This project holds the code used for the Framework Laptop Embedded Controller.
The Embedded Controller on your Framework Laptop handles low level functions, including power sequencing the system. Modifying the EC code can cause your system to not power on or boot or cause damage to the mainboard, battery, or other parts of the system or devices attached to the system. Hardware damage caused by EC firmware modifications would not be covered under the Framework Limited Warranty.
The Framework Laptop EC code can be built easily outside the Chromium development environment as a standalone project with a minimal set of tools.
On Ubuntu you can install the development tools easily.
sudo apt install gcc-arm-none-eabi libftdi1-dev build-essential pkg-config
The different Framework Laptops are each implemented as their own board:
Laptop Generation | Board Name |
---|---|
Intel 11th Gen Core Processors | hx20 |
Intel 12th Gen Core Processors | hx30 |
Building the project - run the command for the processor you have:
# hx20 (11th Gen)
make BOARD=hx20 CROSS_COMPILE=arm-none-eabi-
# hx30 (12th Gen)
make BOARD=hx30 CROSS_COMPILE=arm-none-eabi-
The output artifact is build/hx20/ec.bin
which can be flashed to the EC SPI flash ROM.
When flashing the EC for Framework Laptops with Intel 11th Gen Core Processors, do not erase or overwrite the sectors 0x3C000 to 0x3FFFF, or 0x79000 to 0x7FFFF.
Currently the EC only runs from the ro region.
00000000:00000fff bootsector
00001000:00039fff lfwro
00040000:00078fff rw
The EC is a MEC1521H-B0-I-SZ WFBGA144 which has 256kB of RAM.
Most changes are limited to the following folders, however there are some modifications in common.
board/hx20
chip/mchp
Note that the EC has a checksum and header verification of the EC code image. Arbitarily modifying code, for example with a reverse engineering tool will cause the EC to fail to boot. Compiling the code from source will correctly generate the required checksum information to allow the EC to boot.
The EC has debug header in the upper right corner of the Mainboard next to the on-board power button. This is the 10 pin EC debug connector JECDB. Pin 1 is nearest the power button. The EC is configured for 2 wire SWD.
Pin | Description |
---|---|
1 | EC_VCC_3.3 |
2 | TDI |
3 | TMS |
4 | CLK |
5 | TDO |
6 | UART_TX |
7 | UART_RX |
8 | |
9 | EC_RESETI |
10 | GND |
The Framework Laptop EC is based upon the Google Chromium EC repository: https://chromium.googlesource.com/chromiumos/platform/ec. We upstream common features where they fit into the design decisions of Chrome OS. However, there are a number of features and changes that will be unlikely to be upstreamed because they are unnecessary for Chrome OS operation or do not fit the philosophy of Chrome OS.
For example, we implement memory mapped regions that are not used in Chrome OS such as the UCSI driver.
The remainder of this README file is directly from Google's Chromium EC project.
[TOC]
The Chromium OS project includes open source software for embedded controllers (EC) used in recent ARM and x86 based Chromebooks. This software includes a lightweight, multitasking OS with modules for power sequencing, keyboard control, thermal control, battery charging, and verified boot. The EC software is written in C and supports a variety of micro-controllers.
This document is a guide to help make you familiar with the EC code, current features, and the process for submitting code patches.
For more see the Chrome OS Embedded Controller presentation and video from the 2014 Firmware Summit.
EC (aka Embedded Controller) can refer to many things in the Chrome OS documentation due to historical reasons. If you just see the term "EC", it probably refers to "the" EC (i.e. the first one that existed). Most Chrome OS devices have an MCU, known as "the EC" that controls lots of things (key presses, turning the AP on/off). The OS that was written for "the" EC is now running on several different MCUs on Chrome OS devices with various tweaks (e.g. the FPMCU, the touchpad one that can do palm rejection, etc.). It's quite confusing, so try to be specific and use terms like FPMCU to distinguish the fingerprint MCU from "the EC".
See the EC Acronyms and Technologies for a more complete glossary.
The code for the EC is open source and is included in the Chromium OS
development environment (~/trunk/src/platform/ec/</code>
).
See http://www.chromium.org/chromium-os/quick-start-guide
for build setup instructions. If you want instant gratification, you can fetch
the source code directly. However, you will need the tool-chain provided by the
Chromium OS development environment to build a binary.
git clone https://chromium.googlesource.com/chromiumos/platform/ec
The source code can also be browsed on the web at:
https://chromium.googlesource.com/chromiumos/platform/ec/
The following is a quick overview of the top-level directories in the EC repository:
baseboard - Code and configuration details shared by a collection of board
variants. Tightly linked with the board
directory described below.
board - Board specific code and configuration details. This includes the GPIO map, battery parameters, and set of tasks to run for the device.
build - Build artifacts are generated here. Be sure to delete this and rebuild when switching branches and before "emerging" (see Building an EC binary below). make clobber is a convenient way to clean up before building.
chip - IC specific code for interfacing with registers and hardware blocks (adc, jtag, pwm, uart etc…)
core - Lower level code for task and memory management.
common - A mix of upper-level code that is shared across boards. This includes the charge state machine, fan control, and the keyboard driver (among other things).
driver - Low-level drivers for light sensors, charge controllers, I2C/onewire LED controllers, and I2C temperature sensors.
include - Header files for core and common code.
util - Host utilities and scripts for flashing the EC. Also includes “ectool” used to query and send commands to the EC from userspace.
test - Unit tests for EC components. These can be run locally in
a mock "host" environment or compiled for a target board.
If building for a target board, the test must be flashed and
run manually on the device.
All unit tests and fuzzers are build/run using the local
host environment during a buildall
.
To run all unit tests locally, run make runhosttests -j
.
To build a specific unit test for a specific board, run
make test-<test_name> BOARD=<board_name>
.
Please contribute new tests if writing new functionality.
Please run make help
for more detail.
fuzz - Fuzzers for EC components. These fuzzers are expected to run in the mock host environment. They follow the same rules as unit tests, as thus use the same commands to build and run.
Each Chrome device has a firmware branch created when the read-only firmware is
locked down prior to launch. This is done so that updates can be made to the
read-write firmware with a minimal set of changes from the read-only. Some
Chrome devices only have build targets on firmware branches and not on
cros/master. Run “git branch -a | grep firmware
” to locate the firmware branch
for your board. Note that for devices still under development, the board
configuration may be on the branch for the platform reference board.
To build EC firmware on a branch, just check it out and build it:
git checkout cros/firmware-falco_peppy-4389.B
To make changes on a branch without creating a whole new development environment (chroot), create a local tracking branch:
git branch --track firmware-falco_peppy-4389.B cros/firmware-falco_peppy-4389.B
git checkout firmware-falco_peppy-4389.B
make clobber
# <make changes, test, and commit them>
repo upload --cbr .
# (The --cbr means "upload to the current branch")
Here is a useful command to see commit differences between branches (change the branch1...branch2 as needed):
git log --left-right --graph --cherry-pick --oneline branch1...branch2
For example, to see the difference between cros/master and the HEAD of the current branch:
git log --left-right --graph --cherry-pick --oneline cros/master...HEAD
# Note: Use three dots “...” or it won’t work!
Note: The EC is normally built from within the Chromium OS development chroot to use the correct toolchain.
Building directly from the EC repository:
cros_sdk
cd ~/trunk/src/platform/ec
make -j BOARD=<boardname>
Where build/<boardname>/ec.bin
. The
-j
tells make to build multi-threaded which can be much faster on a multi-core
machine.
(optional) Run this command if you want to build from local source instead of the most recent stable version:
cros_workon-<boardname> start chromeos-ec
Build the EC binary:
emerge-<boardname> chromeos-ec
Please be careful if doing both local make
s and running emerge. The emerge can
pick up build artifacts from the build subdirectory. It’s best to delete the
build directory before running emerge with make clobber
.
The generated EC binary from emerge is found at:
(chroot) $ /build/<boardname>/firmware/ec.bin
The ebuild file used by Chromium OS is found here:
(chroot) $ ~/trunk/src/third_party/chromiumos-overlay/chromeos-base/chromeos-ec/chromeos-ec-9999.ebuild
If you get an error, you may not have set up the dependencies for servo correctly. The EC (on current Chromebooks) must be powered either by external power or a charged battery for re-flashing to succeed. You can re-flash via servo even if your existing firmware is bad.
(chroot) $ sudo emerge openocd
(chroot) $ ~/trunk/src/platform/ec/util/flash_ec --board=<boardname> [--image=<path/to/ec.bin>]
Note: This command will fail if write protect is enabled.
If you build your own EC firmware with the make BOARD=<boardname>
command the
firmware image will be at:
(chroot) $ ~/trunk/src/platform/ec/build/<boardname>/ec.bin
If you build Chrome OS with build_packages
the firmware image will be at:
(chroot) $ /build/<boardname>/firmware/ec.bin
Specifying --image
is optional. If you leave off the --image
argument, the
flash_ec
script will first look for a locally built ec.bin
followed by one
generated by emerge
.
Assuming your devices boots, you can flash it using the flashrom
utility. Copy
your binary to the device and run:
(chroot) $ flashrom -p ec -w <path-to/ec.bin>
Note: -p internal:bus=lpc
also works on x86 boards...but why would you want to
remember and type all that?
A feature called "Software Sync" keeps a copy of the read-write (RW) EC firmware in the RW part of the system firmware image. At boot, if the RW EC firmware doesn't match the copy in the system firmware, the EC’s RW section is re-flashed. While this is great for normal use as it makes updating the EC and system firmware a unified operation, it can be a challenge for EC firmware development. To disable software sync a flag can be set in the system firmware. Run the following commands from a shell on the device to disable Software Sync and turn on other developer-friendly flags (note that write protect must be disabled for this to work):
(chroot) $ /usr/share/vboot/bin/set_gbb_flags.sh 0x239
(chroot) $ reboot
This turns on the following flags:
GBB_FLAG_DEV_SCREEN_SHORT_DELAY
GBB_FLAG_FORCE_DEV_SWITCH_ON
GBB_FLAG_FORCE_DEV_BOOT_USB
GBB_FLAG_DISABLE_FW_ROLLBACK_CHECK
GBB_FLAG_DISABLE_EC_SOFTWARE_SYNC
The GBB
(Google Binary Block) flags are defined in the
vboot_reference source.
A varying subset of these flags are implemented and/or relevant for any
particular board.
The EC has an interactive serial console available only through the UART connected via servo. This console is essential to developing and debugging the EC.
Find the serial device of the ec console (on your workstation):
(chroot) $ dut-control ec_uart_pty
Connect to the console:
(chroot) $ socat READLINE /dev/pts/XX
Where XX
is the device number. Use cu
, minicom
, or screen
if you prefer
them over socat
.
help - get a list of commands. help
chan - limit logging message to specific tasks (channels). Useful if you’re looking for a specific error or warning and don’t want spam from other tasks.
battfake - Override the reported battery charge percentage. Good for testing low battery conditions (LED behavior for example). Set “battfake -1” to go back to the actual value.
fanduty - Override automatic fan control. “fanduty 0” turns the fan off. “autofan” switches back to automated control.
hcdebug - Display the commands that the host sends to the EC, in varying levels of detail (see include/ec_commands.h for the data structures).
The way in which messages are exchanged between the AP and EC is documented separately.
Most code run on the EC after initialization is run in the context of a task (with the rest in interrupt handlers). Each task has a fixed stack size and there is no heap (malloc). All variable storage must be explicitly declared at build-time. The EC (and system) will reboot if any task has a stack overflow. Tasks typically have a top-level loop with a call to task_wait_event() or usleep() to set a delay in uSec before continuing. A watchdog will trigger if a task runs for too long. The watchdog timeout varies by EC chip and the clock speed the EC is running at.
The list of tasks for a board is specified in ec.tasklist in the board/$BOARD/
sub-directory. Tasks are listed in priority order with the lowest priority task
listed first. A task runs until it exits its main function or puts itself to
sleep. The highest priority task that wants to run is scheduled next. Tasks can
be preempted at any time by an interrupt and resumed after the handler is
finished.
The console taskinfo
command will print run-time stats on each task:
> taskinfo
Task Ready Name Events Time (s) StkUsed
0 R << idle >> 00000000 32.975554 196/256
1 R HOOKS 00000000 0.007835 192/488
2 VBOOTHASH 00000000 0.042818 392/488
3 POWERLED 00000000 0.000096 120/256
4 CHARGER 00000000 0.029050 392/488
5 CHIPSET 00000000 0.017558 400/488
6 HOSTCMD 00000000 0.379277 328/488
7 R CONSOLE 00000000 0.042050 348/640
8 KEYSCAN 00000000 0.002988 292/488
The StkUsed
column reports the largest size the stack for each task grew since
reset (or sysjump).
Hooks allow you to register a function to be run when specific events occur; such as the host suspending or external power being applied:
DECLARE_HOOK(HOOK_AC_CHANGE, ac_change_callback, HOOK_PRIO_DEFAULT);
Registered functions are run in the HOOKS task. Registered functions are called
in priority order if more than one callback needs to be run. There are also
hooks for running functions periodically: HOOK_TICK
(fires every
HOOK_TICK_INVERVAL
ms which varies by EC chip) and HOOK_SECOND
. See
hook_type in
include/hooks.h
for a complete list.
Deferred functions allow you to call a function after a delay specified in uSec without blocking. Deferred functions run in the HOOKS task. Here is an example of an interrupt handler. The deferred function allows the handler itself to be lightweight. Delaying the deferred call by 30 mSec also allows the interrupt to be debounced.
static int debounced_gpio_state;
static void some_interrupt_deferred(void)
{
int gpio_state = gpio_get_level(GPIO_SOME_SIGNAL);
if (gpio_state == debounced_gpio_state)
return;
debounced_gpio_state = gpio_state;
dispense_sandwich(); /* Or some other useful action. */
}
/* A function must be explicitly declared as being deferrable. */
DECLARE_DEFERRED(some_interrupt_deferred);
void some_interrupt(enum gpio_signal signal)
{
hook_call_deferred(some_interrupt_deferred, 30 * MSEC);
}
While there is no heap, there is a shared memory buffer that can be borrowed temporarily (ideally before a context switch). The size of the buffer depends on the EC chip being used. The buffer can only be used by one task at a time. See common/shared_mem.c for more information. At present (May 2014), this buffer is only used by debug commands.
If you see a bug or want to make an improvement to the EC code please file an issue at crbug.com/new. It's best to discuss the change you want to make first on an issue report to make sure the EC maintainers are on-board before digging into the fun part (writing code).
In general, make more, smaller changes that solve single problems rather than bigger changes that solve multiple problems. Smaller changes are easier and faster to review. When changing common code shared between boards along with board specific code, please split the shared code change into its own change list (CL). The board specific CL can depend on the shared code CL.
The EC code follows the Linux Kernel style guide. Please adopt the same style used in the existing code. Use tabs, not spaces, 80 column lines etc...
Other style notes:
static
or const
. Use them for persistent state
within a file or for constant data (such as the GPIO list in board.c). Do
not use globals to pass information between modules without accessors. For
module scope, accessors are not needed.#define
config option to the code, please document it in
include/config.h
with an #undef
statement and descriptive comment.The Chromium copyright header must be included at the top of new files in all contributions to the Chromium project:
/* Copyright <year> The Chromium OS Authors. All rights reserved.
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
Prior to uploading a new change for review, please run the EC unit tests with:
(chroot) $ make -j buildall
(chroot) $ make -j tests
These commands will build and run unit tests in an emulator on your host.
Pre-submit checks are run when you try to upload a change-list. If you wish to
run these checks manually first, commit your change locally then run the
following command from within the chroot and while in the src/platform/ec
directory:
(chroot) $ ~/trunk/src/repohooks/pre-upload.py
The pre-submit checks include checking the commit message. Commit messages must
have a BUG
, BRANCH
, and TEST
line along with Signed-off-by: First Last <name@company.com>
. The signed-off-by line is a statement that you have written
this code and it can be contributed under the terms of the LICENSE
file.
Please refer to existing commits (git log
) to see the proper format for the
commit message. If you have configured git properly, running git commit
with
the -s
argument will add the Signed-off-by line for you.
While adding printf
statements can be handy, there are some other options for
debugging problems during development.
There may already be a message on the serial console that indicates your
problem. If you don’t have a servo connected, the ectool console
command will
show the current contents of the console buffer (the buffer’s size varies by EC
chip). This log persists across warm resets of the host but is cleared if the EC
resets. The ectool console
command will only work when the EC is not write
protected.
If you have interactive access to the serial console via servo, you can use the
read word rw
and write word ww
commands to peek and poke the EC's RAM. You
may need to refer to the datasheet for your EC chip or the disassembled code to
find the memory address you need. There are other handy commands on the serial
console to read temperatures, view the state of tasks (taskinfo) which may help.
Type help
for a list.
The EC may save panic data which persists across resets. Use the “ectool panicinfo
” command or console “panicinfo
” command to view the saved data:
Saved panic data: (NEW)
=== HANDLER EXCEPTION: 05 ====== xPSR: 6100001e ===
r0 :00000001 r1 :00000f15 r2 :4003800c r3 :000000ff
r4 :ffffffed r5 :00000799 r6 :0000f370 r7 :00000000
r8 :00000001 r9 :00000003 r10:20002fe0 r11:00000000
r12:00000008 sp :20000fd8 lr :000012e1 pc :0000105e
The most interesting information are the program counter (pc
) and the link
register (return address, lr
) as they give you an indication of what code the
EC was running when the panic occurred. HANDLER EXCEPTIONS
indicate the panic
occurred while servicing an interrupt. PROCESS EXCEPTIONS
occur in regular
tasks. If you see “Imprecise data bus error” listed, the program counter value
is incorrect as the panic occurred when flushing a write buffer. If using a
cortex-m based EC, add CONFIG_DEBUG_DISABLE_WRITE_BUFFER
to your board.h to
disable write buffering (with a performance hit) to get a “Precise bus error”
with an accurate program counter value.
If you have a program counter address you need to make sense of, you can
generate the assembly code for the EC by checking out the code at the matching
commit for your binary (ectool version
) and running:
(chroot) $ make BOARD=$board dis
This outputs two files with assembly code:
build/$board/RO/ec.RO.dis
build/$board/RW/ec.RW.dis
which (in the case of the LM4 and STM32) are essentially the same, but the RW addresses are offset.
See Firmware Write Protection.
The read-only and read-write sections of the EC firmware each have a version
string. This string tells you the branch and last change at which the firmware
was built. On a running machine, run ectool version
from a shell to see
version information:
RO version: peppy_v1.5.103-7abb4f7
RW version: peppy_v1.5.129-cd1a1e9
Firmware copy: RW
Build info: peppy_v1.5.129-cd1a1e9 2014-03-07 17:18:27 @build120-m2
You can also run the version
command on the EC serial console for a similar
output.
The format of the version string is:
<board>_<branch number>.<number of commits since the branch tag was created>-<git hash of most recent change>
If the version is: rambi_v1.6.68-a6608c8
:
The branch numbers (as of May 2014) are:
Hack command to check the branch tags:
git tag
for hash in $(git for-each-ref --format='%(objectname)' refs/tags/); do
git branch -a --contains $hash | head -1;
done
(If anyone can come up with something prettier, make a CL).
Run util/getversion.sh
to see the current version string. The board name is
passed as an environment variable BOARD
:
(chroot) $ BOARD="cheese" ./util/getversion.sh
cheese_v1.1.1755-4da9520