phoenix/doc/introduction.qbk

[/==============================================================================
    Copyright (C) 2001-2010 Joel de Guzman
    Copyright (C) 2001-2005 Dan Marsden
    Copyright (C) 2001-2010 Thomas Heller

    Distributed under the Boost Software License, Version 1.0. (See accompanying
    file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
===============================================================================/]

[section Introduction]

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The Phoenix library enables FP techniques such as higher order functions,
/lambda/ (unnamed functions), /currying/ (partial function application) and lazy
evaluation in C++. The focus is more on usefulness and practicality than purity,
elegance and strict adherence to FP principles.

FP is a programming discipline that is not at all tied to a specific language.
FP as a programming discipline can, in fact, be applied to many programming
languages. In the realm of C++ for instance, we are seeing more FP techniques
being applied. C++ is sufficiently rich to support at least some of the most
important facets of FP. C++ is a multiparadigm programming language. It is not
only procedural. It is not only object oriented. Beneath the core of the
standard C++ library, a closer look into STL gives us a glimpse of FP already in
place. It is obvious that the authors of STL know and practice FP. In the near
future, we shall surely see more FP trickle down into the mainstream.

The truth is, most of the FP techniques can coexist quite well with the standard
object oriented and imperative programming paradigms. When we are using STL
algorithms and functors (function objects) for example, we are already doing FP.
Phoenix is an evolutionary next step.

[endsect]