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base: technicalkiwi:beta-1.03
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technicalkiwi:main technicalkiwi:p2p technicalkiwi:beta-1.0 technicalkiwi:preset
technicalkiwi:beta-1.03 technicalkiwi:beta-1.01
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compare: technicalkiwi:85490a3bd09f07e29744e098a560fe532fe7afb4
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technicalkiwi:p2p technicalkiwi:main technicalkiwi:beta-1.0 technicalkiwi:preset
technicalkiwi:beta-1.03 technicalkiwi:beta-1.01

5 Commits
beta-1.03 ... 85490a3bd0

Author SHA1 Message Date
Jimmy
85490a3bd0 feat(deploy): add file_hashes.json manifest on device 
Co-authored-by: Cursor <cursoragent@cursor.com>
 2026-05-17 19:14:51 +12:00
Jimmy
94266d5a7c feat(patterns): reverse animation direction via preset n8 
Co-authored-by: Cursor <cursoragent@cursor.com>
 2026-05-17 18:32:01 +12:00
Jimmy
55a97ac51c feat(patterns): merge pattern styles and add mode support 
Consolidate legacy pattern ids into meteor, particles, sparkle, chase,
and colour_cycle with n6/mode style selection; add pattern_modes helper,
self-contained tests/all.py, and preset mode alias on wire.

Co-authored-by: Cursor <cursoragent@cursor.com>
 2026-05-16 21:14:54 +12:00
Jimmy
794f1a2841 feat(patterns): add northern wave, candle glow, starfall, ice sparkle 
Co-authored-by: Cursor <cursoragent@cursor.com>
 2026-05-16 15:11:32 +12:00
Jimmy
8f8bc894a9 feat(patterns): add icicles blizzard and rime winter effects 
Co-authored-by: Cursor <cursoragent@cursor.com>
 2026-05-16 15:09:59 +12:00
41 changed files with 1445 additions and 1085 deletions
Expand all files Collapse all files

26
dev.py
View File

@@ -67,27 +67,9 @@ for cmd in sys.argv[1:]:
print("Error: Port required for 'db' command")
case "test":
if port:
if "all" in sys.argv[1:]:
test_files = sorted(
str(path)
for path in Path("test").rglob("*.py")
if path.is_file()
)
failed = []
for test_file in test_files:
print(f"Running {test_file}")
code = subprocess.call(
[*mpremote_base(), "connect", port, "run", test_file]
)
if code != 0:
failed.append((test_file, code))
if failed:
print("Some tests failed:")
for test_file, code in failed:
print(f" {test_file} (exit {code})")
else:
subprocess.call(
[*mpremote_base(), "connect", port, "run", "test/all.py"]
)
# Single self-contained suite (tests/all.py); requires ``src`` on device first.
subprocess.call(
[*mpremote_base(), "connect", port, "run", "tests/all.py"]
)
else:
print("Error: Port required for 'test' command")

118
docs/patterns.md Normal file
View File

@@ -0,0 +1,118 @@
# Patterns and presets on the LED driver
This document describes **how patterns are wired**, how **presets** map to patterns, and what each **shipped pattern** expects. For the JSON wire format (`v`: `"1"`, `presets`, `select`, short keys `p` / `c` / `b`, etc.), see [API.md](API.md).
## End-to-end control
1. The controller sends a **v1 JSON** object (ESP-NOW, serial bridge, or one line per message over TCP WebSocket in Wi-Fi mode).
2. `controller_messages.process_data()` parses it and applies fields in a fixed order (see `src/controller_messages.py`):
- `device_config` — name, LED count, colour order, startup mode; may reload `presets.json` and re-select the previous preset.
- `b`**global** output brightness (0255), stored in settings and in `presets.b`.
- `presets` — merge definitions into the in-memory preset table (`Presets.edit()` per id).
- `clear_presets` — optional wipe of all presets.
- `select` — pick the active preset (and optional step) for **this** device (matched by `settings["name"]`).
- `default` — update saved default preset when `targets` includes this device.
- `manifest` — pattern OTA: fetch pattern `.py` files and `reload_patterns()`.
- `save` — persist presets and/or settings when combined with the relevant fields.
3. The main loop calls `presets.tick()` so the active pattern **generator** advances one frame per iteration.
## Presets
- **Class:** `src/preset.py``Preset` holds the pattern configuration.
- **Short keys** (what the driver uses internally after `apply_presets` normalisation):
| Key | Meaning | Default |
|-----|---------|--------|
| `p` | Pattern id (string), must match a registered pattern | `"off"` |
| `c` | Colours as RGB tuples (after colour-order conversion) | `[(255,255,255)]` |
| `d` | Delay (ms); meaning is pattern-specific | `100` |
| `b` | Preset brightness 0255 (combined with global `presets.b`) | `127` |
| `a` | Auto: continuous animation; `false` = manual / beat-stepped where supported | `True` |
| `bg` | Background colour (hex string or RGB tuple on device) | `(0,0,0)` |
| `n1``n6` | Pattern-specific integers | `0` |
Long aliases from the controller (`pattern`, `colors`, `delay`, `brightness`, `auto`, `background`) are converted in `Preset.edit()`.
- **Persistence:** `presets.json` on flash; **`MAX_PRESETS` = 32** (exceptions for auto-created `"on"` / `"off"`).
- **Activation:** `Presets.select(preset_name, step=None)` loads the preset, looks up **`preset.p`** in the pattern registry, and sets `generator = patterns[preset.p](preset)`, then runs one `tick()` so the first frame appears.
## Brightness
- **Global:** `presets.b` from message `{"v":"1","b":…}` scales every output channel.
- **Per preset:** `preset.b`; combined in `Presets.apply_brightness(colour, preset.b)` as
`effective = round(preset_channel * presets.b / 255)` with preset level applied first conceptually (`apply_brightness` takes the presets `b` as the override for that colour).
## Pattern registry
Built in `Presets.reload_patterns()` (`src/presets.py`):
1. **Built-ins:** `"off"` and `"on"` — methods on the `Presets` instance (not separate files).
2. **Dynamic modules:** Every `patterns/*.py` on flash (except `__init__.py`), imported as `patterns.<basename>`. The loader takes the **first class** in the module that defines **`run`**, instantiates it with `Presets(self)` (the driver / NeoPixel wrapper), and registers:
```text
patterns[basename] = PatternClass(driver).run
```
So the **`p` field must equal the file basename without `.py`** (e.g. file `radiate.py` ⇒ pattern `"radiate"`).
### Adding or updating patterns on device
- **OTA:** v1 message with `"manifest"` (URL or inline JSON listing `files` with `name`, `url` or `code`) — see `apply_patterns_ota()` in `controller_messages.py`.
- **HTTP:** `POST /patterns/upload` on the device (`src/main.py`) with a safe `.py` filename; optional reload of the registry.
After new files land in `patterns/`, call `presets.reload_patterns()` (done automatically by OTA and upload when configured).
## Auto vs manual (`a`)
- **`a: true` (auto):** The main loop keeps calling `tick()`; the generator runs continuously (subject to internal `yield` timing / `utime`).
- **`a: false` (manual):** Intended for patterns that advance **once per explicit `select`** (or per beat routing from the controller). The driver does **not** call `select()` again when editing a manual preset-only push — manual steps are driven by incoming `select` messages.
Special case in `Presets.select()`: for **manual chase**, if the same preset is re-selected mid-generator, pending frames may be flushed so step indices stay aligned with beats.
## Built-in patterns
### `off`
- **Registration:** built-in method `Presets.off`.
- **Behaviour:** fills the strip with black (after generator setup, `tick` completes immediately).
- **Parameters:** ignores preset colours for the strip; optional `preset` argument unused for pixels.
### `on`
- **Registration:** built-in method `Presets.on`.
- **Behaviour:** solid fill with `preset.c[0]` (or white if no colours), via `apply_brightness(..., preset.b)`.
- **Parameters:** `c`, `b`; `d` / `n*` not used.
## Dynamic pattern: `radiate`
- **File:** `src/patterns/radiate.py`
- **Class:** `Radiate` — `run(self, preset)` is a **generator** (must `yield` each frame).
- **Pattern key:** `p` = `"radiate"`
Concept: repeating **nodes** along the strip every **`n1`** LEDs; from each node a lit region expands outward then contracts (timed by **`n2`** / **`n3`**). In **auto**, a new pulse train starts every **`d`** ms and the active colour index advances. In **manual**, a **single** out-and-back cycle runs, then the generator ends (next colour on the next `select`).
| Field | Role |
|-------|------|
| `n1` | Node spacing in LEDs (`>= 1`; half-spacing used for symmetry) |
| `n2` | Outbound travel time (ms), `>= 1` |
| `n3` | Return travel time (ms), `>= 1` |
| `d` | Auto only: interval (ms) between re-triggers; `>= 1` |
| `c` | Colour list; cycles per retrigger / per manual cycle |
| `bg` | Off state / gap colour (via `preset.background_or`) |
| `b` | Preset brightness |
| `a` | `true` = repeating pulses on a timer; `false` = one shot per select |
Debug: if `presets.debug` is true (from settings), periodic logs print timing and lit LED counts.
## Other pattern names (`blink`, `rainbow`, `pulse`, …)
Those pattern **ids** are valid on the **wire** and in **led-controller** `db/pattern.json`, but they are **not** all present in this repositorys `src/patterns/` tree. On a real device they normally appear as **additional** `patterns/*.py` files delivered by OTA or upload. For the intended **`n1``n6`** semantics on the wire, use [API.md](API.md) **Pattern-Specific Parameters**; the implementation must match that contract in each modules `run(preset)` generator.
## Quick reference: files
| File | Role |
|------|------|
| `src/preset.py` | Preset field model and aliases |
| `src/presets.py` | Registry, `select`, `tick`, `off` / `on`, dynamic load |
| `src/controller_messages.py` | Parse v1 JSON, apply presets/select/brightness/OTA |
| `src/patterns/*.py` | One pattern module per dynamic id (basename = `p`) |

5
src/background_tasks.py
View File

@@ -1,8 +1,8 @@
import asyncio
import gc
import utime
from hello import broadcast_hello_udp
from mem_stats import print_mem
from wifi_sta import try_reconnect
_UDP_HELLO_ATTEMPT = 0
@@ -16,8 +16,7 @@ async def presets_loop(presets, wdt):
if bool(getattr(presets, "debug", False)):
now = utime.ticks_ms()
if utime.ticks_diff(now, last_mem_log) >= 5000:
gc.collect()
print("mem runtime:", {"free": gc.mem_free(), "alloc": gc.mem_alloc()})
print_mem("runtime")
last_mem_log = now
# tick() does not await; yield so UDP hello and HTTP/WebSocket can run.
await asyncio.sleep(0)

101
src/file_hashes.py Normal file
View File

@@ -0,0 +1,101 @@
"""
Deploy hash manifest at flash root (file_hashes.json).
Updated by led-cli after directory uploads; used to skip unchanged files on
the next deploy. Format: {"version": 1, "algorithm": "sha256", "files": {...}}
"""
import json
import os
MANIFEST_VERSION = 1
MANIFEST_FILENAME = "file_hashes.json"
HASH_ALGO = "sha256"
_SKIP_NAMES = frozenset({MANIFEST_FILENAME, "__pycache__"})
_SKIP_SUFFIXES = (".pyc", ".pyo")
def _normalize_path(path):
return path.replace("\\", "/").lstrip("/")
def load():
"""Return path -> sha256 hex map, or {} if missing or invalid."""
try:
with open(MANIFEST_FILENAME, "r") as f:
doc = json.load(f)
except OSError:
return {}
if not isinstance(doc, dict):
return {}
files = doc.get("files")
return files if isinstance(files, dict) else {}
def save(files):
"""Write manifest (path keys use forward slashes, no leading slash)."""
if not isinstance(files, dict):
files = {}
doc = {
"version": MANIFEST_VERSION,
"algorithm": HASH_ALGO,
"files": files,
}
with open(MANIFEST_FILENAME, "w") as f:
json.dump(doc, f)
def _hash_file(path):
import hashlib
h = hashlib.sha256()
with open(path, "rb") as f:
while True:
chunk = f.read(256)
if not chunk:
break
h.update(chunk)
return h.hexdigest()
def _walk_dir(base, prefix, out):
try:
names = os.listdir(base)
except OSError:
return
for name in names:
if name in _SKIP_NAMES or name.endswith(_SKIP_SUFFIXES):
continue
full = base + "/" + name if base else name
key = _normalize_path((prefix + "/" + name) if prefix else name)
try:
mode = os.stat(full)[0]
except OSError:
continue
if mode & 0x4000:
_walk_dir(full, key, out)
else:
out[key] = _hash_file(full)
def rebuild():
"""Rebuild manifest from root .py files plus patterns/ and lib/ trees."""
files = {}
try:
for name in os.listdir("."):
if name in _SKIP_NAMES or name.endswith(_SKIP_SUFFIXES):
continue
try:
mode = os.stat(name)[0]
except OSError:
continue
if mode & 0x4000:
if name in ("patterns", "lib"):
_walk_dir(name, name, files)
else:
files[_normalize_path(name)] = _hash_file(name)
except OSError:
pass
save(files)
return files

37
src/main.py
View File

@@ -1,6 +1,6 @@
import print_timestamp # noqa: F401 — prefixes every print with [ticks_ms]
from settings import Settings
import machine
import network
import utime
import asyncio
import json
@@ -10,8 +10,9 @@ from microdot.websocket import WebSocketError, with_websocket
from presets import Presets
from controller_messages import apply_startup_pattern, process_data
from runtime_state import RuntimeState
from background_tasks import udp_hello_loop_after_http_ready
from wifi_sta import connect_until_up
from background_tasks import presets_loop, udp_hello_loop_after_http_ready
from mem_stats import print_mem
from wifi_sta import boot_sta
try:
import uos as os
except ImportError:
@@ -25,9 +26,8 @@ machine.freq(160000000)
settings = Settings()
gc.collect()
sta_if = boot_sta(settings, wdt)
presets = Presets(settings["led_pin"], settings["num_leds"])
presets.load(settings)
@@ -37,21 +37,6 @@ gc.collect()
apply_startup_pattern(settings, presets)
# On ESP32-C3, soft reboots can leave Wi-Fi driver state allocated.
# Reset both interfaces and collect before bringing STA up.
ap_if = network.WLAN(network.AP_IF)
ap_if.active(False)
sta_if = network.WLAN(network.STA_IF)
if sta_if.active():
sta_if.active(False)
utime.sleep_ms(100)
gc.collect()
sta_if.active(True)
sta_if.config(pm=network.WLAN.PM_NONE)
_boot_ssid = settings.get("ssid") or ""
if _boot_ssid:
connect_until_up(sta_if, _boot_ssid, settings.get("password") or "", wdt)
def _print_network_ips(controller_ip=None):
"""Always log STA address and led-controller (WS client) address when known."""
@@ -64,6 +49,7 @@ def _print_network_ips(controller_ip=None):
_print_network_ips()
print_mem("startup")
runtime_state = RuntimeState()
@@ -94,6 +80,7 @@ async def ws_handler(request, ws):
except Exception:
controller_ip = None
_print_network_ips(controller_ip)
print_mem("ws connect")
try:
while True:
data = await ws.receive()
@@ -167,16 +154,8 @@ async def upload_pattern(request):
}), 201, {"Content-Type": "application/json"}
async def presets_loop():
last_mem_log = utime.ticks_ms()
while True:
presets.tick()
wdt.feed()
await asyncio.sleep(0)
async def main(port=80):
asyncio.create_task(presets_loop())
asyncio.create_task(presets_loop(presets, wdt))
asyncio.create_task(
udp_hello_loop_after_http_ready(sta_if, settings, wdt, runtime_state)
)

34
src/mem_stats.py Normal file
View File

@@ -0,0 +1,34 @@
"""GC / heap snapshot helpers for debug logging."""
import gc
def snapshot():
"""Return a dict of memory stats after ``gc.collect()``."""
gc.collect()
out = {
"free": gc.mem_free(),
"alloc": gc.mem_alloc(),
}
try:
import esp32
blocks = esp32.idf_heap_info(esp32.HEAP_DATA)
if blocks:
block = blocks[0]
if isinstance(block, dict):
if "total_free_bytes" in block:
out["idf_free"] = block["total_free_bytes"]
largest = block.get("largest_free_block")
if largest is None:
largest = block.get("largest_free_block_in_bytes")
if largest is not None:
out["idf_largest"] = largest
except Exception:
pass
return out
def print_mem(label):
"""Print one timestamped memory line (via ``print_timestamp`` when installed)."""
print("mem %s:" % label, snapshot())

76
src/patterns/aurora.py
View File

@@ -1,12 +1,16 @@
import math
import utime
from patterns.pattern_modes import style_mode
_LEGACY = {"northern_wave": 1}
class Aurora:
def __init__(self, driver):
self.driver = driver
def run(self, preset):
colors = preset.c if preset.c else [(40, 200, 140), (80, 120, 255), (160, 80, 220)]
def _run_bands(self, preset, colors):
bands = max(1, int(preset.n1) if int(preset.n1) > 0 else 3)
shimmer = max(0, min(255, int(preset.n2) if int(preset.n2) > 0 else 40))
phase = self.driver.step % 256
@@ -16,16 +20,76 @@ class Aurora:
now = utime.ticks_ms()
if utime.ticks_diff(now, last) >= d:
for i in range(self.driver.num_leds):
idx = ((i * bands) // max(1, self.driver.num_leds) + (phase // 32)) % len(colors)
idx = (
(i * bands) // max(1, self.driver.num_leds) + (phase // 32)
) % len(colors)
c = self.driver.apply_brightness(colors[idx], preset.b)
w = (255 - abs(128 - ((i * 8 + phase) & 255)) * 2)
w = 255 - abs(128 - ((i * 8 + phase) & 255)) * 2
w = max(0, min(255, w + shimmer))
self.driver.n[i] = ((c[0]*w)//255, (c[1]*w)//255, (c[2]*w)//255)
self.driver.n[self.driver.led_i(preset, i)] = (
(c[0] * w) // 255,
(c[1] * w) // 255,
(c[2] * w) // 255,
)
self.driver.n.write()
phase = (phase + 1) & 255
phase = (phase + self.driver.signed(preset, 1)) & 255
self.driver.step = phase
last = utime.ticks_add(last, d)
if not preset.a:
yield
return
yield
def _run_northern(self, preset, colors):
period = max(4, int(preset.n1) if int(preset.n1) > 0 else 20)
contrast = max(1, min(255, int(preset.n2) if int(preset.n2) > 0 else 200))
drift = max(1, int(preset.n3) if int(preset.n3) > 0 else 2)
phase = 0
last = utime.ticks_ms()
ncols = len(colors)
if ncols < 2:
colors = list(colors) + [(120, 180, 255)]
ncols = len(colors)
twopi = 6.2831853
def lerp3(a, b, f):
return (
a[0] + ((b[0] - a[0]) * f) // 255,
a[1] + ((b[1] - a[1]) * f) // 255,
a[2] + ((b[2] - a[2]) * f) // 255,
)
while True:
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) >= d:
bg = self.driver.apply_brightness(preset.background_or(colors), preset.b)
for i in range(self.driver.num_leds):
t = (i * twopi / period) + (phase * twopi / 256.0)
w = (math.sin(t) + 1.0) * 0.5
u = w * (ncols - 1) * 256.0
fi = int(u) >> 8
frac = int(u) & 255
if fi >= ncols - 1:
fi = ncols - 2
frac = 255
peak = lerp3(colors[fi], colors[fi + 1], frac)
peak = self.driver.apply_brightness(peak, preset.b)
mixf = min(255, int(w * contrast * 2) >> 1)
self.driver.n[self.driver.led_i(preset, i)] = lerp3(bg, peak, mixf)
self.driver.n.write()
phase = (phase + self.driver.signed(preset, drift)) % 256
last = utime.ticks_add(last, d)
if not preset.a:
yield
return
yield
def run(self, preset):
"""Aurora bands (n6=0) or sine northern wave (n6=1, legacy northern_wave)."""
colors = preset.c if preset.c else [(40, 200, 140), (80, 120, 255), (160, 80, 220)]
if style_mode(preset, 0, _LEGACY) == 1:
colors = preset.c if preset.c else [(20, 55, 120), (60, 140, 220), (180, 220, 255)]
yield from self._run_northern(preset, colors)
return
yield from self._run_bands(preset, colors)

67
src/patterns/blizzard.py Normal file
View File

@@ -0,0 +1,67 @@
import random
import utime
class Blizzard:
"""Dense falling flakes with sideways drift (compare `snowfall` for gentler flakes)."""
def __init__(self, driver):
self.driver = driver
def run(self, preset):
colors = preset.c if preset.c else [(255, 255, 255), (200, 230, 255), (180, 210, 255)]
# Higher n1 → more spawns (0255 threshold vs random)
density = max(1, int(preset.n1) if int(preset.n1) > 0 else 90)
speed = max(1, int(preset.n2) if int(preset.n2) > 0 else 2)
# n3: 128 = no bias; <128 drift one way, >128 the other (scaled to small steps)
wraw = int(preset.n3)
if wraw <= 0:
wind = 0
else:
wind = max(-4, min(4, (wraw - 128) // 20))
flakes = []
last = utime.ticks_ms()
while True:
d_ms = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) >= d_ms:
nled = self.driver.num_leds
bg = self.driver.apply_brightness(preset.background_or(colors), preset.b)
for i in range(nled):
self.driver.n[i] = bg
if random.randint(0, 255) < density:
flakes.append(
[
nled - 1,
random.randint(0, len(colors) - 1),
0 if wind == 0 else random.randint(-1, 1),
]
)
nf = []
for pos, ci, wj in flakes:
p = pos
lateral = wind + (wj if wj else 0)
p -= self.driver.signed(preset, speed)
p += self.driver.signed(preset, lateral)
if p < -2 or p >= nled + 2:
continue
pi = max(0, min(nled - 1, int(p)))
self.driver.n[self.driver.led_i(preset, pi)] = self.driver.apply_brightness(
colors[ci], preset.b
)
nf.append([p, ci, wj])
flakes = nf
self.driver.n.write()
last = utime.ticks_add(last, d_ms)
if not preset.a:
yield
return
yield

40
src/patterns/breathing_dual.py
View File

@@ -1,40 +0,0 @@
import utime
class BreathingDual:
def __init__(self, driver):
self.driver = driver
def run(self, preset):
colors = preset.c if preset.c else [(255, 0, 140), (0, 120, 255)]
phase_offset = max(0, min(255, int(preset.n1)))
ease = max(1, int(preset.n2) if int(preset.n2) > 0 else 1)
phase = self.driver.step % 256
last = utime.ticks_ms()
while True:
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) >= d:
p1 = phase
p2 = (phase + phase_offset) & 255
t1 = 255 - abs(128 - p1) * 2
t2 = 255 - abs(128 - p2) * 2
if ease > 1:
t1 = (t1 * t1) // 255
t2 = (t2 * t2) // 255
c1 = self.driver.apply_brightness(colors[0], preset.b)
c2 = self.driver.apply_brightness(colors[1 % len(colors)] if len(colors) > 1 else colors[0], preset.b)
half = self.driver.num_leds // 2
for i in range(self.driver.num_leds):
if i < half:
self.driver.n[i] = ((c1[0]*t1)//255, (c1[1]*t1)//255, (c1[2]*t1)//255)
else:
self.driver.n[i] = ((c2[0]*t2)//255, (c2[1]*t2)//255, (c2[2]*t2)//255)
self.driver.n.write()
phase = (phase + 2) & 255
self.driver.step = phase
last = utime.ticks_add(last, d)
if not preset.a:
yield
return
yield

56
src/patterns/candle_glow.py Normal file
View File

@@ -0,0 +1,56 @@
import random
import utime
class CandleGlow:
def __init__(self, driver):
self.driver = driver
def run(self, preset):
colors = preset.c if preset.c else [(255, 140, 40), (255, 200, 120), (255, 90, 20)]
n_candles = max(1, min(self.driver.num_leds, int(preset.n1) if int(preset.n1) > 0 else 4))
width = max(1, int(preset.n2) if int(preset.n2) > 0 else 3)
flicker = max(1, min(255, int(preset.n3) if int(preset.n3) > 0 else 90))
n_led = self.driver.num_leds
centers = tuple(random.randint(0, max(0, n_led - 1)) for _ in range(n_candles))
last = utime.ticks_ms()
while True:
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) >= d:
bg = self.driver.apply_brightness(preset.background_or(colors), preset.b)
for i in range(n_led):
self.driver.n[i] = bg
base_lo = 180 - flicker // 2
if base_lo < 40:
base_lo = 40
for ci, c in enumerate(centers):
warmth = colors[ci % len(colors)]
pulse = base_lo + random.randint(0, flicker)
if pulse > 255:
pulse = 255
for off in range(-width, width + 1):
idx = c + off
if 0 <= idx < n_led:
dist = abs(off)
fall = ((width - dist + 1) * 256) // (width + 1)
fac = (fall * pulse) // 256
px = (
(warmth[0] * fac) // 255,
(warmth[1] * fac) // 255,
(warmth[2] * fac) // 255,
)
lit = self.driver.apply_brightness(px, preset.b)
o = self.driver.n[idx]
self.driver.n[idx] = (
max(o[0], lit[0]),
max(o[1], lit[1]),
max(o[2], lit[2]),
)
self.driver.n.write()
last = utime.ticks_add(last, d)
if not preset.a:
yield
return
yield

52
src/patterns/chase.py
View File

@@ -1,13 +1,49 @@
import utime
from patterns.pattern_modes import style_mode
_LEGACY = {"marquee": 1}
class Chase:
def __init__(self, driver):
self.driver = driver
def _run_marquee(self, preset, colors):
on_len = max(1, int(preset.n1) if int(preset.n1) > 0 else 3)
off_len = max(1, int(preset.n2) if int(preset.n2) > 0 else 2)
step = max(1, abs(self.driver.signed(preset, int(preset.n3) if int(preset.n3) > 0 else 1)))
phase = self.driver.step % (on_len + off_len)
last = utime.ticks_ms()
while True:
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) >= d:
c = self.driver.apply_brightness(colors[0], preset.b)
bg_color = self.driver.apply_brightness(preset.background_or(colors), preset.b)
for i in range(self.driver.num_leds):
m = (i + phase) % (on_len + off_len)
self.driver.n[self.driver.led_i(preset, i)] = c if m < on_len else bg_color
self.driver.n.write()
phase = (phase + self.driver.signed(preset, step)) % (on_len + off_len)
self.driver.step = phase
last = utime.ticks_add(last, d)
if not preset.a:
yield
return
yield
def run(self, preset):
"""Chase pattern: n1 LEDs of color0, n2 LEDs of color1, repeating.
Moves by n3 on even steps, n4 on odd steps (n3/n4 can be positive or negative)"""
"""Chase (n6=0) or marquee dashes (n6=1, legacy marquee).
Chase: n1/n2 segment lengths, n3/n4 step on even/odd beats.
Marquee: n1 on length, n2 off length, n3 scroll step.
"""
if style_mode(preset, 0, _LEGACY) == 1:
colors = preset.c if preset.c else [(255, 255, 255)]
yield from self._run_marquee(preset, colors)
return
colors = preset.c
if len(colors) < 1:
# Need at least 1 color
@@ -30,8 +66,8 @@ class Chase:
n1 = max(1, int(preset.n1)) # LEDs of color 0
n2 = max(1, int(preset.n2)) # LEDs of color 1
n3 = int(preset.n3) # Step movement on even steps (can be negative)
n4 = int(preset.n4) # Step movement on odd steps (can be negative)
n3 = self.driver.signed(preset, int(preset.n3)) # Step movement on even steps
n4 = self.driver.signed(preset, int(preset.n4)) # Step movement on odd steps
segment_length = n1 + n2
@@ -65,9 +101,9 @@ class Chase:
# Determine which color based on position in segment
if relative_pos < n1:
self.driver.n[i] = color0
self.driver.n[self.driver.led_i(preset, i)] = color0
else:
self.driver.n[i] = color1
self.driver.n[self.driver.led_i(preset, i)] = color1
self.driver.n.write()
print("[chase] step", step_count)
@@ -111,9 +147,9 @@ class Chase:
# Determine which color based on position in segment
if relative_pos < n1:
self.driver.n[i] = color0
self.driver.n[self.driver.led_i(preset, i)] = color0
else:
self.driver.n[i] = color1
self.driver.n[self.driver.led_i(preset, i)] = color1
self.driver.n.write()
print("[chase] step", step_count)

72
src/patterns/colour_cycle.py
View File

@@ -1,11 +1,24 @@
import utime
from patterns.pattern_modes import style_mode
_LEGACY = {"rainbow": 1, "gradient_scroll": 0}
class ColourCycle:
def __init__(self, driver):
self.driver = driver
def _render(self, colors, phase, brightness):
def _wheel(self, pos):
if pos < 85:
return (pos * 3, 255 - pos * 3, 0)
if pos < 170:
pos -= 85
return (255 - pos * 3, 0, pos * 3)
pos -= 170
return (0, pos * 3, 255 - pos * 3)
def _render_gradient(self, preset, colors, phase, brightness):
num_leds = self.driver.num_leds
color_count = len(colors)
if num_leds <= 0 or color_count <= 0:
@@ -15,14 +28,11 @@ class ColourCycle:
return
full_span = color_count * 256
# Match rainbow behaviour: phase is 0..255 and maps to one full-strip shift.
phase_shift = (phase * full_span) // 256
for i in range(num_leds):
# Position around the colour loop, shifted by phase.
pos = ((i * full_span) // num_leds + phase_shift) % full_span
idx = pos // 256
frac = pos & 255
c1 = colors[idx]
c2 = colors[(idx + 1) % color_count]
blended = (
@@ -30,27 +40,61 @@ class ColourCycle:
c1[1] + ((c2[1] - c1[1]) * frac) // 256,
c1[2] + ((c2[2] - c1[2]) * frac) // 256,
)
self.driver.n[i] = self.driver.apply_brightness(blended, brightness)
self.driver.n[self.driver.led_i(preset, i)] = self.driver.apply_brightness(
blended, brightness
)
self.driver.n.write()
def _render_rainbow(self, preset, phase, brightness):
num_leds = self.driver.num_leds
for i in range(num_leds):
rc_index = (i * 256 // max(1, num_leds)) + phase
self.driver.n[self.driver.led_i(preset, i)] = self.driver.apply_brightness(
self._wheel(rc_index & 255), brightness
)
self.driver.n.write()
def run(self, preset):
colors = preset.c if preset.c else [(255, 255, 255)]
phase = self.driver.step % 256
step_amount = max(1, int(preset.n1))
"""Scroll gradient (n6=0) or fixed spectrum wheel (n6=1, legacy rainbow).
n1: step rate
n6: 0 gradient scroll, 1 rainbow wheel
"""
mode = style_mode(preset, 0, _LEGACY)
step_amount = max(1, int(preset.n1) if int(preset.n1) > 0 else 1)
phase = self.driver.step % 256
if mode == 1:
if not preset.a:
self._render_rainbow(preset, phase, preset.b)
self.driver.step = (phase + self.driver.signed(preset, step_amount)) % 256
yield
return
last_update = utime.ticks_ms()
while True:
delay_ms = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last_update) >= delay_ms:
self._render_rainbow(preset, phase, preset.b)
phase = (phase + self.driver.signed(preset, step_amount)) % 256
self.driver.step = phase
last_update = utime.ticks_add(last_update, delay_ms)
yield
colors = preset.c if preset.c else [(255, 0, 0), (0, 0, 255)]
if not preset.a:
self._render(colors, phase, preset.b)
self.driver.step = (phase + step_amount) % 256
self._render_gradient(preset, colors, phase, preset.b)
self.driver.step = (phase + self.driver.signed(preset, step_amount)) % 256
yield
return
last_update = utime.ticks_ms()
while True:
current_time = utime.ticks_ms()
delay_ms = max(1, int(preset.d))
if utime.ticks_diff(current_time, last_update) >= delay_ms:
self._render(colors, phase, preset.b)
phase = (phase + step_amount) % 256
now = utime.ticks_ms()
if utime.ticks_diff(now, last_update) >= delay_ms:
self._render_gradient(preset, colors, phase, preset.b)
phase = (phase + self.driver.signed(preset, step_amount)) % 256
self.driver.step = phase
last_update = utime.ticks_add(last_update, delay_ms)
yield

44
src/patterns/comet_dual.py
View File

@@ -1,44 +0,0 @@
import utime
class CometDual:
def __init__(self, driver):
self.driver = driver
def run(self, preset):
colors = preset.c if preset.c else [(255, 255, 255)]
tail = max(1, int(preset.n1) if int(preset.n1) > 0 else 6)
speed = max(1, int(preset.n2) if int(preset.n2) > 0 else 1)
gap = max(0, int(preset.n3))
p1 = 0
p2 = self.driver.num_leds - 1 - gap
last = utime.ticks_ms()
while True:
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) >= d:
bg_color = self.driver.apply_brightness(preset.background_or(colors), preset.b)
for i in range(self.driver.num_leds):
self.driver.n[i] = bg_color
c1 = self.driver.apply_brightness(colors[0 % len(colors)], preset.b)
c2 = self.driver.apply_brightness(colors[1 % len(colors)] if len(colors) > 1 else colors[0], preset.b)
for t in range(tail):
i1 = p1 - t
if 0 <= i1 < self.driver.num_leds:
s = (255 * (tail - t)) // max(1, tail)
self.driver.n[i1] = ((c1[0]*s)//255, (c1[1]*s)//255, (c1[2]*s)//255)
i2 = p2 + t
if 0 <= i2 < self.driver.num_leds:
s = (255 * (tail - t)) // max(1, tail)
self.driver.n[i2] = ((c2[0]*s)//255, (c2[1]*s)//255, (c2[2]*s)//255)
self.driver.n.write()
p1 += speed
p2 -= speed
if p1 - tail > self.driver.num_leds and p2 + tail < 0:
p1 = 0
p2 = self.driver.num_leds - 1 - gap
last = utime.ticks_add(last, d)
if not preset.a:
yield
return
yield

35
src/patterns/fireflies.py
View File

@@ -1,35 +0,0 @@
import random
import utime
class Fireflies:
def __init__(self, driver):
self.driver = driver
def run(self, preset):
colors = preset.c if preset.c else [(255, 210, 80), (120, 255, 120)]
count = max(1, int(preset.n1) if int(preset.n1) > 0 else 6)
speed = max(1, int(preset.n2) if int(preset.n2) > 0 else 8)
bugs = [[random.randint(0, max(0, self.driver.num_leds - 1)), random.randint(0, 255)] for _ in range(count)]
last = utime.ticks_ms()
while True:
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) >= d:
bg_color = self.driver.apply_brightness(preset.background_or(colors), preset.b)
for i in range(self.driver.num_leds):
self.driver.n[i] = bg_color
for b in bugs:
idx, ph = b
tri = 255 - abs(128 - ph) * 2
c = self.driver.apply_brightness(colors[idx % len(colors)], preset.b)
self.driver.n[idx] = ((c[0]*tri)//255, (c[1]*tri)//255, (c[2]*tri)//255)
b[1] = (ph + speed) & 255
if random.randint(0, 31) == 0:
b[0] = random.randint(0, max(0, self.driver.num_leds - 1))
self.driver.n.write()
last = utime.ticks_add(last, d)
if not preset.a:
yield
return
yield

57
src/patterns/gradient_scroll.py
View File

@@ -1,57 +0,0 @@
import utime
class GradientScroll:
def __init__(self, driver):
self.driver = driver
def _render(self, colors, phase, brightness):
num_leds = self.driver.num_leds
color_count = len(colors)
if num_leds <= 0 or color_count <= 0:
return
if color_count == 1:
self.driver.fill(self.driver.apply_brightness(colors[0], brightness))
return
full_span = color_count * 256
phase_shift = (phase * full_span) // 256
for i in range(num_leds):
pos = ((i * full_span) // num_leds + phase_shift) % full_span
idx = pos // 256
frac = pos & 255
c1 = colors[idx]
c2 = colors[(idx + 1) % color_count]
blended = (
c1[0] + ((c2[0] - c1[0]) * frac) // 256,
c1[1] + ((c2[1] - c1[1]) * frac) // 256,
c1[2] + ((c2[2] - c1[2]) * frac) // 256,
)
self.driver.n[i] = self.driver.apply_brightness(blended, brightness)
self.driver.n.write()
def run(self, preset):
"""Scrolling blended gradient.
n1: phase step amount (default 1)
"""
colors = preset.c if preset.c else [(255, 0, 0), (0, 0, 255)]
phase = self.driver.step % 256
step_amount = max(1, int(preset.n1) if int(preset.n1) > 0 else 1)
last_update = utime.ticks_ms()
while True:
delay_ms = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last_update) >= delay_ms:
self._render(colors, phase, preset.b)
phase = (phase + step_amount) % 256
self.driver.step = phase
last_update = utime.ticks_add(last_update, delay_ms)
if not preset.a:
yield
return
yield

36
src/patterns/heartbeat.py
View File

@@ -1,36 +0,0 @@
import utime
class Heartbeat:
def __init__(self, driver):
self.driver = driver
def run(self, preset):
colors = preset.c if preset.c else [(255, 0, 40)]
phase = 0
phase_start = utime.ticks_ms()
did_manual_pulse = False
while True:
p1 = max(20, int(preset.n1) if int(preset.n1) > 0 else 120)
p2 = max(20, int(preset.n2) if int(preset.n2) > 0 else 80)
pause = max(20, int(preset.n3) if int(preset.n3) > 0 else 500)
beat_gap = max(20, int(preset.d))
colors = preset.c if preset.c else [(255, 0, 40)]
lit_color = self.driver.apply_brightness(colors[0], preset.b)
bg_color = self.driver.apply_brightness(preset.background_or(colors), preset.b)
phase_durations = (p1, beat_gap, p2, pause)
phase_colors = (lit_color, bg_color, lit_color, bg_color)
now = utime.ticks_ms()
while utime.ticks_diff(now, phase_start) >= phase_durations[phase]:
phase_start = utime.ticks_add(phase_start, phase_durations[phase])
phase = (phase + 1) % 4
self.driver.fill(phase_colors[phase])
yield
if not preset.a:
if did_manual_pulse or phase == 0:
self.driver.fill(bg_color)
yield
return
did_manual_pulse = True

62
src/patterns/icicles.py Normal file
View File

@@ -0,0 +1,62 @@
import utime
class Icicles:
"""Icicles hanging from anchor points; tips brighten toward max length then shrink."""
def __init__(self, driver):
self.driver = driver
def run(self, preset):
colors = preset.c if preset.c else [(240, 248, 255), (160, 210, 255), (255, 255, 255)]
spacing = max(1, int(preset.n1) if int(preset.n1) > 0 else 12)
nled = self.driver.num_leds
max_len = max(
2,
min(
int(preset.n2) if int(preset.n2) > 0 else min(14, max(3, nled // 4)),
max(2, nled),
),
)
span = max_len * 2
phase_step = max(1, int(preset.n3) if int(preset.n3) > 0 else 1)
phase = 0
last = utime.ticks_ms()
while True:
d_ms = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) >= d_ms:
bg_rgb = preset.background_or(colors)
bg = self.driver.apply_brightness(bg_rgb, preset.b)
for i in range(nled):
self.driver.n[i] = bg
aidx = 0
for anchor in range(0, nled, spacing):
tri_i = (phase + aidx * 5) % span
ic_len = tri_i if tri_i <= max_len else span - tri_i
tip_c = colors[aidx % len(colors)]
tip = self.driver.apply_brightness(tip_c, preset.b)
for k in range(ic_len):
idx = anchor + k
if idx >= nled:
break
br = ((k + 1) * 255) // max(1, ic_len)
self.driver.n[self.driver.led_i(preset, idx)] = (
(tip[0] * br + bg[0] * (255 - br)) // 255,
(tip[1] * br + bg[1] * (255 - br)) // 255,
(tip[2] * br + bg[2] * (255 - br)) // 255,
)
aidx += 1
self.driver.n.write()
phase = (phase + self.driver.signed(preset, phase_step)) % span
last = utime.ticks_add(last, d_ms)
if not preset.a:
yield
return
yield

31
src/patterns/marquee.py
View File

@@ -1,31 +0,0 @@
import utime
class Marquee:
def __init__(self, driver):
self.driver = driver
def run(self, preset):
colors = preset.c if preset.c else [(255, 255, 255)]
on_len = max(1, int(preset.n1) if int(preset.n1) > 0 else 3)
off_len = max(1, int(preset.n2) if int(preset.n2) > 0 else 2)
step = max(1, int(preset.n3) if int(preset.n3) > 0 else 1)
phase = self.driver.step % (on_len + off_len)
last = utime.ticks_ms()
while True:
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) >= d:
c = self.driver.apply_brightness(colors[0], preset.b)
bg_color = self.driver.apply_brightness(preset.background_or(colors), preset.b)
for i in range(self.driver.num_leds):
m = (i + phase) % (on_len + off_len)
self.driver.n[i] = c if m < on_len else bg_color
self.driver.n.write()
phase = (phase + step) % (on_len + off_len)
self.driver.step = phase
last = utime.ticks_add(last, d)
if not preset.a:
yield
return
yield

176
src/patterns/meteor.py Normal file
View File

@@ -0,0 +1,176 @@
import utime
from patterns.pattern_modes import style_mode
_LEGACY = {"comet_dual": 1, "scanner": 2}
class Meteor:
def __init__(self, driver):
self.driver = driver
def _fade(self, color, fade_amount):
return (
(color[0] * fade_amount) // 255,
(color[1] * fade_amount) // 255,
(color[2] * fade_amount) // 255,
)
def _run_meteor(self, preset, colors, color_index, head, direction, last_update):
tail_len = max(1, int(preset.n1) if int(preset.n1) > 0 else 8)
speed = max(1, int(preset.n2) if int(preset.n2) > 0 else 1)
fade_amount = int(preset.n3) if int(preset.n3) > 0 else 192
fade_amount = max(1, min(255, fade_amount))
delay_ms = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last_update) < delay_ms:
return color_index, head, direction, last_update, False
for i in range(self.driver.num_leds):
self.driver.n[i] = self._fade(self.driver.n[i], fade_amount)
base = colors[color_index % len(colors)]
lit = self.driver.apply_brightness(base, preset.b)
if 0 <= head < self.driver.num_leds:
self.driver.n[self.driver.led_i(preset, head)] = lit
self.driver.n.write()
head += self.driver.signed(preset, direction * speed)
if head >= self.driver.num_leds + tail_len:
head = self.driver.num_leds - 1
direction = -1
color_index += 1
elif head < -tail_len:
head = 0
direction = 1
color_index += 1
return color_index, head, direction, utime.ticks_add(last_update, delay_ms), True
def _run_comet_dual(self, preset, colors, p1, p2, last):
tail = max(1, int(preset.n1) if int(preset.n1) > 0 else 6)
speed = max(1, int(preset.n2) if int(preset.n2) > 0 else 1)
gap = max(0, int(preset.n3))
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) < d:
return p1, p2, last, False
bg_color = self.driver.apply_brightness(preset.background_or(colors), preset.b)
for i in range(self.driver.num_leds):
self.driver.n[i] = bg_color
c1 = self.driver.apply_brightness(colors[0 % len(colors)], preset.b)
c2 = self.driver.apply_brightness(
colors[1 % len(colors)] if len(colors) > 1 else colors[0], preset.b
)
for t in range(tail):
i1 = p1 - t
if 0 <= i1 < self.driver.num_leds:
s = (255 * (tail - t)) // max(1, tail)
self.driver.n[self.driver.led_i(preset, i1)] = (
(c1[0] * s) // 255,
(c1[1] * s) // 255,
(c1[2] * s) // 255,
)
i2 = p2 + t
if 0 <= i2 < self.driver.num_leds:
s = (255 * (tail - t)) // max(1, tail)
self.driver.n[self.driver.led_i(preset, i2)] = (
(c2[0] * s) // 255,
(c2[1] * s) // 255,
(c2[2] * s) // 255,
)
self.driver.n.write()
p1 += self.driver.signed(preset, speed)
p2 -= self.driver.signed(preset, speed)
if p1 - tail > self.driver.num_leds and p2 + tail < 0:
p1 = 0
p2 = self.driver.num_leds - 1 - gap
return p1, p2, utime.ticks_add(last, d), True
def _run_scanner(self, preset, colors, color_index, center, direction, pause_frames, last_update):
width = max(1, int(preset.n1) if int(preset.n1) > 0 else 4)
end_pause = max(0, int(preset.n2))
delay_ms = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last_update) < delay_ms:
return color_index, center, direction, pause_frames, last_update, False
base = self.driver.apply_brightness(colors[color_index % len(colors)], preset.b)
bg_color = self.driver.apply_brightness(preset.background_or(colors), preset.b)
for i in range(self.driver.num_leds):
dist = i - center
if dist < 0:
dist = -dist
if dist > width:
self.driver.n[self.driver.led_i(preset, i)] = bg_color
else:
scale = ((width - dist) * 255) // max(1, width)
self.driver.n[self.driver.led_i(preset, i)] = (
(base[0] * scale) // 255,
(base[1] * scale) // 255,
(base[2] * scale) // 255,
)
self.driver.n.write()
if pause_frames > 0:
pause_frames -= 1
else:
center += self.driver.signed(preset, direction)
if center >= self.driver.num_leds - 1:
center = self.driver.num_leds - 1
direction = -1
pause_frames = end_pause
color_index += 1
elif center <= 0:
center = 0
direction = 1
pause_frames = end_pause
color_index += 1
return color_index, center, direction, pause_frames, utime.ticks_add(last_update, delay_ms), True
def run(self, preset):
"""Moving lights: n6 style 0 meteor, 1 dual comet, 2 scanner (legacy ids still work)."""
mode = style_mode(preset, 0, _LEGACY)
colors = preset.c if preset.c else [(255, 255, 255)]
if mode == 1:
gap = max(0, int(preset.n3))
nled = self.driver.num_leds
if self.driver.is_reversed(preset):
p1, p2 = nled - 1, gap
else:
p1, p2 = 0, nled - 1 - gap
last = utime.ticks_ms()
while True:
p1, p2, last, stepped = self._run_comet_dual(preset, colors, p1, p2, last)
if stepped and not preset.a:
yield
return
yield
if mode == 2:
nled = self.driver.num_leds
if self.driver.is_reversed(preset):
color_index, center, direction, pause_frames = 0, max(0, nled - 1), -1, 0
else:
color_index, center, direction, pause_frames = 0, 0, 1, 0
last_update = utime.ticks_ms()
while True:
color_index, center, direction, pause_frames, last_update, stepped = (
self._run_scanner(
preset, colors, color_index, center, direction, pause_frames, last_update
)
)
if stepped and not preset.a:
yield
return
yield
nled = self.driver.num_leds
if self.driver.is_reversed(preset):
color_index, head, direction = 0, max(0, nled - 1), -1
else:
color_index, head, direction = 0, 0, 1
last_update = utime.ticks_ms()
while True:
color_index, head, direction, last_update, stepped = self._run_meteor(
preset, colors, color_index, head, direction, last_update
)
if stepped and not preset.a:
yield
return
yield

62
src/patterns/meteor_rain.py
View File

@@ -1,62 +0,0 @@
import utime
class MeteorRain:
def __init__(self, driver):
self.driver = driver
def _fade(self, color, fade_amount):
return (
(color[0] * fade_amount) // 255,
(color[1] * fade_amount) // 255,
(color[2] * fade_amount) // 255,
)
def run(self, preset):
"""Single meteor with a fading tail.
n1: tail length (default 8)
n2: speed in LEDs per frame (default 1)
n3: fade amount per frame, 1..255 (default 192)
"""
colors = preset.c if preset.c else [(255, 255, 255)]
color_index = 0
head = 0
direction = 1
last_update = utime.ticks_ms()
while True:
delay_ms = max(1, int(preset.d))
tail_len = max(1, int(preset.n1) if int(preset.n1) > 0 else 8)
speed = max(1, int(preset.n2) if int(preset.n2) > 0 else 1)
fade_amount = int(preset.n3) if int(preset.n3) > 0 else 192
fade_amount = max(1, min(255, fade_amount))
now = utime.ticks_ms()
if utime.ticks_diff(now, last_update) >= delay_ms:
for i in range(self.driver.num_leds):
self.driver.n[i] = self._fade(self.driver.n[i], fade_amount)
base = colors[color_index % len(colors)]
lit = self.driver.apply_brightness(base, preset.b)
if 0 <= head < self.driver.num_leds:
self.driver.n[head] = lit
self.driver.n.write()
head += direction * speed
if head >= self.driver.num_leds + tail_len:
head = self.driver.num_leds - 1
direction = -1
color_index += 1
elif head < -tail_len:
head = 0
direction = 1
color_index += 1
last_update = utime.ticks_add(last_update, delay_ms)
if not preset.a:
yield
return
yield

111
src/patterns/particles.py Normal file
View File

@@ -0,0 +1,111 @@
import random
import utime
from patterns.pattern_modes import style_mode
_LEGACY = {"starfall": 1}
class Particles:
def __init__(self, driver):
self.driver = driver
def _run_snowfall(self, preset, colors, flakes, last):
density = max(1, int(preset.n1) if int(preset.n1) > 0 else 20)
speed = max(1, abs(self.driver.signed(preset, int(preset.n2) if int(preset.n2) > 0 else 1)))
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) < d:
return flakes, last, False
bg_color = self.driver.apply_brightness(preset.background_or(colors), preset.b)
if random.randint(0, 255) < density:
flakes.append([self.driver.num_leds - 1, random.randint(0, len(colors) - 1)])
for i in range(self.driver.num_leds):
self.driver.n[i] = bg_color
nf = []
for pos, ci in flakes:
if 0 <= pos < self.driver.num_leds:
self.driver.n[self.driver.led_i(preset, pos)] = self.driver.apply_brightness(
colors[ci], preset.b
)
pos -= self.driver.signed(preset, speed)
if pos >= -1:
nf.append([pos, ci])
self.driver.n.write()
return nf, utime.ticks_add(last, d), True
def _run_starfall(self, preset, colors, stars, last):
rate = max(1, min(255, int(preset.n1) if int(preset.n1) > 0 else 14))
speed = max(1, abs(self.driver.signed(preset, int(preset.n2) if int(preset.n2) > 0 else 2)))
tail = max(2, int(preset.n3) if int(preset.n3) > 0 else 10)
max_stars = 4
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) < d:
return stars, last, False
bg = self.driver.apply_brightness(preset.background_or(colors), preset.b)
for i in range(self.driver.num_leds):
self.driver.n[i] = bg
if len(stars) < max_stars and random.randint(0, 255) < rate:
top = self.driver.num_leds - 1 + random.randint(
0, min(8, self.driver.num_leds // 2)
)
stars.append({"h": float(top), "ci": random.randint(0, len(colors) - 1)})
ns = []
for s in stars:
h = s["h"]
ci = s["ci"]
ih = int(h)
for t in range(tail):
idx = ih + t
if 0 <= idx < self.driver.num_leds:
fade = 255 - (t * 255 // max(1, tail - 1))
base = colors[ci]
lit = (
(base[0] * fade) // 255,
(base[1] * fade) // 255,
(base[2] * fade) // 255,
)
lit = self.driver.apply_brightness(lit, preset.b)
pix = self.driver.led_i(preset, idx)
o = self.driver.n[pix]
self.driver.n[pix] = (
max(o[0], lit[0]),
max(o[1], lit[1]),
max(o[2], lit[2]),
)
h -= self.driver.signed(preset, speed)
if h >= -tail:
s["h"] = h
ns.append(s)
stars = ns
self.driver.n.write()
return stars, utime.ticks_add(last, d), True
def run(self, preset):
"""Falling particles: n6 0 snowfall flakes, 1 starfall streaks."""
mode = style_mode(preset, 0, _LEGACY)
colors = preset.c if preset.c else [(255, 255, 255), (180, 220, 255)]
last = utime.ticks_ms()
if mode == 1:
colors = preset.c if preset.c else [
(255, 255, 255),
(200, 230, 255),
(255, 248, 220),
]
stars = []
while True:
stars, last, stepped = self._run_starfall(preset, colors, stars, last)
if stepped and not preset.a:
yield
return
yield
flakes = []
while True:
flakes, last, stepped = self._run_snowfall(preset, colors, flakes, last)
if stepped and not preset.a:
yield
return
yield

19
src/patterns/pattern_direction.py Normal file
View File

@@ -0,0 +1,19 @@
"""Strip install direction: n5 bit 0 reverses along-strip motion (upside-down wiring)."""
def is_reversed(preset):
return bool(int(getattr(preset, "n5", 0) or 0) & 1)
def led_i(driver, preset, logical_index):
"""Map a logical strip index (0 = pattern start) to a physical pixel index."""
n = int(driver.num_leds)
i = int(logical_index)
if 0 <= i < n and is_reversed(preset):
return n - 1 - i
return i
def signed(preset, value):
v = int(value)
return -v if is_reversed(preset) else v

18
src/patterns/pattern_modes.py Normal file
View File

@@ -0,0 +1,18 @@
"""Resolve pattern style from n6 or legacy preset pattern id (p)."""
def style_mode(preset, default=0, legacy=None):
legacy = legacy or {}
p = getattr(preset, "p", "") or ""
if p in legacy:
return legacy[p]
mode = getattr(preset, "mode", None)
if mode is None and isinstance(preset, dict):
mode = preset.get("mode")
if mode is not None:
try:
return int(mode)
except (TypeError, ValueError):
pass
n6 = int(getattr(preset, "n6", 0) or 0)
return n6 if n6 > 0 else default

20
src/patterns/pulse.py
View File

@@ -13,13 +13,8 @@ class Pulse:
bg_base = preset.background_or(colors)
self.driver.fill(self.driver.apply_brightness(bg_base, preset.b))
manual = not preset.a
color_index = self.driver.step % max(1, len(colors))
if not preset.a:
# Manual / beat trigger: each select restarts this generator and resets
# cycle_start below. Advancing step here makes each beat the next colour
# without requiring a full wall-clock cycle between beats.
nclr = max(1, len(colors))
self.driver.step = (color_index + 1) % nclr
cycle_start = utime.ticks_ms()
# State machine based pulse using a single generator loop
@@ -29,7 +24,7 @@ class Pulse:
attack_ms = max(0, int(preset.n1)) # Attack time in ms
hold_ms = max(0, int(preset.n2)) # Hold time in ms
decay_ms = max(0, int(preset.n3)) # Decay time in ms
delay_ms = max(0, int(preset.d))
delay_ms = 0 if manual else max(0, int(preset.d))
total_ms = attack_ms + hold_ms + decay_ms + delay_ms
if total_ms <= 0:
@@ -58,12 +53,13 @@ class Pulse:
# Delay phase: LEDs off between pulses
self.driver.fill(bg_color)
else:
# End of cycle: auto advances colour and loops; manual already
# advanced step at run start for the next beat.
if not preset.a:
break
color_index = (color_index + 1) % max(1, len(colors))
# End of cycle: advance colour for the next run, then loop or stop.
nclr = max(1, len(colors))
color_index = (color_index + 1) % nclr
self.driver.step = color_index
if manual:
self.driver.fill(bg_color)
break
cycle_start = now
yield
continue

13
src/patterns/radiate.py
View File

@@ -1,7 +1,7 @@
import utime
# When ``driver.debug`` is True (``settings["debug"]``), log at most this often (ms).
_RADIATE_DBG_INTERVAL_MS = 800
_RADIATE_DBG_INTERVAL_MS = 2500
class Radiate:
@@ -37,6 +37,7 @@ class Radiate:
if not preset.a:
# Manual mode: one-shot pulse using the same ms-based timing as auto.
cycle_start = utime.ticks_ms()
last_dbg = cycle_start
while True:
dbg = bool(getattr(self.driver, "debug", False))
spacing = max(1, int(preset.n1))
@@ -78,10 +79,12 @@ class Radiate:
"[radiate] debug on n1=%s n2=%s n3=%s d=%s auto=%s num_leds=%d"
% (preset.n1, preset.n2, preset.n3, preset.d, preset.a, self.driver.num_leds)
)
print(
"[radiate] manual frame age=%d/%d front=%d lit=%d"
% (age, pulse_lifetime, front, lit_count)
)
if utime.ticks_diff(now, last_dbg) >= _RADIATE_DBG_INTERVAL_MS:
print(
"[radiate] manual frame age=%d/%d front=%d lit=%d"
% (age, pulse_lifetime, front, lit_count)
)
last_dbg = now
yield
if age >= pulse_lifetime:

51
src/patterns/rainbow.py
View File

@@ -1,51 +0,0 @@
import utime
class Rainbow:
def __init__(self, driver):
self.driver = driver
def _wheel(self, pos):
if pos < 85:
return (pos * 3, 255 - pos * 3, 0)
elif pos < 170:
pos -= 85
return (255 - pos * 3, 0, pos * 3)
else:
pos -= 170
return (0, pos * 3, 255 - pos * 3)
def run(self, preset):
step = self.driver.step % 256
step_amount = max(1, int(preset.n1)) # n1 controls step increment
# If auto is False, run a single step and then stop
if not preset.a:
for i in range(self.driver.num_leds):
rc_index = (i * 256 // self.driver.num_leds) + step
self.driver.n[i] = self.driver.apply_brightness(self._wheel(rc_index & 255), preset.b)
self.driver.n.write()
# Increment step by n1 for next manual call
self.driver.step = (step + step_amount) % 256
# Allow tick() to advance the generator once
yield
return
last_update = utime.ticks_ms()
while True:
current_time = utime.ticks_ms()
sleep_ms = max(1, int(preset.d)) # Get delay from preset
if utime.ticks_diff(current_time, last_update) >= sleep_ms:
for i in range(self.driver.num_leds):
rc_index = (i * 256 // self.driver.num_leds) + step
self.driver.n[i] = self.driver.apply_brightness(
self._wheel(rc_index & 255),
preset.b,
)
self.driver.n.write()
step = (step + step_amount) % 256
self.driver.step = step
last_update = utime.ticks_add(last_update, sleep_ms)
# Yield once per tick so other logic can run
yield

72
src/patterns/rime.py Normal file
View File

@@ -0,0 +1,72 @@
import random
import utime
class Rime:
"""Slow frost build-up on a chilly background — gentle random brightening then decay."""
def __init__(self, driver):
self.driver = driver
def run(self, preset):
colors = preset.c if preset.c else [(220, 235, 255), (255, 255, 255), (185, 220, 255)]
num = self.driver.num_leds
if num <= 0:
while True:
yield
return
# n1: spawn tendency (like twinkle upper range)
chill = max(1, min(255, int(preset.n1) if int(preset.n1) > 0 else 36))
# n2: decay per refresh (subtract from glow buffer)
melt = max(1, min(255, int(preset.n2) if int(preset.n2) > 0 else 12))
# n3: how many LEDs can flash brighter per refresh (cap)
spark_cap = max(1, min(num, int(preset.n3) if int(preset.n3) > 0 else 3))
glow = [0] * num
last = utime.ticks_ms()
while True:
d_ms = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) >= d_ms:
base_bg = preset.background_or(colors)
bg = self.driver.apply_brightness(base_bg, preset.b)
for i in range(num):
if glow[i] > melt:
glow[i] -= melt
else:
glow[i] = 0
spawned = 0
tries = spark_cap + num // 8
for _ in range(tries):
if spawned >= spark_cap:
break
if random.randint(0, 255) >= chill:
continue
j = random.randint(0, num - 1)
glow[j] = min(255, glow[j] + random.randint(80, 200))
spawned += 1
palette = colors
for i in range(num):
g = glow[i]
fg = palette[i % len(palette)]
hi = self.driver.apply_brightness(fg, preset.b)
mix = max(0, min(255, g))
self.driver.n[i] = (
(hi[0] * mix + bg[0] * (255 - mix)) // 255,
(hi[1] * mix + bg[1] * (255 - mix)) // 255,
(hi[2] * mix + bg[2] * (255 - mix)) // 255,
)
self.driver.n.write()
last = utime.ticks_add(last, d_ms)
if not preset.a:
yield
return
yield

67
src/patterns/scanner.py
View File

@@ -1,67 +0,0 @@
import utime
class Scanner:
def __init__(self, driver):
self.driver = driver
def run(self, preset):
"""Classic scanner eye with soft falloff.
n1: eye width (default 4)
n2: end pause in frames (default 0)
"""
colors = preset.c if preset.c else [(255, 0, 0)]
color_index = 0
center = 0
direction = 1
pause_frames = 0
last_update = utime.ticks_ms()
while True:
delay_ms = max(1, int(preset.d))
width = max(1, int(preset.n1) if int(preset.n1) > 0 else 4)
end_pause = max(0, int(preset.n2))
now = utime.ticks_ms()
if utime.ticks_diff(now, last_update) >= delay_ms:
base = colors[color_index % len(colors)]
base = self.driver.apply_brightness(base, preset.b)
bg_color = self.driver.apply_brightness(preset.background_or(colors), preset.b)
for i in range(self.driver.num_leds):
dist = i - center
if dist < 0:
dist = -dist
if dist > width:
self.driver.n[i] = bg_color
else:
scale = ((width - dist) * 255) // max(1, width)
self.driver.n[i] = (
(base[0] * scale) // 255,
(base[1] * scale) // 255,
(base[2] * scale) // 255,
)
self.driver.n.write()
if pause_frames > 0:
pause_frames -= 1
else:
center += direction
if center >= self.driver.num_leds - 1:
center = self.driver.num_leds - 1
direction = -1
pause_frames = end_pause
color_index += 1
elif center <= 0:
center = 0
direction = 1
pause_frames = end_pause
color_index += 1
last_update = utime.ticks_add(last_update, delay_ms)
if not preset.a:
yield
return
yield

45
src/patterns/segment_chase.py
View File

@@ -1,45 +0,0 @@
import utime
class SegmentChase:
def __init__(self, driver):
self.driver = driver
def run(self, preset):
"""Independent moving segments (distinct from classic two-color chase).
n1: segment size (LEDs per segment)
n2: step size (phase increment each frame)
n3: per-segment phase offset
n4: gap spacing inside segment (0 = solid segment)
"""
colors = preset.c if preset.c else [(255, 0, 0), (0, 0, 255)]
seg = max(1, int(preset.n1) if int(preset.n1) > 0 else 4)
phase_step = max(1, int(preset.n2) if int(preset.n2) > 0 else 1)
seg_offset = max(0, int(preset.n3))
gap = max(0, int(preset.n4))
phase = self.driver.step % 256
last = utime.ticks_ms()
while True:
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) >= d:
bg_color = self.driver.apply_brightness(preset.background_or(colors), preset.b)
for i in range(self.driver.num_leds):
seg_idx = i // seg
in_seg = i % seg
local_phase = (phase + seg_idx * seg_offset) % seg
lit_idx = (in_seg + local_phase) % seg
if gap > 0 and lit_idx >= max(1, seg - gap):
self.driver.n[i] = bg_color
else:
color_idx = seg_idx % len(colors)
self.driver.n[i] = self.driver.apply_brightness(colors[color_idx], preset.b)
self.driver.n.write()
phase = (phase + phase_step) % seg
self.driver.step = phase
last = utime.ticks_add(last, d)
if not preset.a:
yield
return
yield

37
src/patterns/snowfall.py
View File

@@ -1,37 +0,0 @@
import random
import utime
class Snowfall:
def __init__(self, driver):
self.driver = driver
def run(self, preset):
colors = preset.c if preset.c else [(255, 255, 255), (180, 220, 255)]
density = max(1, int(preset.n1) if int(preset.n1) > 0 else 20)
speed = max(1, int(preset.n2) if int(preset.n2) > 0 else 1)
flakes = []
last = utime.ticks_ms()
while True:
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) >= d:
bg_color = self.driver.apply_brightness(preset.background_or(colors), preset.b)
if random.randint(0, 255) < density:
flakes.append([self.driver.num_leds - 1, random.randint(0, len(colors)-1)])
for i in range(self.driver.num_leds):
self.driver.n[i] = bg_color
nf = []
for pos, ci in flakes:
if 0 <= pos < self.driver.num_leds:
self.driver.n[pos] = self.driver.apply_brightness(colors[ci], preset.b)
pos -= speed
if pos >= -1:
nf.append([pos, ci])
flakes = nf
self.driver.n.write()
last = utime.ticks_add(last, d)
if not preset.a:
yield
return
yield

147
src/patterns/sparkle.py Normal file
View File

@@ -0,0 +1,147 @@
import random
import utime
from patterns.pattern_modes import style_mode
_LEGACY = {"sparkle_trail": 0, "ice_sparkle": 1, "fireflies": 2}
class Sparkle:
def __init__(self, driver):
self.driver = driver
def _run_trail(self, preset, colors, last):
density = max(1, int(preset.n1) if int(preset.n1) > 0 else 24)
decay = max(1, min(255, int(preset.n2) if int(preset.n2) > 0 else 210))
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) < d:
return last, False
for i in range(self.driver.num_leds):
r, g, b = self.driver.n[i]
self.driver.n[i] = ((r * decay) // 255, (g * decay) // 255, (b * decay) // 255)
sparks = max(1, self.driver.num_leds * density // 255)
for _ in range(sparks):
idx = random.randint(0, max(0, self.driver.num_leds - 1))
c = self.driver.apply_brightness(
colors[random.randint(0, len(colors) - 1)], preset.b
)
self.driver.n[idx] = c
self.driver.n.write()
return utime.ticks_add(last, d), True
def _run_ice(self, preset, colors, sparks, last):
rate = max(1, min(255, int(preset.n1) if int(preset.n1) > 0 else 55))
decay = max(1, min(255, int(preset.n2) if int(preset.n2) > 0 else 140))
halo = max(0, min(3, int(preset.n3)))
cap = 28
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) < d:
return sparks, last, False
bg = self.driver.apply_brightness(preset.background_or(colors), preset.b)
for i in range(self.driver.num_leds):
self.driver.n[i] = bg
ns = []
for s in sparks:
lv = s["lv"] - decay
if lv > 0:
s["lv"] = lv
ns.append(s)
sparks = ns
if len(sparks) < cap and random.randint(0, 255) < rate:
sparks.append(
{
"p": random.randint(0, max(0, self.driver.num_leds - 1)),
"lv": 255,
"ci": random.randint(0, len(colors) - 1),
}
)
for s in sparks:
p = s["p"]
lv = s["lv"]
ci = s["ci"]
base = colors[ci]
for off in range(-halo, halo + 1):
idx = p + off
if 0 <= idx < self.driver.num_leds:
dist = abs(off)
fac = lv if dist == 0 else (lv * (halo - dist + 1)) // (halo + 1)
lit = self.driver.apply_brightness(
(
(base[0] * fac) // 255,
(base[1] * fac) // 255,
(base[2] * fac) // 255,
),
preset.b,
)
o = self.driver.n[idx]
self.driver.n[idx] = (
min(255, o[0] + lit[0]),
min(255, o[1] + lit[1]),
min(255, o[2] + lit[2]),
)
self.driver.n.write()
return sparks, utime.ticks_add(last, d), True
def _run_fireflies(self, preset, colors, bugs, last):
count = max(1, int(preset.n1) if int(preset.n1) > 0 else 6)
speed = max(1, int(preset.n2) if int(preset.n2) > 0 else 8)
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) < d:
return bugs, last, False
bg_color = self.driver.apply_brightness(preset.background_or(colors), preset.b)
for i in range(self.driver.num_leds):
self.driver.n[i] = bg_color
for b in bugs:
idx, ph = b
tri = 255 - abs(128 - ph) * 2
c = self.driver.apply_brightness(colors[idx % len(colors)], preset.b)
self.driver.n[idx] = ((c[0] * tri) // 255, (c[1] * tri) // 255, (c[2] * tri) // 255)
b[1] = (ph + speed) & 255
if random.randint(0, 31) == 0:
b[0] = random.randint(0, max(0, self.driver.num_leds - 1))
self.driver.n.write()
return bugs, utime.ticks_add(last, d), True
def run(self, preset):
"""Sparkles: n6 0 trail decay, 1 ice burst+halo, 2 fireflies."""
mode = style_mode(preset, 0, _LEGACY)
colors = preset.c if preset.c else [(120, 120, 255)]
last = utime.ticks_ms()
if mode == 2:
colors = preset.c if preset.c else [(255, 210, 80), (120, 255, 120)]
count = max(1, int(preset.n1) if int(preset.n1) > 0 else 6)
bugs = [
[random.randint(0, max(0, self.driver.num_leds - 1)), random.randint(0, 255)]
for _ in range(count)
]
while True:
bugs, last, stepped = self._run_fireflies(preset, colors, bugs, last)
if stepped and not preset.a:
yield
return
yield
if mode == 1:
colors = preset.c if preset.c else [
(240, 248, 255),
(200, 235, 255),
(255, 255, 255),
]
sparks = []
while True:
sparks, last, stepped = self._run_ice(preset, colors, sparks, last)
if stepped and not preset.a:
yield
return
yield
while True:
last, stepped = self._run_trail(preset, colors, last)
if stepped and not preset.a:
yield
return
yield

31
src/patterns/sparkle_trail.py
View File

@@ -1,31 +0,0 @@
import random
import utime
class SparkleTrail:
def __init__(self, driver):
self.driver = driver
def run(self, preset):
colors = preset.c if preset.c else [(120, 120, 255)]
density = max(1, int(preset.n1) if int(preset.n1) > 0 else 24)
decay = max(1, min(255, int(preset.n2) if int(preset.n2) > 0 else 210))
last = utime.ticks_ms()
while True:
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) >= d:
for i in range(self.driver.num_leds):
r,g,b = self.driver.n[i]
self.driver.n[i] = ((r*decay)//255, (g*decay)//255, (b*decay)//255)
sparks = max(1, self.driver.num_leds * density // 255)
for _ in range(sparks):
idx = random.randint(0, max(0, self.driver.num_leds - 1))
c = self.driver.apply_brightness(colors[random.randint(0, len(colors)-1)], preset.b)
self.driver.n[idx] = c
self.driver.n.write()
last = utime.ticks_add(last, d)
if not preset.a:
yield
return
yield

32
src/patterns/wave.py
View File

@@ -1,32 +0,0 @@
import utime
class Wave:
def __init__(self, driver):
self.driver = driver
def run(self, preset):
colors = preset.c if preset.c else [(0, 180, 255)]
wavelength = max(2, int(preset.n1) if int(preset.n1) > 0 else 12)
amp = max(0, min(255, int(preset.n2) if int(preset.n2) > 0 else 180))
drift = max(1, int(preset.n3) if int(preset.n3) > 0 else 1)
phase = self.driver.step % 256
last = utime.ticks_ms()
while True:
d = max(1, int(preset.d))
now = utime.ticks_ms()
if utime.ticks_diff(now, last) >= d:
base = self.driver.apply_brightness(colors[0], preset.b)
for i in range(self.driver.num_leds):
x = (i * 256 // wavelength + phase) & 255
tri = 255 - abs(128 - x) * 2
s = (tri * amp) // 255
self.driver.n[i] = ((base[0]*s)//255, (base[1]*s)//255, (base[2]*s)//255)
self.driver.n.write()
phase = (phase + drift) % 256
self.driver.step = phase
last = utime.ticks_add(last, d)
if not preset.a:
yield
return
yield

13
src/preset.py
View File

@@ -27,10 +27,23 @@ class Preset:
"brightness": "b",
"auto": "a",
"background": "bg",
"mode": "n6",
}
int_fields = {"d", "b", "n1", "n2", "n3", "n4", "n5", "n6"}
allowed_fields = {"p", "c", "d", "b", "a", "bg", "n1", "n2", "n3", "n4", "n5", "n6"}
for key, value in data.items():
if key == "reverse":
try:
if isinstance(value, bool):
self.n5 = 1 if value else 0
elif isinstance(value, (int, float)):
self.n5 = 1 if int(value) else 0
elif isinstance(value, str):
lowered = value.lower()
self.n5 = 1 if lowered in ("true", "1", "yes", "on") else 0
except (TypeError, ValueError):
pass
continue
key = aliases.get(key, key)
if key not in allowed_fields:
continue

62
src/presets.py
View File

@@ -70,8 +70,29 @@ class Presets:
except Exception as e:
print("Pattern init failed:", module_name, e)
self._apply_pattern_aliases(loaded)
return loaded
def _apply_pattern_aliases(self, loaded):
"""Legacy pattern ids -> merged implementations (same generator)."""
aliases = (
("rainbow", "colour_cycle"),
("gradient_scroll", "colour_cycle"),
("meteor_rain", "meteor"),
("comet_dual", "meteor"),
("scanner", "meteor"),
("snowfall", "particles"),
("starfall", "particles"),
("sparkle_trail", "sparkle"),
("ice_sparkle", "sparkle"),
("fireflies", "sparkle"),
("marquee", "chase"),
("northern_wave", "aurora"),
)
for old, new in aliases:
if new in loaded and old not in loaded:
loaded[old] = loaded[new]
def save(self):
"""Save the presets to a file."""
with open("presets.json", "w") as f:
@@ -112,16 +133,24 @@ class Presets:
"""Create or update a preset with the given name."""
if name in self.presets:
# Update existing preset
was_auto = self.presets[name].a
self.presets[name].edit(data)
# Editing the live preset (e.g. toggling auto/manual) must reset runtime
# state; re-select alone keeps step because preset name is unchanged.
# Editing the live preset: auto still re-selects (one tick) so the strip
# restarts without a separate select message (controller often sends both).
# Manual must NOT call select() here — presets-only pushes (e.g. zone sequence
# arming the first step) would otherwise run select's first tick and consume a
# beat/step. Manual advances only on explicit select from the controller.
if self.selected == name:
self.step = 0
self.generator = None
self.fill((0, 0, 0))
# Re-start pattern so manual/auto and other edits apply without a
# separate select message (controller usually sends both).
self.select(name)
preset = self.presets[name]
if preset.a:
self.step = 0
self.generator = None
self.fill((0, 0, 0))
self.select(name)
elif was_auto:
self.step = 0
self.generator = None
self.fill((0, 0, 0))
else:
if len(self.presets) >= MAX_PRESETS and name not in ("on", "off"):
print("Preset limit reached:", MAX_PRESETS)
@@ -169,7 +198,7 @@ class Presets:
if (
preset_name == self.selected
and not preset.a
and preset.p == "chase"
and preset.p in ("chase", "pulse")
and self.generator is not None
):
while self.generator is not None:
@@ -193,6 +222,21 @@ class Presets:
self.n = NeoPixel(Pin(pin, Pin.OUT), num_leds)
self.num_leds = num_leds
def is_reversed(self, preset):
from patterns.pattern_direction import is_reversed as _is_reversed
return _is_reversed(preset)
def led_i(self, preset, logical_index):
from patterns.pattern_direction import led_i as _led_i
return _led_i(self, preset, logical_index)
def signed(self, preset, value):
from patterns.pattern_direction import signed as _signed
return _signed(preset, value)
def apply_brightness(self, color, brightness_override=None):
# Combine per-preset brightness (override) with global brightness self.b
local = brightness_override if brightness_override is not None else 255

17
src/print_timestamp.py Normal file
View File

@@ -0,0 +1,17 @@
"""Install a builtins.print wrapper that prefixes each line with uptime (ms).
Import this module before other led-driver imports that print (e.g. first in main).
"""
import builtins
import utime
_original_print = builtins.print
def _timestamped_print(*args, **kwargs):
ts = utime.ticks_ms()
return _original_print("[%d]" % ts, *args, **kwargs)
builtins.print = _timestamped_print

36
src/wifi_sta.py
View File

@@ -1,5 +1,7 @@
"""STA connect helpers aligned with tests/test_wifi.py (status polling, fatal codes)."""
import gc
import machine
import utime
import network
@@ -57,6 +59,40 @@ def _one_association_campaign(sta_if, ssid, password, wdt):
return True
def boot_sta(settings, wdt):
"""Tear down and bring up STA. Call before large heap users (NeoPixel, patterns).
On ESP32-C3, soft reboots can leave the Wi-Fi driver allocated; init while the
heap is still free. If re-init fails after a soft reboot, hard-reset once.
"""
sta_if = network.WLAN(network.STA_IF)
try:
if sta_if.active():
try:
sta_if.disconnect()
except Exception:
pass
sta_if.active(False)
except Exception:
pass
utime.sleep_ms(100)
gc.collect()
try:
sta_if.active(True)
except OSError as e:
err = str(e)
if "Out of Memory" in err or "WiFi" in err:
if machine.reset_cause() == machine.SOFT_RESET:
print("wifi_sta: init failed after soft reboot, hard reset:", err)
machine.reset()
raise
sta_if.config(pm=network.WLAN.PM_NONE)
ssid = settings.get("ssid") or ""
if ssid:
connect_until_up(sta_if, ssid, settings.get("password") or "", wdt)
return sta_if
def connect_until_up(sta_if, ssid, password, wdt):
"""Boot: repeat campaigns until STA has a route (same strategy as tests/test_wifi.py)."""
if not ssid:

159
tests/all.py
View File

@@ -1,14 +1,50 @@
#!/usr/bin/env python3
"""Self-contained led-driver test runner for MicroPython/mpremote."""
"""Self-contained led-driver test runner for MicroPython/mpremote.
Run on device (from led-driver repo root)::
mpremote connect <port> run tests/all.py
Or via dev helper::
python dev.py <port> test
"""
import json
import os
import sys
import utime
from machine import WDT
from settings import Settings
from presets import Presets, run_tick
from utils import convert_and_reorder_colors
def _bootstrap_import_path():
"""Find ``settings`` / ``presets`` whether this file lives in ``tests/`` or ``:/``."""
try:
import uos as os
except ImportError:
import os
candidates = []
try:
here = __file__.rsplit("/", 1)[0]
if here:
candidates.append(here)
parent = here.rsplit("/", 1)[0]
if parent:
candidates.append(parent)
except NameError:
pass
candidates.extend([".", "..", "/"])
for p in candidates:
if p and p not in sys.path:
sys.path.insert(0, p)
_bootstrap_import_path()
from settings import Settings # noqa: E402
from presets import Presets, run_tick # noqa: E402
from preset import Preset # noqa: E402
from utils import convert_and_reorder_colors # noqa: E402
class _TestContext:
@@ -27,6 +63,20 @@ class _TestContext:
utime.sleep_ms(sleep_ms)
def _pattern_loaded(ctx, pattern_id):
return pattern_id in ctx.presets.patterns
def _smoke_preset(ctx, name, data, ms=80):
pattern_id = data.get("p") or data.get("pattern")
if not _pattern_loaded(ctx, pattern_id):
raise AssertionError("pattern not loaded: %s" % pattern_id)
ctx.presets.edit(name, data)
if not ctx.presets.select(name):
raise AssertionError("select failed: %s" % name)
ctx.tick_for_ms(ms)
def _process_message(ctx, payload):
"""Small test helper that mirrors the main message handling logic."""
try:
@@ -93,8 +143,7 @@ def _process_message(ctx, payload):
should_apply_default = this_device_name_norm in normalized_targets
if (
should_apply_default
and
isinstance(default_name, str)
and isinstance(default_name, str)
and default_name
and default_name in ctx.presets.presets
):
@@ -145,6 +194,40 @@ def test_preset_edit_sanitization():
assert not hasattr(p, "unknown_field")
def test_preset_mode_alias_maps_to_n6():
ctx = _TestContext()
ctx.presets.edit(
"rainbow_mode",
{"pattern": "colour_cycle", "mode": 1, "d": 50, "n1": 2, "a": True},
)
p = ctx.presets.presets["rainbow_mode"]
assert p.p == "colour_cycle"
assert p.n6 == 1
def test_style_mode_and_legacy_aliases():
from patterns.pattern_modes import style_mode
p = Preset({"p": "colour_cycle", "mode": 0, "d": 50, "c": [(255, 0, 0)]})
assert style_mode(p, 0, {"rainbow": 1}) == 0
legacy = Preset({"p": "rainbow", "d": 50, "c": [(255, 0, 0)]})
assert style_mode(legacy, 0, {"rainbow": 1}) == 1
ctx = _TestContext()
legacy_ids = (
"rainbow",
"meteor_rain",
"snowfall",
"sparkle_trail",
"marquee",
"northern_wave",
)
for lid in legacy_ids:
if not _pattern_loaded(ctx, lid):
raise AssertionError("legacy alias not registered: %s" % lid)
def test_colour_conversion_and_transition():
ctx = _TestContext()
msg = {
@@ -162,7 +245,6 @@ def test_colour_conversion_and_transition():
result = _process_message(ctx, msg)
assert result == "ok"
assert ctx.presets.selected == "fade"
# Smoke-run the generator to ensure math runs without type errors.
ctx.tick_for_ms(250)
@@ -172,19 +254,54 @@ def test_pattern_smoke():
"t_on": {"p": "on", "c": [(16, 8, 4)]},
"t_off": {"p": "off"},
"t_blink": {"p": "blink", "c": [(255, 0, 0)], "d": 20},
"t_rainbow": {"p": "rainbow", "d": 5, "n1": 2},
"t_pulse": {"p": "pulse", "c": [(255, 0, 0)], "n1": 20, "n2": 10, "n3": 20, "d": 10},
"t_transition": {"p": "transition", "c": [(255, 0, 0), (0, 0, 255)], "d": 30},
"t_colour_cycle": {"p": "colour_cycle", "n6": 0, "d": 5, "n1": 2, "c": [(255, 0, 0), (0, 255, 0)]},
"t_chase": {"p": "chase", "c": [(255, 0, 0), (0, 0, 255)], "n1": 3, "n2": 2, "n3": 1, "n4": 1, "d": 20},
"t_circle": {"p": "circle", "c": [(255, 255, 0), (0, 0, 8)], "n1": 5, "n2": 10, "n3": 5, "n4": 2},
}
for name, data in cases.items():
ctx.presets.edit(name, data)
assert ctx.presets.select(name), "select failed: %s" % name
ctx.tick_for_ms(120)
_smoke_preset(ctx, name, data, ms=100)
def test_merged_pattern_modes():
"""Smoke each style (``n6`` / ``mode``) for merged multi-mode patterns."""
ctx = _TestContext()
colors = [(200, 220, 255), (255, 180, 80)]
cases = (
("mc_grad", "colour_cycle", {"p": "colour_cycle", "n6": 0, "n1": 2, "d": 8, "c": colors}),
("mc_wheel", "colour_cycle", {"p": "colour_cycle", "mode": 1, "n1": 2, "d": 8}),
("chase_std", "chase", {"p": "chase", "n6": 0, "n1": 2, "n2": 2, "n3": 1, "n4": 1, "d": 15, "c": colors}),
("chase_marq", "chase", {"p": "chase", "n6": 1, "n1": 3, "n2": 2, "n3": 1, "d": 15, "c": colors}),
("meteor_0", "meteor", {"p": "meteor", "n6": 0, "n1": 4, "n2": 2, "n3": 8, "d": 10, "c": colors}),
("meteor_1", "meteor", {"p": "meteor", "n6": 1, "n1": 3, "n2": 2, "n3": 4, "d": 10, "c": colors}),
("part_0", "particles", {"p": "particles", "n6": 0, "n1": 4, "n2": 1, "d": 10, "c": colors}),
("part_1", "particles", {"p": "particles", "mode": 1, "n1": 3, "n2": 1, "n3": 4, "d": 10, "c": colors}),
("spark_0", "sparkle", {"p": "sparkle", "n6": 0, "n1": 4, "n2": 6, "d": 10, "c": colors}),
("spark_1", "sparkle", {"p": "sparkle", "n6": 1, "n1": 3, "n2": 4, "n3": 2, "d": 10, "c": colors}),
("aurora_0", "aurora", {"p": "aurora", "n6": 0, "n1": 3, "n2": 2, "n3": 0, "d": 12, "c": colors}),
("aurora_1", "aurora", {"p": "aurora", "mode": 1, "n1": 8, "n2": 2, "n3": 1, "d": 12, "c": colors}),
)
for name, pattern_id, data in cases:
if not _pattern_loaded(ctx, pattern_id):
continue
_smoke_preset(ctx, name, data, ms=60)
legacy_smoke = (
("leg_rainbow", "rainbow", {"p": "rainbow", "d": 8, "n1": 2}),
("leg_ice", "ice_sparkle", {"p": "ice_sparkle", "n1": 3, "n2": 2, "n3": 2, "d": 10, "c": colors}),
("leg_wave", "northern_wave", {"p": "northern_wave", "n1": 6, "n2": 2, "n3": 1, "d": 12, "c": colors}),
("leg_star", "starfall", {"p": "starfall", "n1": 3, "n2": 1, "n3": 3, "d": 10, "c": colors}),
)
for name, pattern_id, data in legacy_smoke:
if not _pattern_loaded(ctx, pattern_id):
continue
_smoke_preset(ctx, name, data, ms=60)
def test_patterns_do_not_use_blocking_sleep():
try:
import uos as os
except ImportError:
import os
pattern_dir = "patterns"
offenders = []
try:
@@ -192,8 +309,9 @@ def test_patterns_do_not_use_blocking_sleep():
except OSError:
raise AssertionError("patterns directory is missing")
skip = frozenset(("__init__.py", "main.py", "pattern_modes.py"))
for filename in files:
if not filename.endswith(".py") or filename in ("__init__.py", "main.py"):
if not filename.endswith(".py") or filename in skip:
continue
path = pattern_dir + "/" + filename
try:
@@ -223,6 +341,7 @@ def test_default_requires_existing_preset():
_process_message(ctx, {"v": "1", "default": "exists"})
assert ctx.settings.get("default") == "exists"
def test_default_targets_gate_by_device_name():
ctx = _TestContext()
ctx.settings["name"] = "a"
@@ -243,6 +362,11 @@ def test_default_targets_gate_by_device_name():
def test_save_and_load_roundtrip():
try:
import uos as os
except ImportError:
import os
ctx = _TestContext()
ctx.presets.edit(
"persist",
@@ -270,8 +394,11 @@ def run_all():
tests = [
test_invalid_messages_do_not_crash,
test_preset_edit_sanitization,
test_preset_mode_alias_maps_to_n6,
test_style_mode_and_legacy_aliases,
test_colour_conversion_and_transition,
test_pattern_smoke,
test_merged_pattern_modes,
test_patterns_do_not_use_blocking_sleep,
test_default_requires_existing_preset,
test_default_targets_gate_by_device_name,

190
tests/patterns/auto_manual.py
View File

@@ -1,190 +0,0 @@
#!/usr/bin/env python3
import utime
from machine import WDT
from settings import Settings
from presets import Presets, run_tick
def run_for(p, wdt, duration_ms):
"""Run pattern for specified duration."""
start = utime.ticks_ms()
while utime.ticks_diff(utime.ticks_ms(), start) < duration_ms:
wdt.feed()
run_tick(p)
utime.sleep_ms(10)
def main():
s = Settings()
pin = s.get("led_pin", 10)
num = s.get("num_leds", 30)
p = Presets(pin=pin, num_leds=num)
wdt = WDT(timeout=10000)
print("=" * 50)
print("Testing Auto and Manual Modes")
print("=" * 50)
# Test 1: Rainbow in AUTO mode (continuous)
print("\nTest 1: Rainbow pattern in AUTO mode (should run continuously)")
p.edit("rainbow_auto", {
"p": "rainbow",
"b": 128,
"d": 50,
"n1": 2,
"a": True,
})
p.select("rainbow_auto")
print("Running rainbow_auto for 3 seconds...")
run_for(p, wdt, 3000)
print("✓ Auto mode: Pattern ran continuously")
# Test 2: Rainbow in MANUAL mode (one step per tick)
print("\nTest 2: Rainbow pattern in MANUAL mode (one step per tick)")
p.edit("rainbow_manual", {
"p": "rainbow",
"b": 128,
"d": 50,
"n1": 2,
"a": False,
})
p.select("rainbow_manual")
print("Calling tick() 5 times (should advance 5 steps)...")
for i in range(5):
run_tick(p)
utime.sleep_ms(100) # Small delay to see changes
print(f" Tick {i+1}: generator={'active' if p.generator is not None else 'stopped'}")
# Check if generator stopped after one cycle
if p.generator is None:
print("✓ Manual mode: Generator stopped after one step (as expected)")
else:
print("⚠ Manual mode: Generator still active (may need multiple ticks)")
# Test 3: Pulse in AUTO mode (continuous cycles)
print("\nTest 3: Pulse pattern in AUTO mode (should pulse continuously)")
p.edit("pulse_auto", {
"p": "pulse",
"b": 128,
"d": 100,
"n1": 500, # Attack
"n2": 200, # Hold
"n3": 500, # Decay
"c": [(255, 0, 0)],
"a": True,
})
p.select("pulse_auto")
print("Running pulse_auto for 3 seconds...")
run_for(p, wdt, 3000)
print("✓ Auto mode: Pulse ran continuously")
# Test 4: Pulse in MANUAL mode (one cycle then stop)
print("\nTest 4: Pulse pattern in MANUAL mode (one cycle then stop)")
p.edit("pulse_manual", {
"p": "pulse",
"b": 128,
"d": 100,
"n1": 300, # Attack
"n2": 200, # Hold
"n3": 300, # Decay
"c": [(0, 255, 0)],
"a": False,
})
p.select("pulse_manual")
print("Running pulse_manual until generator stops...")
tick_count = 0
max_ticks = 200 # Safety limit
while p.generator is not None and tick_count < max_ticks:
run_tick(p)
tick_count += 1
utime.sleep_ms(10)
if p.generator is None:
print(f"✓ Manual mode: Pulse completed one cycle after {tick_count} ticks")
else:
print(f"⚠ Manual mode: Pulse still running after {tick_count} ticks")
# Test 5: Transition in AUTO mode (continuous transitions)
print("\nTest 5: Transition pattern in AUTO mode (continuous transitions)")
p.edit("transition_auto", {
"p": "transition",
"b": 128,
"d": 500,
"c": [(255, 0, 0), (0, 255, 0), (0, 0, 255)],
"a": True,
})
p.select("transition_auto")
print("Running transition_auto for 3 seconds...")
run_for(p, wdt, 3000)
print("✓ Auto mode: Transition ran continuously")
# Test 6: Transition in MANUAL mode (one transition then stop)
print("\nTest 6: Transition pattern in MANUAL mode (one transition then stop)")
p.edit("transition_manual", {
"p": "transition",
"b": 128,
"d": 500,
"c": [(255, 0, 0), (0, 255, 0)],
"a": False,
})
p.select("transition_manual")
print("Running transition_manual until generator stops...")
tick_count = 0
max_ticks = 200
while p.generator is not None and tick_count < max_ticks:
run_tick(p)
tick_count += 1
utime.sleep_ms(10)
if p.generator is None:
print(f"✓ Manual mode: Transition completed after {tick_count} ticks")
else:
print(f"⚠ Manual mode: Transition still running after {tick_count} ticks")
# Test 7: Switching between auto and manual modes
print("\nTest 7: Switching between auto and manual modes")
p.edit("switch_test", {
"p": "rainbow",
"b": 128,
"d": 50,
"n1": 2,
"a": True,
})
p.select("switch_test")
print("Running in auto mode for 1 second...")
run_for(p, wdt, 1000)
# Switch to manual mode by editing the preset
print("Switching to manual mode...")
p.edit("switch_test", {"a": False})
p.select("switch_test") # Re-select to apply changes
print("Calling tick() 3 times in manual mode...")
for i in range(3):
run_tick(p)
utime.sleep_ms(100)
print(f" Tick {i+1}: generator={'active' if p.generator is not None else 'stopped'}")
# Switch back to auto mode
print("Switching back to auto mode...")
p.edit("switch_test", {"a": True})
p.select("switch_test")
print("Running in auto mode for 1 second...")
run_for(p, wdt, 1000)
print("✓ Successfully switched between auto and manual modes")
# Cleanup
print("\nCleaning up...")
p.edit("cleanup_off", {"p": "off"})
p.select("cleanup_off")
run_tick(p)
utime.sleep_ms(100)
print("\n" + "=" * 50)
print("All tests completed!")
print("=" * 50)
if __name__ == "__main__":
main()

52
tests/patterns/radiate.py
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@@ -1,52 +0,0 @@
#!/usr/bin/env python3
import utime
from machine import WDT
from settings import Settings
from presets import Presets
def main():
print("[test] radiate: start")
s = Settings()
p = Presets(pin=s.get("led_pin", 10), num_leds=s.get("num_leds", 30))
p.debug = True
wdt = WDT(timeout=10000)
print("[test] radiate: auto phase begin")
p.edit("test_pattern", {"p": "radiate", "b": 64, "a": True, "d": 3000, "c": [(255, 0, 0), (0, 0, 255)]})
if not p.select("test_pattern"):
raise Exception("radiate select failed in auto phase")
auto_start = utime.ticks_ms()
while utime.ticks_diff(utime.ticks_ms(), auto_start) < 2500:
wdt.feed()
p.run_step()
utime.sleep_ms(20)
remaining_ms = utime.ticks_diff(p.next_tick_ms, utime.ticks_ms())
if p.next_tick_ms == 0 or remaining_ms <= 0:
raise Exception("radiate delay scheduling invalid")
print("[test] radiate: auto phase end")
print("[test] radiate: manual phase begin")
p.edit("test_pattern", {"p": "radiate", "b": 64, "a": False, "d": 3000, "c": [(255, 0, 0), (0, 0, 255)]})
if not p.select("test_pattern", step=0):
raise Exception("radiate select failed in manual phase")
for _ in range(6):
current_step = int(p.step)
if not p.select("test_pattern", step=current_step):
raise Exception("radiate external select failed")
p.run_step()
wdt.feed()
if int(p.step) == current_step:
raise Exception("radiate external step did not advance")
if p.generator is not None:
raise Exception("radiate manual mode rescheduled generator")
hold_start = utime.ticks_ms()
while utime.ticks_diff(utime.ticks_ms(), hold_start) < 700:
wdt.feed()
utime.sleep_ms(20)
print("[test] radiate: manual phase end")
print("[test] radiate: pass")
if __name__ == "__main__":
main()

151
tests/patterns/rainbow.py
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#!/usr/bin/env python3
import utime
from machine import WDT
from settings import Settings
from presets import Presets, run_tick
def run_for(p, wdt, ms):
"""Helper: run current pattern for given ms using tick()."""
start = utime.ticks_ms()
while utime.ticks_diff(utime.ticks_ms(), start) < ms:
wdt.feed()
run_tick(p)
utime.sleep_ms(10)
def main():
s = Settings()
pin = s.get("led_pin", 10)
num = s.get("num_leds", 30)
p = Presets(pin=pin, num_leds=num)
wdt = WDT(timeout=10000)
# Test 1: Basic rainbow with auto=True (continuous)
print("Test 1: Basic rainbow (auto=True, n1=1)")
p.edit("rainbow1", {
"p": "rainbow",
"b": 255,
"d": 100,
"n1": 1,
"a": True,
})
p.select("rainbow1")
run_for(p, wdt, 3000)
# Test 2: Fast rainbow
print("Test 2: Fast rainbow (low delay, n1=1)")
p.edit("rainbow2", {
"p": "rainbow",
"d": 50,
"n1": 1,
"a": True,
})
p.select("rainbow2")
run_for(p, wdt, 2000)
# Test 3: Slow rainbow
print("Test 3: Slow rainbow (high delay, n1=1)")
p.edit("rainbow3", {
"p": "rainbow",
"d": 500,
"n1": 1,
"a": True,
})
p.select("rainbow3")
run_for(p, wdt, 3000)
# Test 4: Low brightness rainbow
print("Test 4: Low brightness rainbow (n1=1)")
p.edit("rainbow4", {
"p": "rainbow",
"b": 64,
"d": 100,
"n1": 1,
"a": True,
})
p.select("rainbow4")
run_for(p, wdt, 2000)
# Test 5: Single-step rainbow (auto=False)
print("Test 5: Single-step rainbow (auto=False, n1=1)")
p.edit("rainbow5", {
"p": "rainbow",
"b": 255,
"d": 100,
"n1": 1,
"a": False,
})
p.step = 0
for i in range(10):
p.select("rainbow5")
# One tick advances the generator one frame when auto=False
run_tick(p)
utime.sleep_ms(100)
wdt.feed()
# Test 6: Verify step updates correctly
print("Test 6: Verify step updates (auto=False, n1=1)")
p.edit("rainbow6", {
"p": "rainbow",
"n1": 1,
"a": False,
})
initial_step = p.step
p.select("rainbow6")
run_tick(p)
final_step = p.step
print(f"Step updated from {initial_step} to {final_step} (expected increment: 1)")
# Test 7: Fast step increment (n1=5)
print("Test 7: Fast rainbow (n1=5, auto=True)")
p.edit("rainbow7", {
"p": "rainbow",
"b": 255,
"d": 100,
"n1": 5,
"a": True,
})
p.select("rainbow7")
run_for(p, wdt, 2000)
# Test 8: Very fast step increment (n1=10)
print("Test 8: Very fast rainbow (n1=10, auto=True)")
p.edit("rainbow8", {
"p": "rainbow",
"n1": 10,
"a": True,
})
p.select("rainbow8")
run_for(p, wdt, 2000)
# Test 9: Verify n1 controls step increment (auto=False)
print("Test 9: Verify n1 step increment (auto=False, n1=5)")
p.edit("rainbow9", {
"p": "rainbow",
"n1": 5,
"a": False,
})
p.step = 0
initial_step = p.step
p.select("rainbow9")
run_tick(p)
final_step = p.step
expected_step = (initial_step + 5) % 256
print(f"Step updated from {initial_step} to {final_step} (expected: {expected_step})")
if final_step == expected_step:
print("✓ n1 step increment working correctly")
else:
print(f"✗ Step increment mismatch! Expected {expected_step}, got {final_step}")
# Cleanup
print("Test complete, turning off")
p.edit("cleanup_off", {"p": "off"})
p.select("cleanup_off")
run_for(p, wdt, 100)
if __name__ == "__main__":
main()