TOC

Papywizard Developer Guide

Introduction

Papywizard is entirely written in python. Branch 2.x now uses PyQt (Python binding for Qt) for the GUI, pybluez and/or pyserial for hardware control.

Build from source

It is best to work on the subversion branch:

$ svn co http://svn.gbiloba.org/papywizard/trunk papywizard

In order to run Papywizard from source, you need:

• Python >= 2.5: ​http://www.python.org/ftp/python

and the following libs:

• Qt >= 4.5: ​http://qt.nokia.com/downloads
• PyQt >= 4.5: ​http://www.riverbankcomputing.co.uk/static/Downloads/PyQt4
• pybluez: ​http://code.google.com/p/pybluez/downloads/list
• pyserial: ​http://sourceforge.net/projects/pyserial/files

Be sure to use the same python version for all of them.

Gnu/linux

All the needed libs come with most distributions.

Papywizard can be launch by the following commands:

$ ./papywizard.sh

or

$ ./Papywizard.py

Windows

On Windows, PyQt package don't need the Qt package. But the following libs are needed:

• pywin32: ​http://sourceforge.net/projects/pywin32
• MSVC2008 C++ runtime DLLs: ​http://www.microsoft.com/downloads/details.aspx?familyid=9B2DA534-3E03-4391-8A4D-074B9F2BC1BF&displaylang=en

To get the sources from the subversion repository, you can use:

• svn tool: ​http://tortoisesvn.tigris.org

To launch Papywizard, run the windows/papywizard.bat script.

API

You can generate the complete API documentation by running the mkdoc.sh script; the documentation will then be available as web pages in the api/ directory.

Or you can browse the API (subversion) online. Be carefull that it may not be up-to-date.

Architecture

Papywizard uses a MVC-like pattern, which keeps the model separated from the views. This allows to use any other toolkit if needed; I recently switched from Tkinter to PyGTK, to run Papywizard on Nokia plateform. I hope, one day, to be able to run Papywizard on QTopia-based devices, like Openmoko. But I first need to get such device ;o)

A plugin architecture allows to control different hardwares.

Hardware

Merlin/Orion protocole

The head uses a simple ascii serial protocol; the serial line uses standard settings: 9600 8N1 (9600 bauds, 8 bits data, no parity, 1 stop bit). The head waits for incoming commands, and send response to them. The 2 axis are identical, and uses the same commands. They both wait for incoming commands; depending of the first value (see below), the command will be sent to one or the other axis.

A commands always starts with ':', and ends with '\r'. The head response always starts with '=', and also ends with '\r'. As TX/RX lines are wired together, the controller has to first readback its own command, before reading the head response. In the following documentation, the command readback is omitted, as the ':', '=' and '\r' chars.

Parameters used in the documentation:

Parameter	What	Allowed value	Format	Note
<axis>	axis to control	1 or 2	1 ascii digit	1=yaw, 2=pitch axis
<pos>	position	0 to 2²⁴-1	6 ascii digits, hex.	Low byte is sent first (A35483 is read 8354A3). When switched on, read value is 800000. Right sens increments axis 1; left sens decrements it. Up sens increments axis 2; down decrements it. A complete turn (360°) increments/decrements by 0E6600 (so, the axis can make almost 9 turns before the counter overflow)
<dir>	axis direction	0 or 1	1 ascii digit	0=increments (up/right), 1=decrements (down/left)
<status>	Axis status	3 ascii digits		Second digit is 0 when axis is stopped
<state>	State of the shutter contact	1 ascii digit	0 or 1	0 opens the contact, 1 closes the contact

Merlin/Orion commands set

Function	Command	Response	Note
Read axis position	j<axis>	<pos>
Read axis status	f<axis>	<status>
Stop moving	L<axis>
Init (at switch on)	F<axis> a<axis> D<axis>	0E62D3 0006F9	0E62D3 is the number of encoder counts per turn (in hexa) 0006F9 is the sidereal rate (in hexa)
Start moving	L<axis> G<axis>3<dir> I<axis>220000 J<axis>		220000 seems to be the divider for the speed. The lower the value, the higher the speed
Drive to position	L<axis> G<axis>00 S<axis><pos> J<axis>
Set shutter contact state	O<axis><state>	Both axis understand the command, but the contact is only set by yaw (0) axis

Merlin/Orion communication examples

When switched on:

command       response
:F1\r         =\r
:F2\r         =\r
:a1\r         =D3620E\r
:D1\r         =F90600\r
:a2\r         =D3620E\r
:D2\r         =F90600\r
:D2\r         =F90600\r

Note: the last command is sent twice by the original remote control, but all works fine if sent only once (like Papywizard does).

Push up button in fast mode:

command       response
:L2\r         =\r
:G230\r       =\r
:I2220000\r   =\r
:J2\r         =\r

Release up button if fast mode:

command       response
:L2\r         =\r
:f2\r         =503\r

Model

View

Plugins

Plugins implements one or more 'capacity'. Available capacities are:

• yawAxis
• pitchAxis
• shutter

The first two are responsible of yaw/pitch axis; the last is responsible of triggering the camera shutter.

A plugin needs to implement 2 classes (for each implemented capacity): one for the model (real work), and one for the controller (configuration dialog).

Plugin model

All model classes inherit from the AbstractPlugin class (defined in the papywizard.common.abstractPlugin module).

Then, plugins implementing 'yawAxis' and 'pitchAxis' capacities must inherit from AbstractAxisPlugin, and plugins implementing the 'shutter' capacity must inherit from AbstractShutterPlugin (defined in the papywizard.hardware.abstractShutterPlugin module). Depending of the implemented capacity, the plugin must overload some methods for Papywizard to work. Have a look at the above classes to see which ones.

The plugin model may need some user parameters in order to work. These parameters must be defined in the _defineConfig() method. For example:

def _defineConfig(self):
    self._addConfigKey('_myParam', 'MY_PARAM', default='a value')

will add a config param named MY_PARAM. All plugins user params are saved in the config. file. If there is no previous value defined there, the default argument tells Papywizard which value to use. This config param will be saved using MY_PARAM as key.

In the plugin, this config param can be used through self._config['MY_PARAM'] (in a future release, it will be automatically binded to self._myParam). It should not be modified from the model (see below).

Plugin controller

Controller classes inherits from AbstractPluginController class (defined in the papywizard/controller/ package). This abstract class inherits from other classes, which are responsible to load the .ui GUI defining file (see previous chapters). The only method which needs to be oversloaded is _defineGui(). This is where the dialog interface is defined. For example:

def _defineGui(self):
    self._addWidget('Main', "My param", LineEditField, (), 'MY_PARAM')

will create an entry to customize our previous config param. The first argument is the notebook widget tab under which the param will be displayed (Main is the first default tab). The second argument is the label for the config param. The third argument is the field type to use. Availabe fields are defined in the papywizard.view.pluginFields module. The 4th argument is a tuple containing the init arguments of the field. The last argument is the name of the config param, as defined in the plugin model.

Here is another example:

def _defineGui(self):
    self._addTab('Driver')
    self._addWidget('Driver', "Type", ComboBoxField, (['bluetooth', 'serial', 'ethernet'],), 'DRIVER_TYPE')

The main addition is that we first create a new tab, and then add a ComboBoxField, with 3 possible entries.

Plugin registration

Both previous classes must be defined in the same module. To register the plugin, the module also has to implement a register() function, which will be called at startup. For example:

def register():
    PluginManager().register(MyModelClass, MyModelController)

If the plugin module implements several model/controller capacities, just put additional PluginManager().register() calls.

This plugin register() function must be called in the main application. This can be done by modifying the main script; but Papywizard will also automatically register all plugins which are stored in the config. dirrectory, under the plugins/ directory. Just create it if it does not already exist, and put your plugins there.

Complete example

Note: need to be updated with recent API.

Here is the Tethered plugin, defined in the papywizard/plugins/tetheredPlugins module:

import time
import subprocess

from papywizard.common.loggingServices import Logger
from papywizard.common.pluginManager import PluginManager
from papywizard.hardware.abstractShutterPlugin import AbstractShutterPlugin
from papywizard.controller.shutterPluginController import ShutterPluginController
from papywizard.view.pluginFields import ComboBoxField, LineEditField, CheckBoxField


class TetheredShutter(AbstractShutterPlugin):
    _name = "Tethered"

    def _init(self):
        pass

    def _getTimeValue(self):
        return -1

    def _getMirrorLockup(self):
        return self._config['MIRROR_LOCKUP']

    def _getBracketingNbPicts(self):
        return self._config['BRACKETING_NB_PICTS']

    def _getBracketingIntent(self):
        return self._config['BRACKETING_INTENT']

    def _defineConfig(self):
        AbstractShutterPlugin._defineConfig(self)
        self._addConfigKey('_mirrorLockup', 'MIRROR_LOCKUP', default=False)
        self._addConfigKey('_mirrorLockupCommand', 'MIRROR_LOCKUP_COMMAND', default="")
        self._addConfigKey('_shootCommand', 'SHOOT_COMMAND', default="")
        self._addConfigKey('_bracketingNbPicts', 'BRACKETING_NB_PICTS', default=1)
        self._addConfigKey('_bracketingIntent', 'BRACKETING_INTENT', default='exposure')

    def activate(self):
        Logger().trace("TetheredShutter.activate()")

    def shutdown(self):
        Logger().trace("TetheredShutter.shutdown()")

    def establishConnection(self):
        pass

    def shutdownConnection(self):
        pass

    def lockupMirror(self):
        Logger().debug("TetheredShutter.lockupMirror(): execute command '%s'..." % self._config['MIRROR_LOCKUP_COMMAND'])
        time.sleep(1)
        Logger().debug("TetheredShutter.lockupMirror(): command over")
        return 0

    def shoot(self, bracketNumber):
        Logger().debug("TetheredShutter.shoot(): execute command '%s'..." % self._config['SHOOT_COMMAND'])

        # Launch external command
        args = self._config['SHOOT_COMMAND'].split()
        p = subprocess.Popen(args, stdout=subprocess.PIPE, stderr=subprocess.PIPE)

        # Wait end of execution
        stdout, stderr = p.communicate()
        if stderr:
            Logger().debug("TetheredShutter.shoot(): stderr:\n%s" % stderr)
        Logger().debug("TetheredShutter.shoot(): stdout:\n%s" % stdout)

        return p.returncode


class TetheredShutterController(ShutterPluginController):
    def _defineGui(self):
        ShutterPluginController._defineGui(self)
        self._addWidget('Main', "Mirror lockup", CheckBoxField, (), 'MIRROR_LOCKUP')
        self._addWidget('Main', "Mirror lockup command", LineEditField, (), 'MIRROR_LOCKUP_COMMAND')
        self._addWidget('Main', "Shoot command", LineEditField, (), 'SHOOT_COMMAND')
        self._addWidget('Main', "Bracketing nb picts", SpinBoxField, (1, 99), 'BRACKETING_NB_PICTS')
        self._addWidget('Main', "Bracketing intent", ComboBoxField, (['exposure', 'focus', 'white balance', 'movement'],), 'BRACKETING_INTENT')


def register():
    """ Register plugins.
    """
    PluginManager().register(TetheredShutter, TetheredShutterController)

Output XML file

Papywizard can generate a xml data file. This file mainly contains all positions reached during shooting, and can be used by Autopano Giga to help positionning orphan pictures. This is very helpfull for high-resolution panos with deep blue sky, without details. Sift algorithm often fail to find control points in such areas.

The XML file is made of two parts: a header, containing global informations, and a shoot part, containing a list of all pictures positions. The exact header format depends of the mode.

This format is open, and can be used by anyone who wants to implement motorized panohead output data file. Feel free to contact me if you want to add some entries to support special features. The goal is to make some sort of standard format. More informations ​here.

Distributing

Before creating and distributing a package, make sure that the following files are up-to-date:

• ChangeLog
• papywizard/common/config.py (version number)
• setup.py (new/obsolete files)
• papywizard.pro (new/obsolete files)

Debian package

There is no debian packager yet.

Maemo package

Papywizard includes an distutils extension script to build maemo debian package in a easy way:

$ python maemo/setup.py bdist_debian

Then, just move the packages to the web site.

Windows installer

• install NSIS software
• build the executable by launching the script windows/buildexe.bat
• edit (update the version number) and run the script windows/papywizard.nsi

Contribute

There are several ways to contribute:

Help coding

Test and report bugs

Internationalization

If you want to contribute but don't know how to code, you can make translation.

To do that, you just need to ask me for the corresponding papywizard_xx.ts file which contains all sentences and words used in the soft, translate them using ​Qt Linguist (important; don't translate using a simple text editor), and send it back to me.

• keep strings length as close as the original ones
• if you are not sure about the usage of a word/sentence, feel free to ask about the context.