Mercurial > pylearn
view doc/v2_planning/plugin_greenlet.py @ 1196:e9bb3340a870
plugin_greenlet draft0
| author | James Bergstra <bergstrj@iro.umontreal.ca> |
|---|---|
| date | Sun, 19 Sep 2010 13:06:16 -0400 |
| parents | d3ee0d2d03e6 |
| children | a60b3472c4ba |
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"""plugin_greenlet - draft of library architecture using greenlets""" __license__ = None __copyright__ = None import copy, sys import numpy from greenlet import greenlet def vm_unpack(incoming): # can't reliably distinguish between a kwargs-only switch and a switch with one dict # argument if incoming is None: rval = (), {} if isinstance(incoming, dict): rval = (), incoming elif isinstance(incoming, tuple): if (len(incoming)==2 and isinstance(incoming[0], tuple) and isinstance(incoming[1], dict)): rval = incoming else: rval = incoming, {} else: rval = (incoming,), {} #print 'unpack', incoming, rval return rval[0][0], rval[0][1], rval[0][2:], rval[1] def unpack_from_vm(incoming): assert isinstance(incoming, tuple) assert len(incoming)==4 return incoming def vm_run(prog, *args, **kwargs): def vm_loop(gr, dest, a, kw): while True: if gr == 'return': return a, kw #print 'vm_loop gr=',gr,'args=',a, 'kwargs=', kw gr, dest, a, kw = gr.switch(vm, gr, dest, a, kw) #print 'gmain incoming', incoming vm = greenlet(vm_loop) return vm.switch(prog, 'return', args, kwargs) def seq(glets): return repeat(1, glets) def repeat(N, glets): def repeat_task(vm, gself, dest, args, kwargs): while True: for i in xrange(N): for glet in glets: #print 'repeat_task_i dest=%(dest)s args=%(args)s, kw=%(kwargs)s'%locals() # jump to task `glet` # with instructions to report results back to this loop `g` _vm, _gself, _dest, args, kwargs = vm.switch(glet, gself, args, kwargs) assert _gself is gself assert _dest is None # instructions can't tell us where to jump vm, gself, dest, args, kwargs = vm.switch(dest, None, args, kwargs) return greenlet(repeat_task) def choose(which, options): raise NotImplementedError() def weave(threads): raise NotImplementedError() def service(fn): """ Create a greenlet whose first argument is the return-jump location. fn must accept as the first positional argument this greenlet itself, which can be used as the return-jump location for internal greenlet switches (ideally using gswitch). """ def service_loop(vm, gself, dest, args, kwargs): while True: #print 'service calling', fn.__name__, args, kwargs t = fn(vm, gself, *args, **kwargs) #TODO consider a protocol for returning args, kwargs if t is None: _vm,_gself,dest, args, kwargs = vm.switch(dest, None, (), {}) else: _vm,_gself,dest, args, kwargs = vm.switch(dest, None, (t,), {}) assert gself is _gself return greenlet(service_loop) #################################################### class Dataset(object): def __init__(self, data): self.pos = 0 self.data = data def next(self, vm, gself): rval = self.data[self.pos] self.pos += 1 if self.pos == len(self.data): self.pos = 0 return rval class PCA_Analysis(object): def __init__(self): self.mean = 0 self.eigvecs=0 self.eigvals=0 def analyze(self, me, X): self.mean = X.mean(axis=0) self.eigvecs=1 self.eigvals=1 def filt(self,me, X): return (self.X - self.mean) * self.eigvecs #TODO: divide by root eigvals? def pseudo_inverse(self, Y): return Y class Layer(object): def __init__(self, w): self.w = w def filt(self, x): return self.w*x def batches(src, N): # src is a service def rval(me): print 'batches src=', src, 'me=', me return numpy.asarray([gswitch(src, me)[0][0] for i in range(N)]) return rval def print_obj(vm, gself, obj): print obj def no_op(*args, **kwargs): pass def build_pca_trainer(data_src, pca_module, N): return greenlet( batches( N=5, src=inf_data, dest=flow(pca_module.analyze, dest=layer1_trainer))) def main(): dataset = Dataset(numpy.random.RandomState(123).randn(10,2)) prog=repeat(3, [service(dataset.next),service(print_obj)]) vm_run(prog) vm_run(prog) def main_arch(): # create components dataset = Dataset(numpy.random.RandomState(123).randn(10,2)) pca_module = PCA_Analysis() layer1 = Layer(w=4) layer2 = Layer(w=3) kf = KFold(dataset, K=10) # create algorithm train_pca = seq([ np_batch(kf.next, 1000), pca.analyze]) train_layer1 = repeat(100, [kf.next, pca.filt, cd1_update(layer1, lr=.01)]) algo = repeat(10, [ KFold.step, seq([train_pca, train_layer1, train_layer2, train_classifier, save_classifier, test_classifier]), KFold.set_score]) gswitch(algo) def main1(): dataset = Dataset(numpy.random.RandomState(123).randn(10,2)) pca_module = PCA_Analysis() # pca next_data = service(dataset.next) b5 = service(batches(src=next_data, N=5)) print_pca_analyze = flow(pca_module.analyze, dest=sink(print_obj)) # layer1_training layer1_training = driver( fn=cd1_trainer(layer1), srcs=[], ) gswitch(b5, print_pca_analyze) if __name__ == '__main__': sys.exit(main()) def flow(fn, dest): def rval(*args, **kwargs): while True: print 'flow calling', fn.__name__, args, kwargs t = fn(g, *args, **kwargs) args, kwargs = gswitch(dest, t) g = greenlet(rval) return g def sink(fn): def rval(*args, **kwargs): return fn(g, *args, **kwargs) g = greenlet(rval) return g def consumer(fn, src): def rval(*args, **kwargs): while True: fn(gswitch(src, *args, **kwargs)) return greenlet(rval)