LibreMesh software development kit uses the LEDE SDK and ImageBuilder to generate (cook) LibreMesh packages and firmware. If you want to create your own LibreMesh flavor because you need some specific configuration or you just want to have control over your binaries, the cooker is your friend!
Basic usage example for cooking a firmware for TpLink 4300:
./cooker -c ar71xx/generic --flavor=lime_default --profile=tl-wdr4300-v1
Using cooker online with Chef
Preparing the local environment
Building in running system
Before using lime-sdk, make sure your Linux system has the required dependencies installed.
Install build dependencies, for example on a Debian/Ubuntu based Linux distribution install the following packages:
sudo apt-get install subversion zlib1g-dev gawk flex unzip bzip2 gettext build-essential libncurses5-dev libncursesw5-dev libssl-dev binutils cpp psmisc docbook-to-man wget git
For other systems, you might follow these instructions (look for Examples of Package Installations) https://lede-project.org/docs/guide-developer/install-buildsystem
Building in docker container
Install Docker and run the following command:
cd lime-sdk sudo docker build -t cooker . sudo docker run -v "$(pwd)":/app cooker --<parameters>
Targets, profiles and flavors
LibreMesh can be used on many different devices (target and profile) and can be packed in many different ways (flavors), depending on your needs. To this end, it is important to choose the right options for building your firmware.
To generate a firmware, the -c option must be used (cook). But it requires to specify at least the target and subtarget of your router and optionally (recommended) the profile and flavor.
./cooker -c <target/subtarget> --profile=<profile name> --flavor=<flavor name>
For instance, this will work for a TpLink WDR4300:
./cooker -c ar71xx/generic --profile=tl-wdr4300-v1 --flavor=lime_default
Target references to the router architecture, usually depends on the manufactor and the set of chips used for building the hardware. Therefore, you must know the target and subtarget before using cooker. As we use LEDE, this information can be found here https://lede-project.org/toh/start. The most common targets are currently ar71xx/generic (Atheros) and ramips/mt7620 (Ramips). Once we know the target, we must find the specific profile.
To see the list of available targets execute:
The profile is the specific brand/model of the router. Each target has a list of hardware profiles than can be choosed. Cooker build all profiles from a target by default, but it is better if your find and choose the specific profile.
To see the list of available profiles for a specific target execute:
LibreMesh is a modular system, so it can be cooked on many different ways. There are some predefined that we call flavor, however anyone can create its own set of packets and options (for instance the default flavors include bmx6 and batman-adv as routing protocols, but you might create other kinds of setup).
One of the most important things regarding the flavor is the internal flash size of your router. This must be taken into account when choosing a flavor.
Currently there are three main flavors:
- lime_default: the recommended for routers with more than 4MB of flash. It includes all required and optional software.
- lime_mini: the recommended for routers of 4MB, made for end-users, includes a minimal web interface, but new software cannot be installed (opkg is not available).
- lime_zero: for advanced users, it does not include web interface, just the basic software to mesh the network but it does include opkg, so new software can be installed.
Building and cooking
These are two different steps. Building means to compile and prepare all the required packages for LibreMesh. To cook means taking the packages (depending on the flavor) and generating the firmware ready to install on your device.
The standard steps to generate a firmware would be: firstly build and secondly cook, like this:
./cooker -b ar71xx/generic
./cooker -c ar71xx/generic --profile=tl-wdr4300-v1 --flavor=lime_default
However, cooker is smart enough to detect the missing steps and transparently execute them. If we choose to cook before building, it will automatically build before cooking. Therefore, for debugging purposes it is better to execute the steps separately.
On the other hand, if you do not want to build locally (since it requires some special software installed on your Linux machine), you can just cook using the online precompiled binaries.
Building locally or fetch remote?
Cooker can locally build the LibreMesh packages or fetch the remote precompiled ones. For most users there is no real need for building, since using the remote ones might be a better (and fast) option. To remotelly fetch the packages the special option --remote must be used when cooking, like this:
./cooker -c ar71xx/generic --profile=tl-wdr4300-v1 --flavor=lime_default --remote
Using custom SDK and/or IB files
Custom local SDK and IB files can be used (instead of fetching official LEDE sources). Must be specified before building or cooking ("-b" or "-c").
./cooker -i ar71xx/generic --ib-file=myOwnImageBuilder.tar.xz --sdk-file=myOwnSDK.tar.xz
./cooker -b ar71xx/generic --force-local
./cooker -c ar71xx/generic --profile=tl-wdr4300-v1 --flavor=lime_default --force-local
Do not forget to use force-local option to use your own SDK target packages (kernel signature will be different from remote sources).
It is not required to create and/or use a community profile. But if you are constantly cooking LibreMesh for your network and you need a specific configuration, you might want to spend some time creating a community profile. This will make things easier and better coordinated for your community.
A community is mainly a set of files you want to include in the output firmware. For instance, if you want to pre-configure the WiFi SSID, mode or channels, you might want to include a specific /etc/config/lime-defaults file as shown in this article http://libremesh.org/docs/en_config.html.
Also /etc/shadow for setting an initial root password or /etc/uci-defaults/ one-time executed scripts might be useful for your setup.
The default way to create or use a community is to use this Git repository https://github.com/libremesh/network-profiles (ask for writing access in the users mailing list). The directory structure of the Git repository is:
/<community name>/<device profile name>/<files and directories>
Both community and device profile names can be any of your choice (must exist!) , since they are only used for identifying it. When executing a cook order, you can specify the community profile like this:
./cooker -c ar71xx/generic --profile=tl-wdr4300-v1 --flavor=lime_default --community=CommunityName/ProfileName
A community profile might include a special file named PACKAGES on the root of the profile directory (CommunityName/ProfileName/PACKAGES) to specify a list of extra packages which must be added to the firmware image.
Using development branch
If you want to get the last LEDE source because it includes some new feature or it supports some new hardware, you can use the lime-sdk branch named develop. However as LEDE source is changing daily, we cannot assure the correct working of the firmware.
It is recommended to start with a new Git clone instead of reuse an existing one. Once the lime-sdk source is cloned, change the branch:
git checkout develop
Add your own feed repository
If you want to compile and/or cook your own feed package repository, you can follow one of the following methods.
For a permanent build environment
If it is a permanent change on your cooker setup, better add your repository (or modify the existing ones) to the feeds file
cp feeds.conf.default feeds.conf.default.local vim feeds.conf.default.local
Edit and save the new created file feeds.conf.default.local and force the reinstall of the feeds
./cooker -f --force
Crete and add to the SDK config file the new packages you want to include (if any)
cp libremesh.sdk.config libremesh.sdk.config.local echo "CONFIG_PACKAGE_myNewPackage=m" >> libremesh.sdk.config.local
Add your new flavor (or modify the existing ones)
cp flavors.conf flavors.conf.local vim flavors.conf.local
Finally build and cook as usual but adding also your new packages
./cooker -b ar71xx/generic ./cooker -c ar71xx/generic --profile=tl-wdr4300-v1 --flavor=lime_new_flavor
For a casual cooking on a existing feed repository
Download the standard feeds (if not previously downloaded)
Modify the source code of the existing feed
cd feeds/libremesh git checkout feature/somethingToTest
Build the code and cook as usual
./cooker -b ar71xx/generic ./cooker -c ar71xx/generic --profile=tl-wdr4300-v1 --flavor=lime_default --extra-pkg="someExtraPackage?"
Forking lime-sdk for your community
If you like to manage your own set of flavors, options and/or repositories, you might fork the lime-sdk code to your own Git repository. To preserve the compatibility with the official source (so merges can be easily done), none of the original files must be modified.
To this end, cooker will look first for the files named .local and will use them instead. Therefore make a copy of options and flavors.
cp options.conf options.conf.local cp flavors.conf flavors.conf.local
Modify them as your own wish and add them to the Git repository.
git add *.local git commit -m 'Add local options and flavors' git push
Time to time, if you want to update the code with the official one you might add a new remote and perform a merge.
git remote add official https://github.com/libremesh/lime-sdk.git git fetch official git merge official/master git push origin/master
Usage: ./cooker [-f [--force]] [-d <target> [--sdk|ib|force]] [-i <target> [--sdk-file=<file>|ib-file=<file>]] [--download-all|build-all|update-feeds] [--targets|flavors|communities|update-communities|profiles=<target>] [-b <target> [-j<N>] [--no-update|no-link-ib|remote|clean|force-local|package=<pkg>]] [-c <target> [--profile=<profile>|no-update|remote|flavor=<flavor>|community=<path>|extra-pkg=<list>]] [--help] --help : show full help with examples --download-all : download all SDK and ImageBuilders --build-all : build SDK for all available tagets --cook-all : cook firmwares for all available targets and profiles --targets : list all officialy supported targets --profiles=<target> : list available hardware profiles for a specific target --flavors : list available LibreMesh flavors for cooking --communities : list available community profiles --update-communities : update or download community profiles --update-feeds : update previously downloaded feeds (only works for Git feeds) -f : download feeds based on feeds.conf.default file. Feeds will be shared among all targets --force : force reinstall of feeds (remove old if exist) -d <target> : download SDK and ImageBuilder for specific target --sdk : download only SDK --ib : download only ImageBuilder --force : force reinstall of SDK and/or ImageBuilder (remove old if exist) -i <target> : install local/custom SDK or ImageBuilder --sdk-file=<file> : specify SDK file to unpack --ib-file=<file> : specify ImageBuilder file to unpack -b <target> : build SDK for specific target and link it to the ImageBuilder -j<N> : number of threads to use when building (recommended N=#cores+1) --no-link-ib : do not download and link ImageBuilder when building the SDK --no-update : do not update feeds when building SDK --clean : clean sources before compiling --package=<pkg_name> : build only a package (and its dependencies) --force-local : force installation of all local SDK compiled packages when cooking firmware -c <target> : cook the firmware for specific target. Can be used with next options --profile=<profile> : use <profile> when cooking firmware (default is all available target profiles) --flavor=<flavor> : use <flavor> when cooking firmware (default lime_default) --extra-pkg=<pkg_list> : specify extra packages (separated by spaces) for including into the output firmware --remote : instead of building local SDK packages. Use only remote repositories for cooking --community=<name/prof> : specify which network community and profile device to use (if any) --no-update : do not update package list when cooking (requires patch_ib_no_update.sh snippet) Examples: - Build packages using the SDK and cook the firmware for target tl-wdr3500-v1 and flavor generic (all in one command) ./cooker -c ar71xx/generic --flavor=lime_default --profile=tl-wdr3500-v1 - Cook the firmware without compiling the SDK but using only remote precompiled binaries ./cooker -c ar71xx/generic --remote --flavor=lime_mini --profile=tl-wdr3500-v1 - Build SDK and cook ar71xx target with all available profiles (step by step) ./cooker -d ar71xx/generic # download SDK and IB ./cooker -f # download and prepare feeds ./cooker -b ar71xx/generic # build the SDK and link it to IB ./cooker -c ar71xx/generic --flavor=lime_default # cook all firmwares for target ar71xx/generic - If you want to use an existing community network profile, specify it when cooking (in addition to the device profile) ./cooker -c ar71xx/generic --flavor=lime_default --community=quintanalibre.org.ar/comun --profile=tl-wdr3500-v1 - If not profile defined, cook all profiles of target. Also --extra-pkg option can be used to add extra packages when cooking ./cooker -c ar71xx/generic --flavor=lime_zero --extra-pkg="luci-proto-3g iperf" - To see/debug build errors use J (number of threads) and V (verbose) system vars J=1 V=s ./cooker -b ar71xx/generic --profile=tl-wdr3500-v1
Testing on QEMU
While developing new features, or just testing out fixes, being able to see them in action without having to reflash a device can be useful. To achieve this you can spin a QEMU virtual machine and boot the image with your edits. These instruction are based on LEDE documentation but are a bit more specific to LibreMesh building process.
First of all you need to create your cooked version of LibreMesh firmware for the
armvirt target, see up here.
cd lime-sdk ./cooker -c armvirt/generic --flavor=lime_default --update-feeds
cooker finishes to build the image you'll find the needed files in the
output folder of
lime-sdk, they will be located in a subfolder
accordingly to the architecture and profile chosen. The interesting files are:
gunzip -k lede-17.01.2-lime-XXXX-root.ext4.gz
Now you need to install qemu in order to boot the image, usually it's available inside the repositories of the distribution. Here some quick links documenting how to install it on Debian or ArchLinux.
Note that if you
want to use an image built for arm you should have
qemu-system-arm command available, often provided by
Now it's time to spin the virtual machine.
Using plain QEMU
Plain qemu can be launched straight from the command line, if you don't need to access LibreMesh web interface and just want to have a shell you can issue
qemu-system-arm -nographic -M virt -m 64 -kernel lede-17.01.2-lime-XXXX-armvirt-zImage -drive file=lede-17.01.2-lime-XXXX-armvirt-root.ext4,format=raw,if=virtio -append 'root=/dev/vda rootwait'
Press enter and you will find yourself inside the VM booted.
You can also have access to the web interface configuring a tap device on the host as follows.
VirtManager is an higher level way to deal with virtualization using libvirt. Libvirt supports several virtualization technologies, not only Qemu. It's a quick'n'easy way to setup a test environment.
Many distributions provide packages for Virt-Manager, you have to install it together with qemu:
sudo pacman -S virt-manager
- Debian and Ubuntu:
sudo apt-get install virt-manager
If you plan to use networking functions, like accessing the web interface, you'll need to install also
The setup is a bit longer but is persistent and you will only need to rebuild the images from
cooker and re-spin the VM to see your changes.
What you need to do is to start the libvirtd and virtlogd daemons (if not already started start them with
sudo systemctl start libvirtd.service virtlogd.service), open Virt-Manager and ensure you are connected to the
Now you have to create a new virtual machine: click on File/New Virtual Machine, select Import existing disk image and choose the arm architecture under Architecture options and virt machine type.
Taking arm as an example you'll have to choose (clicking Browse and Browse Local buttons) the
lede-17.01.2-lime-XXXX-armvirt-root.ext4 file as storage disk and the
lede-17.01.2-lime-XXXX-armvirt-zImage file as Kernel path. Insert
root=/dev/vda rootwait as Kernel args. You can leave OS type as Generic.
Assign resources (64 MB of RAM memory should be enough) and, under Network selection, choose
NAT as network type. In this way you will be able to connect to the web interface and the device will have internet access.
If you started the VM at this point, it will hang, you can shut it down from the menu Virtual Machine/Shut Down/Force off.
What is missing is to change the disk bus mode: open the VM windows without starting the VM, click on View/Details open the SATA disk 1 tab and change Disk bus from SATA to VirtIO. You should now be able to start the VM.
Libvirt automatically create a bridge interface for you to which the VMs are connected to. Assign your bridge device a network address inside LibreMesh subnet and you should be good to go, something like:
sudo ip address add 10.13.246.1/16 dev virbr0
Or get one via DHCP with:
sudo dhcpcd --metric 9999 virbr0 or
sudo dhclient -e IF_METRIC=9999 -i virbr0
Should be good, you can be sure about the address opening the VM and issuing an
ip address show dev br-lan once the interfaces are correctly set-up.
You can access the router web interface in a browser with the router IP or anygw IP which could be something like
If the router has just one ethernet interface, like in our VM, LibreMesh by default doesn't use that interface as WAN. If you need the router to have access to the internet, using the VM console interface edit
/etc/config/lime adding a specific interface configuration like:
config net manualwan option linux_name 'eth0' list protocols 'wan'
applying the new settings with the command
lime-config; service network reload. A drawback is that in this way the web interface can not be accessed anymore because of LibreMesh firewall blocking connections incoming from the WAN interface.