This file contains instructions to build and install the TSS libraries.
To build and install the tpm2-tss software the following software packages are required. In many cases dependencies are platform specific and so the following sections describe them for the supported platforms.
- GNU Autoconf
- GNU Autoconf Archive, version >= 2019.01.06
- GNU Automake
- GNU Libtool
- C compiler
- C library development libraries and header files
- pkg-config
- doxygen
- OpenSSL development libraries and header files, version >= 1.1.0
- libcurl development libraries
- Access Control List utility (acl)
- JSON C Development library
- Package libusb-1.0-0-dev
The following are dependencies only required when building test suites.
- Integration test suite (see ./configure option --enable-integration):
- uthash development libraries and header files
- ps executable (usually in the procps package)
- ss executable (usually in the iproute2 package)
- tpm_server executable (from https://sourceforge.net/projects/ibmswtpm2/)
- Unit test suite (see ./configure option --enable-unit):
- cmocka unit test framework, version >= 1.0
- Code coverage analysis:
- lcov
Most users will not need to install these dependencies.
$ sudo apt -y update
$ sudo apt -y install \
autoconf-archive \
libcmocka0 \
libcmocka-dev \
procps \
iproute2 \
build-essential \
git \
pkg-config \
gcc \
libtool \
automake \
libssl-dev \
uthash-dev \
autoconf \
doxygen \
libjson-c-dev \
libini-config-dev \
libcurl4-openssl-dev \
uuid-dev \
libltdl-dev \
libusb-1.0-0-dev \
libftdi-dev
Note: In some Ubuntu versions, the lcov and autoconf-archive packages are incompatible with each other. It is recommended to download autoconf-archive directly from upstream and copy ax_code_coverage.m4
and ax_prog_doxygen.m4
to the m4/
subdirectory of your tpm2-tss directory.
libtool automake autoconf and autoconf-archive should be installed:
$ sudo dnf install libtool automake autoconf autoconf-archive
There is a package already, so the package build dependencies information can be used to make sure that the needed packages to compile from source are installed:
$ sudo dnf builddep tpm2-tss
If you want to install a version from 4.0.0 and the default version of the release is lower than this version you have to install libuuid-devel additionally:
$ sudo dnf install libuuid-devel
Windows dlls are built using the LLVM (clang-cl) toolset. We have only tested using Visual Studio 2019, but Visual Studio 2022 should also be supported. Building should be as simple as loading the tpm2-tss solution (tpm2-tss.sln) with a compatible and properly configured version of Visual Studio 2019+ and pressing the 'build' button.
Visual Studio 2019+ with "Clang for Windows": https://learn.microsoft.com/en-us/cpp/build/clang-support-msbuild Universal CRT overview & setup instructions: https://docs.microsoft.com/en-us/cpp/porting/upgrade-your-code-to-the-universal-crt
To configure the tpm2-tss source code first run the bootstrap script, which generates list of source files, and creates the configure script:
$ ./bootstrap
Any options specified to the bootstrap command are passed to autoreconf(1)
.
Then run the configure script, which generates the makefiles:
$ ./configure
In many cases you'll need to provide the ./configure
script with additional
information about your environment. Typically you'll either be telling the
script about some location to install a component, or you'll be instructing
the script to enable some additional feature or function. We'll cover each
in turn.
Invoking the configure script with the --help
option will display
all supported options.
The default values for GNU installation directories are documented here: https://www.gnu.org/prep/standards/html_node/Directory-Variables.html
The typical operation for the tpm2-abrmd
is for it to communicate directly
with the Linux TPM driver using libtcti-device
from the TPM2.0-TSS project.
This requires that the user account that's running the tpm2-abrmd
have both
read and write access to the TPM device node /dev/tpm[0-9]
. But users could
also access the TPM directly so the udev rule is installed by tpm2-tss
.
This requires that udev
be instructed to set the owner and group for this
device node when its created. We provide such a udev rule that is installed to
${libdir}/udev/rules.d
. If your distro stores these rules elsewhere you will
need to tell the build about this location.
Using Debian as an example we can instruct the build to install the udev rules in the right location with the following configure option:
--with-udevrulesdir=/etc/udev/rules.d
It is common for Linux distros to prefix udev rules files with a numeric string (e.g. "70-"). This allows for the rules to be applied in a predictable order. This option allows for the name of the installed udev rules file to have a string prepended to the file name when it is installed.
Then compile the code using make:
$ make -j$(nproc)
Once you've built the tpm2-tss software it can be installed with:
$ sudo make install
This will install the libraries to a location determined at configure time. See the output of ./configure --help for the available options. Typically you won't need to do much more than provide an alternative --prefix option at configure time, and maybe DESTDIR at install time if you're packaging for a distro.
Once you have this udev rule installed in the right place for your distro you'll need to instruct udev to reload its rules and apply the new rule. Typically this can be accomplished with the following command:
$ sudo udevadm control --reload-rules && sudo udevadm trigger
If this doesn't work on your distro please consult your distro's documentation for UDEVADM(8).
Users who should have access to the TPM and the FAPI keystore should be included in the tss group. ``` sudo usermod -aG tss
## ldconfig
It may be necessary to run ldconfig (as root) to update the run-time
bindings before executing a program that links against libsapi or a TCTI
library:
$ sudo ldconfig
## Building In A Container
If you are having trouble installing the dependencies on your machine you can
build in a container.
$ docker build -t tpm2 . $ docker run --name temp tpm2 /bin/true $ docker cp temp:/tmp/tpm2-tss tpm2-tss $ docker rm temp
tpm2-tss is now in your working directory and contains all the built files.
To rebuild using your local changes mount your tpm2-tss directory as a volume.
```console
$ docker run --rm -ti -v $PWD:/tmp/tpm2-tss tpm2-tss \
sh -c 'make -j$(nproc) check'
To build Doxygen documentation files, first install package Doxygen. Then generate the documentation with:
$ ./configure --enable-doxygen-doc
$ make doxygen-doc
The generated documentation will appear here:
- doxygen-doc/html HTML format (start with file doxygen-doc/html/index.html)
- doxygen-doc/rtf/refman.rtf RTF format
The libraries SYS, ESYS, MU, RC, tctildr, tcti-spi-helper, tcti-i2c-helper can also be build for embedded devices. The following is an example to build for cortex-m4:
./bootstrap
./configure \
--disable-fapi \
--disable-esys \
--disable-policy \
--disable-tcti-cmd \
--disable-tcti-device \
--disable-tcti-libtpms \
--disable-tcti-mssim \
--disable-tcti-pcap \
--disable-tcti-spi-lt2go \
--disable-tcti-spi-ftdi \
--disable-tcti-swtpm \
--disable-doxygen-doc \
--enable-nodl \
--host=arm-none-eabi \
--prefix=/home/afuchs/tpm2-software/INSTALL.uC \
CFLAGS='-mcpu=cortex-m4 -mfloat-abi=hard -mfpu=fpv4-sp-d16 -mthumb' \
LDFLAGS='--specs=nosys.specs'
make
- ubuntu-20.04
- fedora-32
- opensuse-leap
- ubuntu-22.04
- alpine-3.15
- FreeBSD