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The Apollo spacecraft used for lunar missions in the late 1960's and early 1970's was really two different spacecraft, the Command Module (CM) and the Lunar Module (LM). The CM was used to get the three astronauts to the moon, and back again. The LM was used to land two of the astronauts on the moon while the third astronaut remained in the CM, in orbit around the moon.
Each of the spacecraft needed to be able to navigate through space, with or without the assistance of the astronauts, and therefore needed to have a "guidance system". The guidance system was developed by MIT's Instrumentation Lab, now an independent company known as the Charles Stark Draper Laboratory.
An important part of the guidance system was the Apollo Guidance Computer—or just "AGC" for short. On any given Apollo mission, there were two AGCs, one for the Command Module, and one for the Lunar Module. The two AGCs were identical and interchangeable, but they ran different software because the tasks the spacecraft had to perform were different. Moreover, the software run by the AGC evolved over time, so that the AGC software used in later missions like Apollo 17 differed somewhat from that of earlier missions like Apollo 8.
Considered just as a computer, the AGC was severely underpowered by modern standards.
Since you are looking at this README file, you are in the "master" branch of the repository, which contains source-code transcriptions of the original Project Apollo software for the Apollo Guidance Computer (AGC) and Abort Guidance System (AGS), as well as our software for emulating the AGC, AGS, and some of their peripheral devices (such as the display-keyboard unit, or DSKY).
Other branches of the repository often contain very different files. Here are some of the more-significant branches which differ in that way from the master branch:
- gh-pages: HTML files and imagery for the main Virtual AGC Project website. Contains the complete website, exclusive of the large library of scanned supplementary documentation and drawings.
- mechanical: 2D CAD files and 3D models in DXF and STEP formats, intended to replicate the original AGC/DSKY mechanical design.
- scenarios: Pad loads or other setup for mission scenarios.
- schematics: CAD transcriptions in KiCad format of the original AGC/DSKY electrical design.
- wiki: Wiki files associated with the repository.
- 2048 words of RAM. A "word" was 15 bits of data—therefore just under 2 bytes (16 bits) of data—and so the total RAM was just 3840 bytes.
- 36,864 words of read-only memory, equivalent to 69,120 bytes.
- Maximum of about 85,000 CPU instructions executed per second.
- Dimensions: 24.250"Ă—12.433"Ă—5.974" (61.595cmĂ—31.580cmĂ—15.174cm).
- Weight: 70.1 pounds (31.8kg).
- Power supply: 2.5A of current at 28V DC
- Real DSKY.
It is occasionally quipped—with perhaps greater wit than insight—that the AGC was more like a calculator than a computer. But to say this is to grossly underestimate the AGC's sophistication. For example, the AGC was multi-tasking, so that it could seemingly run multiple programs simultaneously.
Another important part of the guidance system was the Display/Keyboard unit—or just "DSKY" for short. The AGC by itself was simply a box with electrical connections, without any built-in way for the astronaut to access it. The DSKY provided the astronaut with an interface by which to access the AGC.
The Lunar Module had a single DSKY, positioned between the two astronauts where it could be operated by either of them. The Command Module actually had two DSKYs. One of the CM's DSKYs was only the main control panel, while the other was positioned near the optical equipment used to mark the positions of stars or other landmarks.
- Dimensions: 8.124"Ă—8.000Ă—6.91" (21.635cmĂ—20.320cmĂ—17.551cm)
- Weight: 17.8 pounds (8.1kg)
Perhaps the most important part of the guidance system was the Inertial Measurement Unit—or just "IMU" for short. The IMU continuously kept track of the acceleration and rotation of the spacecraft, and reported this information back to the AGC. By mathematically processing this data, the AGC could know on a moment-by-moment basis the orientation and position of the spacecraft.
This repository is associated with the website of the Virtual AGC project, which provides a virtual machine which simulates the AGC, the DSKY, and some other portions of the guidance system. In other words, if the virtual machine—which we call yaAGC—is given the same software which was originally run by the real AGCs, and is fed the same input signals encountered by the real AGCs during Apollo missions, then it will respond in the same way as the real AGCs did.
The Virtual AGC software is open source code so that it can be studied or modified. The repository contains the actual assembly-language source code for the AGC, for as many missions as we've been able to acquire, along with software for processing that AGC code. Principal tools are an assembler (to create executable code from the source code) and a CPU simulator (to run the executable code), as well as simulated peripherals (such as the DSKY). Similar source code and tools are provided for the very-different abort computer that resided in the Lunar Module. Finally, any supplemental software material we have been able to find or create for the Saturn rocket's Launch Vehicle Digital Computer or for the Gemini on-board computer (OBC) are provided, though these materials are minimal at present.
Virtual AGC is a computer model of the AGC. It does not try to mimic the superficial behavioral characteristics of the AGC, but rather to model the AGC's inner workings. The result is a computer model of the AGC which is itself capable of executing the original Apollo software on (for example) a desktop PC. In computer terms, Virtual AGC is an emulator. Virtual AGC also provides an emulated Abort Guidance System (AGS) and (in the planning stages) an emulated LVDC. Virtual AGC is a catch-all term that comprises all of these.
The current version of the Virtual AGC software has been designed to work in Linux, in Windows XP/Vista/7, and in Mac OS X 10.3 or later (but 10.5 or later is best). It also works in at least some versions of FreeBSD. However, since I personally work in Linux, I have the most confidence in the Linux version.
You can read about this project in more detail here: http://www.ibiblio.org/apollo/index.html
Virtual AGC is not a flight simulator, nor a lunar-lander simulator, nor even a behavioral simulation of the Apollo Lunar Module (LM) or Command-Module (CM) control panels. (In other words, if you expect a realistic LM control panel to suddenly appear on your computer screen, you'll be disappointed.) Virtual AGC could be used, however, as a component of such a simulation, and developers of such software are encouraged to do so. Indeed, some developers already have! See the FAQ for more information: http://www.ibiblio.org/apollo/faq.html
Caution: The requirements in this README may not be fully up-to-date vs the official ones listed on the Virtual AGC website. You are advised to consult the website.
- Tcl/Tk is required for all platforms.
- Requires Fedora Core 4 or later.
- Requires Ubuntu 7.04 or later.
- Requires SuSE 10.1 or later.
- Known to work on Raspbian (Raspberry Pi) 2016-05-27.
- et, presumably, cetera.
- 32 and 64-bit systems have been tested successfully.
- The X-Window system, xterm, and gtk+ libraries must be installed.
- You will need the normal gcc C/C++ compiler toolchain, as well as developer packages ("dev" or "devel") for wxWidgets, ncurses and SDL.
On Fedora 22 or later you may encounter that the wxWidgets doesn't have the wx-config but the wx-config-3.0 utility as well as the wxrc-3.0 versus wxrc. Just create a symbolic link for wx-config and wxrc respectively
- Requires XP or later. 32-bit systems have been tested successfully.
- Vista and Windows 7 may need workarounds. For example, on the Windows platform it is expected that the Tcl/Tk installation program will create a file called
wish.exe
but on Windows Vista the installation program creates a file calledwish85.exe
. This prevents certain features of Virtual AGC from working. The workaround is to duplicate the filec:\tcl\bin\wish85.exe
and call the duplicatec:\tcl\bin\wish.exe
. - Windows 98 or prior are known not to work. Windows 2000 has not been tested.
- You will need the MinGW compiler with the options selected - if offered - of including g++ compiler and make.
- You will also need the Msys environment, wxWidgets 2.8.9 or above, POSIX Threads for Windows, GNU readline for Windows and the regular-expression library from MinGW called libgnurx.
- Requires 10.4 and later for Intel or PowerPC
- 10.2 or prior are known not to work.
- Requires FreeBSD 7.2 or later.
- Requires PC-BSD 7.1 or later.
- You will need to install wxWidgets 2.8.9, GNU readline 6.0 into
/usr/local
. - libSDL must be installed
- Requires OpenSolaris 0811.
- The code is only confirmed to partially work on this platform.
- You will need SUNWgnome-common-devel, SUNWGtk, SUNWxorg-headers, FSWxorg-headers, SUNWncurses, SUNWtcl, SUNWtk and SUNWlibsdl
- You will also need GNU readline 6.0, wxWidgets 2.8.9 (with
configure --disable-shared
), Allegro 4.2.2 (with "configure --enable-shared=no --enable-static=yes") and to put/usr/local/bin
and/or/usr/local/bin/wx-config
linked into yourPATH
.
- wasi-sdk version 16 provides a WebAssembly toolchain (consisting of the compiler
clang
from the LLVM project, and the C/C++ standard librarywasi-libc
that can compile to WASI system calls).
More information at http://www.ibiblio.org/apollo/download.html#Build
Caution: The instructions in this README may not be fully up-to-date vs the official ones listed on the Virtual AGC website. You are advised to consult the website.
These instructions relate specifically to building from source as of 2016-08-07 on 64-bit Linux Mint 17.3. I'm sorry to have to make them so specific, but hopefully they are easily adapted to other Linux environments. Alternate build instructions (for example, for Raspberry Pi) may be found at http://www.ibiblio.org/apollo/download.html.
You will probably have to install a variety of packages which aren't normally installed. I found that I had to install the following, which were all available from the standard software repositories (in Linux Mint, anyway):
- libsdl1.2-dev
- libncurses5-dev
- liballegro4.4-dev or liballegro4-dev
- g++
- libgtk2.0-dev
- libwxgtk2.8-dev
To build, simply cd
into the directory containing the source and do:
make
Note:
-
Do not
configure
and do notmake install
. While there is aconfigure
script provided, it is presently used only for setting up builds of a couple of now-obsoleted programs, and it does not matter whether you run it or not nor whether it succeeds or fails. If the build does not complete because of a difference when comparing thebin
files then you can rebuild withmake -k
to keep going. This however might mask other issues. -
Do not parallelise make, i.e. do not run
make -j$(nproc)
. This will prevent copying of files to correct places.
The build results can be found at VirtualAGC/temp/lVirtualAGC/
, which contain the binaries and required resources in the correct paths. The VirtualAGC binary can be run at VirtualAGC/temp/lVirtualAGC/bin/VirtualAGC
.
To match the default setup of the installer program execute the following:
mv VirtualAGC/temp/lVirtualAGC ~/VirtualAGC
You can make a desktop icon called Virtual AGC that links to VirtualAGC/bin/VirtualAGC
. The image normally used for the desktop icon is found at VirtualAGC/bin/ApolloPatch2.png
.
If you try to use the ACA simulation (joystick) and it doesn't work you can find some information on configuring it here: http://www.ibiblio.org/apollo/yaTelemetry.html#Joystick_configuration_for_use_with_the
Run Msys
to bring up a command shell and enter your home directory.
Install the SDL library with this command:
make install-sdl prefix=/usr/local
All software needed to build Virtual AGC will be installed under /usr/local
, so eventually it will be populated with sub-directories such as /usr/local/bin
, /usr/local/include
, /usr/local/lib
, and so on. The Virtual AGC makefiles are hard-coded to assume these installation locations. Note, the Virtual AGC binaries you are going to create are not installed under /usr/local
.
At present, Virtual AGC binary packages are always built with wxWidgets 2.8.9, so 2.8.9 is a safe choice. Unpack the tarball in your home directory, 'cd' into the directory this creates, and then do ./configure
, make
, and make install
. The configure
step will accept various command-line options that select unicode vs. ansi, static linking vs. dynamic linking, etc., but the default options seem to work fine.
Install POSIX Threads for Windows ("pthreads"). You can do this by unpacking the source tarball, 'cd' into the directory it creates, then run the command make clean GC-inlined
. This creates various files that you should copy into /usr/local
as follows: copy \*.dll
into /usr/local/bin
; copy \*.h
into /usr/local/include
; copy the single libpthread\*.a
file created into /usr/local/lib
and rename it libpthread.a
.
Install GNU readline for Windows. You should find zipfiles of both binaries and developer files are available for download. They should both be downloaded and unpacked into /usr/local
. (I.e., each zipfile contains directories like bin/
, include/
, lib/
, and so on, and we want these to be merged into /usr/local/bin/
, /usr/local/include/
, etc.)
Install a regular-expression library. The MinGW project has a "contributed" regex library ("libgnurx") that you can use. Download both the bin
and dev
tarballs and unpack them into /usr/local
.
If all of this was done correctly you can build the Virtual AGC as follows:
Unpack the development tarball in your home directory:
tar -xjvf yaAGC-dev-YYYYMMDD.tar.bz2
Build it:
make -C yaAGC WIN32=yes
On Windows 7 (but not on XP) it is also necessary to copy c:\MinGW\bin\mingwm10.dll
to yaAGC/VirtualAGC/temp/lVirtualAGC/Resources/
.
This will create a directory yaAGC/VirtualAGC/temp/lVirtualAGC/
which is the "installation directory". This directory is relocatable and need to remain within the Msys environment so you can move it wherever you like. Regardless you really need to create a desktop icon in order to run the program. The desktop icon should point to lVirtualAGC\bin\VirtualAGC.exe
as the executable, and should use a "starting directory" of lVirtualAGC\Resources
. The graphic normally used for the desktop icon is ApolloPatch2.jpg
in the lVirtualAGC\Resources
directory.
From the command line unpack the development-snapshot tarball as follows:
tar --bzip2 -xf yaAGC-dev-YYYYMMDD.tar.bz2
Get the Terminator application's dmg file: https://storage.googleapis.com/google-code-archive-downloads/v2/code.google.com/jessies/terminator-26.159.6816.zip
Open the Terminator dmg file and drag the Terminator application to the working directory in which you created yaAGC/
above.
From a command line in that working directory, make a tarball from Terminator.app:
tar -cjvf Terminator.app.tar.bz2 Terminator.app
Once you have the tarball, you can delete the Terminator app and its dmg file.
From the working directory (not from within the yaAGC/
directory) build Virtual AGC:
make -C yaAGC MACOSX=yes
In the folder yaAGC/VirtualAGC/temp/
you will now find the VirtualAGC application.
Drag the VirtualAGC application from yaAGC/VirtualAGC/temp/
to the desktop.
From the command line unpack the development-snapshot tarball as follows: tar --bzip2 -xf yaAGC-dev-YYYYMMDD.tar.bz2
After unpacking there will be a new directory called yaAGC
. To build the program:
gmake FREEBSD=yes
Do not configure
and do not gmake install
.
You will find that this has created a directory yaAGC/VirtualAGC/temp/lVirtualAGC/
.
To match the default setup of the installer program execute the following:
mv yaAGC/VirtualAGC/temp/lVirtualAGC ~/VirtualAGC
You can make a desktop icon called Virtual AGC that links to /VirtualAGC/bin/VirtualAGC
. The image normally used for the desktop icon is found at /VirtualAGC/bin/ApolloPatch2.png
.
If you try to use the ACA simulation (joystick) and it doesn't work you can find some information on configuring it here: http://www.ibiblio.org/apollo/yaTelemetry.html#Joystick_configuration_for_use_with_the
Unpack the Virtual AGC snapshot tarball:
tar --bzip2 -xf yaAGC-dev-YYYYMMDD.tar.bz2
Open the yaAGC/
directory and build:
make SOLARIS=yes
Do not configure
and do not gmake install
.
You'll find that this has created a directory yaAGC/VirtualAGC/temp/lVirtualAGC/
.
To match the default setup of the installer program execute the following:
mv yaAGC/VirtualAGC/temp/lVirtualAGC ~/VirtualAGC
You can make a desktop icon called Virtual AGC that links to /VirtualAGC/bin/VirtualAGC
. The image normally used for the desktop icon is found at /VirtualAGC/bin/ApolloPatch2.png
.
Unfortunately the ACA simulation (joystick) programs do not work in this environment.
The Virtual AGC build scripts assume that wasi-sdk
is installed
at the filesystem location /opt/wasi-sdk
. You can customize this path by setting
the environment variable WASI_SDK_PATH
to /path/to/wasi-sdk
when running make
.
For all WebAssembly builds, set the environment variable WASI
to yes
when running make
.
Currently, only the following Virtual AGC components can be compiled for the WebAssembly target:
If you have any leftover build artifacts in the yaAGC
directory, run
make clean
in it.
To build, simply cd
into the root directory and do:
WASI=yes make yaAGC
This will produce yaAGC.wasm
(roughly 32 kB). You could use tools like wasm-opt
(from the
binaryen
package) and wasm-strip
(from the wabt
package) to optimize the code and reduce its
size.
To additionally get a text representation of the generated WebAssembly code, you could use the tool
wasm2wat
(from the wabt
package).
This Readme was created from information contained in the main project website here: http://www.ibiblio.org/apollo/index.html
The project website was created by Ronald Burkey. The first version of this Readme was compiled by Shane Coughlan.