qpic 1.0.1

####################################
⟨q\|pic⟩: Quantum circuits made easy
####################################

.. image:: docs/images/qpic.png

**************************************************************
A compiler from quantum circuits to graphical representations.
**************************************************************

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.. TODO: Publish badge after porting to ReadTheDocs
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- Free software: GNU GPLv3 license
- Documentation: `⟨q\|pic⟩ manual <doc/qpic_doc.pdf>`_

Contents
========
* `Features <#features>`_
* `Examples <#examples>`_
* `Using ⟨q\|pic⟩ <#using-qpic>`_

Features
========

The ⟨q\|pic⟩ language provides a concise, readable, ASCII format for
describing quantum circuits. ``qpic`` converts ⟨q\|pic⟩ files to the
scientific paper standard of LaTeX using TikZ graphic commands.

- Automatic placement of circuit components.
- Human readable.
- Input ⟨q\|pic⟩ syntax can be produced by other scripts.
- Can be included in LaTeX documents in TikZ or PDF form.

⟨q\|pic⟩ produces high quality graphics quickly. The following graphic
illustrating part of a ripple carry adder

.. image:: docs/images/Adder_CDKM_MAJ.png

is compiled from the ⟨q\|pic⟩ code

::

a W a a\oplus{c}
b W b b\oplus{c}
c W c \mbox{MAJ}(a,b,c)

a b c G \rotatebox{90}{MAJ}
=
+b c
+a c
a b +c

Examples
========

Basic quantum teleportation circuit
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

.. image:: docs/images/BasicTeleportation.png

This classic diagram derives from the following code:

::

a W |\psi\rangle
b c W |\beta_{00}\rangle<
c W |\psi\rangle
a +b
a H
a b M
c X b:owire
c Z a:owire

Decorated quantum teleportation circuit
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

⟨q\|pic⟩ has additional features for commenting or highlighting parts of
a circuit.

.. image:: docs/images/QuantumTeleportation.png

This diagram derives from the following:

::

PREAMBLE \providecommand{\K}[1]{\left|#1\right\rangle} # Define ket command
a W \K{\phi} [x]
x1 W type=o # Empty wire used for positioning
x0 W style=dashed # Dividing line
x2 W type=o # Empty wire used for positioning
b0 W \K{0} [y]
b1 W \K{0} \K{\phi}

VERTICAL 0
b1 H % $\K{\phi}\K{0}(\K{0}{+}\K{1})$
+b0 b1 % $(\alpha\K{0}{+}\beta\K{1})(\K{00}{+}\K{11})$
b0 x1 PERMUTE
+b0 a %$\scriptstyle\alpha\K{0}(\K{00}{+}\K{11}){+}\beta\K{1}(\K{10}{+}\K{01})$
a H % $\sum_{x,y}\K{xy}(\alpha\K{y}{+}(-1)^x\beta\K{\bar{y}})$
a b0 M % $[xy](\alpha\K{y}{+}(-1)^x\beta\K{\bar{y}})$
x1 x2 a b0 PERMUTE
+b1 b0 % $[xy](\alpha\K{0}{+}(-1)^x\beta\K{1})$
b1 a % $[xy](\alpha\K{0}{+}\beta\K{1})$

# Colored boxes
b0 b1 x1 x2 @ 0 2 fill=green style=rounded_corners %% $[qq]$ Quantum entanglement
a b0 x2 x1 @ 6 6 fill=blue style=rounded_corners %% \hspace{.5cm}$2[c\rightarrow c]$ Classical channel

For an explanation of ``qpic`` commands and more examples, see the
`official documentation <doc/qpic_doc.pdf>`_.

Using ⟨q\|pic⟩
==============

- `Install <#install>`_
- `Uninstall <#uninstall>`_
- `Running ⟨q\|pic⟩ <#running-qpic>`_
- `Using ⟨q\|pic⟩ with LaTeX <#using-qpic-with-latex>`_

Install
=======

Pip
~~~

Recommended installation method is
`pip <https://en.wikipedia.org/wiki/Pip_(package_manager)>`_. Current
versions of Python 2 and 3 include pip. For older versions, use `pip
installation instructions <https://pip.pypa.io/en/stable/installing/>`_.

``pip install qpic``

If you do not have permission to install or wish to install ``qpic`` as
a single user, add ``$HOME/.local/bin`` to your ``$PATH`` and install
using

``pip install --user qpic``

Uninstall
~~~~~~~~~

To uninstall ``qpic`` simply type

``pip uninstall qpic``

Stand alone script
~~~~~~~~~~~~~~~~~~

To try out the basic script without installation:

1. Download the file ``qpic.py``. (located in the ``qpic`` directory)
2. Run ``python qpic.py your_file.qpic > your_file.tex``.

Running ⟨q\|pic⟩
~~~~~~~~~~~~~~~~

``qpic`` generates TikZ code by default. ``qpic`` can also generate pdf
files using ``pdflatex`` and png files using ``convert`` (from
ImageMagic).

Create TikZ file ``diagram.tikz``
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

``qpic -f tikz diagram.qpic``

Create PDF file ``diagram.pdf``
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

``qpic -f pdf diagram.qpic``

Create PNG file ``diagram.png``
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

``qpic -f png diagram.qpic``

Using ⟨q\|pic⟩ with LaTeX
-------------------------

Including graphics in LaTeX documents
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

There are two main methods for including ⟨q\|pic⟩ in LaTeX documents.
Each has its advantage in certain areas. They are:

- `Include TikZ code directly <#tikz>`_
- `Include as a PDF graphic <#pdf>`_

TikZ
~~~~

``qpic my_graphic.qpic`` produces a TikZ file named ``my_graphic.tikz``,
which can be directly included into a normal LaTeX document. You will
need to add

::

\usepackage{tikz}

to the preamble of your paper. Graphics can then be included with the
command:

::

\input{filename.tikz}

In some cases, additional TeX commands may be required in the preamble.
(These will be in the ``.tikz`` file preceded by ``%!``.) See the full
⟨q\|pic⟩ documentation for when additional packages are required.

PDF
~~~

``qpic -f pdf my_graphic.qpic`` will produce a PDF file named
``my_graphic.pdf``. This graphic can be viewed directly with a PDF
viewer. To insert the graphic into a LaTeX document, add the following
line to the preamble:

::

\usepackage{graphicx}

and include the file using the command:

::

\includegraphics{my_graphic.pdf}

This method requires the document to be processed with pdfLaTeX. For
further information see the full `⟨q\|pic⟩ documentation <doc/qpic_doc.pdf>`_.


=======
History
=======

1.0.1 (2016-3-18)
------------------

* Convert REAMDE to ReStructuredText for PyPi.

1.0.0 (2016-3-9)
------------------

* First release on PyPI.