mirror of https://github.com/jeelabs/esp-link.git
You can not select more than 25 topics
Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
276 lines
16 KiB
276 lines
16 KiB
ESP-LINK
|
|
========
|
|
|
|
This firmware implements a transparent bridge between Wifi and serial using an ESP8266 module.
|
|
It also provides support for flash-programming Arduino/AVR microcontrollers as well as
|
|
LPC800-series ARM microcontrollers via the ESP8266.
|
|
|
|
The firmware includes a tiny HTTP server based on
|
|
[esphttpd](http://www.esp8266.com/viewforum.php?f=34)
|
|
with a simple web interface, many thanks to Jeroen Domburg for making it available!
|
|
|
|
[![Chat at https://gitter.im/jeelabs/esp-link](https://badges.gitter.im/Join%20Chat.svg)](https://gitter.im/jeelabs/esp-link?utm_source=badge&utm_medium=badge&utm_campaign=pr-badge&utm_content=badge)
|
|
|
|
Eye Candy
|
|
---------
|
|
These screen shots show the Home page, the Wifi configuration page, the console for the attached microcontroller,
|
|
and the pin assignments card:
|
|
|
|
<img width="45%" src="https://cloud.githubusercontent.com/assets/39480/8261425/6ca395a6-167f-11e5-8e92-77150371135a.png">
|
|
<img width="45%" src="https://cloud.githubusercontent.com/assets/39480/8261427/6caf7326-167f-11e5-8085-bc8b20159b2b.png">
|
|
<img width="45%" src="https://cloud.githubusercontent.com/assets/39480/8261426/6ca7f75e-167f-11e5-827d-9a1c582ad05d.png">
|
|
<img width="30%" src="https://cloud.githubusercontent.com/assets/39480/8261658/11e6c64a-1681-11e5-82d0-ea5ec90a6ddb.png">
|
|
|
|
Hardware info
|
|
-------------
|
|
This firmware is designed for esp8266 modules which have most ESP I/O pins available.
|
|
The default connections are:
|
|
- URXD: connect to TX of microcontroller
|
|
- UTXD: connect to RX of microcontroller
|
|
- GPIO12: connect to RESET of microcontroller
|
|
- GPIO13: connect to ISP of LPC/ARM microcontroller (not used with Arduino/AVR)
|
|
- GPIO0: optionally connect green "conn" LED to 3.3V (indicates wifi status)
|
|
- GPIO2: optionally connect yellow "ser" LED to 3.3V (indicates serial activity)
|
|
|
|
If you are using an FTDI connector, GPIO12 goes to DTR and GPIO13 goes to CTS.
|
|
|
|
The GPIO pin assignments can be changed dynamicall in the web UI and are saved in flash.
|
|
|
|
Initial flashing
|
|
----------------
|
|
(This is not necessary if you receive one of the jn-esp or esp-bridge modules!)
|
|
If you want to simply flash the provided firmware binary, you can download the latest
|
|
[release](https://github.com/jeelabs/esp-link/releases) and use your favorite
|
|
ESP8266 flashing tool to flash the following:
|
|
- `boot_v1.3(b3).bin` to 0x00000
|
|
- `blank.bin` to 0x7e000
|
|
- `user1.bin` to 0x01000
|
|
|
|
Note that the firmware assumes a 512KB flash chip, which most of the esp-01 thru esp-11
|
|
modules appear to have. A larger flash chip should work but has not been tested.
|
|
|
|
Wifi configuration overview
|
|
------------------
|
|
For proper operation the end state the esp-link needs to arrive at is to have it
|
|
join your pre-existing wifi network as a pure station.
|
|
However, in order to get there the esp-link will start out as an access point and you'll have
|
|
to join its network to configure it. The short version is:
|
|
1. the esp-link creates a wifi access point with an SSID of the form `ESP_012ABC`
|
|
2. you join your laptop to the esp-link's network as a station and you configure
|
|
the esp-link wifi with your network info by pointing your browser at http://192.168.4.1/
|
|
3. the esp-link starts to connect to your network while continuing to also be an access point ("AP+STA"),
|
|
the esp-link may show up with the esp-link.local hostname (depends on your DHCP/DNS config)
|
|
4. the esp-link succeeds in connecting and shuts down its own access point after 15 seconds,
|
|
|
|
LED indicators
|
|
--------------
|
|
Assuming appropriate hardware attached to GPIO pins, the green "conn" LED will show the wifi
|
|
status as follows:
|
|
- Very short flash once a second: not connected to a network and running as AP+STA, i.e.
|
|
trying to connect to the configured network
|
|
- Very short flash once every two seconds: not connected to a network and running as AP-only
|
|
- Even on/off at 1HZ: connected to the configured network but no IP address (waiting on DHCP)
|
|
- Steady on with very short off every 3 seconds: connected to the configured network with an IP address
|
|
(esp-link shuts down its AP after 15 seconds)
|
|
|
|
The yellow "ser" LED will blink briefly every time serial data is sent or received by the esp-link.
|
|
|
|
Wifi configuration details
|
|
--------------------------
|
|
After you have serially flashed the module it will create a wifi access point (AP) with an
|
|
SSID of the form `ESP_012ABC` where 012ABC is a piece of the module's MAC address.
|
|
Using a laptop, phone, or tablet connect to this SSID and then open a browser pointed at
|
|
http://192.168.4.1/, you should then see the esp-link web site.
|
|
|
|
Now configure the wifi. The desired configuration is for the esp-link to be a
|
|
station on your local wifi network so you can communicate with it from all your computers.
|
|
|
|
To make this happen, navigate to the wifi page and you should see the esp-link scan
|
|
for available networks. You should then see a list of detected networks on the web page and you can select
|
|
yours. Enter a password if your network is secure (highly recommended...) and hit the connect button.
|
|
|
|
You should now see that the esp-link has connected to your network and it should show you
|
|
its IP address. _Write it down_. You will then have to switch your laptop, phone, or tablet
|
|
back to your network and then you can connect to the esp-link's IP address or, depending on your
|
|
network's DHCP/DNS config you may be able to go to http://esp-link.local
|
|
|
|
At this point the esp-link will have switched to STA mode and be just a station on your
|
|
wifi network. These settings are stored in flash and thereby remembered through resets and
|
|
power cycles. They are also remembered when you flash new firmware. Only flashing `blank.bin`
|
|
via the serial port as indicated above will reset the wifi settings.
|
|
|
|
There is a fail-safe, which is that after a reset or a configuration change, if the esp-link
|
|
cannot connect to your network it will revert back to AP+STA mode after 15 seconds and thus
|
|
both present its `ESP_012ABC`-style network and continue trying to reconnect to the requested network.
|
|
You can then connect to the esp-link's AP and reconfigure the station part.
|
|
|
|
Troubleshooting
|
|
---------------
|
|
- verify that you have sufficient power, borderline power can cause the esp module to seemingly
|
|
function until it tries to transmit
|
|
- check the "conn" LED to see which mode esp-link is in (LED info above)
|
|
- reset or power-cycle the esp-link to force it to become an access-point if it can't
|
|
connect to your network within 15-20 seconds
|
|
- if the LED says that esp-link is on your network but you can't get to it, make sure your
|
|
laptop is on the same network (and no longer on the esp's network)
|
|
- if you do not know the esp-link's IP address on your network, try esp-link.local, try to find the
|
|
lease in your DHCP server; if all fails, you may have to turn off your access point (or walk
|
|
far enough away) and reset/power-cycle esp-link, it will then fail to connect and start its
|
|
own AP after 15-20 seconds
|
|
|
|
Building the firmware
|
|
---------------------
|
|
The firmware has been built using the [esp-open-sdk](https://github.com/pfalcon/esp-open-sdk)
|
|
on a Linux system. Create an esp8266 directory, install the esp-open-sdk into a sub-directory.
|
|
Download the Espressif SDK (1.1.2) and also expand it into a sub-directory. Then clone
|
|
this repository into a third sub-directory. This way the relative paths in the Makefile will work.
|
|
If you choose a different directory structure look at the Makefile for the appropriate environment
|
|
variables to define. (I have not used the esptool for flashing, so I don't know whether what's
|
|
in the Makefile for that works or not.)
|
|
|
|
In order to OTA-update the esp8266 you should `export ESP_HOSTNAME=...` with the hostname or
|
|
IP address of your module.
|
|
|
|
This project makes use of heatshrink, which is a git submodule. To fetch the code:
|
|
```
|
|
cd esp-link
|
|
git submodule init
|
|
git submodule update
|
|
```
|
|
|
|
Now, build the code: `make` in the top-level of esp-link.
|
|
|
|
A few notes from others (I can't fully verify these):
|
|
- You may need to install `zlib1g-dev` and `python-serial`
|
|
- Make sure you have the correct version of the esp_iot_sdk (v1.1.2 with scan patch for
|
|
esp-link release 0.10.0)
|
|
- Make sure the paths at the beginning of the makefile are correct
|
|
- Make sure `esp-open-sdk/xtensa-lx106-elf/bin` is in the PATH
|
|
|
|
Flashing the firmware
|
|
---------------------
|
|
This firmware supports over-the-air (OTA) flashing, so you do not have to deal with serial
|
|
flashing again after the initial one! The recommended way to flash is to use `make wiflash`
|
|
if you are also building the firmware.
|
|
If you are downloading firmware binaries use `./wiflash.sh`.
|
|
`make wiflash` assumes that you set `ESP_HOSTNAME` to the hostname or IP address of your esp-link.
|
|
|
|
The flashing, restart, and re-associating with your wireless network takes about 15 seconds
|
|
and is fully automatic. The 512KB flash are divided into two 236KB partitions allowing for new
|
|
code to be uploaded into one partition while running from the other. This is the official
|
|
OTA upgrade method supported by the SDK, except that the firmware is POSTed to the module
|
|
using curl as opposed to having the module download it from a cloud server.
|
|
|
|
If you are downloading the binary versions of the firmware (links forthcoming) you need to have
|
|
both `user1.bin` and `user2.bin` handy and run `wiflash.sh <esp-hostname> user1.bin user2.bin`.
|
|
This will query the esp-link for which file it needs, upload the file, and then reconnect to
|
|
ensure all is well.
|
|
|
|
Note that when you flash the firmware the wifi settings are all preserved so the esp-link should
|
|
reconnect to your network within a few seconds and the whole flashing process should take 15-30
|
|
from beginning to end. If you need to clear the wifi settings you need to reflash the `blank.bin`
|
|
using the serial port.
|
|
|
|
Serial bridge and connections to Arduino, AVR, ARM, LPC microcontrollers
|
|
------------------------------------------------------------------------
|
|
In order to connect through the esp-link to a microcontroller use port 23. For example,
|
|
on linux you can use `nc esp-hostname 23` or `telnet esp-hostname 23`. (There seems to be
|
|
a problem with the telnet program, please use nc instead for now.)
|
|
|
|
You can reprogram an Arduino / AVR microcontroller by pointing avrdude at port 23. Instead of
|
|
specifying a serial port of the form /dev/ttyUSB0 use `net:esp-link:23` with avrdude's -P option
|
|
(where `esp-link` is either the hostname of your esp-link or its IP address).
|
|
The esp-link detects that avrdude starts its connection with a flash synchronization sequence
|
|
and sends a reset to the AVR microcontroller so it can switch into flash programming mode.
|
|
|
|
You can reprogram NXP's LPC800-series and many other ARM processors as well by pointing your programmer
|
|
similarly at the esp-link's port 23. For example, if you are using
|
|
https://github.com/jeelabs/embello/tree/master/tools/uploader a command line like
|
|
`uploader -t -s -w esp-link:23 build/firmware.bin` should do the trick.
|
|
The way it works is that the uploader uses telnet protocol escape sequences in order to
|
|
make esp-link issue the appropriate "ISP" and reset sequence to the microcontroller to start the
|
|
flash programming. If you use a different ARM programming tool it will work as well as long as
|
|
it starts the connection with the `?\r\n` synchronization sequence.
|
|
|
|
Note that multiple connections to port 23 can be made simultaneously. The esp-link will
|
|
intermix characters received on all these connections onto the serial TX and it will
|
|
broadcast incoming characters from the serial RX to all connections. Use with caution!
|
|
|
|
Flash layout
|
|
------------
|
|
|
|
The flash layout dictated by the bootloader is the following (all this assumes a 512KB flash chip
|
|
and is documented in Espressif's `99C-ESP8266__OTA_Upgrade__EN_v1.5.pdf`):
|
|
- @0x00000 4KB bootloader
|
|
- @0x01000 236KB partition1
|
|
- @0x3E000 16KB esp-link parameters
|
|
- @0x40000 4KB unused
|
|
- @0x41000 236KB partition2
|
|
- @0x7E000 16KB system wifi parameters
|
|
|
|
What this means is that we can flash just about anything into partition1 or partition2 as long
|
|
as it doesn't take more than 236KB and has the right format that the boot loader understands.
|
|
We can't mess with the first 4KB nor the last 16KB of the flash.
|
|
|
|
Now how does a code partition break down? that is reflected in the following definition found in
|
|
the loader scripts:
|
|
```
|
|
dram0_0_seg : org = 0x3FFE8000, len = 0x14000
|
|
iram1_0_seg : org = 0x40100000, len = 0x8000
|
|
irom0_0_seg : org = 0x40201010, len = 0x2B000
|
|
```
|
|
This means that 80KB (0x14000) are reserved for "dram0_0", 32KB (0x8000) for "iram1_0" and
|
|
172KB (0x2B000) are reserved for irom0_0. The segments are used as follows:
|
|
- dram0_0 is the data RAM and some of that gets initialized at boot time from flash (static variable initialization)
|
|
- iram1_0 is the instruction RAM and all of that gets loaded at boot time from flash
|
|
- irom0_0 is the instruction cache which gets loaded on-demand from flash (all functions
|
|
with the `ICACHE_FLASH_ATTR` attribute go there)
|
|
|
|
You might notice that 80KB+32KB+172KB is more than 236KB and that's because not the entire dram0_0
|
|
segment needs to be loaded from flash, only the portion with statically initialized data.
|
|
You might also notice that while iram1_0 is as large as the chip's instruction RAM (at least
|
|
according to the info I've seen) the size of the irom0_0 segment is smaller than it could be,
|
|
since it's really not bounded by any limitation of the processor (it simply backs the cache).
|
|
|
|
When putting the OTA flash process together I ran into loader issues, namely, while I was having
|
|
relatively little initialized data and also not 32KB of iram1_0 instructions I was overflowing
|
|
the allotted 172KB of irom0_0. To fix the problem the build process modifies the loader scripts
|
|
(see the `build/eagle.esphttpd1.v6.ld` target in the Makefile) to increase the irom0_0 segment
|
|
to 224KB (a somewhat arbitrary value). This doesn't mean that there will be 224KB of irom0_0
|
|
in flash, it just means that that's the maximum the linker will put there without giving an error.
|
|
In the end what has to fit into the magic 236KB is the sum of the actual initialized data,
|
|
the actually used iram1_0 segment, and the irom0_0 segment.
|
|
In addition, the dram0_0 and iram1_0 segments can't exceed what's specified
|
|
in the loader script 'cause those are the limitations of the processor.
|
|
|
|
Now that you hopefully understand the above you can understand the line printed by the Makefile
|
|
when linking the firmware, which looks something like:
|
|
```
|
|
** user1.bin uses 218592 bytes of 241664 available
|
|
```
|
|
Here 241664 is 236KB and 218592 is the size of what's getting flashed, so you can tell that you have
|
|
another 22KB to spend (modulo some 4KB flash segment rounding).
|
|
(Note that user2.bin has exactly the same size, so the Makefile doesn't print its info.)
|
|
The Makefile also prints a few more details:
|
|
```
|
|
ls -ls eagle*bin
|
|
4 -rwxrwxr-x 1 tve tve 2652 May 24 10:12 eagle.app.v6.data.bin
|
|
176 -rwxrwxr-x 1 tve tve 179732 May 24 10:12 eagle.app.v6.irom0text.bin
|
|
8 -rwxrwxr-x 1 tve tve 5732 May 24 10:12 eagle.app.v6.rodata.bin
|
|
32 -rwxrwxr-x 1 tve tve 30402 May 24 10:12 eagle.app.v6.text.bin
|
|
```
|
|
This says that we have 179732 bytes of irom0_0, we have 5732+2652 bytes of dram0_0 (read-only data
|
|
plus initialized read-write data), and we have 30402 bytes of iram1_0.
|
|
|
|
There's an additional twist to all this for the espfs "file system" that esphttpd uses.
|
|
The data for this is loaded at the end of irom0_0 and is called espfs.
|
|
The Makefile modifies the loader script to place the espfs at the start of irom0_0 and
|
|
ensure that it's 32-bit aligned. The size of the espfs is shown here:
|
|
```
|
|
4026be14 g .irom0.text 00000000 _binary_espfs_img_end
|
|
40269e98 g .irom0.text 00000000 _binary_espfs_img_start
|
|
00001f7c g *ABS* 00000000 _binary_espfs_img_size
|
|
```
|
|
Namely, 0x1f7c = 8060 bytes.
|
|
|
|
|
|
|