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diff --git a/docs/designDocs.pdf b/docs/designDocs.pdf Binary files differnew file mode 100644 index 0000000..78eb646 --- /dev/null +++ b/docs/designDocs.pdf diff --git a/docs/designDocs.tex b/docs/designDocs.tex new file mode 100644 index 0000000..2a9fd97 --- /dev/null +++ b/docs/designDocs.tex @@ -0,0 +1,178 @@ +\documentclass{article} +\usepackage{fullpage} +\begin{document} + \title{150 Smoots Lighting Installation Design Document} + \author{Russell Cohen} + \date{\today} + \maketitle + \newcommand{\classDoc}[5]{ + \subsection{#1} + \begin{itemize} + \item \textbf{Inherits from: } #2 + \item \textbf{Inherited by: } #3 + \item \textbf{Brief Description: } #4 + \item \textbf{Argument Requirements: } #5 + \end{itemize} + } + \section{Intro} + \textbf{NB: These docs give an overview of the classes and methods but + may lag behind the code for certain in-flux functionality. For + up-to-the minute docs, please use pydoc.} \\ + The system, which we will describe henceforth as SmootLight is a + modular system designed with the following goals in mind: + \begin{itemize} + \item The system must abstract away from all components while + remaining useful (\verb=Renderer=, \verb=Input=, \verb=Behavior=) + \item The system must be modular and be easy to write new code for. + \item More goals as I think of them + \end{itemize} + We accomplish this in the following manner: + \begin{itemize} + \item The system is configured by an XML file which specifies its + components. + \item All classes are initialized with a dictionary as an argument + containing anything a class may need. All objects are passed + between members as python dictionaries because their easy + serialization. + \end{itemize} + \section{Operations Class Patterns} + \classDoc{SmootCoreObject}{None}{All 2nd level classes (PixelAssembler, Renderer, + Input, Behavior)} + {SmootCoreObject is essentially a super-object + that makes things easy for us. It does the following actions: + \begin{itemize} + \item Defines a constructor that sets argDict + \item Defines a \texttt{\_\_getitem\_\_} , which lets us acces items in + argDict as if the class was a dictionary. + (\texttt{self['itemName']}) + \item Defines validateArgs and validateArgDict which + validate the incoming arguments against a dictionary + containing argument names as keys and an error message to + display if they are missing as a values. This file should + be named classname.params and look like a python dict + (\texttt{\{'key':value, 'key2':value2\}} ) + \end{itemize} + Note that at this point, the only class using this functionality + is the PixelEvent class.} + {No required parameters in argDict} + \classDoc{PixelAssembler}{SmootCoreObject}{LineLayout, ZigzagLayout}{ + PixelAssembler is a class that defines the positions of lights. It + provides a method \texttt{getLightLocations} which give a list of + all light locations for a given strip. Inheriting classes must + define \texttt{layoutFunc} which returns the next location given the + previous location. (They may simply override + \texttt{getLightLocations} + instead, if they wish, but be careful when doing so). In + heriting classes may defint \texttt{initLayout} which is called at + initialization.}{\begin{itemize} + \item \texttt{lightToLightSpacing}: this is the length of wire + between 2 adjacent LEDs. Common values are 4 or 12. + \item \texttt{numLights}: Number of lights in a strip. + \item \texttt{originLocation}: Location of the first light. + \end{itemize}} + \classDoc{Renderer}{SmootCoreObject}{PygameRenderer, IndoorRenderer}{ + Renderer is a class that serves as an abstract class for renderers + interacting with the system. Inheriting classes must define + render, which is passed a \texttt{lightSystem} object. Inheriting + classes may define initRenderer which is called on initiation. + }{No required arguments} + \classDoc{Input}{SmootCoreObject, threading.Thread}{PygameInput, + TCPInput,UDPInput}{Input is a abstract class which facilitates Inputs. + It does this by providing a method that is polled at a periodic + interval within which the inheriting class can raise an event. + Inheriting classes must define \texttt{sensingLoop} which is + called at the interval specified in the config. Inheriting + classes should call respond with an dictionary as an argument + to raise an event. Classes using (not + inheriting) input must pass a scope into + the argDict which offers a \texttt{processInput} + method. Inputs are marked as Daemon threads, and + are therefore killed when their parent is + killed.}{\begin{itemize} + \item \texttt{InputId}: The string id of a given input. Must be + unique. + \item Optional:\texttt{RefreshInterval}: The interval in + seconds (will soon be changed to milliseconds) between + sucessive calls to the sensingLoop method. TODO: make + timeout. + \end{itemize}} + \classDoc{Behavior}{SmootCoreObject}{EchoBehavior, DebugBehavior}{ +Abstract class for a behavior. On every time step, the behavior is passed the +inputs from all sensors it is bound to as well as any recursive inputs that it +spawned during the last time step. Inheriting classes MUST define +\texttt{processBehavior}. \texttt{processBehavior} should return a list of dictionaries which +define the properties of the light response. The must return a location +\texttt{PixelEvent} class. Soon be be deprecated:\textit{They must give a location and +color. They may define a function pointer which defines a custom mapping. +[More on this later. Bug Russell if you want to do it].} +Call \texttt{recursiveResponse} to queue a input on the next iteration with a dictionary +argument. This will be passed in via recursive inputs.} +{\begin{itemize} + \item \texttt{Inputs}: A list of input Ids specifying input to the + behavior. In the future, this may also contain behavior ids. +\end{itemize}} +\classDoc{PixelEvent}{SmootCoreObject}{StepResponse}{ + Abstract class defining the behavior of a light after it has been turned on. + Inheriting classes should defint \texttt{lightState} which is passed a + timeDelay in ms as an argument. \texttt{lightState} should return a + color or None if the response is complete.}{\begin{itemize} + \item \texttt{Color}: The color of response. \textit{This is may be + removed in the future} + \end{itemize} + } +\section{The Screen Class and Its Relatives} +\classDoc{Screen}{None}{None} +{The \texttt{Screen} class is a representation of an entire system of pixels, + distributed over space. The Screen class and its relatives process + responses (mapped to pixels via a LayoutEngine), and add PixelEvents + to the individual pixels. The Screen provides an instance that + renderers can call to determine the color of all the individual pixels. It contains a list of PixelStrips, which each + address the individual pixels. \texttt{Screen} offers a + \texttt{respond} method which takes a dictionary containing information + about a response. TODO: detail the contents of this dictionary (maybe + somewhere else). Note: \texttt{Screen} will not process its + responses until \texttt{timeStep} is called which processes all responses that + have been queued since the last time that \texttt{timeStep} was + called. Screen also offers an iterator over \textit{all} lights, + accesible by using an expression like: \texttt{for light in screen:}. For + addressing of specific \texttt{PixelStrips} , \texttt{self.pixelStrips} + is exposed.}{No required parameters} +\classDoc{PixelStrip}{None}{None} +{The \texttt{PixelStrip} class is a representation of a string of Pixels that are + connected in physical space (eg. a strip of lights). A \texttt{PixelStrip} takes a + \texttt{LayoutBuilder} (\textit{Name up for debate, currently known as layout + engine}) as an argument. The \texttt{argDict} of the + \texttt{LayoutBuilder} is + passed becomes the \texttt{argDict} of the \texttt{PixelStrip}. + \texttt{PixelStrip} generally shouldn't be + adressed directly unless you need Strip-Identification for rendering + purposes. You should never, for example, call \texttt{respond} on a + \texttt{PixelStrip} + directly, unless you really know what you're doing. Well, actually you + should never need to do that. + never. Don't do it.}{Takes a \texttt{LayoutBuilder} as an argument.} + \section{Best Practices} + \subsection{Variable and function naming} + I'm pretty bad about being consistent. However, in all future + code, please adhere to the following: + \begin{itemize} + \item Classes: \texttt{FirstLetterCaps} + \item Functions: \texttt{camelCase} + \item Property Names: \texttt{FirstLetterCaps} + \item Constants: \texttt{ALL\_CAPS\_WITH\_UNDERSCORES} + \end{itemize} + \subsection{Time} + For time, use the \texttt{Util.time()} method to return the current + time in ms. + \subsection{Acessing Pixels} + The ideal method for acessing Pixels in a screen is to use its + iterator. Iterating over the individual PixelStrips is also an + acceptable method. + \subsection{Determining the state of a \texttt{Pixel}} + The best practice for determining the color of a \texttt{Pixel} is to call + \texttt{lightState} (may be renamed to State TODO). This ensures + all current active responses running on the Pixel contribute correctly. + \subsection{Color} + For color, use a tuple of (R,G,B) 0-255 for each. Colors can be + easily manipulated with members of the Util class. + \end{document} |