def gibbsSamp(
self,
smpls_fn_incl_trls=False): ########################### GIBBSSAMPH
global interrupted
oo = self
signal.signal(signal.SIGINT, signal_handler)
print("****!!!!!!!!!!!!!!!! dohist %s" % str(oo.dohist))
ooTR = oo.TR
ook = oo.k
ooN = oo.N
_kfar.init(oo.N, oo.k, oo.TR)
oo.x00 = _N.array(oo.smpx[:, 2])
oo.V00 = _N.zeros((ooTR, ook, ook))
if oo.dohist:
oo.loghist = _N.zeros(oo.Hbf.shape[0])
else:
print("fixed hist is")
print(oo.loghist)
print("oo.mcmcRunDir %s" % oo.mcmcRunDir)
if oo.mcmcRunDir is None:
oo.mcmcRunDir = ""
elif (len(oo.mcmcRunDir) > 0) and (oo.mcmcRunDir[-1] != "/"):
oo.mcmcRunDir += "/"
ARo = _N.zeros((ooTR, ooN + 1))
kpOws = _N.empty((ooTR, ooN + 1))
lv_f = _N.zeros((ooN + 1, ooN + 1))
lv_u = _N.zeros((ooTR, ooTR))
Bii = _N.zeros((ooN + 1, ooN + 1))
#alpC.reverse()
# F_alfa_rep = alpR + alpC already in right order, no?
Wims = _N.empty((ooTR, ooN + 1, ooN + 1))
Oms = _N.empty((ooTR, ooN + 1))
smWimOm = _N.zeros(ooN + 1)
smWinOn = _N.zeros(ooTR)
bConstPSTH = False
D_f = _N.diag(_N.ones(oo.B.shape[0]) * oo.s2_a) # spline
iD_f = _N.linalg.inv(D_f)
D_u = _N.diag(_N.ones(oo.TR) * oo.s2_u) # This should
iD_u = _N.linalg.inv(D_u)
iD_u_u_u = _N.dot(iD_u, _N.ones(oo.TR) * oo.u_u)
if oo.bpsth:
BDB = _N.dot(oo.B.T, _N.dot(D_f, oo.B))
DB = _N.dot(D_f, oo.B)
BTua = _N.dot(oo.B.T, oo.u_a)
it = -1
oous_rs = oo.us.reshape((ooTR, 1))
#runTO = ooNMC + oo.burn - 1 if (burns is None) else (burns - 1)
runTO = oo.ITERS - 1
oo.allocateSmp(runTO + 1, Bsmpx=oo.doBsmpx)
if cython_arc:
_arcfs.init(ooN + 1 - oo.ignr,
oo.k,
oo.TR,
oo.R,
oo.Cs,
oo.Cn,
aro=_cd.__NF__)
alpR = _N.array(oo.F_alfa_rep[0:oo.R])
alpC = _N.array(oo.F_alfa_rep[oo.R:])
else:
alpR = oo.F_alfa_rep[0:oo.R]
alpC = oo.F_alfa_rep[oo.R:]
BaS = _N.zeros(oo.N + 1) #_N.empty(oo.N+1)
# H shape 100 x 9
Hbf = oo.Hbf
RHS = _N.empty((oo.histknots, 1))
print("----------- histknots %d" % oo.histknots)
cInds = _N.arange(oo.iHistKnotBeginFixed, oo.histknots)
vInds = _N.arange(0, oo.iHistKnotBeginFixed)
#cInds = _N.array([4, 12, 13])
#vInds = _N.array([0, 1, 2, 3, 5, 6, 7, 8, 9, 10, 11, ])
#vInds = _N.arange(0, oo.iHistKnotBeginFixed)
RHS[cInds, 0] = 0
Msts = []
for m in range(ooTR):
Msts.append(_N.where(oo.y[m] == 1)[0])
HcM = _N.ones((len(vInds), len(vInds)))
HbfExpd = _N.zeros((oo.histknots, ooTR, oo.N + 1))
#HbfExpd = _N.zeros((oo.histknots, ooTR, oo.Hbf.shape[0]))
# HbfExpd is 11 x M x 1200
# find the mean. For the HISTORY TERM
for i in range(oo.histknots):
for m in range(oo.TR):
sts = Msts[m]
HbfExpd[i, m, 0:sts[0]] = 0
for iss in range(len(sts) - 1):
t0 = sts[iss]
t1 = sts[iss + 1]
#HbfExpd[i, m, t0+1:t1+1] = Hbf[1:t1-t0+1, i]#Hbf[0:t1-t0, i]
HbfExpd[i, m, t0 + 1:t1 + 1] = Hbf[0:t1 - t0, i]
HbfExpd[i, m, sts[-1] + 1:] = 0
_N.dot(oo.B.T, oo.aS, out=BaS)
if oo.hS is None:
oo.hS = _N.zeros(oo.histknots)
if oo.dohist:
_N.dot(Hbf, oo.hS, out=oo.loghist)
oo.stitch_Hist(ARo, oo.loghist, Msts)
## ORDER OF SAMPLING
## f_xx, f_V
## DA: PG, kpOws
## history, build ARo
## psth
## offset
## DA: latent state
## AR coefficients
## q2
K = _N.empty((oo.TR, oo.N + 1, oo.k)) # kalman gain
iterBLOCKS = oo.ITERS // oo.peek
smpx_C_cont = _N.empty((oo.TR, oo.N + 1, oo.k)) # need C contiguous
# oo.smpx[:, 1+oo.ignr:, 0:ook], oo.smpx[:, oo.ignr:, 0:ook-1]
smpx_contiguous1 = _N.zeros((oo.TR, oo.N + 2, oo.k))
smpx_contiguous2 = _N.zeros((oo.TR, (oo.N + 1) + 2, oo.k - 1))
if (cython_inv_v == 3) or (cython_inv_v == 5):
oo.if_V = _N.array(oo.f_V)
oo.chol_L_fV = _N.array(oo.f_V)
###### Gibbs sampling procedure
ttts = _N.zeros((oo.ITERS, 9))
for itrB in range(iterBLOCKS):
it = itrB * oo.peek
if it > 0:
# 0.5*oo.fs because (dt*2) -> 1 corresponds to Fs/2
print("---------it: %(it)d mnStd %(mnstd).3f" % {
"it": itrB * oo.peek,
"mnstd": oo.mnStds[it - 1]
})
if not oo.noAR:
print(prt)
mnttt = _N.mean(ttts[0:it - 1], axis=0)
for ti in range(9):
print("t%(2)d-t%(1)d %(ttt).4f" % {
"1": ti + 1,
"2": ti + 2,
"ttt": mnttt[ti]
})
if interrupted:
break
for it in range(itrB * oo.peek, (itrB + 1) * oo.peek):
ttt1 = _tm.time()
itstore = it // oo.BsmpxSkp
# generate latent AR state
oo.f_x[:, 0] = oo.x00
if it == 0:
for m in range(ooTR):
oo.f_V[m, 0] = oo.s2_x00
else:
oo.f_V[:, 0] = _N.mean(oo.f_V[:, 1:], axis=1)
### PG latent variable sample
ttt2 = _tm.time()
for m in range(ooTR):
lw.rpg_devroye(oo.rn,
oo.smpx[m, 2:, 0] + oo.us[m] + BaS +
ARo[m] + oo.knownSig[m],
out=oo.ws[m]) ###### devryoe
ttt3 = _tm.time()
if ooTR == 1:
oo.ws = oo.ws.reshape(1, ooN + 1)
_N.divide(oo.kp, oo.ws, out=kpOws)
if oo.dohist:
O = kpOws - oo.smpx[..., 2:, 0] - oo.us.reshape(
(ooTR, 1)) - BaS - oo.knownSig
#print(oo.ws)
# for i in vInds:
# #print("i %d" % i)
# #print(_N.sum(HbfExpd[i]))
# for j in vInds:
# #print("j %d" % j)
# #print(_N.sum(HbfExpd[j]))
# HcM[i-iOf, j-iOf] = _N.sum(oo.ws*HbfExpd[i]*HbfExpd[j])
# RHS[i, 0] = _N.sum(oo.ws*HbfExpd[i]*O)
# for cj in cInds:
# RHS[i, 0] -= _N.sum(oo.ws*HbfExpd[i]*HbfExpd[cj])*RHS[cj, 0]
for ii in range(len(vInds)):
#print("i %d" % i)
#print(_N.sum(HbfExpd[i]))
i = vInds[ii]
for jj in range(len(vInds)):
j = vInds[jj]
#print("j %d" % j)
#print(_N.sum(HbfExpd[j]))
HcM[ii,
jj] = _N.sum(oo.ws * HbfExpd[i] * HbfExpd[j])
RHS[ii, 0] = _N.sum(oo.ws * HbfExpd[i] * O)
for cj in cInds:
RHS[ii, 0] -= _N.sum(
oo.ws * HbfExpd[i] * HbfExpd[cj]) * RHS[cj, 0]
# print("HbfExpd..............................")
# for i in range(oo.histknots):
# print(_N.sum(HbfExpd[i]))
# print("HcM..................................")
# print(HcM)
# print("RHS..................................")
# print(RHS[vInds])
vm = _N.linalg.solve(HcM, RHS[vInds])
Cov = _N.linalg.inv(HcM)
#print vm
#print(Cov)
#print(vm[:, 0])
cfs = _N.random.multivariate_normal(vm[:, 0], Cov, size=1)
RHS[vInds, 0] = cfs[0]
oo.smp_hS[it] = RHS[:, 0]
#RHS[2:6, 0] = vm[:, 0]
#vv = _N.dot(Hbf, RHS)
#print vv.shape
#print oo.loghist.shape
_N.dot(Hbf, RHS[:, 0], out=oo.loghist)
oo.smp_hist[it] = oo.loghist
oo.stitch_Hist(ARo, oo.loghist, Msts)
else:
oo.smp_hist[it] = oo.loghist
oo.stitch_Hist(ARo, oo.loghist, Msts)
# Now that we have PG variables, construct Gaussian timeseries
# ws(it+1) using u(it), F0(it), smpx(it)
# cov matrix, prior of aS
# oo.gau_obs = kpOws - BaS - ARo - oous_rs - oo.knownSig
# oo.gau_var =1 / oo.ws # time dependent noise
ttt4 = _tm.time()
if oo.bpsth:
Oms = kpOws - oo.smpx[..., 2:,
0] - ARo - oous_rs - oo.knownSig
_N.einsum("mn,mn->n", oo.ws, Oms, out=smWimOm) # sum over
ilv_f = _N.diag(_N.sum(oo.ws, axis=0))
# diag(_N.linalg.inv(Bi)) == diag(1./Bi). Bii = inv(Bi)
_N.fill_diagonal(lv_f, 1. / _N.diagonal(ilv_f))
lm_f = _N.dot(lv_f, smWimOm) # nondiag of 1./Bi are inf
# now sample
iVAR = _N.dot(oo.B, _N.dot(ilv_f, oo.B.T)) + iD_f
ttt4a = _tm.time()
VAR = _N.linalg.inv(iVAR) # knots x knots
ttt4b = _tm.time()
#iBDBW = _N.linalg.inv(BDB + lv_f) # BDB not diag
#Mn = oo.u_a + _N.dot(DB, _N.dot(iBDBW, lm_f - BTua))
# BDB + lv_f (N+1 x N+1)
# lm_f - BTua (N+1)
Mn = oo.u_a + _N.dot(
DB, _N.linalg.solve(BDB + lv_f, lm_f - BTua))
#t4c = _tm.time()
oo.aS = _N.random.multivariate_normal(Mn, VAR,
size=1)[0, :]
oo.smp_aS[it] = oo.aS
_N.dot(oo.B.T, oo.aS, out=BaS)
ttt5 = _tm.time()
######## per trial offset sample burns==None, only psth fit
Ons = kpOws - oo.smpx[..., 2:, 0] - ARo - BaS - oo.knownSig
# solve for the mean of the distribution
if not oo.bpsth: # if not doing PSTH, don't constrain offset, as there are no confounds controlling offset
_N.einsum("mn,mn->m", oo.ws, Ons,
out=smWinOn) # sum over trials
ilv_u = _N.diag(_N.sum(oo.ws, axis=1)) # var of LL
# diag(_N.linalg.inv(Bi)) == diag(1./Bi). Bii = inv(Bi)
_N.fill_diagonal(lv_u, 1. / _N.diagonal(ilv_u))
lm_u = _N.dot(
lv_u, smWinOn) # nondiag of 1./Bi are inf, mean LL
# now sample
iVAR = ilv_u + iD_u
VAR = _N.linalg.inv(iVAR) #
Mn = _N.dot(VAR, _N.dot(ilv_u, lm_u) + iD_u_u_u)
oo.us[:] = _N.random.multivariate_normal(Mn, VAR,
size=1)[0, :]
if not oo.bIndOffset:
oo.us[:] = _N.mean(oo.us)
oo.smp_u[it] = oo.us
else:
H = _N.ones((oo.TR - 1, oo.TR - 1)) * _N.sum(oo.ws[0])
uRHS = _N.empty(oo.TR - 1)
for dd in range(1, oo.TR):
H[dd - 1, dd - 1] += _N.sum(oo.ws[dd])
uRHS[dd - 1] = _N.sum(oo.ws[dd] * Ons[dd] -
oo.ws[0] * Ons[0])
MM = _N.linalg.solve(H, uRHS)
Cov = _N.linalg.inv(H)
oo.us[1:] = _N.random.multivariate_normal(MM, Cov, size=1)
oo.us[0] = -_N.sum(oo.us[1:])
if not oo.bIndOffset:
oo.us[:] = _N.mean(oo.us)
oo.smp_u[it] = oo.us
# Ons = kpOws - ARo
# _N.einsum("mn,mn->m", oo.ws, Ons, out=smWinOn) # sum over trials
# ilv_u = _N.diag(_N.sum(oo.ws, axis=1)) # var of LL
# # diag(_N.linalg.inv(Bi)) == diag(1./Bi). Bii = inv(Bi)
# _N.fill_diagonal(lv_u, 1./_N.diagonal(ilv_u))
# lm_u = _N.dot(lv_u, smWinOn) # nondiag of 1./Bi are inf, mean LL
# # now sample
# iVAR = ilv_u + iD_u
# VAR = _N.linalg.inv(iVAR) #
# Mn = _N.dot(VAR, _N.dot(ilv_u, lm_u) + iD_u_u_u)
# oo.us[:] = _N.random.multivariate_normal(Mn, VAR, size=1)[0, :]
# if not oo.bIndOffset:
# oo.us[:] = _N.mean(oo.us)
# oo.smp_u[:, it] = oo.us
ttt6 = _tm.time()
if not oo.noAR:
# _d.F, _d.N, _d.ks,
#_kfar.armdl_FFBS_1itrMP(oo.gau_obs, oo.gau_var, oo.Fs, _N.linalg.inv(oo.Fs), oo.q2, oo.Ns, oo.ks, oo.f_x, oo.f_V, oo.p_x, oo.p_V, oo.smpx, K)
oo.gau_obs = kpOws - BaS - ARo - oous_rs - oo.knownSig
oo.gau_var = 1 / oo.ws # time dependent noise
#print(oo.Fs)
#print(_N.linalg.inv(oo.Fs))
if (cython_inv_v == 2):
_kfar.armdl_FFBS_1itrMP(oo.gau_obs, oo.gau_var, oo.Fs,
_N.linalg.inv(oo.Fs), oo.q2,
oo.Ns, oo.ks, oo.f_x, oo.f_V,
oo.p_x, oo.p_V, smpx_C_cont, K)
else:
_kfar.armdl_FFBS_1itrMP(oo.gau_obs, oo.gau_var, oo.Fs,
_N.linalg.inv(oo.Fs), oo.q2,
oo.Ns, oo.ks, oo.f_x, oo.f_V,
oo.chol_L_fV, oo.if_V, oo.p_x,
oo.p_V, smpx_C_cont, K)
oo.smpx[:, 2:] = smpx_C_cont
oo.smpx[:, 1, 0:ook - 1] = oo.smpx[:, 2, 1:]
oo.smpx[:, 0, 0:ook - 2] = oo.smpx[:, 2, 2:]
if oo.doBsmpx and (it % oo.BsmpxSkp == 0):
oo.Bsmpx[it // oo.BsmpxSkp, :, 2:] = oo.smpx[:, 2:, 0]
#oo.Bsmpx[it // oo.BsmpxSkp, :, 2:] = oo.smpx[:, 2:, 0]
stds = _N.std(oo.smpx[:, 2 + oo.ignr:, 0], axis=1)
oo.mnStds[it] = _N.mean(stds, axis=0)
ttt7 = _tm.time()
#print("..................................")
#print(alpR)
#print(alpC)
#print(alpR)
#print(alpC)
# print(oo.smpx[0, 0:20, 0])
# print(oo.q2)
if cython_arc:
_N.copyto(smpx_contiguous1, oo.smpx[:, 1 + oo.ignr:])
_N.copyto(smpx_contiguous2, oo.smpx[:, oo.ignr:,
0:ook - 1])
#ARcfSmpl(int N, int k, int TR, AR2lims_nmpy, smpxU, smpxW, double[::1] q2, int R, int Cs, int Cn, complex[::1] valpR, complex[::1] valpC, double sig_ph0L, double sig_ph0H, double prR_s2)
oo.uts[itstore], oo.wts[itstore] = _arcfs.ARcfSmpl(
ooN + 1 - oo.ignr, ook, oo.TR, oo.AR2lims,
smpx_contiguous1, smpx_contiguous2, oo.q2, oo.R,
oo.Cs, oo.Cn, alpR, alpC, oo.sig_ph0L, oo.sig_ph0H,
0.2 * 0.2)
else:
oo.uts[itstore], oo.wts[itstore] = _arcfs.ARcfSmpl(
ooN + 1 - oo.ignr,
ook,
oo.AR2lims,
oo.smpx[:, 1 + oo.ignr:, 0:ook],
oo.smpx[:, oo.ignr:, 0:ook - 1],
oo.q2,
oo.R,
oo.Cs,
oo.Cn,
alpR,
alpC,
oo.TR,
aro=oo.ARord,
sig_ph0L=oo.sig_ph0L,
sig_ph0H=oo.sig_ph0H)
#oo.F_alfa_rep = alpR + alpC # new constructed
oo.F_alfa_rep[0:oo.R] = alpR
oo.F_alfa_rep[oo.R:] = alpC
prt, rank, f, amp = ampAngRep(oo.F_alfa_rep,
oo.dt,
f_order=True)
#print(f)
#print(amp)
ttt8 = _tm.time()
#print prt
#ut, wt = FilteredTimeseries(ooN+1, ook, oo.smpx[:, 1:, 0:ook], oo.smpx[:, :, 0:ook-1], oo.q2, oo.R, oo.Cs, oo.Cn, alpR, alpC, oo.TR)
#ranks[it] = rank
oo.allalfas[it] = oo.F_alfa_rep
for m in range(ooTR):
#oo.wts[m, it, :, :] = wt[m, :, :, 0]
#oo.uts[m, it, :, :] = ut[m, :, :, 0]
if not oo.bFixF:
oo.amps[it, :] = amp
oo.fs[it, :] = f
ttt9 = _tm.time()
oo.F0 = (-1 *
_Npp.polyfromroots(oo.F_alfa_rep)[::-1].real)[1:]
for tr in range(oo.TR):
oo.Fs[tr, 0] = oo.F0[:]
# sample u WE USED TO Do this after smpx
# u(it+1) using ws(it+1), F0(it), smpx(it+1), ws(it+1)
oo.a2 = oo.a_q2 + 0.5 * (ooTR * ooN + 2) # N + 1 - 1
#oo.a2 = 0.5*(ooTR*(ooN-oo.ignr) + 2) # N + 1 - 1
BB2 = oo.B_q2
#BB2 = 0
for m in range(ooTR):
# set x00
oo.x00[m] = oo.smpx[m, 2] * 0.1
##################### sample q2
rsd_stp = oo.smpx[m, 3 + oo.ignr:, 0] - _N.dot(
oo.smpx[m, 2 + oo.ignr:-1], oo.F0).T
#oo.rsds[it, m] = _N.dot(rsd_stp, rsd_stp.T)
BB2 += 0.5 * _N.dot(rsd_stp, rsd_stp.T)
oo.q2[:] = _ss.invgamma.rvs(oo.a2, scale=BB2)
oo.smp_q2[it] = oo.q2
ttt10 = _tm.time()
else:
ttt7 = ttt8 = ttt9 = ttt10 = ttt6
ttt10 = _tm.time()
ttts[it, 0] = ttt2 - ttt1
ttts[it, 1] = ttt3 - ttt2
ttts[it, 2] = ttt4 - ttt3
ttts[it, 3] = ttt5 - ttt4
ttts[it, 4] = ttt6 - ttt5
ttts[it, 5] = ttt7 - ttt6
ttts[it, 6] = ttt8 - ttt7
ttts[it, 7] = ttt9 - ttt8
ttts[it, 8] = ttt10 - ttt9
oo.last_iter = it
if it > oo.minITERS:
smps = _N.empty((3, it + 1))
smps[0, :it + 1] = oo.amps[:it + 1, 0]
smps[1, :it + 1] = oo.fs[:it + 1, 0]
smps[2, :it + 1] = oo.mnStds[:it + 1]
#frms = _mg.stationary_from_Z_bckwd(smps, blksz=oo.peek)
if _mg.stationary_test(oo.amps[:it + 1, 0],
oo.fs[:it + 1, 0],
oo.mnStds[:it + 1],
it + 1,
blocksize=oo.mg_blocksize,
points=oo.mg_points):
break
"""
fig = _plt.figure(figsize=(8, 8))
fig.add_subplot(3, 1, 1)
_plt.plot(range(1, it), oo.amps[1:it, 0], color="grey", lw=1.5)
_plt.plot(range(0, it), oo.amps[0:it, 0], color="black", lw=3)
_plt.ylabel("amp")
fig.add_subplot(3, 1, 2)
_plt.plot(range(1, it), oo.fs[1:it, 0]/(2*oo.dt), color="grey", lw=1.5)
_plt.plot(range(0, it), oo.fs[0:it, 0]/(2*oo.dt), color="black", lw=3)
_plt.ylabel("f")
fig.add_subplot(3, 1, 3)
_plt.plot(range(1, it), oo.mnStds[1:it], color="grey", lw=1.5)
_plt.plot(range(0, it), oo.mnStds[0:it], color="black", lw=3)
_plt.ylabel("amp")
_plt.xlabel("iter")
_plt.savefig("%(dir)stmp-fsamps%(it)d" % {"dir" : oo.mcmcRunDir, "it" : it+1})
fig.subplots_adjust(left=0.15, bottom=0.15, right=0.95, top=0.95)
_plt.close()
"""
#if it - frms > oo.stationaryDuration:
# break
oo.getComponents()
oo.dump_smps(0,
toiter=(it + 1),
dir=oo.mcmcRunDir,
smpls_fn_incl_trls=smpls_fn_incl_trls)
def dirichletAllocate(self): ########################### GIBBSSAMP
oo = self
ooTR = oo.TR
print ooTR
ook = oo.k
ooNMC = oo.NMC
ooN = oo.N
oo.allocateSmp(oo.burn + oo.NMC)
oo.x00 = _N.array(oo.smpx[:, 2])
oo.V00 = _N.zeros((ooTR, ook, ook))
ARo = _N.empty((ooTR, oo._d.N + 1))
ARo01 = _N.empty((oo.nStates, ooTR, oo._d.N + 1))
kpOws = _N.empty((ooTR, ooN + 1))
lv_f = _N.zeros((ooN + 1, ooN + 1))
lv_u = _N.zeros((ooTR, ooTR))
Bii = _N.zeros((ooN + 1, ooN + 1))
#alpC.reverse()
# F_alfa_rep = alpR + alpC already in right order, no?
Wims = _N.empty((ooTR, ooN + 1, ooN + 1))
Oms = _N.empty((ooTR, ooN + 1))
smWimOm = _N.zeros(ooN + 1)
smWinOn = _N.zeros(ooTR)
bConstPSTH = False
D_f = _N.diag(_N.ones(oo.B.shape[0]) * oo.s2_a) # spline
iD_f = _N.linalg.inv(D_f)
D_u = _N.diag(_N.ones(oo.TR) * oo.s2_u) # This should
iD_u = _N.linalg.inv(D_u)
iD_u_u_u = _N.dot(iD_u, _N.ones(oo.TR) * oo.u_u)
BDB = _N.dot(oo.B.T, _N.dot(D_f, oo.B))
DB = _N.dot(D_f, oo.B)
BTua = _N.dot(oo.B.T, oo.u_a)
it = 0
oo.lrn = _N.empty((ooTR, ooN + 1))
oo.s_lrn = _N.empty((ooTR, ooN + 1))
oo.sprb = _N.empty((ooTR, ooN + 1))
oo.lrn_scr1 = _N.empty(ooN + 1)
oo.lrn_iscr1 = _N.empty(ooN + 1)
oo.lrn_scr2 = _N.empty(ooN + 1)
oo.lrn_scr3 = _N.empty(ooN + 1)
oo.lrn_scld = _N.empty(ooN + 1)
oo.lrn = _N.empty((ooTR, ooN + 1))
if oo.l2 is None:
oo.lrn[:] = 1
else:
for tr in xrange(ooTR):
oo.lrn[tr] = oo.build_lrnLambda2(tr)
############################### MCMC LOOP ########################
### need pointer to oo.us, but reshaped for broadcasting to work
############################### MCMC LOOP ########################
oous_rs = oo.us.reshape((ooTR, 1)) # done for broadcasting rules
lrnBadLoc = _N.empty((oo.TR, oo.N + 1), dtype=_N.bool)
sd01 = _N.zeros((oo.nStates, oo.TR, oo.TR))
_N.fill_diagonal(sd01[0], oo.s[0])
_N.fill_diagonal(sd01[1], oo.s[1])
smpx01 = _N.zeros((oo.nStates, oo.TR, oo.N + 1))
ARo01 = _N.empty((oo.nStates, oo.TR, oo.N + 1))
zsmpx = _N.empty((oo.TR, oo.N + 1))
# zsmpx created
# PG
zd = _N.zeros((oo.TR, oo.TR))
izd = _N.zeros((oo.TR, oo.TR))
ll = _N.zeros(oo.nStates)
Bp = _N.empty((oo.nStates, oo.N + 1))
for m in xrange(ooTR):
oo._d.f_V[m, 0] = oo.s2_x00
oo._d.f_V[m, 1] = oo.s2_x00
THR = _N.empty(oo.TR)
dirArgs = _N.empty(oo.nStates) # dirichlet distribution args
expT = _N.empty(ooN + 1)
BaS = _N.dot(oo.B.T, oo.aS)
oo.nSMP_smpxC = 0
if oo.processes > 1:
print oo.processes
pool = Pool(processes=oo.processes)
while (it < ooNMC + oo.burn - 1):
lowsts = _N.where(oo.Z[:, 0] == 1)
#print "lowsts %s" % str(lowsts)
t1 = _tm.time()
it += 1
print "****------------ %d" % it
# generate latent AR state
###### Z
#print "!!!!!!!!!!!!!!! 1"
for tryZ in xrange(oo.nStates):
_N.dot(sd01[tryZ], oo.smpx[..., 2:, 0], out=smpx01[tryZ])
#oo.build_addHistory(ARo01[tryZ], smpx01[tryZ, m], BaS, oo.us, lrnBadLoc)
oo.build_addHistory(ARo01[tryZ], smpx01[tryZ], BaS, oo.us,
oo.knownSig)
"""
for m in xrange(oo.TR):
locs = _N.where(lrnBadLoc[m] == True)
if locs[0].shape[0] > 0:
print "found a bad loc"
fig = _plt.figure(figsize=(8, 5))
_plt.suptitle("%d" % m)
_plt.subplot(2, 1, 1)
_plt.plot(smpx01[tryZ, m])
_plt.subplot(2, 1, 2)
_plt.plot(ARo01[tryZ, m])
"""
#print "!!!!!!!!!!!!!!! 2"
for m in oo.varz:
for tryZ in xrange(
oo.nStates): # only allow certain trials to change
# calculate p0, p1 p0 = m_0 x PROD_n Ber(y_n | Z_j)
# = m_0 x _N.exp(_N.log( ))
# p0, p1 not normalized
ll[tryZ] = 0
# Ber(0 | ) and Ber(1 | )
_N.exp(smpx01[tryZ, m] + BaS + ARo01[tryZ, m] + oo.us[m],
out=expT)
Bp[0] = 1 / (1 + expT)
Bp[1] = expT / (1 + expT)
# z[:, 1] is state label
for n in xrange(oo.N + 1):
ll[tryZ] += _N.log(Bp[oo.y[m, n], n])
ofs = _N.min(ll)
ll -= ofs
nc = oo.m[0] * _N.exp(ll[0]) + oo.m[1] * _N.exp(ll[1])
iARo = 1
oo.Z[m, 0] = 0
oo.Z[m, 1] = 1
THR[m] = (oo.m[0] * _N.exp(ll[0]) / nc)
if _N.random.rand() < THR[m]:
oo.Z[m, 0] = 1
oo.Z[m, 1] = 0
iARo = 0
oo.smp_zs[m, it] = oo.Z[m]
#### did we forget to do this?
ARo[m] = ARo01[iARo, m]
for m in oo.fxdz: ##### outside BM loop
oo.smp_zs[m, it] = oo.Z[m]
t2 = _tm.time()
# Z set
_N.fill_diagonal(zd, oo.s[oo.Z[:, 1]])
_N.fill_diagonal(izd, 1. / oo.s[oo.Z[:, 1]])
#for kkk in xrange(oo.TR):
# print zd[kkk, kkk]
_N.dot(zd, oo.smpx[..., 2:, 0], out=zsmpx)
###### sample m's
_N.add(oo.alp, _N.sum(oo.Z[oo.varz], axis=0), out=dirArgs)
oo.m[:] = _N.random.dirichlet(dirArgs)
oo.smp_ms[it] = oo.m
print oo.m
oo.build_addHistory(ARo, zsmpx, BaS, oo.us, oo.knownSig)
t3 = _tm.time()
###### PG generate
nanLoc = _N.where(_N.isnan(BaS))
for m in xrange(ooTR):
lw.rpg_devroye(oo.rn,
zsmpx[m] + oo.us[m] + BaS + ARo[m],
out=oo.ws[m]) ###### devryoe ####TRD change
nanLoc = _N.where(_N.isnan(oo.ws[m]))
if len(nanLoc[0]) > 0:
loc = nanLoc[0][0]
_N.divide(oo.kp, oo.ws, out=kpOws)
######## per trial offset sample
Ons = kpOws - zsmpx - ARo - BaS
_N.einsum("mn,mn->m", oo.ws, Ons, out=smWinOn) # sum over trials
ilv_u = _N.diag(_N.sum(oo.ws, axis=1)) # var of LL
_N.fill_diagonal(lv_u, 1. / _N.diagonal(ilv_u))
lm_u = _N.dot(lv_u, smWinOn) # nondiag of 1./Bi are inf, mean LL
# now sample
iVAR = ilv_u + iD_u
VAR = _N.linalg.inv(iVAR) #
Mn = _N.dot(VAR, _N.dot(ilv_u, lm_u) + iD_u_u_u)
oo.us[:] = _N.random.multivariate_normal(Mn, VAR, size=1)[0, :]
oo.smp_u[:, it] = oo.us
######## PSTH sample Do PSTH after we generate zs
if oo.bpsth:
Oms = kpOws - zsmpx - ARo - oous_rs
_N.einsum("mn,mn->n", oo.ws, Oms, out=smWimOm) # sum over
ilv_f = _N.diag(_N.sum(oo.ws, axis=0))
_N.fill_diagonal(lv_f, 1. / _N.diagonal(ilv_f))
lm_f = _N.dot(lv_f, smWimOm) # nondiag of 1./Bi are inf
# now sample
iVAR = _N.dot(oo.B, _N.dot(ilv_f, oo.B.T)) + iD_f
VAR = _N.linalg.inv(iVAR) # knots x knots
#iBDBW = _N.linalg.inv(BDB + lv_f) # BDB not diag
#Mn = oo.u_a + _N.dot(DB, _N.dot(iBDBW, lm_f - BTua))
Mn = oo.u_a + _N.dot(DB,
_N.linalg.solve(BDB + lv_f, lm_f - BTua))
oo.aS = _N.random.multivariate_normal(Mn, VAR, size=1)[0, :]
oo.smp_aS[it, :] = oo.aS
#iBDBW = _N.linalg.inv(BDB + lv_f) # BDB not diag
#Mn = oo.u_a + _N.dot(DB, _N.dot(iBDBW, lm_f - BTua))
#oo.aS = _N.random.multivariate_normal(Mn, VAR, size=1)[0, :]
#oo.smp_aS[it, :] = oo.aS
else:
oo.aS[:] = 0
BaS = _N.dot(oo.B.T, oo.aS)
t4 = _tm.time()
#### Sample latent state
oo._d.y = _N.dot(izd, kpOws - BaS - ARo - oous_rs)
oo._d.copyParams(oo.F0, oo.q2)
# (MxM) (MxN) = (MxN) (Rv is MxN)
_N.dot(_N.dot(izd, izd), 1. / oo.ws, out=oo._d.Rv)
oo._d.f_x[:, 0, :, 0] = oo.x00
#if it == 1:
for m in xrange(ooTR):
oo._d.f_V[m, 0] = oo.s2_x00
else:
oo._d.f_V[:, 0] = _N.mean(oo._d.f_V[:, 1:], axis=1)
tpl_args = zip(oo._d.y, oo._d.Rv, oo._d.Fs, oo.q2, oo._d.Ns,
oo._d.ks, oo._d.f_x[:, 0], oo._d.f_V[:, 0])
t5 = _tm.time()
if oo.processes == 1:
for m in xrange(ooTR):
oo.smpx[m, 2:], oo._d.f_x[m], oo._d.f_V[
m] = _kfar.armdl_FFBS_1itrMP(tpl_args[m])
oo.smpx[m, 1, 0:ook - 1] = oo.smpx[m, 2, 1:]
oo.smpx[m, 0, 0:ook - 2] = oo.smpx[m, 2, 2:]
oo.smp_q2[m, it] = oo.q2[m]
else:
sxv = pool.map(_kfar.armdl_FFBS_1itrMP, tpl_args)
for m in xrange(ooTR):
oo.smpx[m, 2:] = sxv[m][0]
oo._d.f_x[m] = sxv[m][1]
oo._d.f_V[m] = sxv[m][2]
oo.smpx[m, 1, 0:ook - 1] = oo.smpx[m, 2, 1:]
oo.smpx[m, 0, 0:ook - 2] = oo.smpx[m, 2, 2:]
#oo.Bsmpx[m, it, 2:] = oo.smpx[m, 2:, 0]
stds = _N.std(oo.smpx[:, 2:, 0], axis=1)
oo.mnStds[it] = _N.mean(stds, axis=0)
print "mnStd %.3f" % oo.mnStds[it]
###
lwsts = _N.where(oo.Z[:, 0] == 1)[0]
hists = _N.where(oo.Z[:, 1] == 1)[0]
sts2chg = hists
if (it > oo.startZ) and (len(sts2chg) > 0):
AL = 0.5 * _N.sum(oo.smpx[sts2chg, 2:, 0] *
oo.smpx[sts2chg, 2:, 0] * oo.ws[sts2chg])
BRL = kpOws[sts2chg] - BaS - oous_rs[sts2chg] - ARo[sts2chg]
BL = _N.sum(oo.ws[sts2chg] * BRL * oo.smpx[sts2chg, 2:, 0])
UL = BL / (2 * AL)
sgL = 1 / _N.sqrt(2 * AL)
U = UL
sg = sgL
print "U %(U).3f s %(s).3f" % {"U": U, "s": sg}
oo.s[1] = U + sg * _N.random.randn()
_N.fill_diagonal(sd01[0], oo.s[0])
_N.fill_diagonal(sd01[1], oo.s[1])
print oo.s[1]
oo.smp_ss[it] = oo.s[1]
oo.a2 = oo.a_q2 + 0.5 * (ooTR * ooN + 2) # N + 1 - 1
BB2 = oo.B_q2
for m in xrange(ooTR):
# set x00
#oo.x00[m] = oo.smpx[m, 2]*0.1
oo.x00[m] = oo.smpx[m, 2] * 0.001
##################### sample q2
rsd_stp = oo.smpx[m, 3:, 0] - _N.dot(oo.smpx[m, 2:-1], oo.F0).T
BB2 += 0.5 * _N.dot(rsd_stp, rsd_stp.T)
oo.q2[:] = _ss.invgamma.rvs(oo.a2, scale=BB2)
oo.smp_q2[:, it] = oo.q2
t7 = _tm.time()
print "gibbs iter %.3f" % (t7 - t1)
def gibbsSamp(self): ########################### GIBBSSAMPH
oo = self
print("****!!!!!!!!!!!!!!!! dohist %s" % str(oo.dohist))
ooTR = oo.TR
ook = oo.k
ooN = oo.N
_kfar.init(oo.N, oo.k, oo.TR)
oo.x00 = _N.array(oo.smpx[:, 2])
oo.V00 = _N.zeros((ooTR, ook, ook))
if oo.dohist:
oo.loghist = _N.zeros(oo.N + 1)
else:
print("fixed hist is")
print(oo.loghist)
print("oo.mcmcRunDir %s" % oo.mcmcRunDir)
if oo.mcmcRunDir is None:
oo.mcmcRunDir = ""
elif (len(oo.mcmcRunDir) > 0) and (oo.mcmcRunDir[-1] != "/"):
oo.mcmcRunDir += "/"
ARo = _N.zeros((ooTR, ooN + 1))
kpOws = _N.empty((ooTR, ooN + 1))
lv_f = _N.zeros((ooN + 1, ooN + 1))
lv_u = _N.zeros((ooTR, ooTR))
Bii = _N.zeros((ooN + 1, ooN + 1))
#alpC.reverse()
# F_alfa_rep = alpR + alpC already in right order, no?
Wims = _N.empty((ooTR, ooN + 1, ooN + 1))
Oms = _N.empty((ooTR, ooN + 1))
smWimOm = _N.zeros(ooN + 1)
smWinOn = _N.zeros(ooTR)
bConstPSTH = False
D_f = _N.diag(_N.ones(oo.B.shape[0]) * oo.s2_a) # spline
iD_f = _N.linalg.inv(D_f)
D_u = _N.diag(_N.ones(oo.TR) * oo.s2_u) # This should
iD_u = _N.linalg.inv(D_u)
iD_u_u_u = _N.dot(iD_u, _N.ones(oo.TR) * oo.u_u)
if oo.bpsth:
BDB = _N.dot(oo.B.T, _N.dot(D_f, oo.B))
DB = _N.dot(D_f, oo.B)
BTua = _N.dot(oo.B.T, oo.u_a)
it = -1
oous_rs = oo.us.reshape((ooTR, 1))
#runTO = ooNMC + oo.burn - 1 if (burns is None) else (burns - 1)
runTO = oo.ITERS - 1
oo.allocateSmp(runTO + 1, Bsmpx=oo.doBsmpx)
alpR = oo.F_alfa_rep[0:oo.R]
alpC = oo.F_alfa_rep[oo.R:]
BaS = _N.zeros(oo.N + 1) #_N.empty(oo.N+1)
# H shape 100 x 9
Hbf = oo.Hbf
RHS = _N.empty((oo.histknots, 1))
print("----------- histknots %d" % oo.histknots)
if oo.h0_1 > 1: # no spikes in first few time bins
print("!!!!!!! hist scenario 1")
#cInds = _N.array([0, 1, 5, 6, 7, 8, 9, 10])
#cInds = _N.array([0, 4, 5, 6, 7, 8, 9])
cInds = _N.array([0, 5, 6, 7, 8, 9])
#vInds = _N.array([2, 3, 4])
vInds = _N.array([1, 2, 3, 4])
RHS[cInds, 0] = 0
RHS[0, 0] = -5
elif oo.hist_max_at_0: # no refractory period
print("!!!!!!! hist scenario 2")
#cInds = _N.array([5, 6, 7, 8, 9, 10])
cInds = _N.array([
0,
4,
5,
6,
7,
8,
])
vInds = _N.array([1, 2, 3])
#vInds = _N.array([0, 1, 2, 3, 4])
RHS[cInds, 0] = 0
RHS[0, 0] = 0
else:
print("!!!!!!! hist scenario 3")
#cInds = _N.array([5, 6, 7, 8, 9, 10])
cInds = _N.array([
4,
5,
6,
7,
8,
9,
])
vInds = _N.array([
0,
1,
2,
3,
])
#vInds = _N.array([0, 1, 2, 3, 4])
RHS[cInds, 0] = 0
Msts = []
for m in range(ooTR):
Msts.append(_N.where(oo.y[m] == 1)[0])
HcM = _N.empty((len(vInds), len(vInds)))
HbfExpd = _N.zeros((oo.histknots, ooTR, oo.N + 1))
# HbfExpd is 11 x M x 1200
# find the mean. For the HISTORY TERM
for i in range(oo.histknots):
for m in range(oo.TR):
sts = Msts[m]
HbfExpd[i, m, 0:sts[0]] = 0
for iss in range(len(sts) - 1):
t0 = sts[iss]
t1 = sts[iss + 1]
#HbfExpd[i, m, t0+1:t1+1] = Hbf[1:t1-t0+1, i]#Hbf[0:t1-t0, i]
HbfExpd[i, m, t0 + 1:t1 + 1] = Hbf[0:t1 - t0, i]
HbfExpd[i, m, sts[-1] + 1:] = 0
_N.dot(oo.B.T, oo.aS, out=BaS)
if oo.hS is None:
oo.hS = _N.zeros(oo.histknots)
if oo.dohist:
_N.dot(Hbf, oo.hS, out=oo.loghist)
oo.stitch_Hist(ARo, oo.loghist, Msts)
## ORDER OF SAMPLING
## f_xx, f_V
## DA: PG, kpOws
## history, build ARo
## psth
## offset
## DA: latent state
## AR coefficients
## q2
K = _N.empty((oo.TR, oo.N + 1, oo.k)) # kalman gain
iterBLOCKS = oo.ITERS // oo.peek
smpx_tmp = _N.empty((oo.TR, oo.N + 1, oo.k))
###### Gibbs sampling procedure
for itrB in range(iterBLOCKS):
it = itrB * oo.peek
if it > 0:
print("it: %(it)d mnStd %(mnstd).3f" % {
"it": itrB * oo.peek,
"mnstd": oo.mnStds[it - 1]
})
#tttA = _tm.time()
for it in range(itrB * oo.peek, (itrB + 1) * oo.peek):
#ttt1 = _tm.time()
# generate latent AR state
oo.f_x[:, 0] = oo.x00
if it == 0:
for m in range(ooTR):
oo.f_V[m, 0] = oo.s2_x00
else:
oo.f_V[:, 0] = _N.mean(oo.f_V[:, 1:], axis=1)
### PG latent variable sample
#ttt2 = _tm.time()
for m in range(ooTR):
lw.rpg_devroye(oo.rn,
oo.smpx[m, 2:, 0] + oo.us[m] + BaS +
ARo[m] + oo.knownSig[m],
out=oo.ws[m]) ###### devryoe
#ttt3 = _tm.time()
if ooTR == 1:
oo.ws = oo.ws.reshape(1, ooN + 1)
_N.divide(oo.kp, oo.ws, out=kpOws)
if oo.dohist:
O = kpOws - oo.smpx[..., 2:, 0] - oo.us.reshape(
(ooTR, 1)) - BaS - oo.knownSig
if it == 2000:
_N.savetxt("it2000.dat", O)
iOf = vInds[0] # offset HcM index with RHS index.
#print(oo.ws)
for i in vInds:
#print("i %d" % i)
#print(_N.sum(HbfExpd[i]))
for j in vInds:
#print("j %d" % j)
#print(_N.sum(HbfExpd[j]))
HcM[i - iOf, j - iOf] = _N.sum(oo.ws * HbfExpd[i] *
HbfExpd[j])
RHS[i, 0] = _N.sum(oo.ws * HbfExpd[i] * O)
for cj in cInds:
RHS[i, 0] -= _N.sum(
oo.ws * HbfExpd[i] * HbfExpd[cj]) * RHS[cj, 0]
# print("HbfExpd..............................")
# print(HbfExpd)
# print("HcM..................................")
# print(HcM)
# print("RHS..................................")
# print(RHS[vInds])
vm = _N.linalg.solve(HcM, RHS[vInds])
Cov = _N.linalg.inv(HcM)
#print vm
#print(Cov)
#print(vm[:, 0])
cfs = _N.random.multivariate_normal(vm[:, 0], Cov, size=1)
RHS[vInds, 0] = cfs[0]
oo.smp_hS[:, it] = RHS[:, 0]
#RHS[2:6, 0] = vm[:, 0]
#vv = _N.dot(Hbf, RHS)
#print vv.shape
#print oo.loghist.shape
_N.dot(Hbf, RHS[:, 0], out=oo.loghist)
oo.smp_hist[:, it] = oo.loghist
oo.stitch_Hist(ARo, oo.loghist, Msts)
else:
oo.smp_hist[:, it] = oo.loghist
oo.stitch_Hist(ARo, oo.loghist, Msts)
# Now that we have PG variables, construct Gaussian timeseries
# ws(it+1) using u(it), F0(it), smpx(it)
# cov matrix, prior of aS
# oo.gau_obs = kpOws - BaS - ARo - oous_rs - oo.knownSig
# oo.gau_var =1 / oo.ws # time dependent noise
#ttt4 = _tm.time()
if oo.bpsth:
Oms = kpOws - oo.smpx[..., 2:,
0] - ARo - oous_rs - oo.knownSig
_N.einsum("mn,mn->n", oo.ws, Oms, out=smWimOm) # sum over
ilv_f = _N.diag(_N.sum(oo.ws, axis=0))
# diag(_N.linalg.inv(Bi)) == diag(1./Bi). Bii = inv(Bi)
_N.fill_diagonal(lv_f, 1. / _N.diagonal(ilv_f))
lm_f = _N.dot(lv_f, smWimOm) # nondiag of 1./Bi are inf
# now sample
iVAR = _N.dot(oo.B, _N.dot(ilv_f, oo.B.T)) + iD_f
#ttt4a = _tm.time()
VAR = _N.linalg.inv(iVAR) # knots x knots
#ttt4b = _tm.time()
#iBDBW = _N.linalg.inv(BDB + lv_f) # BDB not diag
#Mn = oo.u_a + _N.dot(DB, _N.dot(iBDBW, lm_f - BTua))
# BDB + lv_f (N+1 x N+1)
# lm_f - BTua (N+1)
Mn = oo.u_a + _N.dot(
DB, _N.linalg.solve(BDB + lv_f, lm_f - BTua))
#t4c = _tm.time()
oo.aS = _N.random.multivariate_normal(Mn, VAR,
size=1)[0, :]
oo.smp_aS[it, :] = oo.aS
_N.dot(oo.B.T, oo.aS, out=BaS)
#ttt5 = _tm.time()
######## per trial offset sample burns==None, only psth fit
Ons = kpOws - oo.smpx[..., 2:, 0] - ARo - BaS - oo.knownSig
# solve for the mean of the distribution
if not oo.bpsth: # if not doing PSTH, don't constrain offset, as there are no confounds controlling offset
_N.einsum("mn,mn->m", oo.ws, Ons,
out=smWinOn) # sum over trials
ilv_u = _N.diag(_N.sum(oo.ws, axis=1)) # var of LL
# diag(_N.linalg.inv(Bi)) == diag(1./Bi). Bii = inv(Bi)
_N.fill_diagonal(lv_u, 1. / _N.diagonal(ilv_u))
lm_u = _N.dot(
lv_u, smWinOn) # nondiag of 1./Bi are inf, mean LL
# now sample
iVAR = ilv_u + iD_u
VAR = _N.linalg.inv(iVAR) #
Mn = _N.dot(VAR, _N.dot(ilv_u, lm_u) + iD_u_u_u)
oo.us[:] = _N.random.multivariate_normal(Mn, VAR,
size=1)[0, :]
if not oo.bIndOffset:
oo.us[:] = _N.mean(oo.us)
oo.smp_u[:, it] = oo.us
else:
H = _N.ones((oo.TR - 1, oo.TR - 1)) * _N.sum(oo.ws[0])
uRHS = _N.empty(oo.TR - 1)
for dd in range(1, oo.TR):
H[dd - 1, dd - 1] += _N.sum(oo.ws[dd])
uRHS[dd - 1] = _N.sum(oo.ws[dd] * Ons[dd] -
oo.ws[0] * Ons[0])
MM = _N.linalg.solve(H, uRHS)
Cov = _N.linalg.inv(H)
oo.us[1:] = _N.random.multivariate_normal(MM, Cov, size=1)
oo.us[0] = -_N.sum(oo.us[1:])
if not oo.bIndOffset:
oo.us[:] = _N.mean(oo.us)
oo.smp_u[:, it] = oo.us
# Ons = kpOws - ARo
# _N.einsum("mn,mn->m", oo.ws, Ons, out=smWinOn) # sum over trials
# ilv_u = _N.diag(_N.sum(oo.ws, axis=1)) # var of LL
# # diag(_N.linalg.inv(Bi)) == diag(1./Bi). Bii = inv(Bi)
# _N.fill_diagonal(lv_u, 1./_N.diagonal(ilv_u))
# lm_u = _N.dot(lv_u, smWinOn) # nondiag of 1./Bi are inf, mean LL
# # now sample
# iVAR = ilv_u + iD_u
# VAR = _N.linalg.inv(iVAR) #
# Mn = _N.dot(VAR, _N.dot(ilv_u, lm_u) + iD_u_u_u)
# oo.us[:] = _N.random.multivariate_normal(Mn, VAR, size=1)[0, :]
# if not oo.bIndOffset:
# oo.us[:] = _N.mean(oo.us)
# oo.smp_u[:, it] = oo.us
#ttt6 = _tm.time()
if not oo.noAR:
# _d.F, _d.N, _d.ks,
#_kfar.armdl_FFBS_1itrMP(oo.gau_obs, oo.gau_var, oo.Fs, _N.linalg.inv(oo.Fs), oo.q2, oo.Ns, oo.ks, oo.f_x, oo.f_V, oo.p_x, oo.p_V, oo.smpx, K)
oo.gau_obs = kpOws - BaS - ARo - oous_rs - oo.knownSig
oo.gau_var = 1 / oo.ws # time dependent noise
_kfar.armdl_FFBS_1itrMP(oo.gau_obs, oo.gau_var, oo.Fs,
_N.linalg.inv(oo.Fs), oo.q2, oo.Ns,
oo.ks, oo.f_x, oo.f_V, oo.p_x,
oo.p_V, smpx_tmp, K)
oo.smpx[:, 2:] = smpx_tmp
oo.smpx[:, 1, 0:ook - 1] = oo.smpx[:, 2, 1:]
oo.smpx[:, 0, 0:ook - 2] = oo.smpx[:, 2, 2:]
if oo.doBsmpx and (it % oo.BsmpxSkp == 0):
oo.Bsmpx[:, it // oo.BsmpxSkp, 2:] = oo.smpx[:, 2:, 0]
#oo.Bsmpx[it // oo.BsmpxSkp, :, 2:] = oo.smpx[:, 2:, 0]
stds = _N.std(oo.smpx[:, 2 + oo.ignr:, 0], axis=1)
oo.mnStds[it] = _N.mean(stds, axis=0)
#ttt7 = _tm.time()
if not oo.bFixF:
#ARcfSmpl(oo.lfc, ooN+1-oo.ignr, ook, oo.AR2lims, oo.smpx[:, 1+oo.ignr:, 0:ook], oo.smpx[:, oo.ignr:, 0:ook-1], oo.q2, oo.R, oo.Cs, oo.Cn, alpR, alpC, oo.TR, prior=oo.use_prior, accepts=8, aro=oo.ARord, sig_ph0L=oo.sig_ph0L, sig_ph0H=oo.sig_ph0H)
ARcfSmpl(ooN + 1 - oo.ignr,
ook,
oo.AR2lims,
oo.smpx[:, 1 + oo.ignr:, 0:ook],
oo.smpx[:, oo.ignr:, 0:ook - 1],
oo.q2,
oo.R,
oo.Cs,
oo.Cn,
alpR,
alpC,
oo.TR,
prior=oo.use_prior,
accepts=8,
aro=oo.ARord,
sig_ph0L=oo.sig_ph0L,
sig_ph0H=oo.sig_ph0H)
oo.F_alfa_rep = alpR + alpC # new constructed
prt, rank, f, amp = ampAngRep(oo.F_alfa_rep,
f_order=True)
#print prt
#ut, wt = FilteredTimeseries(ooN+1, ook, oo.smpx[:, 1:, 0:ook], oo.smpx[:, :, 0:ook-1], oo.q2, oo.R, oo.Cs, oo.Cn, alpR, alpC, oo.TR)
#ranks[it] = rank
oo.allalfas[it] = oo.F_alfa_rep
for m in range(ooTR):
#oo.wts[m, it, :, :] = wt[m, :, :, 0]
#oo.uts[m, it, :, :] = ut[m, :, :, 0]
if not oo.bFixF:
oo.amps[it, :] = amp
oo.fs[it, :] = f
oo.F0 = (-1 *
_Npp.polyfromroots(oo.F_alfa_rep)[::-1].real)[1:]
for tr in range(oo.TR):
oo.Fs[tr, 0] = oo.F0[:]
# sample u WE USED TO Do this after smpx
# u(it+1) using ws(it+1), F0(it), smpx(it+1), ws(it+1)
oo.a2 = oo.a_q2 + 0.5 * (ooTR * ooN + 2) # N + 1 - 1
#oo.a2 = 0.5*(ooTR*(ooN-oo.ignr) + 2) # N + 1 - 1
BB2 = oo.B_q2
#BB2 = 0
for m in range(ooTR):
# set x00
oo.x00[m] = oo.smpx[m, 2] * 0.1
##################### sample q2
rsd_stp = oo.smpx[m, 3 + oo.ignr:, 0] - _N.dot(
oo.smpx[m, 2 + oo.ignr:-1], oo.F0).T
#oo.rsds[it, m] = _N.dot(rsd_stp, rsd_stp.T)
BB2 += 0.5 * _N.dot(rsd_stp, rsd_stp.T)
oo.q2[:] = _ss.invgamma.rvs(oo.a2, scale=BB2)
oo.smp_q2[:, it] = oo.q2
#ttt8 = _tm.time()
# print("--------------------------------")
# print ("t2-t1 %.4f" % (#ttt2-#ttt1))
# print ("t3-t2 %.4f" % (#ttt3-#ttt2))
# print ("t4-t3 %.4f" % (#ttt4-#ttt3))
# # print ("t4b-t4a %.4f" % (t4b-t4a))
# # print ("t4c-t4b %.4f" % (t4c-t4b))
# # print ("t4-t4c %.4f" % (t4-t4c))
# print ("t5-t4 %.4f" % (#ttt5-#ttt4))
# print ("t6-t5 %.4f" % (#ttt6-#ttt5))
# print ("t7-t6 %.4f" % (#ttt7-#ttt6))
# print ("t8-t7 %.4f" % (#ttt8-#ttt7))
#tttB = _tm.time()
#print("#tttB - #tttA %.4f" % (#tttB - #tttA))
oo.last_iter = it
if it > oo.minITERS:
smps = _N.empty((3, it + 1))
smps[0, :it + 1] = oo.amps[:it + 1, 0]
smps[1, :it + 1] = oo.fs[:it + 1, 0]
smps[2, :it + 1] = oo.mnStds[:it + 1]
#frms = _mg.stationary_from_Z_bckwd(smps, blksz=oo.peek)
if _mg.stationary_test(oo.amps[:it + 1, 0],
oo.fs[:it + 1, 0],
oo.mnStds[:it + 1],
it + 1,
blocksize=oo.mg_blocksize,
points=oo.mg_points):
break
"""
fig = _plt.figure(figsize=(8, 8))
fig.add_subplot(3, 1, 1)
_plt.plot(range(1, it), oo.amps[1:it, 0], color="grey", lw=1.5)
_plt.plot(range(0, it), oo.amps[0:it, 0], color="black", lw=3)
_plt.ylabel("amp")
fig.add_subplot(3, 1, 2)
_plt.plot(range(1, it), oo.fs[1:it, 0]/(2*oo.dt), color="grey", lw=1.5)
_plt.plot(range(0, it), oo.fs[0:it, 0]/(2*oo.dt), color="black", lw=3)
_plt.ylabel("f")
fig.add_subplot(3, 1, 3)
_plt.plot(range(1, it), oo.mnStds[1:it], color="grey", lw=1.5)
_plt.plot(range(0, it), oo.mnStds[0:it], color="black", lw=3)
_plt.ylabel("amp")
_plt.xlabel("iter")
_plt.savefig("%(dir)stmp-fsamps%(it)d" % {"dir" : oo.mcmcRunDir, "it" : it+1})
fig.subplots_adjust(left=0.15, bottom=0.15, right=0.95, top=0.95)
_plt.close()
"""
#if it - frms > oo.stationaryDuration:
# break
oo.dump_smps(0, toiter=(it + 1), dir=oo.mcmcRunDir)
oo.VIS = ARo # to examine this from outside
def sample_posterior(self,
ITER,
a_F0,
b_F0,
a_q2,
B_q2,
smp_Bns,
smp_offsets,
smp_F0s,
smp_q2s,
off_mu=0,
off_sig2=0.4,
random_walk=False):
w1_px = _N.random.randn(Tm1)
w1_pV = _N.ones(Tm1) * 0.2
w1_fx = _N.zeros(Tm1)
w1_fV = _N.ones(Tm1) * 0.1
w2_px = _N.random.randn(Tm1)
w2_pV = _N.random.rand(Tm1)
w2_fx = _N.zeros(Tm1)
w2_fV = _N.ones(Tm1) * 0.1
t1_px = _N.random.randn(Tm1)
t1_pV = _N.ones(Tm1) * 0.2
t1_fx = _N.zeros(Tm1)
t1_fV = _N.ones(Tm1) * 0.1
t2_px = _N.random.randn(Tm1)
t2_pV = _N.random.rand(Tm1)
t2_fx = _N.zeros(Tm1)
t2_fV = _N.ones(Tm1) * 0.1
l1_px = _N.random.randn(Tm1)
l1_pV = _N.ones(Tm1) * 0.2
l1_fx = _N.zeros(Tm1)
l1_fV = _N.ones(Tm1) * 0.1
l2_px = _N.random.randn(Tm1)
l2_pV = _N.random.rand(Tm1)
l2_fx = _N.zeros(Tm1)
l2_fV = _N.ones(Tm1) * 0.1
w1_K = _N.empty(Tm1)
t1_K = _N.empty(Tm1)
l1_K = _N.empty(Tm1)
w2_K = _N.empty(Tm1)
t2_K = _N.empty(Tm1)
l2_K = _N.empty(Tm1)
o_w1 = _N.random.randn(Tm1) # start at 0 + u
o_t1 = _N.random.randn(Tm1) # start at 0 + u
o_l1 = _N.random.randn(Tm1) # start at 0 + u
o_w2 = _N.random.randn(Tm1) # start at 0 + u
o_t2 = _N.random.randn(Tm1) # start at 0 + u
o_l2 = _N.random.randn(Tm1) # start at 0 + u
B1wn = _N.random.randn(Tm1) # start at 0 + u
B1tn = _N.random.randn(Tm1) # start at 0 + u
B1ln = _N.random.randn(Tm1) # start at 0 + u
B2wn = _N.random.randn(Tm1) # start at 0 + u
B2tn = _N.random.randn(Tm1) # start at 0 + u
B2ln = _N.random.randn(Tm1) # start at 0 + u
q2_Bw1 = 1.
q2_Bt1 = 1.
q2_Bl1 = 1.
q2_Bw2 = 1.
q2_Bt2 = 1.
q2_Bl2 = 1.
F0_Bw1 = 0
F0_Bt1 = 0
F0_Bl1 = 0
F0_Bw2 = 0
F0_Bt2 = 0
F0_Bl2 = 0
ws1 = _N.random.rand(Tm1)
ws2 = _N.random.rand(Tm1)
zr2 = _N.where(
N_vec[:, 1] == 0)[0] # dat where N_2 == 0 (only 1 PG var)
nzr2 = _N.where(N_vec[:, 1] == 1)[0]
W_n = _N.zeros(Tm1, dtype=_N.int)
T_n = _N.zeros(Tm1, dtype=_N.int)
L_n = _N.zeros(Tm1, dtype=_N.int)
if covariates == _WTL:
win = _N.where(hnd_dat[0:Tm1, 2] == 1)[0]
tie = _N.where(hnd_dat[0:Tm1, 2] == 0)[0]
los = _N.where(hnd_dat[0:Tm1, 2] == -1)[0]
elif covariates == _RPS:
win = _N.where(hnd_dat[0:Tm1, 0] == 1)[0]
tie = _N.where(hnd_dat[0:Tm1, 0] == 2)[0]
los = _N.where(hnd_dat[0:Tm1, 0] == 3)[0]
W_n[win] = 1
T_n[win] = -1
L_n[win] = -1
#
W_n[tie] = -1
T_n[tie] = 1
L_n[tie] = -1
#
W_n[los] = -1
T_n[los] = -1
L_n[los] = -1
K = 3
N_vec = _N.zeros((Tm1, K), dtype=_N.int) # The N vector
N = 1
kappa = _N.empty((Tm1, K))
# hand n, n-1 ---> obs of
# 1 < 2 R < P 1%3 < 2%3 1 < 2
# 2 < 3 P < S 2%3 < 3%3 2 < 3
# 3 < 1 S < R 3%3 < 1%3 0 < 1
if signal == _RELATIVE_LAST_ME:
col_n0 = 0 # current
col_n1 = 0 # previous
elif signal == _RELATIVE_LAST_AI:
col_n0 = 0 # did player copy AI's last move
col_n1 = 1 # or did player go to move that beat (loses) to the last AI
elif signal == _RELATIVE_LAST_OU:
col_n0 = 0 # did player copy AI's last move
col_n1 = 2 # or did player go to move that beat (loses) to the last AI
# RELATIVE LAST ME - stay or switch (2 types of switch)
# RELATIVE LAST AI - copy AI or
y_vec = _N.zeros((Tm1, 3), dtype=_N.int)
y = _N.zeros(Tm1, dtype=_N.int) # indices of the random var
for n in range(1, Tobs):
if signal != _RELATIVE_LAST_OU:
if (hnd_dat[n, col_n0] == hnd_dat[n - 1, col_n1]):
y[n - 1] = 0 # Goo, choki, paa goo->choki
# choki->paa
y_vec[n - 1, 0] = 1 # [1, 0, 0] stay
elif ((hnd_dat[n, col_n0] == 1) and (hnd_dat[n-1, col_n1] == 3)) or \
((hnd_dat[n, col_n0] == 2) and (hnd_dat[n-1, col_n1] == 1)) or \
((hnd_dat[n, col_n0] == 3) and (hnd_dat[n-1, col_n1] == 2)):
y[n - 1] = -1
y_vec[n - 1, 1] = 1 # [0, 1, 0] choose weaker
elif ((hnd_dat[n, col_n0] == 1) and (hnd_dat[n-1, col_n1] == 2)) or \
((hnd_dat[n, col_n0] == 2) and (hnd_dat[n-1, col_n1] == 3)) or \
((hnd_dat[n, col_n0] == 3) and (hnd_dat[n-1, col_n1] == 1)):
y[n - 1] = 1
y_vec[n - 1, 2] = 1 # [0, 0, 1] choose stronger
else:
if (hnd_dat[n, col_n1] == 1): # win
y[n - 1] = 1
y_vec[n - 1, 0] = 1 # [1, 0, 0] stay
elif (hnd_dat[n, col_n1] == 0): # tie
y[n - 1] = 0
y_vec[n - 1, 1] = 1 # [0, 1, 0] stay
elif (hnd_dat[n, col_n1] == -1): # los
y[n - 1] = -1
y_vec[n - 1, 2] = 1 # [0, 0, 1] stay
for n in range(Tm1):
N_vec[n, 0] = 1
for k in range(1, K):
N_vec[n, k] = N - _N.sum(y_vec[n, 0:k])
for k in range(K):
kappa[n, k] = y_vec[n, k] - 0.5 * N_vec[n, k]
print("3")
smp_offsets = _N.empty((6, ITER, Tm1))
smp_Bns = _N.empty((6, ITER, Tm1))
smp_q2s = _N.empty((ITER, 6))
smp_F0s = _N.empty((ITER, 6))
#_d.copyData(_N.empty(N), _N.empty(N), onetrial=True) # dummy data copied
off_sig2 = 0.4
off_mu = 0
o_w1[:] = 0
o_t1[:] = 0
o_l1[:] = 0
o_w2[:] = 0
o_t2[:] = 0
o_l2[:] = 0
do_order = _N.arange(6)
for it in range(ITER):
if it % 1000 == 0:
print("%(it)d capped %(cp)d" % {"it": it, "cp": capped})
vrncL1 = 1 / _N.sum(ws1)
vrnc1 = (off_sig2 * vrncL1) / (off_sig2 + vrncL1)
vrncL2 = 1 / _N.sum(ws2)
vrnc2 = (off_sig2 * vrncL2) / (off_sig2 + vrncL2)
_N.random.shuffle(do_order)
for di in do_order:
#################
if di == 0:
o_w1, F0_Bw1, q2_Bw1 = sampleAR_and_offset(
it, Tm1, vrnc1, vrncL1, B1wn, W_n, o_w1, B1tn, T_n,
o_t1, B1ln, L_n, o_l1, kappa[:, 0], ws1, q2_Bw1, a_F0,
b_F0, a_q2, B_q2, w1_px, w1_pV, w1_fx, w1_fV, w1_K,
random_walk)
smp_offsets[0, it] = o_w1[0]
elif di == 1:
#################
o_t1, F0_Bt1, q2_Bt1 = sampleAR_and_offset(
it, Tm1, vrnc1, vrncL1, B1tn, T_n, o_t1, B1ln, L_n,
o_l1, B1wn, W_n, o_w1, kappa[:, 0], ws1, q2_Bt1, a_F0,
b_F0, a_q2, B_q2, t1_px, t1_pV, t1_fx, t1_fV, t1_K,
random_walk)
smp_offsets[1, it] = o_t1[0]
elif di == 2:
#################
o_l1, F0_Bl1, q2_Bl1 = sampleAR_and_offset(
it, Tm1, vrnc1, vrncL1, B1ln, L_n, o_l1, B1wn, W_n,
o_w1, B1tn, T_n, o_t1, kappa[:, 0], ws1, q2_Bl1, a_F0,
b_F0, a_q2, B_q2, l1_px, l1_pV, l1_fx, l1_fV, l1_K,
random_walk)
smp_offsets[2, it] = o_l1[0]
elif di == 3:
#################
o_w2, F0_Bw2, q2_Bw2 = sampleAR_and_offset(
it, Tm1, vrnc2, vrncL2, B2wn, W_n, o_w2, B2tn, T_n,
o_t2, B2ln, L_n, o_l2, kappa[:, 1], ws2, q2_Bw2, a_F0,
b_F0, a_q2, B_q2, w2_px, w2_pV, w2_fx, w2_fV, w2_K,
random_walk)
smp_offsets[3, it] = o_w2[0]
elif di == 4:
#################
o_t2, F0_Bt2, q2_Bt2 = sampleAR_and_offset(
it, Tm1, vrnc2, vrncL2, B2tn, T_n, o_t2, B2ln, L_n,
o_l2, B2wn, W_n, o_w2, kappa[:, 1], ws2, q2_Bt2, a_F0,
b_F0, a_q2, B_q2, t2_px, t2_pV, t2_fx, t2_fV, t2_K,
random_walk)
smp_offsets[4, it] = o_t2[0]
elif di == 5:
#################
o_l2, F0_Bl2, q2_Bl2 = sampleAR_and_offset(
it, Tm1, vrnc2, vrncL2, B2ln, L_n, o_l2, B2wn, W_n,
o_w2, B2tn, T_n, o_t2, kappa[:, 1], ws2, q2_Bl2, a_F0,
b_F0, a_q2, B_q2, l2_px, l2_pV, l2_fx, l2_fV, l2_K,
random_walk)
smp_offsets[5, it] = o_l2[0]
smp_Bns[0, it] = B1wn
smp_Bns[1, it] = B1tn
smp_Bns[2, it] = B1ln
smp_Bns[3, it] = B2wn
smp_Bns[4, it] = B2tn
smp_Bns[5, it] = B2ln
smp_q2s[it] = q2_Bw1, q2_Bt1, q2_Bl1, q2_Bw2, q2_Bt2, q2_Bl2
#if random_walk:
# F0_Bw1 = F0_Bt1 = F0_Bl1 = F0_Bw2 = F0_Bt2 = F0_Bl2 = 1
smp_F0s[it] = F0_Bw1, F0_Bt1, F0_Bl1, F0_Bw2, F0_Bt2, F0_Bl2
lw.rpg_devroye(N_vec[:, 0],
o_w1 * W_n + o_t1 * T_n + o_l1 * L_n,
out=ws1)
lw.rpg_devroye(N_vec[:, 1],
o_w2 * W_n + o_t2 * T_n + o_l2 * L_n,
out=ws2)
ws2[zr2] = 1e-20 #1e-20
pklme = {}
smp_every = 50
pklme["smp_Bns"] = smp_Bns[:, ::smp_every]
pklme["smp_q2s"] = smp_q2s[::smp_every]
pklme["smp_F0s"] = smp_F0s[::smp_every]
pklme["smp_offsets"] = smp_offsets[:, ::smp_every]
pklme["smp_every"] = smp_every
pklme["Wn"] = W_n
pklme["Tn"] = T_n
pklme["Ln"] = L_n
pklme["hnd_dat"] = hnd_dat
pklme["y_vec"] = y_vec
pklme["N_vec"] = N_vec
pklme["a_q2"] = a_q2
pklme["B_q2"] = B_q2
pklme["l_capped"] = l_capped
dmp = open(
"%(dir)s/%(rel)s,%(cov)s%(ran)s2.dmp" % {
"rel": ssig,
"cov": scov,
"ran": sran,
"dir": out_dir
}, "wb")
pickle.dump(pklme, dmp, -1)
dmp.close()
print("capped: %d" % capped)
def sample_posterior(self,
ITER,
a_F0,
b_F0,
a_q2,
B_q2,
smp_Bns,
smp_offsets,
smp_F0s,
smp_q2s,
off_mu=0,
off_sig2=0.4,
random_walk=False):
oo = self
w1_px = _N.random.randn(oo.Tm1)
w1_pV = _N.ones(oo.Tm1) * 0.2
w1_fx = _N.zeros(oo.Tm1)
w1_fV = _N.ones(oo.Tm1) * 0.1
w2_px = _N.random.randn(oo.Tm1)
w2_pV = _N.random.rand(oo.Tm1)
w2_fx = _N.zeros(oo.Tm1)
w2_fV = _N.ones(oo.Tm1) * 0.1
w1_K = _N.empty(oo.Tm1)
w2_K = _N.empty(oo.Tm1)
o_w1 = _N.random.randn(oo.Tm1) # start at 0 + u
o_w2 = _N.random.randn(oo.Tm1) # start at 0 + u
B1wn = _N.random.randn(oo.Tm1) # start at 0 + u
B2wn = _N.random.randn(oo.Tm1) # start at 0 + u
q2_Bw1 = 1.
q2_Bw2 = 1.
F0_Bw1 = 0
F0_Bw2 = 0
ws1 = _N.random.rand(oo.Tm1)
ws2 = _N.random.rand(oo.Tm1)
zr2 = _N.where(
oo.N_vec[:, 1] == 0)[0] # dat where N_2 == 0 (only 1 PG var)
nzr2 = _N.where(oo.N_vec[:, 1] == 1)[0]
do_order = _N.arange(2)
for it in range(ITER):
if it % 1000 == 0:
print("%(it)d capped %(cp)d" % {"it": it, "cp": capped})
vrncL1 = 1 / _N.sum(ws1)
vrnc1 = (off_sig2 * vrncL1) / (off_sig2 + vrncL1)
vrncL2 = 1 / _N.sum(ws2)
vrnc2 = (off_sig2 * vrncL2) / (off_sig2 + vrncL2)
_N.random.shuffle(do_order)
for di in do_order:
#################
if di == 0:
o_w1, F0_Bw1, q2_Bw1 \
= sampleAR1_and_offset(it, oo.Tm1, off_mu, off_sig2,
vrnc1, vrncL1,B1wn, o_w1,
oo.kappa[:, 0], ws1, q2_Bw1,
a_F0, b_F0, a_q2, B_q2,
w1_px, w1_pV, w1_fx, w1_fV,
w1_K, random_walk)
smp_offsets[0, it] = o_w1
elif di == 1:
#################
o_w2, F0_Bw2, q2_Bw2 \
= sampleAR1_and_offset(it, oo.Tm1, off_mu, off_sig2,
vrnc2, vrncL2, B2wn, o_w2,
oo.kappa[:, 1], ws2, q2_Bw2,
a_F0, b_F0, a_q2, B_q2,
w2_px, w2_pV, w2_fx, w2_fV,
w2_K, random_walk)
smp_offsets[1, it] = o_w2
smp_Bns[0, it] = B1wn
smp_Bns[1, it] = B2wn
#smp_q2s[it, 2*cond:2*cond+2] = q2_Bw1, q2_Bw2y
smp_q2s[it] = q2_Bw1, q2_Bw2
#if random_walk:
# F0_Bw1 = F0_Bt1 = F0_Bl1 = F0_Bw2 = F0_Bt2 = F0_Bl2 = 1
smp_F0s[it] = F0_Bw1, F0_Bw2
lw.rpg_devroye(oo.N_vec[:, 0], B1wn + o_w1, out=ws1)
lw.rpg_devroye(oo.N_vec[:, 1], B2wn + o_w2, out=ws2)
ws2[zr2] = 1e-20 #1e-20
print(smp_F0s[:, 0])
print(smp_F0s[:, 1])
def dirichletAllocate(self): ########################### GIBBSSAMP
oo = self
ooTR = oo.TR
print ooTR
ook = oo.k
ooNMC = oo.NMC
ooN = oo.N
oo.allocateSmp(oo.burn + oo.NMC)
oo.x00 = _N.array(oo.smpx[:, 2])
oo.V00 = _N.zeros((ooTR, ook, ook))
oo.loghist = _N.zeros(oo.N + 1)
ARo = _N.empty((ooTR, oo._d.N + 1))
kpOws = _N.empty((ooTR, ooN + 1))
lv_f = _N.zeros((ooN + 1, ooN + 1))
lv_u = _N.zeros((ooTR, ooTR))
Bii = _N.zeros((ooN + 1, ooN + 1))
#alpC.reverse()
# F_alfa_rep = alpR + alpC already in right order, no?
Wims = _N.empty((ooTR, ooN + 1, ooN + 1))
Oms = _N.empty((ooTR, ooN + 1))
smWimOm = _N.zeros(ooN + 1)
smWinOn = _N.zeros(ooTR)
bConstPSTH = False
D_f = _N.diag(_N.ones(oo.B.shape[0]) * oo.s2_a) # spline
iD_f = _N.linalg.inv(D_f)
D_u = _N.diag(_N.ones(oo.TR) * oo.s2_u) # This should
iD_u = _N.linalg.inv(D_u)
iD_u_u_u = _N.dot(iD_u, _N.ones(oo.TR) * oo.u_u)
BDB = _N.dot(oo.B.T, _N.dot(D_f, oo.B))
DB = _N.dot(D_f, oo.B)
BTua = _N.dot(oo.B.T, oo.u_a)
it = 0
############################### MCMC LOOP ########################
### need pointer to oo.us, but reshaped for broadcasting to work
############################### MCMC LOOP ########################
oous_rs = oo.us.reshape((ooTR, 1)) # done for broadcasting rules
sd01 = _N.zeros((oo.nStates, oo.TR, oo.TR))
_N.fill_diagonal(sd01[0], oo.s[0])
_N.fill_diagonal(sd01[1], oo.s[1])
smpx01 = _N.zeros((oo.nStates, oo.TR, oo.N + 1))
zsmpx = _N.empty((oo.TR, oo.N + 1))
# zsmpx created
# PG
zd = _N.zeros((oo.TR, oo.TR))
izd = _N.zeros((oo.TR, oo.TR))
ll = _N.zeros(oo.nStates)
Bp = _N.empty((oo.nStates, oo.N + 1))
for m in xrange(ooTR):
oo._d.f_V[m, 0] = oo.s2_x00
oo._d.f_V[m, 1] = oo.s2_x00
THR = _N.empty(oo.TR)
dirArgs = _N.empty(oo.nStates) # dirichlet distribution args
expT = _N.empty(ooN + 1)
BaS = _N.dot(oo.B.T, oo.aS)
alpR = oo.F_alfa_rep[0:oo.R]
alpC = oo.F_alfa_rep[oo.R:]
oo.nSMP_smpxC = 0
if oo.processes > 1:
print oo.processes
pool = Pool(processes=oo.processes)
print "oo.mcmcRunDir %s" % oo.mcmcRunDir
if oo.mcmcRunDir is None:
oo.mcmcRunDir = ""
elif (len(oo.mcmcRunDir) > 0) and (oo.mcmcRunDir[-1] != "/"):
oo.mcmcRunDir += "/"
# H shape 100 x 9
Hbf = oo.Hbf
RHS = _N.empty((oo.histknots, 1))
if oo.h0_1 > 1: # first few are 0s
#cInds = _N.array([0, 1, 5, 6, 7, 8, 9, 10])
cInds = _N.array([0, 4, 5, 6, 7, 8, 9])
#vInds = _N.array([2, 3, 4])
vInds = _N.array([
1,
2,
3,
])
RHS[cInds, 0] = 0
RHS[0, 0] = -5
else:
#cInds = _N.array([5, 6, 7, 8, 9, 10])
cInds = _N.array([
4,
5,
6,
7,
8,
9,
])
vInds = _N.array([
0,
1,
2,
3,
])
#vInds = _N.array([0, 1, 2, 3, 4])
RHS[cInds, 0] = 0
Msts = []
for m in xrange(ooTR):
Msts.append(_N.where(oo.y[m] == 1)[0])
HcM = _N.empty((len(vInds), len(vInds)))
HbfExpd = _N.empty((oo.histknots, ooTR, oo.N + 1))
# HbfExpd is 11 x M x 1200
# find the mean. For the HISTORY TERM
for i in xrange(oo.histknots):
for m in xrange(oo.TR):
sts = Msts[m]
HbfExpd[i, m, 0:sts[0]] = 0
for iss in xrange(len(sts) - 1):
t0 = sts[iss]
t1 = sts[iss + 1]
HbfExpd[i, m, t0 + 1:t1 + 1] = Hbf[0:t1 - t0, i]
HbfExpd[i, m, sts[-1] + 1:] = 0
_N.dot(oo.B.T, oo.aS, out=BaS)
if oo.hS is None:
oo.hS = _N.zeros(oo.histknots)
_N.dot(Hbf, oo.hS, out=oo.loghist)
oo.stitch_Hist(ARo, oo.loghist, Msts)
## ORDER OF SAMPLING
## f_xx, f_V
## BINARY state
## DA: PG, kpOws
## history, build ARo
## psth
## offset
## DA: latent state
## AR coefficients
## q2
while (it < ooNMC + oo.burn - 1):
lowsts = _N.where(oo.Z[:, 0] == 1)
#print "lowsts %s" % str(lowsts)
t1 = _tm.time()
it += 1
print "****------------ %d" % it
oo._d.f_x[:, 0, :, 0] = oo.x00
if it == 0:
for m in xrange(ooTR):
oo._d.f_V[m, 0] = oo.s2_x00
else:
oo._d.f_V[:, 0] = _N.mean(oo._d.f_V[:, 1:], axis=1)
# generate latent AR state
if it > oo.startZ:
for tryZ in xrange(oo.nStates):
_N.dot(sd01[tryZ], oo.smpx[..., 2:, 0], out=smpx01[tryZ])
for m in oo.varz:
for tryZ in xrange(
oo.nStates
): # only allow certain trials to change
# calculate p0, p1 p0 = m_0 x PROD_n Ber(y_n | Z_j)
# = m_0 x _N.exp(_N.log( ))
# p0, p1 not normalized
ll[tryZ] = 0
# Ber(0 | ) and Ber(1 | )
_N.exp(smpx01[tryZ, m] + BaS + ARo[m] + oo.us[m] +
oo.knownSig[m],
out=expT)
Bp[0] = 1 / (1 + expT)
Bp[1] = expT / (1 + expT)
# z[:, 1] is state label
for n in xrange(oo.N + 1):
ll[tryZ] += _N.log(Bp[oo.y[m, n], n])
ofs = _N.min(ll)
ll -= ofs
nc = oo.m[0] * _N.exp(ll[0]) + oo.m[1] * _N.exp(ll[1])
oo.Z[m, 0] = 0
oo.Z[m, 1] = 1
THR[m] = (oo.m[0] * _N.exp(ll[0]) / nc)
if _N.random.rand() < THR[m]:
oo.Z[m, 0] = 1
oo.Z[m, 1] = 0
oo.smp_zs[m, it] = oo.Z[m]
for m in oo.fxdz: ##### outside BM loop
oo.smp_zs[m, it] = oo.Z[m]
t2 = _tm.time()
# Z set
_N.fill_diagonal(zd, oo.s[oo.Z[:, 1]])
_N.fill_diagonal(izd, 1. / oo.s[oo.Z[:, 1]])
#for kkk in xrange(oo.TR):
# print zd[kkk, kkk]
_N.dot(zd, oo.smpx[..., 2:, 0], out=zsmpx)
###### sample m's
_N.add(oo.alp, _N.sum(oo.Z[oo.varz], axis=0), out=dirArgs)
oo.m[:] = _N.random.dirichlet(dirArgs)
oo.smp_ms[it] = oo.m
else:
_N.fill_diagonal(zd, oo.s[oo.Z[:, 1]])
_N.fill_diagonal(izd, 1. / oo.s[oo.Z[:, 1]])
_N.dot(zd, oo.smpx[..., 2:, 0], out=zsmpx)
###### sample m's
oo.smp_ms[it] = oo.m
oo.smp_zs[:, it, 1] = 1
oo.smp_zs[:, it, 0] = 0
print oo.m
lwsts = _N.where(oo.Z[:, 0] == 1)[0]
hists = _N.where(oo.Z[:, 1] == 1)[0]
t3 = _tm.time()
###### PG generate
for m in xrange(ooTR):
lw.rpg_devroye(oo.rn,
zsmpx[m] + oo.us[m] + BaS + ARo[m] +
oo.knownSig[m],
out=oo.ws[m]) ###### devryoe ####TRD change
_N.divide(oo.kp, oo.ws, out=kpOws)
if not oo.bFixH:
O = kpOws - zsmpx - oo.us.reshape(
(ooTR, 1)) - BaS - oo.knownSig
iOf = vInds[0] # offset HcM index with RHS index.
for i in vInds:
for j in vInds:
HcM[i - iOf,
j - iOf] = _N.sum(oo.ws * HbfExpd[i] * HbfExpd[j])
RHS[i, 0] = _N.sum(oo.ws * HbfExpd[i] * O)
for cj in cInds:
RHS[i, 0] -= _N.sum(
oo.ws * HbfExpd[i] * HbfExpd[cj]) * RHS[cj, 0]
# print HbfExpd
# print HcM
# print RHS[vInds]
vm = _N.linalg.solve(HcM, RHS[vInds])
Cov = _N.linalg.inv(HcM)
print vm
cfs = _N.random.multivariate_normal(vm[:, 0], Cov, size=1)
RHS[vInds, 0] = cfs[0]
oo.smp_hS[:, it] = RHS[:, 0]
#RHS[2:6, 0] = vm[:, 0]
#print HcM
#vv = _N.dot(Hbf, RHS)
#print vv.shape
#print oo.loghist.shape
_N.dot(Hbf, RHS[:, 0], out=oo.loghist)
oo.smp_hist[:, it] = oo.loghist
oo.stitch_Hist(ARo, oo.loghist, Msts)
######## PSTH sample Do PSTH after we generate zs
if oo.bpsth:
Oms = kpOws - zsmpx - ARo - oous_rs - oo.knownSig
_N.einsum("mn,mn->n", oo.ws, Oms, out=smWimOm) # sum over
ilv_f = _N.diag(_N.sum(oo.ws, axis=0))
_N.fill_diagonal(lv_f, 1. / _N.diagonal(ilv_f))
lm_f = _N.dot(lv_f, smWimOm) # nondiag of 1./Bi are inf
# now sample
iVAR = _N.dot(oo.B, _N.dot(ilv_f, oo.B.T)) + iD_f
VAR = _N.linalg.inv(iVAR) # knots x knots
#iBDBW = _N.linalg.inv(BDB + lv_f) # BDB not diag
#Mn = oo.u_a + _N.dot(DB, _N.dot(iBDBW, lm_f - BTua))
Mn = oo.u_a + _N.dot(DB,
_N.linalg.solve(BDB + lv_f, lm_f - BTua))
oo.aS = _N.random.multivariate_normal(Mn, VAR, size=1)[0, :]
oo.smp_aS[it, :] = oo.aS
#iBDBW = _N.linalg.inv(BDB + lv_f) # BDB not diag
#Mn = oo.u_a + _N.dot(DB, _N.dot(iBDBW, lm_f - BTua))
#oo.aS = _N.random.multivariate_normal(Mn, VAR, size=1)[0, :]
#oo.smp_aS[it, :] = oo.aS
else:
oo.aS[:] = 0
BaS = _N.dot(oo.B.T, oo.aS)
######## per trial offset sample
Ons = kpOws - zsmpx - ARo - BaS - oo.knownSig
# solve for the mean of the distribution
H = _N.ones((oo.TR - 1, oo.TR - 1)) * _N.sum(oo.ws[0])
uRHS = _N.empty(oo.TR - 1)
for dd in xrange(1, oo.TR):
H[dd - 1, dd - 1] += _N.sum(oo.ws[dd])
uRHS[dd - 1] = _N.sum(oo.ws[dd] * Ons[dd] - oo.ws[0] * Ons[0])
MM = _N.linalg.solve(H, uRHS)
Cov = _N.linalg.inv(H)
oo.us[1:] = _N.random.multivariate_normal(MM, Cov, size=1)
oo.us[0] = -_N.sum(oo.us[1:])
oo.smp_u[:, it] = oo.us
t4 = _tm.time()
#### Sample latent state
oo._d.y = _N.dot(izd, kpOws - BaS - ARo - oous_rs - oo.knownSig)
oo._d.copyParams(oo.F0, oo.q2)
# (MxM) (MxN) = (MxN) (Rv is MxN)
_N.dot(_N.dot(izd, izd), 1. / oo.ws, out=oo._d.Rv)
oo._d.f_x[:, 0, :, 0] = oo.x00
#if it == 1:
for m in xrange(ooTR):
oo._d.f_V[m, 0] = oo.s2_x00
else:
oo._d.f_V[:, 0] = _N.mean(oo._d.f_V[:, 1:], axis=1)
tpl_args = zip(oo._d.y, oo._d.Rv, oo._d.Fs,
_N.linalg.inv(oo._d.Fs, ), oo.q2, oo._d.Ns,
oo._d.ks, oo._d.f_x[:, 0], oo._d.f_V[:, 0])
t5 = _tm.time()
if oo.processes == 1:
for m in xrange(ooTR):
oo.smpx[m, 2:], oo._d.f_x[m], oo._d.f_V[
m] = _kfar.armdl_FFBS_1itrMP(tpl_args[m])
oo.smpx[m, 1, 0:ook - 1] = oo.smpx[m, 2, 1:]
oo.smpx[m, 0, 0:ook - 2] = oo.smpx[m, 2, 2:]
oo.smp_q2[m, it] = oo.q2[m]
else:
sxv = pool.map(_kfar.armdl_FFBS_1itrMP, tpl_args)
for m in xrange(ooTR):
oo.smpx[m, 2:] = sxv[m][0]
oo._d.f_x[m] = sxv[m][1]
oo._d.f_V[m] = sxv[m][2]
oo.smpx[m, 1, 0:ook - 1] = oo.smpx[m, 2, 1:]
oo.smpx[m, 0, 0:ook - 2] = oo.smpx[m, 2, 2:]
#oo.Bsmpx[m, it, 2:] = oo.smpx[m, 2:, 0]
stds = _N.std(oo.smpx[:, 2:, 0], axis=1)
oo.mnStds[it] = _N.mean(stds, axis=0)
print "mnStd %.3f" % oo.mnStds[it]
###
if not oo.bFixF:
ARcfSmpl(oo.lfc,
ooN + 1,
ook,
oo.AR2lims,
oo.smpx[:, 1:, 0:ook],
oo.smpx[:, :, 0:ook - 1],
oo.q2,
oo.R,
oo.Cs,
oo.Cn,
alpR,
alpC,
oo.TR,
prior=oo.use_prior,
accepts=80,
aro=oo.ARord,
sig_ph0L=oo.sig_ph0L,
sig_ph0H=oo.sig_ph0H)
oo.F_alfa_rep = alpR + alpC # new constructed
prt, rank, f, amp = ampAngRep(oo.F_alfa_rep, f_order=True)
print prt
#ut, wt = FilteredTimeseries(ooN+1, ook, oo.smpx[:, 1:, 0:ook], oo.smpx[:, :, 0:ook-1], oo.q2, oo.R, oo.Cs, oo.Cn, alpR, alpC, oo.TR)
#ranks[it] = rank
oo.allalfas[it] = oo.F_alfa_rep
for m in xrange(ooTR):
#oo.wts[m, it, :, :] = wt[m, :, :, 0]
#oo.uts[m, it, :, :] = ut[m, :, :, 0]
if not oo.bFixF:
oo.amps[it, :] = amp
oo.fs[it, :] = f
oo.F0 = (-1 * _Npp.polyfromroots(oo.F_alfa_rep)[::-1].real)[1:]
print "len(lwsts) %(l)d len(hists) %(h)d" % {
"l": len(lwsts),
"h": len(hists)
}
sts2chg = hists
if (it > oo.startZ) and oo.doS and len(sts2chg) > 0:
AL = 0.5 * _N.sum(oo.smpx[sts2chg, 2:, 0] *
oo.smpx[sts2chg, 2:, 0] * oo.ws[sts2chg])
BRL = kpOws[sts2chg] - BaS - oous_rs[sts2chg] - ARo[
sts2chg] - oo.knownSig[sts2chg]
BL = _N.sum(oo.ws[sts2chg] * BRL * oo.smpx[sts2chg, 2:, 0])
UL = BL / (2 * AL)
#sgL= 1/_N.sqrt(2*AL)
sg2 = 1. / (2 * AL)
q2_pr = 0.0025 # 0.05**2
u_pr = 1.
U = (u_pr * sg2 + UL * q2_pr) / (sg2 + q2_pr)
sg = _N.sqrt((sg2 * q2_pr) / (sg2 + q2_pr))
print "U %(U).4f UL %(UL).4f s %(s).3f" % {
"U": U,
"s": sg,
"UL": UL
}
if _N.isnan(U):
print "U is nan UL %.4f" % UL
print "U is nan AL %.4f" % AL
print "U is nan BL %.4f" % BL
print "U is nan BaS "
print "hists"
print hists
print "lwsts"
print lwsts
oo.s[1] = U + sg * _N.random.randn()
_N.fill_diagonal(sd01[0], oo.s[0])
_N.fill_diagonal(sd01[1], oo.s[1])
print oo.s[1]
oo.smp_ss[it] = oo.s[1]
oo.a2 = oo.a_q2 + 0.5 * (ooTR * ooN + 2) # N + 1 - 1
BB2 = oo.B_q2
for m in xrange(ooTR):
# set x00
#oo.x00[m] = oo.smpx[m, 2]*0.1
oo.x00[m] = oo.smpx[m, 2] * 0.001
##################### sample q2
rsd_stp = oo.smpx[m, 3:, 0] - _N.dot(oo.smpx[m, 2:-1], oo.F0).T
BB2 += 0.5 * _N.dot(rsd_stp, rsd_stp.T)
oo.q2[:] = _ss.invgamma.rvs(oo.a2, scale=BB2)
oo.smp_q2[:, it] = oo.q2
t7 = _tm.time()
print "gibbs iter %.3f" % (t7 - t1)
if (it > 1) and (it % oo.peek == 0):
fig = _plt.figure(figsize=(12, 8))
fig.add_subplot(4, 1, 1)
_plt.plot(oo.amps[1:it, 0])
fig.add_subplot(4, 1, 2)
_plt.plot(oo.fs[1:it, 0])
fig.add_subplot(4, 1, 3)
_plt.plot(oo.mnStds[1:it])
fig.add_subplot(4, 1, 4)
_plt.plot(oo.smp_ms[1:it, 0])
_plt.savefig("%(dir)s/tmp-fsamps%(it)d" % {
"dir": oo.mcmcRunDir,
"it": it
})
_plt.close()
oo.dump_smpsS(toiter=it, dir=oo.mcmcRunDir)
oo.dump_smpsS(dir=oo.mcmcRunDir)
l2_px, l2_pV, l2_fx, l2_fV, l2_K, random_walk)
smp_offsets[5, it] = o_l2[0]
smp_Bns[0, it] = B1wn
smp_Bns[1, it] = B1tn
smp_Bns[2, it] = B1ln
smp_Bns[3, it] = B2wn
smp_Bns[4, it] = B2tn
smp_Bns[5, it] = B2ln
smp_q2s[it] = q2_Bw1, q2_Bt1, q2_Bl1, q2_Bw2, q2_Bt2, q2_Bl2
#if random_walk:
# F0_Bw1 = F0_Bt1 = F0_Bl1 = F0_Bw2 = F0_Bt2 = F0_Bl2 = 1
smp_F0s[it] = F0_Bw1, F0_Bt1, F0_Bl1, F0_Bw2, F0_Bt2, F0_Bl2
lw.rpg_devroye(N_vec[:, 0], o_w1 * W_n + o_t1 * T_n + o_l1 * L_n, out=ws1)
lw.rpg_devroye(N_vec[:, 1], o_w2 * W_n + o_t2 * T_n + o_l2 * L_n, out=ws2)
ws2[zr2] = 1e-20 #1e-20
pklme = {}
smp_every = 50
pklme["smp_Bns"] = smp_Bns[:, ::smp_every]
pklme["smp_q2s"] = smp_q2s[::smp_every]
pklme["smp_F0s"] = smp_F0s[::smp_every]
pklme["smp_offsets"] = smp_offsets[:, ::smp_every]
pklme["smp_every"] = smp_every
pklme["Wn"] = W_n
pklme["Tn"] = T_n
pklme["Ln"] = L_n
pklme["hnd_dat"] = hnd_dat
def dirichletAllocate(self): ########################### GIBBSSAMP
oo = self
signal.signal(signal.SIGINT, signal_handler)
ooTR = oo.TR
ook = oo.k
ooN = oo.N
runTO = oo.ITERS - 1
oo.allocateSmp(runTO + 1, Bsmpx=oo.doBsmpx)
#oo.allocateSmp(oo.burn + oo.NMC)
oo.x00 = _N.array(oo.smpx[:, 2])
oo.V00 = _N.zeros((ooTR, ook, ook))
_kfar.init(oo.N, oo.k, oo.TR)
if oo.dohist:
oo.loghist = _N.zeros(oo.Hbf.shape[0])
else:
print("fixed hist is")
print(oo.loghist)
ARo = _N.zeros((ooTR, ooN + 1))
kpOws = _N.empty((ooTR, ooN + 1))
lv_f = _N.zeros((ooN + 1, ooN + 1))
lv_u = _N.zeros((ooTR, ooTR))
Bii = _N.zeros((ooN + 1, ooN + 1))
#alpC.reverse()
# F_alfa_rep = alpR + alpC already in right order, no?
Wims = _N.empty((ooTR, ooN + 1, ooN + 1))
Oms = _N.empty((ooTR, ooN + 1))
smWimOm = _N.zeros(ooN + 1)
smWinOn = _N.zeros(ooTR)
bConstPSTH = False
D_f = _N.diag(_N.ones(oo.B.shape[0]) * oo.s2_a) # spline
iD_f = _N.linalg.inv(D_f)
D_u = _N.diag(_N.ones(oo.TR) * oo.s2_u) # This should
iD_u = _N.linalg.inv(D_u)
iD_u_u_u = _N.dot(iD_u, _N.ones(oo.TR) * oo.u_u)
BDB = _N.dot(oo.B.T, _N.dot(D_f, oo.B))
DB = _N.dot(D_f, oo.B)
BTua = _N.dot(oo.B.T, oo.u_a)
it = 0
############################### MCMC LOOP ########################
### need pointer to oo.us, but reshaped for broadcasting to work
############################### MCMC LOOP ########################
oous_rs = oo.us.reshape((ooTR, 1)) # done for broadcasting rules
sd01 = _N.zeros((oo.nStates, oo.TR, oo.TR))
_N.fill_diagonal(sd01[0], oo.s[0])
_N.fill_diagonal(sd01[1], oo.s[1])
smpx01 = _N.zeros((oo.nStates, oo.TR, oo.N + 1))
zsmpx = _N.empty((oo.TR, oo.N + 1))
# zsmpx created
# PG
zd = _N.zeros((oo.TR, oo.TR))
izd = _N.zeros((oo.TR, oo.TR))
ll = _N.zeros(oo.nStates)
Bp = _N.empty((oo.nStates, oo.N + 1))
for m in range(ooTR):
oo.f_V[m, 0] = oo.s2_x00
oo.f_V[m, 1] = oo.s2_x00
THR = _N.empty(oo.TR)
dirArgs = _N.empty(oo.nStates) # dirichlet distribution args
expT = _N.empty(ooN + 1)
BaS = _N.dot(oo.B.T, oo.aS)
alpR = oo.F_alfa_rep[0:oo.R]
alpC = oo.F_alfa_rep[oo.R:]
print("!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!")
print(oo.F_alfa_rep)
print("*****************************")
print(alpR)
print(alpC)
oo.nSMP_smpxC = 0
if oo.mcmcRunDir is None:
oo.mcmcRunDir = ""
elif (len(oo.mcmcRunDir) > 0) and (oo.mcmcRunDir[-1] != "/"):
oo.mcmcRunDir += "/"
# H shape 100 x 9
Hbf = oo.Hbf
RHS = _N.empty((oo.histknots, 1))
cInds = _N.arange(oo.iHistKnotBeginFixed, oo.histknots)
vInds = _N.arange(0, oo.iHistKnotBeginFixed)
RHS[cInds, 0] = 0
Msts = []
for m in range(ooTR):
Msts.append(_N.where(oo.y[m] == 1)[0])
HcM = _N.empty((len(vInds), len(vInds)))
HbfExpd = _N.empty((oo.histknots, ooTR, oo.N + 1))
# HbfExpd is 11 x M x 1200
# find the mean. For the HISTORY TERM
for i in range(oo.histknots):
for m in range(oo.TR):
sts = Msts[m]
HbfExpd[i, m, 0:sts[0]] = 0
for iss in range(len(sts) - 1):
t0 = sts[iss]
t1 = sts[iss + 1]
HbfExpd[i, m, t0 + 1:t1 + 1] = Hbf[0:t1 - t0, i]
HbfExpd[i, m, sts[-1] + 1:] = 0
_N.dot(oo.B.T, oo.aS, out=BaS)
if oo.hS is None:
oo.hS = _N.zeros(oo.histknots)
_N.dot(Hbf, oo.hS, out=oo.loghist)
oo.stitch_Hist(ARo, oo.loghist, Msts)
K = _N.empty((oo.TR, oo.N + 1, oo.k)) # kalman gain
iterBLOCKS = oo.ITERS // oo.peek
smpx_tmp = _N.empty((oo.TR, oo.N + 1, oo.k))
## ORDER OF SAMPLING
## f_xx, f_V
## BINARY state
## DA: PG, kpOws
## history, build ARo
## psth
## offset
## DA: latent state
## AR coefficients
## q2
oo.gau_var = _N.array(oo.ws)
#iterBLOCKS = 1
#oo.peek = 1
arangeNp1 = _N.arange(oo.N + 1)
for itrB in range(iterBLOCKS):
it = itrB * oo.peek
if it > 0:
print(
"it: %(it)d mnStd %(mnstd).3f fs %(fs).3f m %(m).3f [%(0).2f,%(1).2f]"
% {
"it": itrB * oo.peek,
"mnstd": oo.mnStds[it - 1],
"fs": oo.fs[it - 1, 0],
"m": oo.m[0],
"0": oo.s[0],
"1": oo.s[1]
})
#tttA = _tm.time()
if interrupted:
break
for it in range(itrB * oo.peek, (itrB + 1) * oo.peek):
lowsts = _N.where(oo.Z[:, 0] == 1)
#print "lowsts %s" % str(lowsts)
t1 = _tm.time()
oo.f_x[:, 0] = oo.x00
if it == 0:
for m in range(ooTR):
oo.f_V[m, 0] = oo.s2_x00
else:
oo.f_V[:, 0] = _N.mean(oo.f_V[:, 1:], axis=1)
# generate latent AR state
if it > oo.startZ:
for tryZ in range(oo.nStates):
_N.dot(sd01[tryZ], oo.smpx[:, 2:, 0], out=smpx01[tryZ])
for m in range(oo.TR):
for tryZ in range(
oo.nStates
): # only allow certain trials to change
# calculate p0, p1 p0 = m_0 x PROD_n Ber(y_n | Z_j)
# = m_0 x _N.exp(_N.log( ))
# p0, p1 not normalized
# Ber(0 | ) and Ber(1 | )
_N.exp(smpx01[tryZ, m] + BaS + ARo[m] + oo.us[m] +
oo.knownSig[m],
out=expT)
Bp[0] = 1 / (1 + expT)
Bp[1] = expT / (1 + expT)
# z[:, 1] is state label
#ll[tryZ] = 0
ll[tryZ] = _N.sum(
_N.log(Bp[oo.y[m, arangeNp1], arangeNp1]))
ofs = _N.min(ll)
ll -= ofs
#nc = oo.m[0]*_N.exp(ll[0]) + oo.m[1]*_N.exp(ll[1])
nc = oo.m[0] + oo.m[1] * _N.exp(ll[1] - ll[0])
oo.Z[m, 0] = 0
oo.Z[m, 1] = 1
#THR[m] = (oo.m[0]*_N.exp(ll[0]) / nc)
THR[m] = (oo.m[0] / nc)
if _N.random.rand() < THR[m]:
oo.Z[m, 0] = 1
oo.Z[m, 1] = 0
oo.smp_zs[m, it] = oo.Z[m]
for m in oo.fxdz: ##### outside BM loop
oo.smp_zs[m, it] = oo.Z[m]
# Z set
_N.fill_diagonal(zd, oo.s[oo.Z[:, 1]])
_N.fill_diagonal(izd, 1. / oo.s[oo.Z[:, 1]])
_N.dot(zd, oo.smpx[..., 2:, 0], out=zsmpx)
###### sample m's
_N.add(oo.alp, _N.sum(oo.Z[oo.varz], axis=0), out=dirArgs)
oo.m[:] = _N.random.dirichlet(dirArgs)
oo.smp_ms[it] = oo.m
else: # turned off dirichlet, always allocate to low state
_N.fill_diagonal(zd, oo.s[oo.Z[:, 1]])
_N.fill_diagonal(izd, 1. / oo.s[oo.Z[:, 1]])
_N.dot(zd, oo.smpx[:, 2:, 0], out=zsmpx)
###### sample m's
oo.smp_ms[it] = oo.m
oo.smp_zs[:, it, 1] = 1
oo.smp_zs[:, it, 0] = 0
lwsts = _N.where(oo.Z[:, 0] == 1)[0]
hists = _N.where(oo.Z[:, 1] == 1)[0]
#print(zsmpx[0, 0:20])
#print(oo.smpx[0, 2:22, 0])
t3 = _tm.time()
###### PG generate
for m in range(ooTR):
### CHANGE 1
#lw.rpg_devroye(oo.rn, oo.smpx[m, 2:, 0] + oo.us[m] + BaS + ARo[m] + oo.knownSig[m], out=oo.ws[m]) ###### devryoe
lw.rpg_devroye(
oo.rn,
zsmpx[m] + oo.us[m] + BaS + ARo[m] + oo.knownSig[m],
out=oo.ws[m]) ###### devryoe ####TRD change
_N.divide(oo.kp, oo.ws, out=kpOws)
if oo.dohist:
#O = kpOws - oo.smpx[..., 2:, 0] - oo.us.reshape((ooTR, 1)) - BaS - oo.knownSig
O = kpOws - zsmpx - oo.us.reshape(
(ooTR, 1)) - BaS - oo.knownSig
for ii in range(len(vInds)):
#print("i %d" % i)
#print(_N.sum(HbfExpd[i]))
i = vInds[ii]
for jj in range(ii, len(vInds)):
j = vInds[jj]
#print("j %d" % j)
#print(_N.sum(HbfExpd[j]))
HcM[ii,
jj] = _N.sum(oo.ws * HbfExpd[i] * HbfExpd[j])
HcM[jj, ii] = HcM[ii, jj]
RHS[ii, 0] = _N.sum(oo.ws * HbfExpd[i] * O)
for cj in cInds:
RHS[ii, 0] -= _N.sum(
oo.ws * HbfExpd[i] * HbfExpd[cj]) * RHS[cj, 0]
vm = _N.linalg.solve(HcM, RHS[vInds])
Cov = _N.linalg.inv(HcM)
cfs = _N.random.multivariate_normal(vm[:, 0], Cov, size=1)
RHS[vInds, 0] = cfs[0]
oo.smp_hS[:, it] = RHS[:, 0]
#RHS[2:6, 0] = vm[:, 0]
#print HcM
#vv = _N.dot(Hbf, RHS)
#print vv.shape
#print oo.loghist.shape
_N.dot(Hbf, RHS[:, 0], out=oo.loghist)
oo.smp_hist[:, it] = oo.loghist
oo.stitch_Hist(ARo, oo.loghist, Msts)
######## PSTH sample Do PSTH after we generate zs
if oo.bpsth:
#Oms = kpOws - oo.smpx[..., 2:, 0] - ARo - oous_rs - oo.knownSig
Oms = kpOws - zsmpx - ARo - oous_rs - oo.knownSig
_N.einsum("mn,mn->n", oo.ws, Oms, out=smWimOm) # sum over
ilv_f = _N.diag(_N.sum(oo.ws, axis=0))
_N.fill_diagonal(lv_f, 1. / _N.diagonal(ilv_f))
lm_f = _N.dot(lv_f, smWimOm) # nondiag of 1./Bi are inf
# now sample
iVAR = _N.dot(oo.B, _N.dot(ilv_f, oo.B.T)) + iD_f
VAR = _N.linalg.inv(iVAR) # knots x knots
#iBDBW = _N.linalg.inv(BDB + lv_f) # BDB not diag
#Mn = oo.u_a + _N.dot(DB, _N.dot(iBDBW, lm_f - BTua))
Mn = oo.u_a + _N.dot(
DB, _N.linalg.solve(BDB + lv_f, lm_f - BTua))
oo.aS = _N.random.multivariate_normal(Mn, VAR,
size=1)[0, :]
oo.smp_aS[it, :] = oo.aS
#iBDBW = _N.linalg.inv(BDB + lv_f) # BDB not diag
#Mn = oo.u_a + _N.dot(DB, _N.dot(iBDBW, lm_f - BTua))
#oo.aS = _N.random.multivariate_normal(Mn, VAR, size=1)[0, :]
#oo.smp_aS[it, :] = oo.aS
else:
oo.aS[:] = 0
_N.dot(oo.B.T, oo.aS, out=BaS)
######## per trial offset sample
#Ons = kpOws - zsmpx - ARo - BaS - oo.knownSig
Ons = kpOws - oo.smpx[..., 2:, 0] - ARo - BaS - oo.knownSig
# solve for the mean of the distribution
H = _N.ones((oo.TR - 1, oo.TR - 1)) * _N.sum(oo.ws[0])
uRHS = _N.empty(oo.TR - 1)
for dd in range(1, oo.TR):
H[dd - 1, dd - 1] += _N.sum(oo.ws[dd])
uRHS[dd - 1] = _N.sum(oo.ws[dd] * Ons[dd] -
oo.ws[0] * Ons[0])
MM = _N.linalg.solve(H, uRHS)
Cov = _N.linalg.inv(H)
oo.us[1:] = _N.random.multivariate_normal(MM, Cov, size=1)
oo.us[0] = -_N.sum(oo.us[1:])
oo.smp_u[:, it] = oo.us
t4 = _tm.time()
#### Sample latent state
#oo.gau_obs = kpOws - BaS - ARo - oous_rs - oo.knownSig
oo.gau_obs = _N.dot(izd,
kpOws - BaS - ARo - oous_rs - oo.knownSig)
#oo.copyParams(oo.F0, oo.q2)
# (MxM) (MxN) = (MxN) (Rv is MxN)
_N.dot(_N.dot(izd, izd), 1. / oo.ws, out=oo.gau_var)
#oo.gau_var =1 / oo.ws
t5 = _tm.time()
_kfar.armdl_FFBS_1itrMP(oo.gau_obs, oo.gau_var, oo.Fs,
_N.linalg.inv(oo.Fs), oo.q2, oo.Ns,
oo.ks, oo.f_x, oo.f_V, oo.p_x, oo.p_V,
smpx_tmp, K)
oo.smpx[:, 2:] = smpx_tmp
oo.smpx[:, 1, 0:ook - 1] = oo.smpx[:, 2, 1:]
oo.smpx[:, 0, 0:ook - 2] = oo.smpx[:, 2, 2:]
if oo.doBsmpx and (it % oo.BsmpxSkp == 0):
oo.Bsmpx[:, it // oo.BsmpxSkp, 2:] = oo.smpx[:, 2:, 0]
stds = _N.std(oo.smpx[:, 2:, 0], axis=1)
oo.mnStds[it] = _N.mean(stds, axis=0)
if len(hists) == 0:
print("!!!!!! length hists is 0 before ARcfSmpl")
###
#_arcfs.ARcfSmpl(ooN+1, ook, oo.AR2lims, oo.smpx[:, 1:, 0:ook], oo.smpx[:, 0:, 0:ook-1], oo.q2, oo.R, oo.Cs, oo.Cn, alpR, alpC, oo.TR, prior=oo.use_prior, accepts=8, aro=oo.ARord, sig_ph0L=oo.sig_ph0L, sig_ph0H=oo.sig_ph0H)
_arcfs.ARcfSmpl(ooN + 1,
ook,
oo.AR2lims,
oo.smpx[hists, 1:, 0:ook],
oo.smpx[hists, 0:, 0:ook - 1],
oo.q2,
oo.R,
oo.Cs,
oo.Cn,
alpR,
alpC,
len(hists),
prior=oo.use_prior,
accepts=8,
aro=oo.ARord,
sig_ph0L=oo.sig_ph0L,
sig_ph0H=oo.sig_ph0H)
oo.F_alfa_rep = alpR + alpC # new constructed
prt, rank, f, amp = ampAngRep(oo.F_alfa_rep, f_order=True)
#ut, wt = FilteredTimeseries(ooN+1, ook, oo.smpx[:, 1:, 0:ook], oo.smpx[:, :, 0:ook-1], oo.q2, oo.R, oo.Cs, oo.Cn, alpR, alpC, oo.TR)
#ranks[it] = rank
oo.allalfas[it] = oo.F_alfa_rep
for m in range(ooTR):
#oo.wts[m, it, :, :] = wt[m, :, :, 0]
#oo.uts[m, it, :, :] = ut[m, :, :, 0]
if not oo.bFixF:
oo.amps[it, :] = amp
oo.fs[it, :] = f
oo.F0 = (-1 * _Npp.polyfromroots(oo.F_alfa_rep)[::-1].real)[1:]
for tr in range(oo.TR):
oo.Fs[tr, 0] = oo.F0[:]
#print "len(lwsts) %(l)d len(hists) %(h)d" % {"l" : len(lwsts), "h" : len(hists)}
# sts2chg = hists
# #sts2chg = lwsts
# #if (it > oo.startZ) and oo.doS and len(sts2chg) > 0:
# if oo.doS and len(sts2chg) > 0:
# AL = 0.5*_N.sum(oo.smpx[sts2chg, 2:, 0]*oo.smpx[sts2chg, 2:, 0]*oo.ws[sts2chg])
# #AL = 0.5*_N.sum(oo.smpx[sts2chg, 2:, 0]*oo.smpx[sts2chg, 2:, 0])
# BRL = kpOws[sts2chg] - BaS - oous_rs[sts2chg] - ARo[sts2chg] - oo.knownSig[sts2chg]
# BL = 0.5*_N.sum(oo.ws[sts2chg]*BRL*oo.smpx[sts2chg, 2:, 0])
# UL = BL / (2*AL)
# #sgL= 1/_N.sqrt(2*AL)
# sg2= 1./(2*AL)
# if it % 50 == 0:
# print("u %(u).3f %(s).3f" % {"u" : UL, "s" : _N.sqrt(sg2)})
# q2_pr = 0.25 # 0.05**2
# u_pr = 1.
# #u_pr = 0
# U = (u_pr * sg2 + UL * q2_pr) / (sg2 + q2_pr)
# sg= _N.sqrt((sg2*q2_pr) / (sg2 + q2_pr))
# #print "U %(U).4f UL %(UL).4f s %(s).3f" % {"U" : U, "s" : sg, "UL" : UL}
# if _N.isnan(U):
# print("U is nan UL %.4f" % UL)
# print("U is nan AL %.4f" % AL)
# print("U is nan BL %.4f" % BL)
# print("U is nan BaS ")
# print("hists")
# print(hists)
# print("lwsts")
# print(lwsts)
# oo.s[1] = U + sg*_N.random.randn()
# #oo.s[0] = U + sg*_N.random.randn()
# _N.fill_diagonal(sd01[0], oo.s[0])
# _N.fill_diagonal(sd01[1], oo.s[1])
# #print oo.s[1]
# oo.smp_ss[it] = oo.s[1]
# #oo.smp_ss[it] = oo.s[0]
#oo.a2 = oo.a_q2 + 0.5*(ooTR*ooN + 2) # N + 1 - 1
oo.a2 = oo.a_q2 + 0.5 * (len(hists) * ooN + 2) # N + 1 - 1
BB2 = oo.B_q2
#for m in range(ooTR):
for m in hists:
# set x00
#oo.x00[m] = oo.smpx[m, 2]*0.1
oo.x00[m] = oo.smpx[m, 2] * 0.1
##################### sample q2
rsd_stp = oo.smpx[m, 3:, 0] - _N.dot(
oo.smpx[m, 2:-1], oo.F0).T
BB2 += 0.5 * _N.dot(rsd_stp, rsd_stp.T)
oo.q2[:] = _ss.invgamma.rvs(oo.a2, scale=BB2)
oo.smp_q2[:, it] = oo.q2
t7 = _tm.time()
