--- /dev/null
+The m5 utility provides a command line and library interface for gem5
+operations.
+
+These operations are requested by the simulated software through some special
+behavior which is recognized by gem5. gem5 will then perform the requested
+operation which is outside the normal behavior of the simulated system.
+
+
+
+# Trigger mechanisms
+
+There are a few different ways the simulated software can let gem5 know it
+wants to perform an operation. Different CPU models have different constraints
+depending on how they're implemented, and may not support all of these
+different mechanisms.
+
+ Trigger | Native | KVM | Fast Model
+-------------|---------|-----|------------
+ Instruction | Yes | |
+ Address | ARM/X86 | Yes |
+ Semihosting | ARM | | Yes
+
+## "Magic" Instructions
+
+This is the oldest trigger mechanism in gem5, and is supported by all of the
+CPU models which interpret instructions one at a time using gem5's ISA
+definitions. It works by co-opting instructions which normally are undefined,
+and redefining them to trigger gem5 operations. Exactly what instructions
+these are, how they encode what operation they go with, etc., vary from ISA to ISA.
+
+When using the KVM CPU models, the instruction stream is executing on actual
+physical hardware which won't treat these instructions specially. They will
+retain their old behavior and, most likely, raise an undefined instruction
+exception if executed.
+
+Other external models, like ARM's Fast Model CPUs, also won't treat these
+instructions specially.
+
+## "Magic" Address Range
+
+This mechanism was added for the KVM CPUs so that they could trigger gem5
+operations without having to recognize special instructions. This trigger is
+based on a specially set aside range of physical addresses. When a read or
+write is targetted at that range, instead of a normal device or memory access,
+a gem5 operation is triggered.
+
+Depending on the ISA, gem5 native CPUs should support this mechanism (see the
+table below).
+
+When using the KVM CPU, the special range of addresses are not registered as
+memory, and so the KVM virtual machine will exit when they're accessed. gem5
+will have a chance to recognize the special address, and can trigger the
+operation.
+
+When using an external model like ARM's Fast Model CPUs, these external
+accesses will leave the CPU complex, and gem5 will be able to recognize them.
+Unfortunately if the CPU has multiple threads of execution, gem5 won't be able
+to tell which the access came from. Also, the memory access may not happen at a
+precise point in the simulated instruction stream due to binary translation.
+The architectural state may not be in a consistent state which is suitable to
+extract arguments or inject a return value.
+
+### Default address range
+
+Since x86 has a predictable address space layout, the "magic" address range can
+be put in a predictable, default location, which is at 0xFFFF0000.
+
+On other architectures, notably ARM, the address space is less predictable, and
+it doesn't make sense to set a default location which won't be valid on all
+configurations.
+
+## Semihosting
+
+This mechanism was added to support ARM's Fast Model CPUs. It extends ARM's
+semihosting support, a mechanism which was already defined to interrupt normal
+execution and trigger some sort of behavior in a containing host.
+
+On ISAs which support semihosting (only ARM now, and probably going forward),
+gem5 native CPUs can support semihosting instructions, and so should support
+the semihosting trigger mechanism.
+
+KVM CPUs use real hardware, and so semihosting instructions will not have
+special behavior and will act like their normal counterparts (HLT, etc.).
+
+
+
+# Building
+
+## Supported ABIs
+
+To build either the command line utility or one of the versions of the library,
+first identify what ABI(s) you're targetting.
+
+ ABI | Description | Triggers
+---------|--------------|----------
+ aarch64 | 64 bit ARM | instruction, adddress, semihosting
+ arm | 32 bit ARM | instruction
+ thumb | ARM thumb | instruction
+ sparc | 64 bit SPARC | instruction
+ x86 | amd64/x86_64 | instruction, address
+
+## SCons
+
+The m5 utility uses a scons based build system. gem5 itself also uses SCons,
+but these builds are (mostly) not related and separate.
+
+The SConscript for this utility is set up to use a build directory called
+"build", similar to gem5 itself. The build directory is structured so that you
+can ask scons to build a portion of it to help narrow down what you want to
+build.
+
+### native
+
+There is a **build/native** directory which is for some test binaries which
+test generic functionality and are compiled for the host, whatever that happens
+to be. These can be run directly, unlike ABI specific tests which may be
+possible to run directly depending on the host's architecture, but may not.
+
+### ABI
+
+The first level subdirectories of the build directory (other than "native",
+described above) is named after the ABI you're targetting. For instance, build
+products for x86 would be in the **build/x86** subdirectory.
+
+Within an ABI subdirectory will be linked copies of all the source files needed
+for the build, and also "test" and "out" subdirectories.
+
+#### test
+
+The "test" subdirectory, for instance **build/x86/test**, holds the test
+binaries for that ABI in a bin subdirectory, and the results of running those
+tests (if requested and possible) in a "result" subdirectory.
+
+#### out
+
+The "out" subdirectory, for instance **build/x86/out**, holds the various final
+build products. This includes:
+
+- m5: The command line utility.
+- libm5.a: C library.
+- gem5OpJni.jar, libgem5OpJni.so, jni/gem5Op.class: Java support files.
+- libgem5OpLua.so: Lua module/library.
+
+## Build options
+
+There are some variables which set build options which need to be controlled on
+a per ABI level. Currently, these are:
+
+- CROSS_COMPILE: The cross compiler prefix.
+- QEMU_ARCH: The QEMU architecture suffix.
+
+To set these for a particular ABI, prefix the variable name with the ABI's name
+and then a dot. For instance, to set the cross compiler prefix to
+"x86_64-linux-gnu-" for x86, you would run scons like this:
+
+```shell
+scons x86.CROSS_COMPILE=x86_64-linux-gnu- build/x86/out/m5
+```
+
+ ABI | QEMU_ARCH | CROSS_COMPILE
+---------|-----------|---------------------
+ aarch64 | aarch64 | aarch64-linux-gnu-
+ arm | arm | arm-linux-gnueabihf-
+ thumb | arm | arm-linux-gnueabihf-
+ sparc | sparc64 | sparc64-linux-gnu-
+ x86 | x86_64 |
+
+Note that the default setting for the x86 cross compiler prefix is blank,
+meaning that the native/host compiler will be used. If building on a non-x86
+host, then you'll need to set an appopriate prefix and may be able to clear
+some other prefix corresponding to that host.
+
+## External dependency detection
+
+In some cases, if an external dependency isn't detected, the build will
+gracefully exclude some targets which depend on it. These include:
+
+### Java support
+
+The SConscript will attempt to find the javac and jar programs. If it can't, it
+will disable building the Java support files.
+
+### Lua support
+
+The SConscript will attempt to find lua51 support using pkg-config. If it
+can't, it will disable building the lua module/library.
+
+### Non-native tests
+
+The SConscript will attempt to find various QEMU binaries so that it can run
+non-native tests using QEMU's application level emulation. The name of the
+binary it looks for depends on the ABI and is set to qemu-${QEMU_ARCH}. See
+above for a description of per ABI build variables, including QEMU_ARCH.
+
+If it can't find a program with that name, it will disable running non-native
+test binaries for that ABI.
+
+
+
+# Testing
+
+Tests are based on the googletest system. There are native tests which test
+mechanisms which are not specific to any ABI and can be run on the host. These
+are built using the native toolchain.
+
+There are also tests for ABI specific mechanisms like the various trigger
+types. These will be built using the cross compiler configured for a given ABI.
+These tests can be run in QEMU in its application emulation mode, and the build
+system can run them automatically if requested and if the required dependencies
+have been met.
+
+The tests for the trigger mechanisms can't count on those mechanisms actually
+working when running under QEMU, and so will try to set up intercepts which
+will catch attempts to use them and verify that they were used correctly. When
+running these tests under gem5, set the RUNNING_IN_GEM5 environment variable
+which will tell the test to expect the trigger mechanism to actually work.
+
+
+
+# Command line utility
+
+The command line utility provides a way of triggering gem5 operations either
+interactively through a terminal connection to the simulated system, or scripts
+running within it.
+
+## Calling syntax
+
+Any call to the utility should have the following structure:
+
+```shell
+m5 [call type] <command> [arguments]
+```
+
+Call type is optional and selects what trigger mechanism should be used. If
+it's omitted, the default mechanism will be used. What the default mechanism is
+varies based on the ABI.
+
+ ABI | Default call type
+---------|-------------------
+ aarch64 | instruction
+ arm | instruction
+ thumb | instruction
+ sparc | instruction
+ x86 | address
+
+The default is usually to use a magic instruction, which for most ABIs is the
+only mechanism that's supported, and is what the m5 utility would
+tradditionally have used. On x86, the address based mechanism is the default
+since it's supported on all current CPU types which also support x86.
+
+### Call type
+
+To override the default call type, you can use one of these arguments.
+
+```shell
+--addr [address override]
+```
+
+Selects the magic address call type. On most ABIs which don't have a default
+magic address range, this argument must be followed by the address range to
+use. On x86 if no address is specified, the default (0xFFFF0000) will be used.
+
+```shell
+--inst
+```
+
+Selects the magic instruction call type.
+
+```shell
+--semi
+```
+
+Selects the semihosting based call type.
+
+### Commands and arguments
+
+To see a list of commands and the arguments they support, run the utility with
+the --help argument.
+
+```shell
+m5 --help
+```
+
+
+
+# C library
+
+The C library provides a set of functions which can trigger gem5 operations
+from within compiled programs.
+
+## Building in the library
+
+To use the C library, include the header file located at
+
+```shell
+include/gem5/m5ops.h
+```
+
+like so:
+
+```shell
+#include <gem5/m5ops.h>
+```
+
+That will declare the various functions which wrap each of the gem5 operations.
+It includes another header file located at
+
+```shell
+include/gem5/asm/generic/m5ops.h
+```
+
+using a path relative to include. Be sure that include path will resolve based
+on the settings of your compiler, or move or modify to fit the existing
+options.
+
+As part of the linking step of your application, link in the libm5.a static
+library archive which provides the definitions of those functions.
+
+## Trigger mechanisms
+
+The bare function name as defined in the header file will use the magic
+instruction based trigger mechanism, what would have historically been the
+default.
+
+Some macros at the end of the header file will set up other declarations which
+mirror all of the other definitions, but with an "_addr" and "_semi" suffix.
+These other versions will trigger the same gem5 operations, but using the
+"magic" address or semihosting trigger mechanisms. While those functions will
+be unconditionally declared in the header file, a definition will exist in the
+library only if that trigger mechanism is supported for that ABI.
+
+
+
+# Java jar
+
+To use the gem5 java jar, you will need to load the corresponding .so.
+
+```shell
+System.loadLibrary("gem5OpJni");
+```
+
+In your java source, import the gem5Op class which will have methods for
+calling each of the gem5 operations.
+
+```shell
+import jni.gem5Op
+```
+
+These methods will all use the magic instruction based trigger mechanism.
+
+
+
+# lua module
+
+The lua module is implemented in a file called libgem5OpLua.so, and should be
+loaded using typical lua mechanisms. It will be built against lua 5.1.
+
+## Integer values
+
+In lua 5.1, all numeric values are (typically) represented as doubles. That
+means that 64 bit integer argument values of any type, but in particular
+addresses, can't be represented exactly. Calls to gem5 operations using that
+type of argument or returning that type of value may not work properly.
+
+In lua 5.3, numeric values can be represented by either a double or a proper
+integer without having to rebuild the lua interpreter configured for one or the
+other. If the module was ported to lua 5.3 then integer values could be passed
+safely.
+
+
+
+# Known problems
+
+## Java/lua cross compiling
+
+When building the java or lua modules, a C cross compiler is used so that any
+generated binary will be built for the target ABI. Unfortunately, other tools,
+headers, etc, come from the host and may not be useable, or worse may be
+subtley broken, when used to target a different ABI. To build these objects
+correctly, we would need to use a proper cross build environment for their
+corresponding languages. Something like this could likely be set up using a
+tool like buildroot.
+
+