Difference between revisions of "Documentation"
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+ | * [http://hginit.com/ hginit] provides a good introduction to the basic Mercurial concept | ||
+ | * [http://mercurial.selenic.com/guide/ Mercurial Guide] also provides a good basic introduction | ||
+ | * [http://hgbook.red-bean.com/read/ HGBook] is the definitive guide to Mercurial | ||
===Building=== | ===Building=== |
Revision as of 22:18, 7 March 2011
Outline for some new documentation. Maybe we should be doing this wit LaTeX and using pandoc (LaTeX->mediawiki converter)?
Contents
- 1 Getting Started
- 2 Source Code
- 3 Build System
- 4 SimObjects
- 5 Configuration Scripts
- 6 General memory system
- 7 Classic memory system
- 8 Ruby
- 9 Events
- 10 Devices
- 11 Execution Basics
- 12 Architectural State
- 13 Address Translation
- 14 CPUs
- 15 Interrupts
- 16 ISA parser
- 17 Multiple ISA support
- 18 Alpha Implementation
- 19 ARM Implementation
- 20 MIPS Implementation
- 21 Power Implementation
- 22 SPARC Implemenation
- 23 X86 Implementation
- 24 Pseudo Instructions
- 25 SE mode
- 26 Statistics (don’t know what to say here)
- 27 Summary: gem5 Capabilities/Recipes
- 28 Utility Code
- 29 Debugging
- 30 Development Tools/Contributing
- 31 External Dependencies
Getting Started
What is gem5?
gem5 is a modular discrete event driven computer system simulator platform. That means that:
- gem5's components can be rearranged, parameterized, extended or replaced easily to suite your needs.
- It simulates the passing of time as a series of discrete events.
- It's intended use is to simulate one or more computer systems in various ways.
- It's more than just a simulator, it's a simulator platform that lets you use as many of its premade components as you want to build up your own simulation system.
gem5 is written primarily in C++ and python and most components are provided under a BSD style license. It can simulate a complete system with devices and an operating system in full system mode (FS mode), or user space only programs where system services are provided directly by the simulator in syscall emulation mode (SE mode). There are varying levels of support for executing Alpha, ARM, MIPS, Power, SPARC, and 64 bit x86 binaries on CPU models including two simple single CPI models, an out of order model, and an in order pipelined model. A memory system can be flexibly built out of caches and interconnects. Recently the Ruby simulator has been integrated with gem5 to provide even better, more flexible memory system modeling.
There are many components and features not mentioned here, but from just this partial list it should be obvious that M5 is a sophisticated and capable simulation platform. Even with all gem5 can do today, active development continues through the support of individuals and some companies, and new features are added and existing features improved on a regular basis. For the most up to date information you can check out the project's website at www.gem5.org.
Pointer to gem5 Capabilities/Recipes
Getting a copy
M5's source code is managed using the mercurial revision control system. There are several repositories you may be interested in:
- m5 – The main repository is where active development takes place.
- m5-stable – A repository which lags behind “m5” repository but has basically the same contents. It’s usually better to use “m5” instead of “m5-stable”
- encumbered – A repository for extensions to M5 that are under a different, more restrictive license. Currently this only includes support for SimpleScalar's EIO trace format.
- linux-patches – A repository for patches to the linux kernel that modify it so it can be simulated more efficiently. These patches are optional, but it's a good idea to use them if possible to cut down on simulation run time.
To check out a copy, first, make sure you have mercurial installed on your system and that you can run the hg command. Then use hg clone to create your own local copy using the URL http://repo.m5sim.org/XXX where XXX is replaced by the name of the repository your interested in. For example, to check out the main repository, you'd use the command:
hg clone http://repo.m5sim.org/m5
You can find out more about mercurial and its commands using its built in help by running:
hg help
or by visiting any of the following websites:
- hginit provides a good introduction to the basic Mercurial concept
- Mercurial Guide also provides a good basic introduction
- HGBook is the definitive guide to Mercurial
Building
M5 uses the scons build system which is based on python. To build the simulator binary, run scons from the top of the source directory with a target of the form build/<config>/<binary> where <config> is replaced with one of the predefined set of build parameters and <binary> is replaced with one of the possible m5 binary names. The predefined set of parameters determine build wide configuration settings that affect the behavior, composition, and capabilities of the binary being built. These include whether the simulator will run in FS or SE mode, if Ruby support is included, which ISA will be supported, which CPU models to build, and what coherence protocol Ruby should use. Examples are ARM_FS, X86_SE, and ALPHA_SE_MOESI_CMP_token. All of the available options can be found in the build_opts directory, and it should be fairly easy to see what each is for. We'll talk about the build system in more detail later. Valid binary names are m5.debug, m5.opt, m5.fast, and m5.prof. These binaries all have different properties suggested by their extension. m5.debug has optimization turned off to make debugging easier in tools like gdb, m5.opt has optimizations turned on but debug output and asserts left in, m5.fast removes those debugging tools, and m5.prof is built to use with gprof. Normally you'll want to use m5.opt. To build the simulator in syscall emulation mode with Alpha support, optimizations turned on, and debugging left in, you would run:
scons build/ALPHA_SE/m5.opt
In your source tree, you'd then find a new build/ALPHA_FS/ directory with the requested m5.opt in it. For the rest of this chapter we'll assume this is the binary you're using.
Running
Now that you've built M5, it's time to try running it. An M5 command line is composed of four parts, the binary itself, options for M5, a configuration script to run, and then finally options for the configuration script. Several example configuration scripts are provided in the “configs/example” directory and are generally pretty powerful. You are encouraged to make your own scripts, but these are a good starting point. The example script we'll use in SE mode is called se.py and sets up a basic SE mode simulation for us. We'll tell it to run the hello world binary provided in the M5 source tree.
build/ALPHA_SE/m5.opt configs/example/se.py -c tests/test-progs/hello/bin/alpha/linux/hello
This builds up a simulated system, tells it to run the binary found at the location specified, and kicks off the simulation. As the binary runs, it's output is sent to the console by default and looks like this:
M5 Simulator System Copyright (c) 2001-2008 The Regents of The University of Michigan All Rights Reserved M5 compiled Feb 12 2011 20:43:55 M5 revision e00ef55a2c49 7933 default tip M5 started Feb 12 2011 20:45:47 M5 executing on fajita command line: build/ALPHA_SE/m5.opt configs/example/se.py -c tests/test-progs/hello/bin/alpha/linux/hello Global frequency set at 1000000000000 ticks per second 0: system.remote_gdb.listener: listening for remote gdb #0 on port 7000 **** REAL SIMULATION **** info: Entering event queue @ 0. Starting simulation... info: Increasing stack size by one page. Hello world! hack: be nice to actually delete the event here Exiting @ tick 3240000 because target called exit()
You can see a lot of output from the simulator itself, but the line “Hello world!” came from the simulated program. In this example we didn't provide any options to M5 itself. If we had, they would have gone on the command line between m5.opt and se.py. If you'd like to see what command line options are supported, you can pass the --help option to either M5 or the configuration script. The two groups of options are different, so make sure you keep track of whether they go before or after the configuration script.
Asking for help
M5 has two main mailing lists where you can ask for help or advice. m5-dev is for developers who are working on the main version of M5. This is the version that's distributed from the website and most likely what you'll base your own work off of. m5-users is a larger mailing list and is for people working on their own projects which are not, at least initially, going to be distributed as part of the official version of M5. Most of the time m5-users is the right mailing list to use. Most of the people on m5-dev are also on m5-users including all the main developers, and in addition many other members of the M5 community will see your post. That helps you because they might be able to answer your question, and it also helps them because they'll be able to see the answers people send you. To find more information about the mailing lists, to sign up, or to look through archived posts visit:
http://m5sim.org/wiki/index.php/Mailing_Lists
Cross-product status matrix
gem5 combines several different ISAs, system modes (SE or FS), CPU models and memory models under a single infrastructure. The cross-product of these combinations may or may not actually work. The following page describes the current status of these combinations.
http://m5sim.org/wiki/index.php/Status_Matrix
Source Code
Tour of the tree
These are the files and directories at the top of the tree:
AUTHORS LICENSE README RELEASE_NOTES SConstruct build_opts configs ext src system tests util
AUTHORS, LICENSE, README are files with general information about the simulator. AUTHORS is a list of people who have historically contributed to M5. LICENSE has the license terms that applies to M5 as a whole, unless overridden by a more specific license. README has some very basic information introducing M5 and explaining how to get started.
The SConstruct file is part of the build system, as is the build_opts directory. build_opts holds files that define default settings for build different build configurations. These include X86_FS and MIPS_SE, for instance.
The configs directory is for simulation configuration scripts which are written in python. These are described in more detail later. The files in this directory help make writing configurations easier by providing some basic prepackaged functionality, and include a few examples which can be used directly or as a starting point for your own scripts.
The ext directory is for things M5 depends on but which aren’t actually part of M5. Specifically these are for dependencies that are harder to find, not likely to be available, or where a particular version is needed.
The src directory is where most of M5 is located. This is where all of the C++ and python source that contributes to the M5 binary is kept, excluding components in the ext directory.
The system directory is for the source for low level software like firmware or bootloaders for use in simulated systems. Currently this includes Alpha’s PAL and console code, and a simple bootloader for ARM.
The tests directory stores files related to M5’s regression tests. These include the scripts that build up the configurations used in the tests and reference outputs. Simple hello world binaries are also stored here, but other binaries need to be downloaded separately.
Finally, in the util directory are utility scripts, programs and useful files which are not part of the M5 binary but are generally useful when working on M5.
Style rules
Generated files - where do they end up
.m5 config files
jobfile to run multiple jobs
Build System
M5's build system is based on Scons, an open source build system implemented in python. You can find more information about scons at www.scons.org. The main scons file is called SConstruct and is found in the root of the source tree. additional scons files are called SConscript and are found throughout the tree, usually near the files they're associated with.
Build targets
In M5, scons build targets are of the form <build dir>/<configuration>/<target>. The <build dir> part of the target is a directory path that ends in "build". Typically this is simply "build" by itself, but you can specify a directory called "build" located somewhere else instead. The <configuration> part selects a set of preset build configuration variables values which correspond to common . The possible options are the file names in the build_opts directory, and are discussed more below. The build targets can be regression tests which are explained in more detail below, or they can be different versions of the M5 binary. The name of the binary is "m5" with an extension that specifies what version to build. Currently supported versions are m5.debug, m5.opt, m5.fast, and m5.prof.
m5.debug has optimizations turned off. This ensures that variables won't be optimized out, functions won't be unexpectedly inlined, and control flow will won't behave in surprising ways. That makes this version easier to work with in tools like gdb, but without optimizations this version is significantly slower than the others. You should choose it when using tools like gdb and valgrind and don't want any details obscured, but other wise more optimized versions are recommended.
m5.opt has optimizations turned on and debugging functionality like asserts and DPRINTFs left in. This gives a good balance between the speed of the simulation and insight into what's happening in case something goes wrong. This version is best in most circumstances.
m5.fast has optimizations turned on and debugging functionality compiled out. This pulls out all the stops performance wise, but does so at the expense of run time error checking and the ability to turn on debug output. This version is recommended if you're very confident everything is working correctly and want to get peak performance from the simulator.
m5.prof is similar to m5.fast but also includes instrumentation that allows it to be used with the gprof profiling tool. This version is not needed very often, but can be used to identify the areas of M5 that should be focused on to improve performance.
These versions are summarized in the following table.
Binary name | Optimizations | Run time debugging support | Profiling support |
---|---|---|---|
m5.debug | X | ||
m5.opt | X | X | |
m5.fast | X | ||
m5.prof | X | X |
Command line options
Scons will recognize the following command line options specific to M5.
Option | Effect |
---|---|
--color | Turn on colorized output |
--no-color | Turn off colorized output |
Environment variables
The following environment variables are imported from the host environment for use in scons:
Variable | Use |
---|---|
AS | Assembler command |
AR | Archive tool command |
CC | C compiler command |
CXX | C++ compiler command |
HOME | User's home directory |
LD_LIBRARY_PATH | Path to search for library files |
PATH | Path to search for programs |
PYTHONPATH | Path to search for python files |
RANLIB | Ranlib command |
M5_CONFIG | Where to look for the special ".m5" directory |
M5_DEFAULT_BINARY | The default build target which overrides the default default build/ALPHA_SE/m5.debug |
Configuration variables
These configuration variables are used to control the way M5 is built. Some are global, affecting all configurations built in the same build directory. Some are sticky, which means they retain their value once set. The available options are summarized in the following tables.
Global sticky
Variable | Description | Default |
---|---|---|
CC | C Compiler | CC environment variable or value determined by scons |
CXX | C++ Compiler | CXX environment variable or value determined by scons |
BATCH | Use batch pool for build and tests | False |
BATCH_CMD | Batch pool submission command | qdo |
M5_BUILD_CACHE | Cache built objects in this directory | False |
EXTRAS | Add extra directories to the compilation |
Global non-sticky
Variable | Description | Default |
---|---|---|
VERBOSE | Print full tool command lines | False |
update_ref | Update test reference outputs | False |
Non-global sticky
Variable | Description | Default | Exported as config/*.hh |
---|---|---|---|
TARGET_ISA | Target ISA | alpha | X |
FULL_SYSTEM | Full-system support | False | X |
CPU_MODELS | CPU Models | AtomicSimpleCPU,InOrderCPU,O3CPU,TimingSimpleCPU | |
NO_FAST_ALLOC | Disable fast object allocator | False | X |
FAST_ALLOC_DEBUG | Enable fast object allocator debugging | False | X |
FAST_ALLOC_STATS | Enable fast object allocator statistics | False | X |
EFENCE | Link with Electric Fence malloc debugger | False | |
SS_COMPATIBLE_FP | Make floating-point results compatible with SimpleScalar | False | X |
USE_SSE2 | Compile for SSE2 (-msse2) to get IEEE FP on x86 hosts | False | |
USE_MYSQL | Use MySQL for stats output | whether mysql_config was found | X |
USE_POSIX_CLOCK | Use POSIX Clocks | whether posix clocks are available on this host | X |
USE_FENV | Use <fenv.h> IEEE mode control | whether fenv.h was found on this host | X |
USE_CHECKER | Use checker for detailed CPU models | False | X |
CP_ANNOTATE | Enable critical path annotation capability | False | X |
RUBY | Build with Ruby | False | |
PROTOCOL | Coherence protocol for Ruby | MI_example | X |
NO_HTML | Do not create HTML files | False | |
NO_VECTOR_BOUNDS_CHECKS | Don't do bounds checks | True | X |
GEMS_ROOT | Add debugging stuff to Ruby | the directory where GEMS is stored, currently src/mem | X |
Setting configuration variable values
The first way you set configuration variable values is through the configuration name you choose as part of the build target. This file is loaded from build_opts and contains preset values for some of these variables which configures the build as the file name suggests. For instance, using the SPARC_FS configuration will turn on full system mode with the FULL_SYSTEM variable and set the TARGET_ISA to sparc.
It is important to note that the values in the file corresponding to the configuration you picked are -default- values and are only used if no directory already exists with its own values already in place. Those files are for defining reasonable starting points to configure M5 to behave the way you want it to, and are not intended to actively configure a particular build.
If you want to change a value after your build and configuration directory is already created, or if you want to override a value as it's created, you can specify the new values on the command line. The syntax is similar to setting environment variables at a shell prompt, but these go after the scons command. For example, to turn on RUBY support for an existing ALPHA_FS build, you could use the following command.
scons RUBY=True build/ALPHA_FS/m5.opt
It's often a good idea to add --help to the scons command line which will print out all of the configuration variables and what their values are. This way you can make sure everything is set up like you want, and that you don't have any typos in any variable names. If everything is as you expect, you can remove --help to actually start the build.
Running regressions
Adding files to the build
Using EXTRAS
SimObjects
The python side
Param types
Inheritance
Special attribute names
Rules for importing - how to get what
Pro tips - avoiding cycles, always descend from root, etc.
The C++ side
create functions
Stages of initialization
Header files to include
Configuration Scripts
SimObject hierarchy
Explanation of infrastructure scripts in configs
How to use se.py and fs.py.
How to use other top level scripts (what are they?)
Where M5 looks for files
General memory system
Ports system
Ports in general
Various port types
Packets
Requests
Atomic/Timing/Functional accesses
Two memory systems: Classic and Ruby
Classic memory system
Summarize functionality and highlight advantages and disadvantages. Uses ports to connect all components.
Ruby memory system
Summarize functionality and highlight advantages and disadvantages. Uses ports to connect cpus to the Ruby memory system. Uses message buffers to connect components within the memory system.
Classic memory system
MemObjects
Caches
Hooking them up
Parameters
Interconnects
Buses
Bridges
Anything else?
Coherence
Ruby
High level components of Ruby
Need to talk about the overview of Ruby and what are the major components.
Rathijit will do it
SLICC + Coherence protocols:
Need to say what is SLICC and whats its purpose. Talk about high level strcture of a typical coherence protocol file, that SLICC uses to generate code. A simple example structure from protocol like MI_example can help here.
Nilay will do it
Protocol independent memory components
- Cache Memory
- Replacement Policies
- Memory Controller
Arka will do it
Topologies and Networks
There is a separation between the network topology and the implementation.
Rathijit will do it
Implementation of Ruby
Low level details goes here. Need to explain code directory structure as well.
SLICC
Explain functionality/ capability of SLICC Talk about AST, Symbols, Parser and code generation in some details but NO need to cover every file and/or functions. Few examples should suffice.
Nilay will do it
Protocols
Need to talk about each protocol being shipped. Need to talk about protocol specific configuration parameters. NO need to explain every action or every state/events, but need to give overall idea and how it works and assumptions (if any).
MI example
MI protocols don't support LL/SC semantics.
Rathijit will do it
MOESI_hammer
Somayeh will do it
MOESI_CMP_token
Shoaib will do it
MOESI_CMP_directory
Rathijit will do it
MESI_CMP_directory
Arka will do it
Protocol Independent Memory components
System
Arka will do it
Sequencer
Arka will do it
CacheMemory
Arka will do it
DMASequencer
Derek will do it
Memory Controller
Rathijit will do it
Topologies and Networks
Topology specification
Python files specify connections. Shortest path graph traversals program the routing tables.
Network implementation
- SimpleNetwork
- Garnet
Life of a memory request in Ruby
Cpu model generates a packet -> RubyPort converts it to a ruby request -> L1 cache controller converts it to a protocol specific message ...etc.
Arka will do it
Events
Event queue
EventManager objects (I don’t know a lot about these)
Event objects
Time sync
Devices
I/O device base classes
IDE
NICS
Timers
PCI devices
DMA devices
UARTs and serial terminals
Execution Basics
Predecoding
StaticInsts
Microcode support
ExecContext
ThreadContext
Faults
Architectural State
Registers
Register types - float, int, misc
Indexing - register spaces stuff
PCs
Address Translation
TLB management
Delayed translation
Page table walkers (defer to ISA discussion?)
Differences between SE and FS mode
CPUs
Simple CPU
Flow of execution
Sharing of code between atomic and timing
O3 CPU
Anatomy of the pipeline
DynInsts
Wires/delay
Squashing
Load/store handling
Renaming
etc.
InOrder (what to say here?)
Interrupts
Traditional handling with platform object
New, currently X86 only system
Interrupt sources/sinks/wires/pins
Interrupt messages
Interrupt managing objects in the CPU
ISA parser
Formats
operands
decode tree
let blocks
microcode assembler
microops
macroops
directives
rom object
Lots more stuff
Multiple ISA support
Switching header files
Specialized classes and functions
Matrix of supported ISA/mode/CPU combinations
Alpha Implementation
ARM Implementation
Supported features and modes
Thumb support
Special PC management
MIPS Implementation
Power Implementation
SPARC Implemenation
Supported features and modes
X86 Implementation
Microcode ISA
Macroop specialization
Platform objects
Physical memory space allocation
Supported features and modes
Pseudo Instructions
List of pseudo instructions and what they do
How to get at and use them from a binary, script, etc.
SE mode
Loading binaries
System call instruction handling
Implementation of various system calls
Limitations
Statistics (don’t know what to say here)
Summary: gem5 Capabilities/Recipes
Atomic mode
Only supported by the classic memory system.
Timing mode
Classic memory system
Ruby memory system
MOESI_hammer in ALPHA_SE mode running multiple SPEC benchmarks with Mesh topology
Highlight no DMA controllers
??? FS mode
Highlight DMA controllers and how they are connected in the network.
Atomic mode then timing mode
Only supported with the classic memory system.
Utility Code
Bitfield functions
BitUnion classes
FastAlloc
IntMath
panic, warn, etc., when to use what
random number generation
reference counting pointers
Debugging
Trace flags
State trace/Tracer objects
Remote GDB support
tracediff
Regressions
Unit tests
Development Tools/Contributing
his page describes the methods available to extend M5 while preserving the ability to update to new versions. If you intend to make any changes to M5 we strongly advise you to follow one of the following methods. It will save you a great deal of time in the future and allow you to take advantage of new M5 versions without the error prone process of manually diffing and patching versions.
There are two recommend ways to add your own functionality to M5 and retain the ability to revision control your own code. The first suggested method relies on the queues feature of Mercurial (the revision control tool used for M5 development). The second relies on your own source control scheme (you could use mercurial or something else), and instead uses the Extras functionality in the build process to link extra objects into M5. In some situations a hybrid approach may be the best one, where the features you're attempting to evaluate are handled via the extras functionality, and minor changes to interfaces are done with Mercurial queues.
If you are extending M5 in a way that could be useful to the community, please consider pushing it back upstream. See Contributing Your Changes.
Using Mercurial Queues
The first method is using Mercurial Queues (MQ). MQ provides management commands inis to provide management commands to create and apply patches to an upstream source tree. When the underlying source tree is updated (see above), you can remove your patches, get the new changes and reapply your patches very quickly. The patches themselves can be an complete mercurial repository that is revision controlled. It's essential to read the above chapter in the Mercurial manual to understand this process, but briefly you would begin by creating a mercurial queues repository. You can then add patches to the mercurial queues repository and automatically update them based on the changes you've made. With this method it is good to segment changes into logical blocks rather than have one large patch for all your changes. When it comes time to update to a new version of M5 you remove all your patches from the repository, update to the latest version and add re-apply all of your patches. Normally this requires minimal effort. For example:
hg qinit -c hg qnew my_new_feature.diff echo "// Not so much a new feature as an additional line in the source tree" >> src/sim/main.cc hg qrefresh # my_new_feature.diff now contains the the extra line in the source tree # Remove the patch by executing hg qpop # Reapply the patch by executing hg qpush # Commit the changes to the path hg qcommit #To update to the latest version of M5 hg qpop -a hg fetch hg qpush -a # Again PLEASE read the manual
Using EXTRAS
The other method relies on the Extras functionality in the build process. This feature allows you to keep new M5 models in a directory of your choosing and have them compile and link code in with the M5 binary from arbitrary directories. Because the location of this directory is completely independent of the M5 mercurial repository, you can use any revision control system you like, and you can include code that you don't want to release (or that was released under a different license) without worrying about contaminating the M5 repository.
The drawback of the Extras technique is that it only allows the addition of new source code to M5, not the replacement or modification of any existing source code.
The EXTRAS functionality is used to support EIO traces. The trace reader for EIO is licensed under the SimpleScalar license and the code to read these traces is not included in the M5 distribution.
The next examples show how to compile the EIO code. By adding to or modifying the extras path, any other suitable extra could be compiled in. To compile in code using EXTRAS simply execute the following
scons EXTRAS=/path/to/m5_2.0_encumbered build/ALPHA_SE/m5.opt
In the root of this directory you should have a SConscript that uses the Source()
and SimObject()
scons functions that are used in the rest of M5 to compile the appropriate sources and add any SimObjects of interest.
Note that EXTRAS is a "sticky" parameter, so after a value is provided to scons once, the value will be reused for future scons invocations targeting the same build directory (build/ALPHA_SE
in this case) as long as it is not overridden. Thus you only need to specify EXTRAS the first time you build a particular configuration or if you want to override a previously specified value. For more information on sticky scons options, see the SCons build system page.
To run a regression with EXTRAS use a command line similar to the following:
./util/regress --scons-opts="EXTRAS=/tmp/m5_2.0b4_encumbered" -j 2 quick
Contributing Your Changes
If you make a changes to gem5 that others would find useful, please consider sharing that code with the community. The best way to do this is create an account on our code review website. You can then either upload a diff directly to the website or use the hg post-review extension to send the patch directly to the website from your mercurial repository.
Mercurial repo browser
The source code of gem5 is available to browse online here.
External Dependencies
Like most software gem5 requires a number of packages and tools to be able to build itself. Since it's highly likely that any user will be required to make some changes to gem5 to use it unlike most software having an environment capable of building gem5 is require. The following tools are needed to build gem5:
Required versions
To build M5, you will need the following software:
- g++ version 3.4.6 or newer. < 3.4 seems to have some issues with templates or internal compiler errors prevent compilation.
- Python, version 2.4 or newer. M5 links in the Python interpreter, so you need the Python header files and shared library (e.g., /usr/lib/libpython2.4.so) in addition to the interpreter executable. These may or may not be installed by default. For example, on Debian/Ubuntu, you need the "python-dev" package in addition to the "python" package. If you need a newer or different Python installation but can't or don't want to upgrade the default Python on your system, see our page on using a non-default Python installation.
- SCons, version 0.98.1 or newer. SCons is a powerful replacement for make. See here to download SCons. If you don't have administrator privileges on your machine, you can use the "scons-local" package to install scons in your m5 directory, or install SCons in your home directory using the '--prefix=' option.
- SWIG, version 1.3.31 or newer.
- zlib, any recent version. For Debian/Ubuntu, you will need the "zlib-dev" or "zlib1g-dev" package to get the zlib.h header file as well as the library itself.
- m4, the macro processor.
Things in ext
There are a number of libraries that are in the ext directory under the source tree. This is done primarily so that users don't need to install rarely used packages. These include:
- dnet -- dnet provides a simplified, portable interface to several low-level networking routines.
- gzstream -- Gzstream is a small C++ library, basically just a wrapper, that provides the functionality of the zlib C-library in a C++ iostream.
- libelf -- ELF object file access library.
- PLY -- PLY is an implementation of lex and yacc parsing tools for Python.
- x11ksyms -- Keycodes from X11 for VNC support.