doublebuf
Ondřej Hruška 7 years ago
parent adee8b7b0f
commit 76ade9f5cd
Signed by: MightyPork
GPG Key ID: 2C5FD5035250423D
  1. 21
      gex/Unit.py
  2. 1
      gex/__init__.py
  3. 13
      gex/units/ADC.py
  4. 21
      gex/units/DIn.py
  5. 20
      gex/units/DOut.py
  6. 2
      gex/units/I2C.py
  7. 46
      gex/units/SIPO.py
  8. 6
      gex/units/SPI.py
  9. 8
      main.py
  10. 72
      pymodoro.py

@ -67,3 +67,24 @@ class Unit:
def _on_event(self, evt:EventReport): def _on_event(self, evt:EventReport):
""" Stub for an event handler """ """ Stub for an event handler """
raise NotImplementedError("Missing _on_event() in Unit class \"%s\"" % self.__class__.__name__) raise NotImplementedError("Missing _on_event() in Unit class \"%s\"" % self.__class__.__name__)
# --- utils ---
def pins2int(self, list_or_int):
if type(list_or_int) != int:
p = 0
for pin in list_or_int:
p |= 1 << pin
return p
else:
return list_or_int
def pins2list(self, list_or_int):
if type(list_or_int) == int:
L = []
for i in range(0,32): # this is up to 32 in order to allow using it also for adc channels
if list_or_int & (1 << i) != 0:
L.append(i)
return L
else:
return list_or_int

@ -17,6 +17,7 @@ from gex.units.SPI import SPI
from gex.units.USART import USART from gex.units.USART import USART
from gex.units.OneWire import OneWire from gex.units.OneWire import OneWire
from gex.units.ADC import ADC from gex.units.ADC import ADC
from gex.units.SIPO import SIPO
# General, low level # General, low level

@ -319,15 +319,11 @@ class ADC(gex.Unit):
Set which channels should be active. Set which channels should be active.
""" """
word = 0
for c in channels:
word |= 1 << c
pb = gex.PayloadBuilder() pb = gex.PayloadBuilder()
pb.u32(word) pb.u32(self.pins2int(channels))
self._send(cmd=CMD_ENABLE_CHANNELS, pld=pb.close(), confirm=confirm) self._send(cmd=CMD_ENABLE_CHANNELS, pld=pb.close(), confirm=confirm)
self.channels = channels self.channels = self.pins2list(channels)
def _parse_buffer(self, buf): def _parse_buffer(self, buf):
""" """
@ -414,7 +410,10 @@ class ADC(gex.Unit):
self._query_async(cmd=CMD_STREAM_START, callback=self._on_stream_capt) self._query_async(cmd=CMD_STREAM_START, callback=self._on_stream_capt)
def stream_stop(self, delay=0.1, confirm=True): def stream_stop(self, delay=0.1, confirm=True):
""" Stop a stream """ """
Stop a stream. Delay is an extra time before removing the listener
to let the queued frames to finish being received.
"""
if not self._stream_running: if not self._stream_running:
raise Exception("Not streaming") raise Exception("Not streaming")

@ -23,24 +23,24 @@ class DIn(gex.Unit):
pp = gex.PayloadParser(msg) pp = gex.PayloadParser(msg)
return pp.u16() return pp.u16()
def arm(self, pins:int, auto:bool=False, confirm:bool=False): def arm(self, pins, auto:bool=False, confirm:bool=False):
""" """
Arm pins for single shot event generation Arm pins for single shot event generation
pins - array of pin indices to arm pins - array of pin indices to arm
auto - use auto trigger (auto re-arm after hold-off) auto - use auto trigger (auto re-arm after hold-off)
""" """
pb = gex.PayloadBuilder() pb = gex.PayloadBuilder()
pb.u16(pins) pb.u16(self.pins2int(pins))
self._send(0x02 if auto else 0x01, pb.close()) self._send(0x02 if auto else 0x01, pb.close())
def disarm(self, pins:int, confirm:bool=False): def disarm(self, pins, confirm:bool=False):
""" """
DisArm pins DisArm pins
pins - array of pin indices to arm pins - array of pin indices to arm
""" """
pb = gex.PayloadBuilder() pb = gex.PayloadBuilder()
pb.u16(pins) pb.u16(self.pins2int(pins))
self._send(0x03, pb.close()) self._send(0x03, pb.close())
def on_trigger(self, sensitive_pins, callback): def on_trigger(self, sensitive_pins, callback):
@ -50,24 +50,17 @@ class DIn(gex.Unit):
Arguments are: pins snapshot, timestamp Arguments are: pins snapshot, timestamp
""" """
if type(sensitive_pins) == int: for i in self.pins2list(sensitive_pins):
L = []
for i in range(0,16):
if sensitive_pins & (1 << i) != 0:
L.append(i)
sensitive_pins = L
for i in sensitive_pins:
self.handlers[i] = callback self.handlers[i] = callback
def _on_event(self, evt:EventReport): def _on_event(self, evt:EventReport):
if evt.code == 0x00: if evt.code == 0x00:
# trigger interrupt # trigger interrupt
pp = gex.PayloadParser(evt.payload) pp = gex.PayloadParser(evt.payload)
triggersource = pp.u16() triggersources = pp.u16() # multiple can happen at once
snapshot = pp.u16() snapshot = pp.u16()
for i in range(0,16): for i in range(0,16):
if triggersource & (1<<i): if triggersources & (1<<i):
if i in self.handlers: if i in self.handlers:
self.handlers[i](snapshot, evt.timestamp) self.handlers[i](snapshot, evt.timestamp)

@ -14,25 +14,25 @@ class DOut(gex.Unit):
return 'DO' return 'DO'
def write(self, pins:int, confirm=True): def write(self, pins:int, confirm=True):
""" Set pins to a value """ """ Set pins to a value - packed, as int """
pb = gex.PayloadBuilder() pb = gex.PayloadBuilder()
pb.u16(pins) pb.u16(pins)
self._send(0x00, pb.close(), confirm=confirm) self._send(0x00, pb.close(), confirm=confirm)
def set(self, pins:int, confirm=True): def set(self, pins, confirm=True):
""" Set pins high """ """ Set pins high - packed, int or list """
pb = gex.PayloadBuilder() pb = gex.PayloadBuilder()
pb.u16(pins) pb.u16(self.pins2int(pins))
self._send(0x01, pb.close(), confirm=confirm) self._send(0x01, pb.close(), confirm=confirm)
def clear(self, pins:int, confirm=True): def clear(self, pins, confirm=True):
""" Set pins low """ """ Set pins low - packed, int or list """
pb = gex.PayloadBuilder() pb = gex.PayloadBuilder()
pb.u16(pins) pb.u16(self.pins2int(pins))
self._send(0x02, pb.close(), confirm=confirm) self._send(0x02, pb.close(), confirm=confirm)
def toggle(self, pins:int, confirm=True): def toggle(self, pins, confirm=True):
""" Toggle pins """ """ Toggle pins - packed, int or list """
pb = gex.PayloadBuilder() pb = gex.PayloadBuilder()
pb.u16(pins) pb.u16(self.pins2int(pins))
self._send(0x03, pb.close(), confirm=confirm) self._send(0x03, pb.close(), confirm=confirm)

@ -10,7 +10,7 @@ class I2C(gex.Unit):
def _begin_i2c_pld(self, address:int, a10bit:bool=False): def _begin_i2c_pld(self, address:int, a10bit:bool=False):
pb = gex.PayloadBuilder() pb = gex.PayloadBuilder()
if a10bit: address |= 0x8000 if a10bit: address |= 0x8000 # indication for the Unit driver that it's a 10b address
pb.u16(address) pb.u16(address)
return pb return pb

@ -0,0 +1,46 @@
import gex
CMD_WRITE = 0
CMD_DIRECT_DATA = 1
CMD_DIRECT_SHIFT = 2
CMD_DIRECT_CLEAR = 3
CMD_DIRECT_STORE = 4
class SIPO(gex.Unit):
"""
Multi-channel SIPO driver
Designed for loading up to 16 74xx595 or 74xx4094 serial-input-parallel-output shift registers
The number of drivers can be significantly expanded via daisy-chaining.
"""
def _type(self):
return 'SIPO'
def load(self, buffers, confirm=True):
""" Load data - buffers is a list of lists or byte arrays """
if type(buffers[0]) == int:
buffers = [buffers]
pb = gex.PayloadBuilder()
for b in buffers:
pb.blob(b)
self._send(CMD_WRITE, pb.close(), confirm=confirm)
def set_data(self, packed:int, confirm=True):
""" Manually set the data pins """
pb = gex.PayloadBuilder()
pb.u16(packed)
self._send(CMD_DIRECT_DATA, pb.close(), confirm=confirm)
def shift(self, confirm=True):
""" Manually send a shift pulse (shift data one step further into the registers) """
self._send(CMD_DIRECT_SHIFT, confirm=confirm)
def store(self, confirm=True):
""" Manually send a store pulse (copy the shift register data to the outputs) """
self._send(CMD_DIRECT_STORE, confirm=confirm)
def clear(self, confirm=True):
""" Manually send a clear pulse (if connected correctly, this immediately resets the shift register outputs) """
self._send(CMD_DIRECT_CLEAR, confirm=confirm)

@ -39,12 +39,12 @@ class SPI(gex.Unit):
""" """
self.query(slave, tbytes, rlen=0, rskip=0, confirm=confirm) self.query(slave, tbytes, rlen=0, rskip=0, confirm=confirm)
def multicast(self, slaves:int, tbytes, confirm=True): def multicast(self, slaves, tbytes, confirm=True):
""" """
Write with multiple slaves at once. Write with multiple slaves at once.
Slaves is a right-aligned bitmap (eg. pins 0,2,3 would be 0b1101) Slaves is a right-aligned bitmap (eg. pins 0,2,3 would be 0b1101), or a list of active positions
""" """
pb = gex.PayloadBuilder() pb = gex.PayloadBuilder()
pb.u16(slaves) pb.u16(self.pins2int(slaves))
pb.blob(tbytes) pb.blob(tbytes)
self._send(0x01, pb.close(), confirm=confirm) self._send(0x01, pb.close(), confirm=confirm)

@ -16,6 +16,12 @@ with gex.Client(transport) as client:
# print(s) # print(s)
# client.ini_write(s) # client.ini_write(s)
if True:
sipo = gex.SIPO(client, 'sipo')
while True:
sipo.load([[0xFF], [0xAA], [0x11], [0x00]])
time.sleep(0.2)
if False: if False:
adc = gex.ADC(client, 'adc') adc = gex.ADC(client, 'adc')
print("Enabled channels:", adc.get_channels()) print("Enabled channels:", adc.get_channels())
@ -30,7 +36,7 @@ with gex.Client(transport) as client:
raw[17], smooth[17])) raw[17], smooth[17]))
time.sleep(0.5) time.sleep(0.5)
if True: if False:
adc = gex.ADC(client, 'adc') adc = gex.ADC(client, 'adc')
adc.set_active_channels([1]) adc.set_active_channels([1])

@ -15,11 +15,12 @@ class Pymodoro:
self.phase = PH_BREAK_OVER self.phase = PH_BREAK_OVER
self.work_s = 0 self.work_s = 0
self.break_s = 0 self.break_s = 0
self.color = 0x000000
self.colors = [0x000000 for _ in range(0, LIGHT_CNT)] self.colors = [0x000000 for _ in range(0, LIGHT_CNT)]
client = gex.Client(gex.TrxRawUSB()) self.client = gex.Client(gex.TrxRawUSB())
self.btn = gex.DIn(client, 'btn') self.btn = gex.DIn(self.client, 'btn')
self.neo = gex.Neopixel(client, 'neo') self.neo = gex.Neopixel(self.client, 'neo')
self.btn.on_trigger([0], self.on_btn) self.btn.on_trigger([0], self.on_btn)
self.switch(PH_BREAK_OVER) self.switch(PH_BREAK_OVER)
@ -42,50 +43,75 @@ class Pymodoro:
print("Switch to %s" % phase) print("Switch to %s" % phase)
if phase == PH_BREAK: if phase == PH_BREAK:
self.colors = [0x009900 for _ in range(0, LIGHT_CNT)] self.color = 0x009900
self.break_s = BK_TIME * 60 self.break_s = BK_TIME * 60
elif phase == PH_BREAK_OVER: elif phase == PH_BREAK_OVER:
self.colors = [0x662200 for _ in range(0, LIGHT_CNT)] self.color = 0x662200
elif phase == PH_WORK: elif phase == PH_WORK:
self.colors = [0x990000 for _ in range(0, LIGHT_CNT)] self.color = 0x990000
self.work_s = WK_TIME * 60 self.work_s = WK_TIME * 60
elif phase == PH_WORK_OVER: elif phase == PH_WORK_OVER:
self.colors = [0x113300 for _ in range(0, LIGHT_CNT)] self.color = 0x113300
self.colors = [self.color for _ in range(0, LIGHT_CNT)]
self.phase = phase self.phase = phase
def extinguish(self, dark, total): def show_progress(self, dark, total):
per_light = total / LIGHT_CNT per_light = total / LIGHT_CNT
lights = int((dark + per_light / 2) / per_light) lights = dark / per_light
for n in range(0, LIGHT_CNT - lights):
self.colors[n] = 0x000000 lights /= 2
def tick(self): remainder = float(lights - int(lights))
if remainder == 0:
remainder = 1
# print("lights %f, remainder %f" % (lights, remainder))
for i in range(0, int(LIGHT_CNT/2)):
if i < int((LIGHT_CNT/2)-lights):
c = 0x000000
elif i == int((LIGHT_CNT/2)-lights):
r = (self.color&0xFF0000)>>16
g = (self.color&0xFF00)>>8
b = self.color&0xFF
c = (int(r*remainder))<<16 | (int(g*remainder))<<8 | (int(b*remainder))
else:
c = self.color
self.colors[i] = c
self.colors[LIGHT_CNT - 1 - i] = c
def tick(self, elapsed):
if self.phase == PH_BREAK: if self.phase == PH_BREAK:
self.break_s -= 1 self.break_s -= elapsed
print("Break remain: %d s" % self.break_s) # print("Break remain: %d s" % self.break_s)
self.extinguish(self.break_s, BK_TIME * 60) self.show_progress(self.break_s, BK_TIME * 60)
if self.break_s == 0: if self.break_s <= 0:
self.switch(PH_BREAK_OVER) self.switch(PH_BREAK_OVER)
elif self.phase == PH_WORK: elif self.phase == PH_WORK:
self.work_s -= 1 self.work_s -= elapsed
print("Work remain: %d s" % self.work_s) # print("Work remain: %d s" % self.work_s)
self.extinguish(self.work_s, WK_TIME * 60) self.show_progress(self.work_s, WK_TIME * 60)
if self.work_s == 0: if self.work_s <= 0:
self.switch(PH_WORK_OVER) self.switch(PH_WORK_OVER)
self.display() self.display()
def run(self): def run(self):
step=0.5
try:
while True: while True:
time.sleep(1) time.sleep(step)
self.tick() self.tick(step)
except KeyboardInterrupt:
self.client.close()
print() # this puts the ^C on its own line
a = Pymodoro() a = Pymodoro()

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