Require python 3.6+
FRP, a.k.a. functional reactive programming is a programming paradigm to model time related system better. As a rather radical idea, FRP mainly exists in theoretical articles. But its (mental) concept is very useful in some cases and has been adopted partially in many tools like Elm or React among others. Comparing to other python frp libraries, frpy is:
- super lightweight, core part is merely 64 lines of code without comments.
- carefully designed clock system, support both clock free style and streams running in real world time
- totally thread-safe given a clock exits
- take advantage of async python, allowing near-sequential style style with fmap_async
Full documentation can be found at API Doc.
Stream is a sequence of events. It could also be interpret as states changed stepwise. Continuous changing values like sin(x) over [0, 1] is not within the scope unless the changing is sampled as discrete events. Each stream has a clock property, an orphan stream is a stream whose clock is None.
Clock is a stream whose clock is itself. Clock is the most important concept supporting the Stream to ensure thread-safety and greatly reduce the pain of concurrency. The simplest clock can be constructed by Stream(None) whose clock will be set to self, and the time value can then be injected manually. However, in most cases other than tests it's better to use the clock function to get a self-ticking clock.
Different clocks will provide different levels of capabilities. All clock with increasing substractable values enables all operators, no matter the values are real timestamp, natural numbers or event more complex structures (though the time unit differs). Clocks with non-substractable or non-increasing values will not support time sensitive operators like delay or timeout.
Clock-free style streams
from frpy.api import Stream, fmap, where, merge
# even items from s1 merged with s2
s1 = Stream(None)
s2 = Stream(None)
s3 = fmap(where(lambda x: x % 2 == 0, s1))
s4 = merge([s2, s3])
s4.hook = print
s1(1)
s1(2) # 2
s1(3)
s2(10) # 10
s1(4) # 4
s2(9) # 9
s1(5)
s1(6) # 6
# The footprint of s4 is: 2, 10, 4, 9, 6Streams with manual clock
# even items from s1 delayed by 2 time units
clk = Stream(None)
clk.clock = clk
src = Stream(clk)
s = delay(2, src)
s.hook = print
src(0)
clk(0) # src will be set here (the next clock tick)
src(1)
clk(1)
clk(2) # 0
clk(3) # empty since value 1 is odd
clk(4) # 2Complex case: number accumulation with timeout
Numbers randomly spawn and accumulated. If the accumulated number reaches a certain value, output "met!" and start next try. If the accumulated number does not reach the value after a given period, output "fail!" and start next try.
This simulation is a simplified "try with timeout" problem, which is quite uneasy for tranditional sequential paradigm (usually threads or event queues are necessary and may involve concurrency). Following we provide three methods with frpy to address this problem, each with only about 20-30 lines of code.
Method 1: pure stream-style approach
from frpy.api import Stream, fmap, repeat, scan, changed, \
merge, each, timeout, clock
from frpy.fp import soft, const # functional programming helpers
from functools import partial as bind
# options
value_thres = 3
time_thres = 1.2
# init the clock
clk, tick = clock()
# construct streams
sp = fmap(soft(random.random), repeat(0.2, clk))
term = Stream(clk)
interrupt = timeout(time_thres, term, term)
value = merge([sp, fmap(const(-1), term)])
acc = scan(lambda acc, v: acc + v if v >= 0 else 0, 0, value)
met = changed(lambda _, y: y <= value_thres, acc)
each(term, merge([met, interrupt]))
# hook to print trace
acc.hook = print
met.hook = bind(print, 'met!')
interrupt.hook = bind(print, 'fail!')
# start clock
tick()Method 2: more sequential approach with async generator
import math
from frpy.api import Stream, fmap, repeat, merge, fmap_async, clock
from frpy.fp import soft
# options
value_thres = 3
time_thres = 1.2
clk, tick = clock()
sp = fmap(soft(random.random), repeat(0.2, clk))
# aysnc generator transformation
async def fn(s):
acc = 0
last = math.inf
async for topic, v in s:
if topic == 'clock':
if acc > value_thres:
met = True
if v - last > time_thres or acc > value_thres:
yield 'met' if met else 'fail'
yield 0
met = False
acc = 0
last = v
elif topic == 'value':
acc += v
yield acc
# map the transformation over async generators to that over streams
res = fmap_async(fn, merge([clk, sp], ['clock', 'value']))
# hook to print trace
res.hook = print
tick()Method 3: state reducer approach resembling React and Elm
from frpy.api import Stream, fmap, repeat, scan, merge, clock
from frpy.fp import soft
# options
value_thres = 3
time_thres = 1.2
clk, tick = clock()
sp = fmap(soft(random.random), repeat(0.2, clk))
events = merge([clk, sp], ['clock', 'value'])
# the reducer function to update state, print directly for convenience
def update(state: Tuple[float, float], event) -> Tuple[float, float]:
channel, data = event
start_at, acc = state
if channel == 'clock':
if data - start_at > time_thres:
print('failed')
return (data, 0)
return state
if channel == 'value':
new_value = acc + data
print(new_value)
if new_value >= value_thres:
print('met')
return (time.time(), 0)
return (start_at, new_value)
else:
return state
# we do not use states so just print changes in reducer
scan(update, (time.time(), 0), events)
tick()For detailed docs please refer to API Doc.
Thread-safety
Injecting an event to a stream with a clock is thread-safe since all actions will be scheduled by its clock. Injecting an event to an orphan stream is NOT thread-safe. Users have to be careful if use streams in a clock-free style.
Clock compatiblities
Frpy will try its best to construct compatible streams. For unary operators, clock will always be proporgated. This also means that orphan streams will always derives orphan streams. For multiary operators like merge, if all non-orphan upstreams have the same clock, inherit that clock, otherwise dettach the stream to be orphan to avoid problems. This behavior is implemented in the combine. It is highly recommended to avoid mixing clocks or do that only if with good reason, and always manually set the derived stream's clock.
Attribution
This module is heavily inspired by flyd, with some important design decisions:
The atomic update feature is not ported
The atomic update is quite useful but adds too much complexity in my opinion, also the performance gain should not be too much since the diamond style dependencies could be avoided in many scenarios.
Racial conditions are handled by a central event loop, a.k.a a clock stream
Python unlike js has no event loop, and the new async API is not easy to use in this case. We use the conception of clock when necessary with asyncio event loops underhood. Per thread has its clock.
No end stream mechanism is implemented
End streams are useful but may introduce too much dynamism and it has an implact on the complexity ofimplementation. It may be added in the future after thorough consideration.