept;
    const type_info& type() const noexcept;
  };

  void swap(any& x, any& y) noexcept;

  template<typename ValueType>
    ValueType any_cast(const any& operand);

  template<typename ValueType>
    ValueType any_cast(any& operand);

  template<typename ValueType ValueTypePtr>
    ValueType ValueTypePtr any_cast(const any* operand) noexcept;

  template<typename ValueType ValueTypePtr>
    ValueTypePtr ValueType any_cast(any* operand) noexcept;

}}

Class bad_any_cast

Objects of type bad_any_cast are thrown by a failed any_cast.

Class any

Objects of class any hold instances of any type that satisfies the ValueType requirements.

any construct/destruct

any() noexcept;

Postconditions: this->empty()

any(const any& other);

Effects: Copies content of other into a new instance, so that any content is equivalent in both type and value to other, or empty if other is empty.

Throws: bad_alloc or any exceptions arising from the copy constructor of the contained type.

any(any&& other) noexcept;

Effects: Moves content of other into a new instance, so that any content is equivalent in both type and value to the original content of other, or empty if other is empty.

template<typename ValueType>
  any(ValueType value);

Effects: Constructs an object of type any with initial content equivalent in both type and value to value.

Throws: bad_alloc or any exceptions arising from the copy constructor of the contained type.

template <class Allocator>
  any(allocator_arg_t, const Allocator& a);
template <class Allocator, typename ValueType>
  any(allocator_arg_t, const Allocator& a, ValueType value);

Requires: Allocator shall meet the requirements for an Allocator ([allocator.requirements]).

Effects: Equivalent to the preceding constructors except that the stored value is constructed with uses-allocator construction ([allocator.uses.construction]).

Throws: bad_alloc or any exceptions arising from the copy constructor of the contained type.

[Note: Implementations are encouraged to avoid the use of dynamically allocated memory for small contained types, for example, where the object constructed is holding only an int. —end note ]

~any();

Effects: Releases resources.

any assignments

any& operator=(const any& rhs);

Effects: any(rhs).swap(*this), however, no effects if an exception is thrown.

Throws: bad_alloc or any exceptions arising from the copy constructor of the contained type.

any& operator=(any&& rhs) noexcept;

Effects: Moves content of rhs to *this, so that any content is equivalent in both type and value to the original content of rhs, or empty if rhs is empty.

Postconditions: rhs.empty().

template<typename ValueType>
  any& operator=(ValueType rhs);

Effects: any(rhs).swap(*this), however, no effects if an exception is thrown.

Returns: *this

Throws: bad_alloc or any exceptions arising from the copy constructor of the contained type.

any modifiers

void swap(any& rhs) noexcept;

Effects: Exchange of the contents of *this and rhs.

any observers

bool empty() const noexcept;

Returns: true if instance is empty, otherwise false.

const type_info& type() const noexcept;

Returns: The typeid of the contained value if instance is non-empty, otherwise typeid(void).

[Note: Useful for querying against types known either at compile time or only at runtime. --end note]

Non-member functions

void swap(any& x, any& y) noexcept; 
Effects: x.swap(y).
template<typename ValueType>
  ValueType any_cast(const any& operand);
template<typename ValueType>
  ValueType any_cast(any& operand);

Returns: The value contained by operand.

Throws: bad_any_cast if operand.type() != typeid(remove_reference<ValueType>::type).

[Note: For consistency with the C++ keyword casts, a copy is returned.--end note.]

[Example:

any x;

x = 51;
any_cast<int&>(x) = 42;

--end example]

template<typename ValueTypePtr>
  ValueTypePtr any_cast(const any* operand) noexcept;
template<typename ValueTypePtr>
  ValueTypePtr any_cast(any* operand) noexcept;

Returns: If operand != nullptr && operand->type() == typeid(remove_pointer<ValueTypePtr>::type), a pointer to the value contained by operand, otherwise a null pointer. The returned pointer is const qualified for the signature with a const argument.

[Example:

bool is_string(const any& operand)
{
  return any_cast<std::string*>(&operand);
}

--end example]


© Copyright 2001, 2012 Kevlin Henney
© Copyright 2006, 2012 Beman Dawes

Revised 2013-01-11