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812 lines
29 KiB
Markdown
| [Home](/trick) → [Tutorial Home](Tutorial) → Analytical Cannon Simulation |
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|-------------------------------------------------------------------------|
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<!-- Section -->
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<a id=building-and-running-a-trick-based-simulation></a>
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# Building & Running a Trick-based Simulation
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**Contents**
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* [Organizing the Simulation Code in Directories](#organizing-the-simulation-code-in-directories)<br>
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* [Representing the Cannonball](#representing-the-cannonball)<br>
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- [Listing 2 : **cannon.h**](#listing_2_cannon_h)<br>
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- [The Input/Output (I/O) Specification](#the-input_output-io-specification)<br>
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- [Units Specification](#units-specification)<br>
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* [Initializing the Cannonball Simulation](#initializing-the-cannonball-simulation)<br>
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- [Listing 3 : **cannon_init.c**](#listing_3_cannon_init_c)<br>
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* [Updating the Cannonball State Over Time](#updating-the-cannonball-state-over-time)<br>
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- [listing 4 : **cannon\_analytic.h**](#listing_4_cannon_analytic_h)<br>
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- [listing 5 : **cannon\_analytic.c**](#listing_5_cannon_analytic_c)<br>
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* [Cannonball Cleanup And Shutdown](#cannonball_cleanup_and_shutdown)
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- [listing 6 : **cannon\_shutdown.c**](#listing_6_cannon_shutdown_c)<br>
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* [The Simulation Definition File (S_define)](#simulation-definition-file)<br>
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- [listing 7 : **S_define**](#listing_7_s_define)<br>
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* [Compiling, and Building the Simulation](#compiling-and-building-the-simulation)<br>
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- [Listing 8 : **S_overrides.mk**](#listing_8_s_overrides.mk)
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* [Running the Simulation](#running-the-simulation)<br>
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- [Listing 9 : **input.py**](#listing_9_input_py)
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***
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In this and subsequent sections, we're going to build and run a Trick-based cannonball simulation.
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---
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<a id=organizing-the-simulation-code-in-directories></a>
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### Organizing the Simulation Code in Directories
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We'll begin by creating a directory system to hold our simulation source code:
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```bash
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% cd $HOME
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% mkdir -p trick_sims/SIM_cannon_analytic
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% mkdir -p trick_sims/SIM_cannon_analytic/models/cannon/src
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% mkdir -p trick_sims/SIM_cannon_analytic/models/cannon/include
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```
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---
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<a id=representing-the-cannonball></a>
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### Representing the Cannonball
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To represent the cannonball model, we need to create a header file (**cannon.h**)
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that will contain:
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* A CANNON structure to hold the state of the cannonball, and
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* Prototypes for cannonball functions
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The CANNON data-type contains the cannonball's initial conditions,
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its acceleration, velocity, and position, the model time, whether the cannonball
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has impacted the ground, and the time of impact.
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The prototypes will declare two functions for initializing our CANNON data-type.
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We'll discuss these in the next section.
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<a id=listing_2_cannon_h></a>
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**Listing 2 - `cannon.h`**
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```c
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/*************************************************************************
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PURPOSE: (Represent the state and initial conditions of a cannonball)
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**************************************************************************/
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#ifndef CANNON_H
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#define CANNON_H
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typedef struct {
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double vel0[2] ; /* *i m Init velocity of cannonball */
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double pos0[2] ; /* *i m Init position of cannonball */
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double init_speed ; /* *i m/s Init barrel speed */
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double init_angle ; /* *i rad Angle of cannon */
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double acc[2] ; /* m/s2 xy-acceleration */
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double vel[2] ; /* m/s xy-velocity */
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double pos[2] ; /* m xy-position */
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double time; /* s Model time */
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int impact ; /* -- Has impact occured? */
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double impactTime; /* s Time of Impact */
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} CANNON ;
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#ifdef __cplusplus
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extern "C" {
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#endif
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int cannon_default_data(CANNON*) ;
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int cannon_init(CANNON*) ;
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int cannon_shutdown(CANNON*) ;
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#ifdef __cplusplus
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}
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#endif
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#endif
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```
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#### Creating The `cannon.h` Header File
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Using your favorite text editor, create and save the file `cannon.h` from
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**Listing 2**. We will assume from this point that your favorite text editor
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is **vi**. So when you see **vi** following the %, just replace it
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with **emacs**, **nedit**, **jot**, **wordpad**, **kate**, **bbedit**, or
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whatever you like.
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```bash
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% cd $HOME/trick_sims/SIM_cannon_analytic/models/cannon/include
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% vi cannon.h
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```
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Type, or cut and paste the contents of **Listing 2** and save.
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<a id=deciphering-the-trick Comments In The Header File></a>
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### Deciphering The Trick Comments In The Header File
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In the file above, note the comments at the top, and to the right of each
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structure member. These are specially formatted comments that are parsed by Trick.
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The comment at the top of the file, containing the keyword `PURPOSE:` (the colon
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is part of the keyword) is called a "Trick header". The presence of a Trick
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header lets Trick know that it should scan the file to collect information about
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the data types it contains. The full Trick header syntax will be detailed later, for
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now, `PURPOSE:` is all that is necessary.
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To the right of each structure member is a comment that (optionally) provides
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the following information for the member:
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1. Input/Output Specification
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2. Units Specification
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3. Description
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These are each described in **Figure 2** and in the sections below.
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![DataMemberComments](images/DataMemberComments.png)
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**Figure 2 - Data Member Comments**
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---
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<a id=the-input_output-io-specification></a>
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#### The Input/Output (I/O) Specification
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An I/O specification is an optional field that specifies data flow
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direction for a variable. The default, `*io` , specifies that both input and
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output are allowed.
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* `*i` tells Trick that the parameter will be input only.
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* `*o` tells Trick that the parameter is output only.
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* `*io` is the default and means the parameter may be used for input or output.
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* `**` tells Trick that you do NOT want this parameter processed.
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---
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#### Comment Field
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The comment field is extracted and used in GUI tools to describe variables.
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---
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<a id=units-specification></a>
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#### Units Specification
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A unit specification indicates the units of measure for a variable. For example,
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in the figure above, (m/s) indicates that `init_speed` is a measure of meters
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per second. Unit specs allow unit conversions to be performed by the Trick input
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file processor, Trick View and plotting tools.
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As of Version 17.0, Trick uses [UDUNITS2](http://www.unidata.ucar.edu/software/udunits/),
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an Open Source unit conversion package, developed at http://www.unidata.ucar.edu.
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It is similar in many respects to Trick's previous unit conversion package, but,
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frankly it's a lot better. Like the previous Trick unit conversion package,
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UDUNITS2 supports unit-prefixes (for example: kilo, micro, etc.) as well as
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unit-composition, the ability to compose unit specifications from previously
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defined unit specifications (for example: m/s, kg.m/s^2). Unlike the previous
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unit conversion, its units database is much more substantial, it's more
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extensible, its design is more capable, and it supports Unicode characters in
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unit specifications.
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Below, we are going to see how to specify commonly needed unit specifications
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for our Trick simulations. But, we are not going to describe the full capability
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of UDUNITS2 package. In order to see **ALL** available unit definitions, one would
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need to look at the UDUNITS2 xml files that comprise the units database.
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Rather than requiring that, the [Common Units & Unit Prefixes](ATutUnitTables) page
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lists optional prefixes, and many of the most commonly used units in simulations
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at the Johnson Space Center Engineering Branch.
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#### Composite Units (Making Units From Existing Units)
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Often, units are composed of other predefined units as in the following unit
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specification examples:
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* **m/s** (meters per second, speed)
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* **m/s^2** (meters per second squared, acceleration)
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* **kg.m/s^2** (Newtons, force)
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* **m^3** (cubic meters, volume)
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Note the operators `/` (division), `.`(multiplication), `^2`(square), and
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`^3`(cube) for composing unit specs.
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#### Scaling Units With Unit Prefixes
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Unit prefixes, listed in the table `Unit Prefixes`, below can also be prepended
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to unit specifications, as in the following examples:
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* **k**m, **kilo**meters
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* **M**W, **mega**watts
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#### Unicode Characters in Units
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Some units and unit-prefixes can also be represented using unicode characters.
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For example:
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* **^2** can instead be represented as **²** (Unicode char U+00B2).
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* **^3** can instead be represented as **³** (Unicode char U+00B3).
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* The prefix **micro**, or **u** can be represented as **μ** (Unicode
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char U+03BC).
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* The unit **ohms** can be represented as **Ω** (Unicode char U+2126
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or U+03A9).
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So, one could specify **m/s²** rather than **m/s^2**, or **m³**
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rather than **m^3**, or **μm** rather than **micrometers**. The table below
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lists Unicode characters that can be used in units specifications.
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<a id=unicode-characters-used-in-units-specifications></a>
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### Unicode Characters Used in Units Specifications
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| Character | Unicode Number | Unicode Name |
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|-----------|----------------| ----------------------|
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| ° | U+00B0 | Degree Sign |
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| ² | U+00B2 | Superscript Two |
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| ³ | U+00B3 | Superscript Three |
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| Ω | U+03A9 | Greek Capital Letter Omega |
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| μ | U+03BC | Greek Small Letter Mu |
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| π | U+03C0 | Greek Small Letter Pi |
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| ′ | U+2032 | Prime |
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| ″ | U+2033 | Double Prime |
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| ℃ | U+2103 | Degree Celsius |
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| ℉ | U+2109 | Degree Fahrenheit |
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| Ω | U+2126 | Ohm Sign |
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| K | U+212A | Kelvin Sign |
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| Å | U+212B | Angstrom Sign |
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#### Specifying "No Units"
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In Trick, a unit specification of "--" means *unit-less*. If your variable
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doesn't have units, use "--" as the unit specification.
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---
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<a id=initializing-the-cannonball-simulation></a>
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### Initializing the Cannonball Simulation
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The Trickless simulation performed a two-part initialization of the
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simulation variables. The first part assigned default values to the simulation
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parameters. The second part performed calculations necessary to initialize the
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remaining simulation variables.
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Trick based simulations perform a three-part initialization of simulation
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variables. The first part runs "**default-data**" jobs, that is, it calls one or
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more user-provided C functions, whose purpose is to set default values for the
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simulation's variables. In the second initialization step, Trick executes the
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simulation's Python "**input file**". Variable assignments can be made in the input file.
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If a parameter value isn't set in the input file, its default value is used. In the third and final
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initialization step, Trick runs "**initialization**" jobs. These perform any
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final initialization calculations, needed prior to running the sim.
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The two functions in the listing below will serve as the default-data and
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initialization jobs for our cannonball simulation. These are the functions for
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which we created the prototypes in the cannon.h header file.
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We'll create the python input file in a later section.
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<a id=listing_3_cannon_init_c></a>
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**Listing 3 - `cannon_init.c`**
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```c
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/******************************* TRICK HEADER ****************************
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PURPOSE: (Set the initial data values)
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*************************************************************************/
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/* Model Include files */
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#include <math.h>
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#include "../include/cannon.h"
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/* default data job */
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int cannon_default_data( CANNON* C ) {
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C->acc[0] = 0.0;
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C->acc[1] = -9.81;
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C->init_angle = M_PI/6 ;
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C->init_speed = 50.0 ;
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C->pos0[0] = 0.0 ;
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C->pos0[1] = 0.0 ;
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C->time = 0.0 ;
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C->impact = 0 ;
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C->impactTime = 0.0 ;
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return 0 ;
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}
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/* initialization job */
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int cannon_init( CANNON* C) {
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C->vel0[0] = C->init_speed*cos(C->init_angle);
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C->vel0[1] = C->init_speed*sin(C->init_angle);
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C->vel[0] = C->vel0[0] ;
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C->vel[1] = C->vel0[1] ;
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C->impactTime = 0.0;
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C->impact = 0.0;
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return 0 ;
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}
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```
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Some important things to note:
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* These are just C functions. Trick will have them compiled, and linked into the simulation
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executable.
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* Both functions' arguments have a pointer to the CANNON data-type which was defined in `cannon.h`.
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* Both functions return an **int**. Returning 0 indicates success. Non-zero indicates failure.
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The return values can optionally be used (by setting trick\_ret in the S\_define) to terminate the simulation.
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```bash
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% cd $HOME/trick_sims/SIM_cannon_analytic/models/cannon/src
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% vi cannon_init.c
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```
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Type in the contents of **Listing 3** and save.
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<a id=updating-the-cannonball-state-over-time></a>
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### Updating The Cannonball State Over Time
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Trick's job scheduler provides a **"Scheduled"** job type for periodically calling functions when the sim is in RUN (cyclic) mode.
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In the case of our cannonball simulation, where there is an analytical solution, we can
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calculate the the cannonball state by evaluating a function at each time step.
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<a id=listing_4_cannon_analytic_h></a>
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**Listing 4 - `cannon_analytic.h`**
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```c
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/*************************************************************************
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PURPOSE: ( Cannon Analytic Model )
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**************************************************************************/
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#ifndef CANNON_ANALYTIC_H
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#define CANNON_ANALYTIC_H
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#include "cannon.h"
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#ifdef __cplusplus
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extern "C" {
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#endif
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int cannon_analytic(CANNON*) ;
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#ifdef __cplusplus
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}
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#endif
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#endif
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```
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```bash
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% cd $HOME/trick_sims/SIM_cannon_analytic/models/cannon/include
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% vi cannon_analytic.h
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```
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Type in the contents of **Listing 4** and save.
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<a id=listing_5_cannon_analytic_c></a>
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**Listing 5 - `cannon_analytic.c`**
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```c
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/*****************************************************************************
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PURPOSE: ( Analytical Cannon )
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*****************************************************************************/
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#include <stdio.h>
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#include <math.h>
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#include "../include/cannon_analytic.h"
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int cannon_analytic( CANNON* C ) {
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C->acc[0] = 0.00;
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C->acc[1] = -9.81 ;
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C->vel[0] = C->vel0[0] + C->acc[0] * C->time ;
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C->vel[1] = C->vel0[1] + C->acc[1] * C->time ;
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C->pos[0] = C->pos0[0] + (C->vel0[0] + (0.5) * C->acc[0] * C->time) * C->time ;
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C->pos[1] = C->pos0[1] + (C->vel0[1] + (0.5) * C->acc[1] * C->time) * C->time ;
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if (C->pos[1] < 0.0) {
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C->impactTime = (- C->vel0[1] - sqrt( C->vel0[1] * C->vel0[1] - 2 * C->pos0[1]))/C->acc[1];
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C->pos[0] = C->impactTime * C->vel0[0];
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C->pos[1] = 0.0;
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C->vel[0] = 0.0;
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C->vel[1] = 0.0;
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if ( !C->impact ) {
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C->impact = 1;
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fprintf(stderr, "\n\nIMPACT: t = %.9f, pos[0] = %.9f\n\n", C->impactTime, C->pos[0] ) ;
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}
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}
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/*
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* Increment time by the time delta associated with this job
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* Note that the 0.01 matches the frequency of this job
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* as specified in the S_define.
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*/
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C->time += 0.01 ;
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return 0 ;
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}
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```
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This routine looks much like the routine found in our Trick-less simulation. It
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is the piece that was surrounded by a while-loop. Underneath, Trick will
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surround this job with its own while-loop. As in the case of the `cannon_init()`
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routine, there is nothing particularly special about `cannon_analytic()`. It is
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just another C function that will be compiled into an object, and later, linked
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with a number of libraries to create a simulation executable.
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```bash
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% cd $HOME/trick_sims/SIM_cannon_analytic/models/cannon/src
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% vi cannon_analytic.c
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```
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Type in the contents of **Listing 5** and save.
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<a id=cannonball_cleanup_and_shutdown></a>
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### Cannonball Cleanup And Shutdown
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**shutdown** job types are called by Trick's job scheduler when the simulation ends.
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These types of jobs are for doing anything that one might want to do at the end of a simulation, like releasing resources, or doing some final result calculation, or maybe just printing a message.
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In our case we're just going to print the final cannon ball state.
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<a id=listing_6_cannon_shutdown_c></a>
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**Listing 6 - `cannon_shutdown.c `**
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```c
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/************************************************************************
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PURPOSE: (Print the final cannon ball state.)
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*************************************************************************/
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#include <stdio.h>
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#include "../include/cannon.h"
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#include "trick/exec_proto.h"
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int cannon_shutdown( CANNON* C) {
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double t = exec_get_sim_time();
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printf( "========================================\n");
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printf( " Cannon Ball State at Shutdown \n");
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printf( "t = %g\n", t);
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printf( "pos = [%.9f, %.9f]\n", C->pos[0], C->pos[1]);
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printf( "vel = [%.9f, %.9f]\n", C->vel[0], C->vel[1]);
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printf( "========================================\n");
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return 0 ;
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}
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```
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```bash
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% cd $HOME/trick_sims/SIM_cannon_analytic/models/cannon/src
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% vi cannon_shutdown.c
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```
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<a id=simulation-definition-file></a>
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## The Simulation Definition File (S_define)
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To automate the build process of a Trick based simulation, Trick needs to
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know user source code locations, data types, functions, variables and scheduling
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requirements of a simulations models. This starts with the simulation
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definition file (**S_define**), an example of which, that we will use to define
|
||
our Cannonball simulation is shown in Listing 7, below.
|
||
|
||
<a id=listing_7_s_define></a>
|
||
**Listing 7 - `S_define`**
|
||
|
||
```c++
|
||
/************************TRICK HEADER*************************
|
||
PURPOSE:
|
||
(This S_define works with the RUN_analytic input file)
|
||
LIBRARY DEPENDENCIES:
|
||
(
|
||
(cannon/src/cannon_init.c)
|
||
(cannon/src/cannon_analytic.c)
|
||
(cannon/src/cannon_shutdown.c)
|
||
)
|
||
*************************************************************/
|
||
|
||
#include "sim_objects/default_trick_sys.sm"
|
||
##include "cannon/include/cannon_analytic.h"
|
||
|
||
class CannonSimObject : public Trick::SimObject {
|
||
|
||
public:
|
||
CANNON cannon;
|
||
|
||
CannonSimObject() {
|
||
("default_data") cannon_default_data( &cannon ) ;
|
||
("initialization") cannon_init( &cannon ) ;
|
||
(0.01, "scheduled") cannon_analytic( &cannon ) ;
|
||
("shutdown") cannon_shutdown( &cannon ) ;
|
||
}
|
||
} ;
|
||
|
||
CannonSimObject dyn ;
|
||
```
|
||
|
||
|
||
|
||
The `S_define` file syntax is C++ with a couple of Trick specific constructs.
|
||
Let us dissect this S_define file to see what makes it tick.
|
||
|
||
### Trick Header
|
||
|
||
* `PURPOSE:` keyword tells Trick to scan the remainder of the file for data
|
||
types, variable definitions, job scheduling specifications and compilation unit
|
||
dependencies.
|
||
|
||
* `LIBRARY_DEPENDENCY: ((cannon/src/cannon_analytic.c) ...` Lists the
|
||
|
||
*compilation units* (the .c source files), upon which this S_define depends. The
|
||
specified source files are the starting point for the recursive determination of
|
||
the list of files that need to be compiled and linked to build the simulation.
|
||
Trick headers that are included within each of these files may specify additional
|
||
source code dependencies, and so forth. Libraries may also be specified for
|
||
linking into the final executable.
|
||
|
||
Trick uses your `$TRICK_CFLAGS` environment variable ([see section 3.2 of the Trick User Guide](/trick/documentation/building_a_simulation/Environment-Variables)) in
|
||
conjunction with `cannon/src` to find the listed files. The entire path
|
||
name following the `$TRICK_CFLAGS` path must be included.
|
||
|
||
### Included Files
|
||
|
||
* `#include "sim_objects/default_trick_sys.sm"` This line is mandatory in an
|
||
S_define. It includes predefined data types, variable definitions, and jobs the
|
||
that provide standard Trick Simulation functionality.
|
||
|
||
* `##include "cannon/include/cannon_analytic.h"` The S_define must `##include`
|
||
type definitions for all of the classes and structures that it uses. It also
|
||
needs to include prototypes for all of the functions that it calls. You may also
|
||
put the prototypes in the `S_define` block using ([user code blocks](/trick/documentation/building_a_simulation/Simulation-Definition-File#user-code-block)), but if you need to call any of the C functions from the input file then you must include the
|
||
prototypes in a header file (the preferred method).
|
||
|
||
### Data Lines
|
||
|
||
`Class CannonSimObject : public Trick::SimObject`
|
||
|
||
The sim object is defined as a C++ class and must be derived from the base class
|
||
SimObject.
|
||
|
||
* `Class CannonSimObject`
|
||
The name of the sim_object class is arbitrary.
|
||
|
||
* `public Trick::SimObject`
|
||
As mentioned above, your sim_object class must be derived from the Trick base
|
||
class SimObject.
|
||
|
||
`public : CANNON cannon ;`
|
||
|
||
* `CANNON` This is the name of the structure typedef that you created in the
|
||
cannon.h header.
|
||
|
||
* `cannon` This is an alias for the CANNON structure. It is mandatory.
|
||
|
||
* `CannonSimObject()` This is the constructor of the sim_object and it will
|
||
contain the job declarations.
|
||
|
||
### Initialization Job
|
||
|
||
It is custom to refer to the C-functions created by the developer as **jobs**.
|
||
The statement below tells Trick how to handle the `cannon_init()` job.
|
||
|
||
("initialization") cannon_init( &cannon) ;
|
||
|
||
* `("initialization")`
|
||
This assigns `cannon_init()` a job classification of `initialization`. There are
|
||
many classes of jobs. The job classes, for the most part, determine the order
|
||
the job is called in the **executive loop**. If there are two jobs of the same
|
||
class in the `S_define`, the one seen first in the `S_define` is called first.
|
||
Jobs that are classified `initialization` will be called once before the main
|
||
executive loop and will not be called again.
|
||
|
||
* `cannon_init(`
|
||
The name of the function we created in $HOME/trick_sims/models/cannon/src/cannon_init.c.
|
||
|
||
* `&cannon)`
|
||
This is the actual value passed to cannon_init(). It is the address of the
|
||
object 'CANNON' structure and "cannon" is the alias for the CANNON structure.
|
||
|
||
### Default Data Job
|
||
The default data jobs are called one time before the initialization jobs.
|
||
|
||
`("default_data") cannon_default_data(&cannon) ;`
|
||
|
||
* `("default_data")`
|
||
This assigns cannon\_default\_data() a job classification of *default_data*.
|
||
|
||
|
||
### Scheduled Job
|
||
The next job needs to be called at a regular frequency while the cannonball is
|
||
flying in the air. A *scheduled* class job is one of many jobs that can be
|
||
called at a given frequency. The only thing new about the declaration for
|
||
cannon\_analytic is the additional specification of 0.01.
|
||
|
||
`(0.01, "scheduled") cannon_analytic(&cannon) ;`
|
||
|
||
|
||
* `(0.01, "scheduled")`
|
||
The 0.01 specification tells Trick to run this job every 0.01 seconds (starting
|
||
at time=0.0). "scheduled" is the job classification.
|
||
|
||
### Create The S\_define
|
||
|
||
```
|
||
% cd $HOME/trick_sims/SIM_cannon_analytic
|
||
% vi S_define
|
||
```
|
||
|
||
Type in the contents of **Listing 7** and save.
|
||
|
||
<a id=compiling-and-building-the-simulation></a>
|
||
## Compiling, and Building the Simulation
|
||
|
||
The pieces are in order. The simulation is ready to be built!
|
||
|
||
### Setting `$TRICK_CFLAGS` and `$TRICK_CXXFLAGS`
|
||
|
||
![TRICK_CFLAGS WARNING](images/Warning_TRICK_CFLAGS.png)
|
||
|
||
Before we continue with the magical building of the cannonball, **PLEASE** take
|
||
the time to understand this section. It will save you much heartache and time.
|
||
|
||
The environment variables **`$TRICK_CFLAGS`** and **`$TRICK_CXXFLAGS`** are used
|
||
to provide TRICK, and the compilers that it uses with information that is
|
||
necessary to build your sim. Most importantly, they will tell TRICK where to
|
||
find your model files. They also provide a way for you to invoke some very useful
|
||
compiler options.
|
||
|
||
* `$TRICK_CFLAGS` is used by the C compiler and by the Trick Interface Code Generator.
|
||
* `$TRICK_CXXFLAGS` is for C++ compiler
|
||
|
||
#### Resolving Relative Paths
|
||
|
||
In the files that we have created so far, the file paths in `#include` directives
|
||
and in the `LIBRARY_DEPENDENCY` sections, are **relative** paths. These paths
|
||
are relative to a **base-path**, that we still need to specify.
|
||
|
||
For example, the `S_define` file listed above, `#includes` the relative path:
|
||
`cannon/include/cannon.h`. We intend for this path to be relative to the
|
||
`trick_models` directory that we created in our `$HOME` directory. The complete
|
||
path to our cannon.h header file should be:
|
||
|
||
![Trick Path Construction](images/TrickPaths.png)
|
||
|
||
So, we need to specify the base-path(s), to the compilers, and to Trick by adding
|
||
-I*dir* options, that contain the base-paths, to `$TRICK_CFLAGS` and
|
||
`$TRICK_CXXFLAGS`.
|
||
|
||
The easiest, and most portable way of setting `TRICK_CFLAGS` for your simulation
|
||
is to create a file named **`S_overrides.mk`** in your simulation directory, and
|
||
then add the following lines to it:
|
||
|
||
<a id=listing_8_s_overrides.mk></a>
|
||
**Listing 8 - `S_overrides.mk`**
|
||
|
||
```sh
|
||
TRICK_CFLAGS += -Imodels
|
||
TRICK_CXXFLAGS += -Imodels
|
||
```
|
||
|
||
When Trick encounters relative paths, these base-paths will be prepended to the
|
||
relative paths to create a complete path to the file, thus allowing it to be
|
||
located.
|
||
|
||
#### Additional Compiler Flag Recommendations
|
||
|
||
Some additional compiler flags recommendations are provided in the `.cshrc` and
|
||
`.profile` snippets below. They tell the compilers to provide debugging support
|
||
and to check for and warn of possibly dubious code constructs.
|
||
|
||
##### For Your .profile File
|
||
```bash
|
||
export TRICK_CFLAGS="-g -Wall -Wmissing-prototypes -Wextra -Wshadow"
|
||
export TRICK_CXXFLAGS="-g -Wall -Wextra -Wshadow"
|
||
|
||
```
|
||
|
||
##### For Your .cshrc File
|
||
```bash
|
||
TRICK_CFLAGS= -g -Wall -Wmissing-prototypes -Wextra -Wshadow
|
||
TRICK_CXXFLAGS= -g -Wall -Wextra -Wshadow
|
||
```
|
||
|
||
### trick-CP
|
||
The source code and environment are set up. The Trick simulation build tool is
|
||
called **trick-CP** (Trick Configuration Processor). It is responsible for
|
||
parsing through the S_define, finding structures, functions, and ultimately
|
||
creating a simulation executable.
|
||
|
||
```
|
||
% cd $HOME/trick_sims/SIM_cannon_analytic
|
||
% trick-CP
|
||
```
|
||
|
||
If you typed everything perfectly... Trick is installed properly... there are no
|
||
bugs in the tutorial... the stars are aligned... and Trick is in a good mood...
|
||
You should, ultimately see :
|
||
|
||
![Simulation Make Complete](images/SimMakeComplete.png)
|
||
|
||
Now, take a look at the sim directory. Is there an `S_main*.exe` file?? (* is a wildcard, instead of * you will see the name of your platform). If so, cool deal. If not, scream!, then take a look at the next section "Troubleshooting A Bad Build". If all went well, you will notice several other files now resident in the `SIM_cannon_analytic` directory.
|
||
|
||
```bash
|
||
% ls
|
||
Modified_data S_overrides.mk makefile
|
||
RUN_test S_sie.resource trick.zip
|
||
S_define S_source.hh
|
||
S_main_<your_platform_name_here>.exe build
|
||
```
|
||
|
||
#### Troubleshooting A Bad Build
|
||
|
||
Here are some common problems.
|
||
|
||
* Trick cannot seem to find a function or structure that you have in your
|
||
S_define.
|
||
* Make sure that your TRICK_CFLAGS are set.
|
||
* You have a misspelling.
|
||
* In order for Trick to find a job, argument types must match exactly.
|
||
* Trick barfs when building the simulation
|
||
* One of your C routines may not compile because of a C syntax error.
|
||
* Trick was not installed properly on your system.
|
||
* trick-CP croaks - You may have a syntax error in your S_define.
|
||
|
||
|
||
<a id=running-the-simulation></a>
|
||
## Running The Simulation
|
||
|
||
You've done a lot of work to get to this point. You've created a header, a
|
||
default data job, an initialization job, a scheduled job, and an S_define.
|
||
You've also had to set up an environment and trudge through trick-CP errors. The
|
||
tiny Trickless main() program may be looking short-n-sweet at this point! There
|
||
can't be anything more to do!?! There is one more file to create to get the
|
||
cannonball out of the barrel and into the air.
|
||
|
||
### Simulation Input File
|
||
Every Trick simulation needs an input file. This input file will be simple (only
|
||
one line). In practice, input files can get ridiculously complex. The input file
|
||
is processed by Python. There is no need to recompile the simulation after
|
||
changing the input file. The file is interpreted.
|
||
|
||
<a id=listing_9_input_py></a>
|
||
**Listing 9 - input.py**
|
||
|
||
```python
|
||
trick.stop(5.2)
|
||
```
|
||
|
||
By convention, the input file is placed in a `RUN_*` directory.
|
||
|
||
```bash
|
||
% cd $HOME/trick_sims/SIM_cannon_analytic
|
||
% mkdir RUN_test
|
||
% cd RUN_test
|
||
% vi input.py <edit and save>
|
||
```
|
||
|
||
### Sim Execution
|
||
To run the simulation, simply execute the `S_main*exe`:
|
||
|
||
```bash
|
||
% cd $HOME/trick_sims/SIM_cannon_analytic
|
||
% ./S_main_*.exe RUN_test/input.py
|
||
```
|
||
|
||
If all is well, something similar to the following sample output will be
|
||
displayed on the terminal.
|
||
|
||
```
|
||
IMPACT: t = 5.096839959, pos[0] = 220.699644186
|
||
|
||
========================================
|
||
Cannon Ball State at Shutdown
|
||
t = 5.2
|
||
pos = [220.699644186, 0.000000000]
|
||
vel = [0.000000000, 0.000000000]
|
||
========================================
|
||
REALTIME SHUTDOWN STATS:
|
||
REALTIME TOTAL OVERRUNS: 0
|
||
ACTUAL INIT TIME: 0.203
|
||
ACTUAL ELAPSED TIME: 12.434
|
||
SIMULATION TERMINATED IN
|
||
PROCESS: 0
|
||
ROUTINE: Executive_loop_single_thread.cpp:98
|
||
DIAGNOSTIC: Reached termination time
|
||
|
||
SIMULATION START TIME: 0.000
|
||
SIMULATION STOP TIME: 5.200
|
||
SIMULATION ELAPSED TIME: 5.200
|
||
ACTUAL CPU TIME USED: 0.198
|
||
SIMULATION / CPU TIME: 26.264
|
||
INITIALIZATION CPU TIME: 0.144
|
||
```
|
||
|
||
We got the same answer! But, what about the trajectory? In the next section, we’ll see how to record our simulation variables to a file, so we can plot them.
|
||
|
||
---
|
||
|
||
[Next Page](ATutRecordingData)
|