Developer Workflow Improvements: Difference between revisions

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Build SDK by building <tt>your-image:populate_sdk_ext</tt> in toaster.
Build SDK by building <tt>your-image:populate_sdk_ext</tt> in toaster.


=== Publish SDK contents ===
=== Publish SDK Updater ===
For publishing HTML content assume /var/www/html/path/to is served up as http://my.server.com/path/to<br/>
The eSDK allows web updates, so you have to ensure they appeat at the URK specified by SDK_UPDATE_URL. Assume /var/www/html/path/to is served up as http://my.server.com/path/to<br/>
In the docker shell created when you started Toaster container run the following
In the docker shell created when you started Toaster container run the following
  oe-publish-sdk tmp/deploy/sdk/distro-image-toolchain-ext-ver.sh /var/www/html/path/to/esdk-update
  oe-publish-sdk tmp/deploy/sdk/distro-image-toolchain-ext-ver.sh /var/www/html/path/to/esdk-update

Revision as of 16:48, 17 October 2016

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Introduction

The page describes how new tools such as Toaster, Extensible SDK (eSDK) and CROPS make it easier to get the best out of Yocto. We envisage two distinct workflows, layer maintenance and application development.

Layer Maintenance

  • Toaster is used to generate image that exercises layers under test
  • Layers and recipes are edited as necessary. Image is rebuilt with Toaster and tested.

Application Development

  • Toaster is used to generate a minimal eSDK installer.
  • A developer uses resulting eSDK to create an application by using devtool (iterative process).
    • devtool is used to create/fix/augment application recipe
    • Toaster can optionally monitor builds and allow inspection of OE environment
  • Once application is complete its recipe is added to a layer and Toaster is used to build an image that includes it

There are two personas in this scenario; 'os-dev' who maintains the OS image and generates its extensible SDK and the 'app-dev' who creates new C/C++ applications to run on OS. The scenario assumes that an early version of the application exists but it needs features added and to be integrated into OS image. We recognize that in smaller organizations the roles of os-dev and app-dev may be blurry but the concept of two separate personas simplifies description of workflow.

The set-up instructions at the end of this page represent the "what can currently be done" version of the workflows.

I have a concern that the focus on C/C++ is misplaced as IoT is not proving to be just more embedded development as we knew it. Other languages are proving popular, with many pundits putting JavaScript at the forefront. [1] [2] [3]

Workflow Vision

This section calls out the workflows in more detail, describing specific use of tools in each step.

Application Development

  1. os-dev: On OS of your choice install containerized 'production' toaster instance. There will a number of containers; one with toaster and core tools, the other with a toaster database. These will have to be hooked together via bind mounts. Details TBD.# os-dev: Add new layer and application package to Toaster
  2. os-dev: Build image and validate
  3. os-dev: Add new layer and application package to Toaster
  4. os-dev: Build image and validate
  1. os-dev: Set up your base distro build with toaster by simply importing appropriate configuration (e.g. Ostro)
  2. os-dev: Use toaster to create and publish components required for app development
    1. OS image
    2. eSDK
    3. sstate-cache created by building image
    4. CROPS toolchain container installers for Windows, Mac and Linux
  3. app-dev: On OS of your choice install Eclipse and CROPS and configure
  4. app-dev: Using Eclipse devtool plug-in add app-name, this pulls down all dependent packages and makes a good guess at recipe
  5. app-dev: Develop application code in Eclipse, deploying and testing on target
  6. app-dev: Check in "completed" code
  7. app-dev: Edit recipe using Eclipse devtool plug-in until it builds app correctly
  8. app-dev: Build new image using Eclipse devtool plug-in and test
  9. app-dev: Hand off recipe to os-dev
  10. os-dev: Create base image
  11. os-dev: Add recipe to layer or create a new one
  12. os-dev: Add new layer and application package to Toaster
  13. os-dev: Build image and validate

Layer Maintenance

  1. os-dev: On OS of your choice install containerized 'production' toaster instance. There will a number of containers; one with toaster and core tools, the other with a toaster database. These will have to be hooked together via bind mounts. Details TBD.
  2. os-dev: Set up your base distro build with toaster by simply importing appropriate configuration (e.g. Ostro)
  3. os-dev: Add layer(s) required by packages you add to image
  4. os-dev: Update and/or add layers as required with iterative image builds
  5. os-dev: Push layer updates to appropriate repo when done
  6. os-dev: Add new layer and application package to Toaster
  7. os-dev: Build image and validate

Missing Features

These are the features currently missing from the above workflow vision. Think of these as stories in an Agile development environment, rather than bugs. Where possible these are linked to bugzilla entries.

  • Toaster: Base configuration (e.g. define what was Ostro in single configuration file) [9588]
  • Toaster: Simple generation of eSDK installer in Toaster. [9297]
  • Toaster: Layer Maintenance workflow. Requires "local layers" re-design. No bugzilla entry, but see design proposal video
  • Toaster: Publish layer to Layer Index from Toaster [9895]
  • CROPS: Application builder (but running eSDK in a container gets us close). [10119] [4209]
  • CROPS: Eclipse integration. In progress. No bugzilla entry.

Instructions for Workflow in Current Form

Toaster Setup

Install Toaster

  • Install docker for your Linux distro. Install using your distro's package feed as this will also configure you to be a docker user so you don't need to use sudo when running a container
  • If inside a corporate firewall, install and configure the Chameleonsocks container based proxy solution.
  • Make a folder for toaster output files on your workstation.
mkdir /path/to/toaster/tmp_files

Start Toaster Web Service

Start toaster container so it's only available on localhost

docker run -it --rm -p 127.0.0.1:18000:8000 -v /path/to/toaster/tmp_files:/workdir crops/toaster

Or start toaster container so anyone can access it remotely

docker run -it --rm -p 18000:8000 -v /path/to/toaster/tmp_files:/workdir crops/toaster

For more details on Toaster container see https://github.com/crops/toaster-container.

Build and Publish eSDK

This section is not part of the developer workflow but documents how the SDK components are generated and published. This step creates a small installer that is made available to the developer. You must have access to an http server so you can publish SDK update files.
Building and publishing the SDK takes a number of steps. Toaster will be updated to make this process much simpler.

Configure and build extensible SDK

Set the following variables. Normally this would be done in local.conf but as we are using toaster we add them as bitbake variables.

SDK_EXT_TYPE = "minimal" ensure a minimal SDK build. This produces a small installer and enable components to de downloaded as they are installed
SDK_INCLUDE_PKGDATA = "1" forces a 'world' build up to do_packagedata and is required to populate sstate-cache with all packages, as we don't know which ones developers will need. If you know the packages the application developers will require, add then the your build and avoid setting SDK_INCLUDE_PKGDATA for a much faster build.
SDK_UPDATE_URL points eSDK to URL that contains updates
SDK_EXT_TYPE = "minimal"
SDK_INCLUDE_PKGDATA = "1"
SDK_UPDATE_URL = "http://my.server.com/path/to/esdk-update"

Now set SSTATE_MIRRORS URL so devtool can use your sstate-cache to avoid re-building packages. This is normally done by setting SSTATE_MIRRORS in conf/sdk-extra.conf but this is not possible as we're using toaster. Instead ensure you are not already using an existing SSTATE_MIRROR and set bitbake variables as follows

SDK_LOCAL_CONF_WHITELIST = "SSTATE_MIRRORS"
SSTATE_MIRRORS = "file://.* http://my.server.com/path/to/sstate-cache/PATH" 

Build SDK by building your-image:populate_sdk_ext in toaster.

Publish SDK Updater

The eSDK allows web updates, so you have to ensure they appeat at the URK specified by SDK_UPDATE_URL. Assume /var/www/html/path/to is served up as http://my.server.com/path/to
In the docker shell created when you started Toaster container run the following

oe-publish-sdk tmp/deploy/sdk/distro-image-toolchain-ext-ver.sh /var/www/html/path/to/esdk-update

Publish installer

Copy installer to web server and give this URL to your app developers.

cp tmp/deploy/sdk/distro-image-toolchain-ext-ver.sh /var/www/html/path/to/sdk-installer.sh

Publish SSTATE

cp -r build/sstate-cache /var/www/html/path/to/sstate-cache

Application Development

Install and Use eSDK

  • This assumes you have docker already installed as per Toaster instructions. No other dependencies are required (that the beauty of containers).
  • Create folder for esdk bind mount where output from container will appear, say /path/to/esdk/workdir
mkdir /path/to/esdk/workdir
docker run --rm -it -v /path/to/esdk-workdir:/workdir crops/extsdk-container --url https://downloads.yoctoproject.org/tools/support/workflow/poky-glibc-x86_64-core-image-minimal-i586-toolchain-ext-2.1.1.sh

If you see the error ERROR: The extensible sdk cannot be installed as root. it means that the folder /path/to/esdk-workdir does not exist