This port of FastLED 3.3 runs under the 4.x ESP-IDF development environment. Enjoy.

Updates: Aug, Sept 2020:

• I2S hardware working and now default.
• RMT interface well tested.
• WS2812FX library ported and working.

There are some new tunables, and if you're also fighting glitches, you need to read components/FastLED-idf/ESP-IDF.md.

Note you must use the ESP-IDF environment, and the ESP-IDF build system. That's how the paths and whatnot are created.

Here is the link to the ESP-IDF getting started guide. https://docs.espressif.com/projects/esp-idf/en/latest/esp32/get-started/

Pull requests welcome.

The ESP32 is a pretty great SOC package. It has two cores, 240Mhz speed, a meg of DRAM ( sorta ), low power mode, wifi and bluetooth, and can be had in pre-built modules at prices between $24 ( Adafruit, Sparkfun ), $10 (Espressif-manufactured boards through Mauser and Digikey), or 'knock off' boards for $4 from AliExpress as of 2020.

If you're going to program this board, you might use Arduino. Although I love the concept of Arduino - and the amazing amount of libraries - the reality is the Arduino IDE is a mess, and the compile environment is "funky", that is, it's not really C - about my first minute in the IDE, I managed to write a perfectly valid C preprocessor directive that's illegal in Arduino.

Enter ESP-IDF, which is Espressif's RTOS for this platform. It's based on FreeRTOS, but they had to fork it for multiple cores. It's based on FreeRTOS 9, but has some of the work done later backported so it has a few of the FreeRTOS 10 functions, apparently. Development seems vibrant, and they use the stock GCC 8.0 compiler with no strange overlays.

There are a TON of useful modules included with ESP-IDF. Notably, nghttp server, mdns, https servers, websockets, json, mqtt, etc etc.

What I tend to do with embedded systems is blink LEDs! Sure, there's other fun stuff, but blinking LEDs is pretty good. The included ledc module in ESP-IDF is only for changing the duty cycle and brightness, it doesn't control color-controlled LEDs like the WS8211.

Thus, we need FastLED

Playing around, there are "a lot of nice libraries on FastLED", but each and every one of them requires porting. At least, now there's a single one to start with. See the underlying component, and use it or not. If you don't want it, just don't bring that component over into your project.

At first, I focused the port on RMT, as it seemed the hardware everyone talked about. As you see below, the RMT interface even has a Espressif provided example! Thus the journey of getting the MEM_BUFS code working and soak up the interrupt latency.

But, the I2S hardware is almost certainly better than RMT. It has more parallelism, and less code, and seems enormously resistant to glitches.

The default is I2S, see below.

As with any ESP-IDF project, there is a sdkconfig file. It contains things that might or might not be correct for your ESP32. I've checked in a version that runs at 240Mhz, runs both cores, uses 40Mhz 4MB DIO Flash, auto-selects the frequency of the clock, and only runs on Rev1 hardware, and has turned off things like memory poisoning.

Because I'm trying to support different versions of esp-idf, and the sdkconfig files seem contradictory, the one in this repo matches "current" master, with a 4.0, 4.1, and 4.2 version. If you'd like to test my starting point, copy the correct one over to sdkconfig and give it a try.

For master, either use the standard sdkconfig or build your own. Remove this one, and idf.py menuconfig, and set whatever paramenters you need. There is nothing in this library that's specific to any particular version.

I tend to set the compiler into -O2 mode.

I've now read a lot of reddit posts about people saying "but I hook LEDs up to an Arudino and it works, but the ESP32 is flakey". Why yes. That's because ESP32 pins are 3.3v, Arduino pins are 5v, and LED signal levels are 5v. Either you get lucky with the LEDs you have, or you go find out about level shifting.

Adafruit's page on level shifting is perfectly good, although you don't need a breakout board, and using a 4-pin package isn't so cool as an 8 pin package, since an ESP32 can drive 8 channels. That's SN74HCT245N , and they're to be had from Digikey at $0.60. Read the datasheet carefully and get the direction and the enable pins right - they can't float.

Mid 2019, The following post showed up on reddit: https://www.reddit.com/r/FastLED/comments/bjq0sm/new_24way_parallel_driver_for_esp32/ which announced using I2S hardware instead of RMT hardware that had been used in the past.

I2S hardware is aimed to generate sound, but it can also be configured (as it is in this case) to provide a parallel bus interface. It is best understood by reading the Espressif documentation.

https://docs.espressif.com/projects/esp-idf/en/latest/esp32/api-reference/peripherals/i2s.html

What you'll see is there's 12 parallel pins that can be supported with each hardware module, and frankly if you need more than 12 way parallelism I worry about you. That should be enough for a module of this size.

From Sam's post: WARNINGS and LIMITATIONS

-- All strips must use the same clockless chip (e.g., WS2812). Due to the way the I2S peripheral works, it would be much more complicated to drive strips that have different timing parameters, so we punted on it. If you need to use multiple strips with different chips, use the default RMT-base driver.

-- Yves has written some mad code to compute the various clock dividers, so that the output is timing-accurate. If you see timing problems, however, let us know.

-- This is new software. We tested it on our machines. If you find bugs or other issues, please let us know!

Of course, new in 2019 is not so new now :-).

I have set the default to I2S, because it ran all of my torture tests immediately and flawlessly. I am somewhat unclear why it's so good. It's hard to suss out how deep the DMA queue is at a glance in time, and it seems that the interupt handler might be running at a different priority. I don't know if I can argue that it's doing less work. Since it's written for audio, there might be more attention paid to the driver.

Obviously, if you need the I2S hardware for something else, you'll want RMT, but there are two I2S components on an ESP32 and one on a ESP32-S2. The other uses of I2S include ( according to the documentation ) LCD master transmitting mode, camera slave receiving mode, and ADC / DAC mode ( feed directly to the DAC for output ).

You can still fall back to RMT, see below.

The I2S code uses the underlying hardware interface ( ll ) fast and furious. For this reason, nothing you see in the official documentation about I2S matches what the code is written to. Just to beware.

There's a #define at the top of fastled.h which chooses I2S or RMT. Switch to RMT by commenting out.

Comment back in "platforms/esp/32/clockless_rmt_esp32.cpp" from components\FastLED-idf\CMakeLists.txt

To compile the default I2S, you need to remove the RMT file from the compile because you don't want to waste RAM, and there are colliding symbols. You can't use both because there's no current way to define which strings use which hardware. If there was a new interface, you'd fix the colliding symbols and enable both.

The ESP32 has an interesting module, called RMT. It's a module that's meant to make arbitrary waveforms on pins, without having to bang each pin at the right time. While it was made for IR Remote Control devices, it works great for LEDs, and appears to be better than the PWM hardware.

There are 8 channels, which tends to match well with the the desires of most people for LED control. 8 channels is basically still a ton of LEDs, even if the FastLED ESP32 module is even fancier and multiplexes the use of these channels.

With the 800k WS8211 and similar that are now common, the end result of the math and the buffers is you need to fill the RMT hardware buffer about every 35microseconds. Even with an RTOS, it seems this is problematic, using C code. For this reason, the default settings are to use two "memory buffers", which double the depth of the RMT hardware buffer, and means that interrupt jitter of up to about 60us can be absorbed without visual artifact. However, this means getting hardware accelleration with only 4 channels instead of 8. This can be changed back to 8.

Please see the lengthy discussion under components/FastLED-idf/ESP-IDF.md to enable some tracing to find your timers, and similar.

The FastLED ESP32 RMT use has two modes: one which uses the "driver", and one which doesn't, and claims to be more efficient due to when it's converting between LED RGB and not.

The ESP-IDF driver does support a translate mode which would be the same as what the internal mode does.

Interestingly, four wire LEDs can't use the RMT interface, because the clock and data lines have to be controled together ( duh ), and the RMT interface doesn't do that. What does do that is the SPI interface, and I don't think I've wired that up.

The I2S interface, on the other hand, appears synchronized. I think you could write an APA102 driver using I2S and it would be fast and happy.

However, simply doing hardware SPI using the single SPI driver should be good enough. Work to do.

Since hardware banging is used ( that's the big ugly warning ), these LEDs are very likely far slower, and probably do not respond to parallelism the same way.

I have pulled in enough of the HAL for the APA102 code to compile, but I don't know if it works, since I don't have any four-wire LEDs around. Since it's very much a different code path, I'm not going to make promises until someone tries it.

The right way to use a system like this is with some form of async mode, where the CPU is loading and managing the RMT buffer(s), but then goes off to do other works while that's happening. This would allow much better multi-channel work, because the CPU could fill one channel, then go off and fill the next channel, etc. For that, you'd have to use the LastLED async interfaces.

It turns out this all works just peachy, it's just that the FastLED interface is a little peculiar. If you see the THREADING document in this directory, you'll see that this port is enabling multi-channel mode when using 3-wire LEDs, which means you change all the pixels, and when you call FastLED.show(), they'll all bang on the RMT hardware, and use very little main CPU.

It would be nicer if FastLED had some sort of Async mode, but that's not really the Arduino way, and this code is meant for arduino. Arduino doesn't have threads of control or message queues or anything like that.

ESP-IDF, in its new 4.x incarnation, has moved entirely to a cmake infrastructure. It creates a couple of key files at every level: CMakeLists.txt , Kconfig.

The CMakeLists.txt is where elements like which directories have source and includes live. Essentially, these define your projects.

The Kconfig files allow you to create variables that show up in MenuConfig. When you're building a new project, what you do is run idf.py menuconfig and that allows you to set key variables, like whether you want to bit-bang or use optimized hardware, which cores to run on, etc.

One element of esp-idf that took a while to cotton onto is that it doesn't build a single binary then you build your program and link against it. Since there are so many interdependancies - it's an RTOS, right - what really happens is when you build your code, you build everything in the standard set too. This means compiles are really long because you're rebuilding the entire system every time.

There's no way to remove components you're not using. Don't want to compile in HTTPS server? Tough. The menuconfig system allows you to not run it, but you can't not compile it without going in and doing surgery.

First of all, if you're changing versions, you have to be quite careful. The only foolproof method I've found is a brand new clone, a new install.sh, manually removing the project's build directory, and using the defult sdkconfig with a menuconfig, setting the parameters you need within this version.

Within menuconfig, I tend to use the following settings. Minimum required silicon rev to 1, because there are speed workarounds at Rev0 that get compiled in. I change the compiler options to -O2 instead of -Os or -Og. Default flash size to 4M, because all the devices I have are 4G.

Although ESP-IDF v4.x has apparently made great strides in working with VS and Platform.io, they still suggest you use cmake in windows. This avoids the elephant which is WSL - Windows Service for Linux. I use that exclusively for this project, and all of the instructions on how to install and use ESP-IDF for Linux work great, including flashing devices over USB. Serial devices are mounted as "/dev/ttySX", where X is the COMM number in the device. Really works nicely.

It appears that set of code was an earlier version of FastLED, and probably only still works with ESP-IDF 3.x. There was a major update to ESP-IDF, a new build system, lots of submodule updates, cleaned up headers and names, which seem to be all for the better - but with lots of breaking changes.

Thus, updating both, and using eskrab's version as a template, I attempt to have a running version of FastLED with the ESP-IDF 4.0 development environment

Not really. There is an included 'ledc' library, which simply changes the duty cycle on a pin using the RMT interface. It doesn't do pixel color control. It can be an example of using the RMT system, that's it.

There is an example of LED control, using the RMT interface directly. If you just want to it like that, without all the cool stuff in FastLED, be everyone's guest!

Interestingly, the LED library uses RMT, has glitches just like the older versions of RMT that FastLED had, and don't support I2S which is far more stable.

I did reach out to Espressif. I think they should include or have a FastLED port. In their forums, they said they don't intend to do anything like that.

When I started on this journey, I read a series of Reddit posts saying that Sam's FastLED port was the best for ESP32. It used RMT by default, and it still glitched a lot, which put me down the path of doing major work on the RMT code and finding the fundamental issue which he backported.

The code for the I2S driver, however, just came over peachy, and once I enabled it, the entire system was far more stable.

Kudos to Sam for getting the code to a better point, where it was amenable to the optimizations I did.

https://github.com/samguyer/FastLED

There is no reason to have ones own ISR. The ESP-IDF system has a 'translator', which is a function which will take pixel bytes to RMT buffers. This is the structure of the code already, so the entire ISR can be removed. This functionality is not in the Arduino implementation of RMT, which is why its not used here yet.

However, now that one has the I2S code, I would think improving the RMT code is a low priority.

This package basically depends on three packages: two that you pull in, and the fact that you've got to use the version that works with your intended version of esp-idf. Those two packages are FastLED, and also arduino-esp32, since FastLED is using the arduino interfaces.

It would have been possible to just have at the FastLED code and nuke the portions that are Arduino-ish, however, that removes the obvious benefit of eventually being able to update FastLED.

As a starting point, then I've taken the choice of keeping the libraries as unmodified as possible.

Drop this into the components/FastLED-idf directory. Now, it might have been cleaner to create a subdirectory with nothing but the FastLED-source code, this could be an organizational change the future.

You need a few of the HAL files. Please update these in the subdirectory hal. Don't forget to close the pod bay doors.

On an ESP32 running at 240Mhz, I was able to time 40 pixels at 1.2 milliseconds. I timed showLeds() at 3.0 milliseconds at 100 LEDs.

However, if you use more than one controller ( see the THREADING document ), three different controllers each will do 100 LEDs in 3 milliseconds. I have tested this with 1, 3, and 6 controllers. They all take the same amount of time.

If 30 milliseconds makes 30fps, then you should be able to do 1000 pixels on one of the two cores, and still, potentially, have the ability to do some extra work, because you've got the other CPU.

I have not determined if this is using the RMT interface, which would mean we could use an async internal interface. The timing, however, is very solid.

What I like about using FreeRTOS and a more interesting development environment is you should be able to use more of the CPU for other things. Essentially, you should be able to have the RMT system feeding itself, which then allows the main CPU to be updating the arrays of colors, and multiple channels to be doing the right thing all at the same time.

However, really being multi-core would mean having a locking semantic around the color array, or double buffering. FastLED doesn't seem to really think that way, rightfully so.

FastLED is MIT license.

I intend my portions to be MIT license. AKA the don't sue me license.

However, the Espressif HAL code is LGPL. Mostly, these are used as headers, not as code itself. There's very little of value there. If LGPL bothers you, I would propose a quick rewrite of those files, and submit a pull request that would be under MIT license.

I am honestly not sure what happens to LGPL in this case. It's a component in an embedded system, which is morally a library, but it is clearly very statically linked and in the "application", which I think would generate a copy-left. OTOH, that would also mean that ESP-IDF is all GPL and copy-left, and Espressif doesn't seem to think so ... whatever.

I don't intend to make any money off this, don't charge people, and do not intend the use for commercial art projects, so the use is safe for me. But don't say I didn't warn you.

I banged my head for a few hours on how to define ESP32, which is needed by FastLED to choose its platform. This should be doable in the CMakeLists.txt, but when I followed the instructions, I got an error about the command not being scriptable. Thus, to move things along, I define-ed at the top of the FastLED.h file.

Someone please fix that!

This is just a whine about esp-idf.

It seems idf.py build uses cores+2. That means when you're actually building your component, you're compiling all the other esp idf components, and you'll see a lot of stuff compile then finally what you want.

However, in recent versions of ESP-IDF, they've fixed a lot of things about the build system, so we really shouldn't complain. Builds are now really fast, and build just builds what's not touched.

Thanks, espressif!

Defined in arduino, maps to esp_timer_get_time() . There is an implementation of this in esp32-hal-misc.c, but no definition, because you are meant to supply a function that is defined by Arduino.

I have defined these functions in esp32-hal.h out of a lack of other places to put them. And, wouldn't it be better to use defines for these instead of functions???

The FastLED code is fast because it doesn't call digital read and digital write, it instead grabs the ports and ors directly into them. This is done with digitalPinToBitMask and digitalPinToPort. Once you have the port, and you have the mask, bang, you can go to town.

The esp-idf code supports the usual set of function calls to bang bits, and they include if statements, math, and a huge check to see if your pin number is right, inside every freaking inner loop. No wonder why a sane person would circumvent it. However, the ESP32 is also running at 240Mhz instead of 16Mhz, so performance optimizations will certainly matter less.

Looking at the eshkrab FastLED port, it appears that person just pulled in most of the registers, and has run with it.

HOWEVER, what's more interesting is the more recent FastLED code has an implementation of everything correctly under platforms///fastpin_esp32.h. There's a template there with all the right mojo. In a q-and-a section, it says that the PIN class is unused these days, and only FastPin is used. FastPin still uses 'digitalPinToPort', but has a #define in case those functions don't exist.

The following github issue is instructive. FastLED/FastLED#766

It in fact says that the FASTLED_NO_PINMAP is precisely to be used in ports where there is no Arduino. That's me! So let's go set that and move along to figuring out how to get the FastPins working.

Best current guess. There is an arduino add-only library called "Arduino_GPIO", which has the same basic structure, and that's what's being used to gain access to the core register pointers and such.

Essentially, this has to be re-written, because GPIO in that way doesn't exist.

A few words about bitbanging here.

There appears to be 4 32-bit values. They are w1tc ( clear ) and w1ts ( set ). When you want to write a 1, you set the correct values in w1ts, and when you want to clear, you set 1 to the values you want to clear in w1tc. Since there are 40 pins, there are two pairs of these.

Explained here: https://esp32.com/viewtopic.php?t=1987 . And noted that perhaps you can only set one value at a time, and it makes the system atomic, where if you try to read, mask, write in a RTOS / multicore case, you'll often hurt yourself. No taking spinlocks in this case, which is great.

There are also two "out" values. Oddly, there are both the GPIO.out, and GPIO.out.value. Unclear why. Reading the code naively, it looks like almost a bug. How could it be that the high pins have such a different name?

Another intereting post on the topic: https://www.esp32.com/viewtopic.php?t=1595 . This points to raw speeds being in the 4mhz / 10mhz range, and says "use the RMT interface". It also has questions about whether you need to or or set. The consensus seems to be that you don't need to do that, and you shoudn't need to disable interrupts either, because these actions are atomic.

Now, let's figure out the best way to adapt those to ESP-IDF.

https://docs.espressif.com/projects/esp-idf/en/v4.0/api-reference/peripherals/gpio.html

IT looks like there are defines for these values in ESP-IDF, so you really just need to find the places these are defined and change the names to GPIO_OUT_W1TS_REG , and GPIO_OUT_REG etc etc

soc/gpio_reg.h --- examples/peripherals/spi_slave or maybe just driver/gpio.h?

WRITE_PERI_REG(GPIO_OUT_W1TS_REG, 1 << GPIO_HANDSHAKE)

Looks like if you grab "gpio.h", it'll include what you need. For full information, it was bugging me where this structure is. It's in: soc/esp32/include/soc/gpio_struct.h . Which I also think is pulled in with gpio.h, or more correctly driver/gpio.h as below.

Hold up! It looks like driver/gpio.c uses the same exact GPIO. name. Is this a namespace or something? Should I just start including the same files gpio.c does?

#include <esp_types.h>
#include "esp_err.h"
#include "freertos/FreeRTOS.h"
#include "freertos/xtensa_api.h"
#include "driver/gpio.h"
#include "driver/rtc_io.h"
#include "soc/soc.h"
#include "soc/gpio_periph.h"
#include "esp_log.h"
#include "esp_ipc.h"

Let's start with:

#include <esp_types.h>
#include "esp_err.h"
#include "freertos/FreeRTOS.h"
#include "freertos/xtensa_api.h"
#include "driver/gpio.h"
#include "soc/gpio_periph.h"

Yay!

Note: what's up with registering the driver? I should, right? Make sure that's done in menuconfig? Doen't seem to be. There are no settings anywhere in the menuconfig regarding gpio. Should probably look at the examples to see if I have to enable the ISR or something.

/mnt/c/Users/bbulk/dev/esp/FastLED-idf/components/FastLED-idf/colorutils.h:455:69: error: 'void* memmove(void*, const void*, size_t)' writing to an object of type 'struct CHSV' with no trivial copy-assignment; use copy-assignment or copy-initialization instead [-Werror=class-memaccess]
         memmove8( &(entries[0]), &(rhs.entries[0]), sizeof( entries));

Files involved are:

FastLED.h
bitswap.h
controller.cpp
colorutils.h 

( Note: bitswap.cpp is rather inscrutable, since it points to a page that no longer exists. It would be really nice to know what it is transposing, or shifting, AKA, what the actual function is intended to do, since the code itself is not readable without a roadmap. )

The offending code is here:

    CHSVPalette16( const CHSVPalette16& rhs)
    {
        memmove8( &(entries[0]), &(rhs.entries[0]), sizeof( entries));
    }

and I think is an unnessary and unsafe optimization. It would be shocking on this processor, with GCC8+, that the memmove8 optimization is sane. This is a straight-up initialization, and the code should probably be simplified to do the simple thing.

This particular warning can be removed in a single file through the following pattern:

#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wclass-memaccess"

https://stackoverflow.com/questions/3378560/how-to-disable-gcc-warnings-for-a-few-lines-of-code

After looking a bit, it doesn't seem unreasonable to remove all the memmoves and turn them into loops. It's been done in other places of the code. Otherwise, one could say "IF GCC8" or something similar, because I bet it really does matter on smaller systems. Maybe even on this one.

In the upstream code of FastLED, there is an introduction of a void * cast in these two places. That's the other way of doing it, and the code does "promise" that the classes in question can be memcpy'd. If someone re-ports the code, they could fix this.

Had a main.c , and FastLED.h includes nothing but C++. Therefore, all the source files that include FastLED have to be using the C++ compiler, and ESP-IDF has the standard rules for using C for C and CPP for CPP because it's not like they are subsets or something.

There is some really scary code about guards. It is defined if ESP32, and seems to override the way the compiler executes a certain kind of guard. I've turned that off, because I think we should probably trust esp-idf to do the right and best thing for that

In order to get 4-wire LEDs compiling, it's necessary to pull in the HAL gpio.c . Just to get one lousy function - pinMode. I probably should have simply had the function call gpio_set_direction(), which is the esp_idf function, directly. If you have a 4-wire system, I left a breadcrumb in the fastpin_esp32 directory. If the alternate code works, then you can take the gpio.c out of the hal compile.

The code in ESP-IDF seems to really like using the pattern of having a macro for a default constructor. In the case of initializing the RMT structure, if I did it "by hand" and used the -O2 compile option, I got instability. The code is now written to do different things in different versions.

The underlying RMT code in ESP-IDF changed fairly radically between 4.0, 4.1, 4.2, and further. Specifically, the 4.1 code introduces the rmt_ll layer, but also initializes the structures used by _set_tx_thr_intr_en to set values in the chip only when the ESP-IDF interrupt handler is registered. This is resolved in 4.2, but in order to support 4.0, 4.1, and 4.2, I've put shadow versions of those functions. There are only three, so it's not a big deal.

The definition of the RMT system states that if you're using a buffer size of greater than 1 MEM_BLOCK, one must not use all the RMT channels. Thus, unlike other similar code in other systems, there are 8 channels and 8 rmt channels, but because we support MEM_BLOCK, the number of channels is limited by the MEM_BLOCKs, and it's important to use mRMT_channel, which is the underlying RMT channel in every case.

It's true! There are no hardware SPI pins defined. SPI is used for 4-wire LEDs, where you have to synchronize the clock and data.

If you have 3-wire LEDs, you'll be using the RMT system, which is super fast anyway.

The upstream code doesn't seem to use SPI on ESP32 either, so that's just a big hairy todo, and don't worry overmuch.