...one of the most highly
regarded and expertly designed C++ library projects in the
world.
— Herb Sutter and Andrei
Alexandrescu, C++
Coding Standards
A tuple (or n-tuple) is a fixed size collection of elements. Pairs, triples, quadruples etc. are tuples. In a programming language, a tuple is a data object containing other objects as elements. These element objects may be of different types.
Tuples are convenient in many circumstances. For instance, tuples make it easy to define functions that return more than one value.
Some programming languages, such as ML, Python and Haskell, have built-in tuple constructs. Unfortunately C++ does not. To compensate for this "deficiency", the Boost Tuple Library implements a tuple construct using templates.
Advanced features (describes some metafunctions etc.).
Rationale behind some design/implementation decisions.
To use the library, just include:
#include "boost/tuple/tuple.hpp"
Comparison operators can be included with:
#include "boost/tuple/tuple_comparison.hpp"
To use tuple input and output operators,
#include "boost/tuple/tuple_io.hpp"
Both tuple_io.hpp
and tuple_comparison.hpp
include tuple.hpp
.
All definitions are in namespace ::boost::tuples
, but the most common names are lifted to namespace ::boost
with using declarations. These names are: tuple
, make_tuple
, tie
and get
. Further, ref
and cref
are defined directly under the ::boost
namespace.
A tuple type is an instantiation of the tuple
template.
The template parameters specify the types of the tuple elements.
The current version supports tuples with 0-10 elements.
If necessary, the upper limit can be increased up to, say, a few dozen elements.
The data element can be any C++ type.
Note that void
and plain function types are valid
C++ types, but objects of such types cannot exist.
Hence, if a tuple type contains such types as elements, the tuple type
can exist, but not an object of that type.
There are natural limitations for element types that cannot
be be copied, or that are not default constructible (see 'Constructing tuples'
below).
For example, the following definitions are valid tuple instantiations (A
, B
and C
are some user defined classes):
tuple<int>
tuple<double&, const double&, const double, double*, const double*>
tuple<A, int(*)(char, int), B(A::*)(C&), C>
tuple<std::string, std::pair<A, B> >
tuple<A*, tuple<const A*, const B&, C>, bool, void*>
The tuple constructor takes the tuple elements as arguments. For an n-element tuple, the constructor can be invoked with k arguments, where 0 <= k <= n. For example:
tuple<int, double>()
tuple<int, double>(1)
tuple<int, double>(1, 3.14)
If no initial value for an element is provided, it is default initialized (and hence must be default initializable). For example.
class X {
X();
public:
X(std::string);
};
tuple<X,X,X>() // error: no default constructor for X
tuple<X,X,X>(string("Jaba"), string("Daba"), string("Duu")) // ok
In particular, reference types do not have a default initialization:
tuple<double&>() // error: reference must be
// initialized explicitly
double d = 5;
tuple<double&>(d) // ok
tuple<double&>(d+3.14) // error: cannot initialize
// non-const reference with a temporary
tuple<const double&>(d+3.14) // ok, but dangerous:
// the element becomes a dangling reference
Using an initial value for an element that cannot be copied, is a compile time error:
class Y {
Y(const Y&);
public:
Y();
};
char a[10];
tuple<char[10], Y>(a, Y()); // error, neither arrays nor Y can be copied
tuple<char[10], Y>(); // ok
Note particularly that the following is perfectly ok:
Y y;
tuple<char(&)[10], Y&>(a, y);
It is possible to come up with a tuple type that cannot be constructed.
This occurs if an element that cannot be initialized has a lower
index than an element that requires initialization.
For example: tuple<char[10], int&>
.
In sum, the tuple construction is semantically just a group of individual elementary constructions.
make_tuple
function
Tuples can also be constructed using the make_tuple
(cf. std::make_pair
) helper functions.
This makes the construction more convenient, saving the programmer from explicitly specifying the element types:
tuple<int, int, double> add_multiply_divide(int a, int b) {
return make_tuple(a+b, a*b, double(a)/double(b));
}
By default, the element types are deduced to the plain non-reference types. E.g:
void foo(const A& a, B& b) {
...
make_tuple(a, b);
The make_tuple
invocation results in a tuple of type tuple<A, B>
.
Sometimes the plain non-reference type is not desired, e.g. if the element type cannot be copied.
Therefore, the programmer can control the type deduction and state that a reference to const or reference to
non-const type should be used as the element type instead.
This is accomplished with two helper template functions: ref
and cref
.
Any argument can be wrapped with these functions to get the desired type.
The mechanism does not compromise const correctness since a const object wrapped with ref
results in a tuple element with const reference type (see the fifth code line below).
For example:
A a; B b; const A ca = a;
make_tuple(cref(a), b); // creates tuple<const A&, B>
make_tuple(ref(a), b); // creates tuple<A&, B>
make_tuple(ref(a), cref(b)); // creates tuple<A&, const B&>
make_tuple(cref(ca)); // creates tuple<const A&>
make_tuple(ref(ca)); // creates tuple<const A&>
Array arguments to make_tuple
functions are deduced to reference to const types by default; there is no need to wrap them with cref
. For example:
make_tuple("Donald", "Daisy");
This creates an object of type tuple<const char (&)[7], const char (&)[6]>
(note that the type of a string literal is an array of const characters, not const char*
).
However, to get make_tuple
to create a tuple with an element of a
non-const array type one must use the ref
wrapper.
Function pointers are deduced to the plain non-reference type, that is, to plain function pointer.
A tuple can also hold a reference to a function,
but such a tuple cannot be constructed with make_tuple
(a const qualified function type would result, which is illegal):
void f(int i);
...
make_tuple(&f); // tuple<void (*)(int)>
...
tuple<tuple<void (&)(int)> > a(f) // ok
make_tuple(f); // not ok
Tuple elements are accessed with the expression:
t.get<N>()
or
get<N>(t)
where t
is a tuple object and N
is a constant integral expression specifying the index of the element to be accessed.
Depending on whether t
is const or not, get
returns the N
th element as a reference to const or
non-const type.
The index of the first element is 0 and thus
N
must be between 0 and k-1
, where k
is the number of elements in the tuple.
Violations of these constrains are detected at compile time. Examples:
double d = 2.7; A a;
tuple<int, double&, const A&> t(1, d, a);
const tuple<int, double&, const A&> ct = t;
...
int i = get<0>(t); i = t.get<0>(); // ok
int j = get<0>(ct); // ok
get<0>(t) = 5; // ok
get<0>(ct) = 5; // error, can't assign to const
...
double e = get<1>(t); // ok
get<1>(t) = 3.14; // ok
get<2>(t) = A(); // error, can't assign to const
A aa = get<3>(t); // error: index out of bounds
...
++get<0>(t); // ok, can be used as any variable
Note! The member get functions are not supported with MS Visual C++ compiler.
Further, the compiler has trouble with finding the non-member get functions without an explicit namespace qualifier.
Hence, all get
calls should be qualified as: tuples::get<N>(a_tuple)
when writing code that shoud compile with MSVC++ 6.0.
A tuple can be copy constructed from another tuple, provided that the element types are element-wise copy constructible. Analogously, a tuple can be assigned to another tuple, provided that the element types are element-wise assignable. For example:
class A {};
class B : public A {};
struct C { C(); C(const B&); };
struct D { operator C() const; };
tuple<char, B*, B, D> t;
...
tuple<int, A*, C, C> a(t); // ok
a = t; // ok
In both cases, the conversions performed are: char -> int
, B* -> A*
(derived class pointer to base class pointer), B -> C
(a user defined conversion) and D -> C
(a user defined conversion).
Note that assignment is also defined from std::pair
types:
tuple<float, int> a = std::make_pair(1, 'a');
Tuples reduce the operators ==, !=, <, >, <=
and >=
to the corresponding elementary operators.
This means, that if any of these operators is defined between all elements of two tuples, then the same operator is defined between the tuples as well.
The equality operators for two tuples a
and b
are defined as:
a == b
iff for each i
: ai == bi
a != b
iff exists i
: ai != bi
<, >, <=
and >=
implement a lexicographical ordering.
Note that an attempt to compare two tuples of different lengths results in a compile time error.
Also, the comparison operators are "short-circuited": elementary comparisons start from the first elements and are performed only until the result is clear.Examples:
tuple<std::string, int, A> t1(std::string("same?"), 2, A());
tuple<std::string, long, A> t2(std::string("same?"), 2, A());
tuple<std::string, long, A> t3(std::string("different"), 3, A());
bool operator==(A, A) { std::cout << "All the same to me..."; return true; }
t1 == t2; // true
t1 == t3; // false, does not print "All the..."
Tiers are tuples, where all elements are of non-const reference types.
They are constructed with a call to the tie
function template (cf. make_tuple
):
int i; char c; double d;
...
tie(i, c, a);
The above tie
function creates a tuple of type tuple<int&, char&, double&>
.
The same result could be achieved with the call make_tuple(ref(i), ref(c), ref(a))
.
A tuple that contains non-const references as elements can be used to 'unpack' another tuple into variables. E.g.:
int i; char c; double d;
tie(i, c, d) = make_tuple(1,'a', 5.5);
std::cout << i << " " << c << " " << d;
This code prints 1 a 5.5
to the standard output stream.
A tuple unpacking operation like this is found for example in ML and Python.
It is convenient when calling functions which return tuples.
The tying mechanism works with std::pair
templates as well:
int i; char c;
tie(i, c) = std::make_pair(1, 'a');
ignore
which allows you to ignore an element assigned by a tuple.
The idea is that a function may return a tuple, only part of which you are interested in. For example (note, that ignore
is under the tuples
subnamespace):
char c;
tie(tuples::ignore, c) = std::make_pair(1, 'a');
The global operator<<
has been overloaded for std::ostream
such that tuples are
output by recursively calling operator<<
for each element.
Analogously, the global operator>>
has been overloaded to extract tuples from std::istream
by recursively calling operator>>
for each element.
The default delimiter between the elements is space, and the tuple is enclosed in parenthesis. For Example:
tuple<float, int, std::string> a(1.0f, 2, std::string("Howdy folks!");
cout << a;
outputs the tuple as: (1.0 2 Howdy folks!)
The library defines three manipulators for changing the default behavior:
set_open(char)
defines the character that is output before the first
element.set_close(char)
defines the character that is output after the
last element.set_delimiter(char)
defines the delimiter character between
elements.tuples
subnamespace.
For example:
cout << tuples::set_open('[') << tuples::set_close(']') << tuples::set_delimiter(',') << a;
outputs the same tuple a
as: [1.0,2,Howdy folks!]
The same manipulators work with operator>>
and istream
as well. Suppose the cin
stream contains the following data:
(1 2 3) [4:5]
The code:
tuple<int, int, int> i;
tuple<int, int> j;
cin >> i;
cin >> tuples::set_open('[') >> tuples::set_close(']') >> tules::set_delimiter(':');
cin >> j;
reads the data into the tuples i
and j
.
Note that extracting tuples with std::string
or C-style string
elements does not generally work, since the streamed tuple representation may not be unambiguously
parseable.
class hand_made_tuple {
A a; B b; C c;
public:
hand_made_tuple(const A& aa, const B& bb, const C& cc)
: a(aa), b(bb), c(cc) {};
A& getA() { return a; };
B& getB() { return b; };
C& getC() { return c; };
};
hand_made_tuple hmt(A(), B(), C());
hmt.getA(); hmt.getB(); hmt.getC();
and this code:
tuple<A, B, C> t(A(), B(), C());
t.get<0>(); t.get<1>(); t.get<2>();
Note, that there are widely used compilers (e.g. bcc 5.5.1) which fail to optimize this kind of tuple usage.
Depending on the optimizing ability of the compiler, the tier mechanism may have a small performance penalty compared to using
non-const reference parameters as a mechanism for returning multiple values from a function.
For example, suppose that the following functions f1
and f2
have equivalent functionalities:
void f1(int&, double&);
tuple<int, double> f2();
Then, the call #1 may be slightly faster than #2 in the code below:
int i; double d;
...
f1(i,d); // #1
tie(i,d) = f2(); // #2
See
[1,
2]
for more in-depth discussions about efficiency.
Compiling tuples can be slow due to the excessive amount of template instantiations.
Depending on the compiler and the tuple length, it may be more than 10 times slower to compile a tuple construct, compared to compiling an equivalent explicitly written class, such as the hand_made_tuple
class above.
However, as a realistic program is likely to contain a lot of code in addition to tuple definitions, the difference is probably unnoticeable.
Compile time increases between 5 to 10 percentages were measured for programs which used tuples very frequently.
With the same test programs, memory consumption of compiling increased between 22% to 27%. See
[1,
2]
for details.
The library code is(?) standard C++ and thus the library works with a standard conforming compiler. Below is a list of compilers and known problems with each compiler:
Compiler | Problems |
gcc 2.95 | - |
edg 2.44 | - |
Borland 5.5 | Can't use function pointers or member pointers as tuple elements |
Metrowerks 6.2 | Can't use ref and cref wrappers |
MS Visual C++ | No reference elements (tie still works). Can't use ref and cref wrappers |
[1] Järvi J.: Tuples and multiple return values in C++, TUCS Technical Report No 249, 1999.
[2] Järvi J.: ML-Style Tuple Assignment in Standard C++ - Extending the Multiple Return Value Formalism, TUCS Technical Report No 267, 1999.
[3] Järvi J.:Tuple Types and Multiple Return Values, C/C++ Users Journal, August 2001.
Last modified 2003-09-07
© Copyright Jaakko Järvi 2001. Permission to copy, use, modify, sell and distribute this software and its documentation is granted provided this copyright notice appears in all copies. This software and its documentation is provided "as is" without express or implied warranty, and with no claim as to its suitability for any purpose.