RSched = RSched + copyconstr.GetConstrSet(in_, TILE_VLD_EXT) + "}" Rsched = isl.Map(RSched).coalesce() print RSched #TILE_VLD_EXT =imperf_tile.SimplifySlice(TILE_VLD_EXT) print 'TILE_VLD_EXT' print TILE_VLD_EXT #print relation_util.islSettoOmegaStr(TILE_VLD_EXT ) #loop_x = iscc.isl_ast_codegen(TILE_VLD_EXT) #loop_x = iscc.isl_ast_codegen(Rsched) #print loop_x loop_x = iscc.iscc_communicate("L :=" + str(Rsched) + "; codegen L;") print loop_x print '-------------' S1 = 'S[i][j] = max(S[i][k+i] + S[k+i+1][j], S[i][j]);' S2 = 'S[i][j] = max(S[i][j], S[i+1][j-1] + can_par(RNA, i, j));' #S1 = 'S[i][j] = S[i][k+i] + S[k+i+1][j]+ S[i][j];' #S2 = 'S[i][j] = S[i][j]+ S[i+1][j-1];' lines = loop_x.split('\n') loop = [] for line in lines:
def fs_new(rel, rel_plus, rtile, LPetit, dane, plik, SIMPLIFY, rap, exact, isl_TILEbis, sym_exvars, maxl, step, isl_tilevld, vars): codegen = 'isl' # compute rtile_plus # podmien exact, rel na tile, rel_plus na rtile_plus #wq = rtile.transitive_closure()[0] #print wp.subtract(wq).coalesce() #print wq.subtract(wp).coalesce() if (exact): print 'R+ exact!' else: print 'R+ approximated. Iterate way...!' r0p_plus = relation_util.oc_IterateClosure(rel) rel_plus = r0p_plus isl_relclosure = rel_plus isl_ident = rel.identity(rel.get_space()) isl_relclosure = isl_relclosure.union( isl_ident).coalesce() # R* = R+ u I print 'Checking (the Pugh method)' # R = R compose RINV if (rel_plus.subtract( rel_plus.apply_range(rel).union(rel)).coalesce().is_empty()): print ' .... OK !!' else: print 'R+ failed.' sys.exit(0) #file = open('lu_rplus.txt', 'r') #isl_relclosure = isl.Map(file.read()) #print isl_relclosure wp = GetRTilePlus(rel_plus, isl_tilevld, sym_exvars, vars).coalesce() rel = rtile rel_plus = wp print '## R' print rel print '## R+' print wp rel = rel.subtract(rel_plus.apply_range(rel)) print '### R = R - R+ compose R' print rel global_size = rel.dim(isl.dim_type.in_) UDS = rel.domain().subtract(rel.range()).coalesce() UDD = rel.range().subtract(rel.domain()).coalesce() DOM_RAN = rel.range().union(rel.domain()).coalesce() cl = clanpy.ClanPy() cl.loop_path = plik cl.Load() cl.RunCandl() IS = DOM_RAN for i in range(0, len(cl.statements)): IS_ = isl.Set(cl.statements[i].domain_map).coalesce() print IS_ set_size = IS_.dim(isl.dim_type.set) for j in range(set_size, global_size - 1): IS_ = IS_.insert_dims(isl.dim_type.set, j, 1) IS_ = IS_.set_dim_name(isl.dim_type.set, j, 'i' + str(j)) c = isl.Constraint.eq_from_names( IS_.get_space(), { IS_.get_dim_name(isl.dim_type.set, j): -1, 1: -1 }) IS_ = IS_.add_constraint(c).coalesce() set_size = IS_.dim(isl.dim_type.set) IS_ = IS_.insert_dims(isl.dim_type.set, set_size, 1) IS_ = IS_.set_dim_name(isl.dim_type.set, set_size, "v") #print cl.statements[i].body c = isl.Constraint.eq_from_names(IS_.get_space(), { "v": -1, 1: int(dane[i]) }) IS_ = IS_.add_constraint(c).coalesce() if i == 0: IS = IS_ else: IS = IS.union(IS_).coalesce() print "IS" print IS IND = IS.subtract(DOM_RAN).coalesce() print "IND" print IND n = rel.dim(isl.dim_type.in_) inp = [] outp = [] for i in range(0, n): inp.append("i" + str(i)) outp.append("o" + str(i)) # Rlex rlex = "{[" + ",".join(inp) + "] -> [" + ",".join( outp) + "] : " + tiling_v3.CreateLex(outp, inp) + "}" rlex = isl.Map(rlex) rip = rel_plus.fixed_power_val(-1) re_rel = isl.Map.from_domain_and_range(IS, IS) #print re print "### RE" re_rel = re_rel.intersect(rlex.subtract(rel_plus).subtract(rip)).coalesce() print re_rel # oblicz Re1 #Re1 = GetRe1(re_rel, rel_plus) #print "### RE2" #re_rel = re_rel.subtract(Re1).coalesce() #print re_rel re2 = re_rel W = re_rel.domain().union(re_rel.range()).coalesce() D = re_rel.domain().subtract(re_rel.range()).coalesce() rel_inv = rel.fixed_power_val(-1) print "R^-1" print rel_inv # R = R compose RINV #RR = rel.apply_range(rel_inv) RR = rel_inv.apply_range(rel) # ------ Jesli RCHECK ---------- if (1 == 0): RRR1 = rel.fixed_power_val(2) RRR2 = rel_inv.fixed_power_val(2) RRR = RRR1.union(RRR2).coalesce() RR = RR.union(RRR).coalesce() # ------------------------------ RR = RR.intersect(rlex).coalesce() print "### RR" print RR IND_lexmin = IND.lexmin() IND0ToIND = isl.Map.from_domain_and_range(IND_lexmin, IND).coalesce() RRPLUS = RR.transitive_closure() RR_EXACT = RRPLUS[1] RRPLUS = RRPLUS[0] if not RR_EXACT: print 'RR+ not exact' #sys.exit(0) # sprawdz dokladnosc R2 = GetR2(re_rel, RRPLUS) print '### RRPLUS' print RRPLUS print '### R2' R2 = R2.coalesce() print R2 RRstar = RRPLUS RR_ident = RR.identity(RR.get_space()) RRstar = RRstar.union(RR_ident).coalesce() # R* = R+ u I print "### Rstar" print RRstar REPR = D.union(DOM_RAN.subtract(W)).coalesce() # poprawka REPR = R2.domain().subtract(R2.range()).coalesce() print '#REPR1' print REPR tmp = REPR.apply(RRstar).coalesce() REPR2 = DOM_RAN.subtract(tmp).coalesce() print '#REPR2' print REPR2 REPR = REPR.union(REPR2).coalesce() REPR = imperf_tile.SimplifySlice(REPR) ##### #REPR1:= domain RE2 - range RE2; #REPR2:= (domain R union R) -RR * (REPR1); #REPR = REPR.intersect(IS) print "### REPR" print REPR if (1 == 0): Rtmp = REPR.polyhedral_hull() if (Rtmp.subtract(REPR).coalesce().is_empty() and REPR.subtract(Rtmp).coalesce().is_empty()): print "upraszczanie" REPR = Rtmp R1 = RRstar.intersect_domain(REPR.coalesce()) # R1 = R1.intersect_range(IS) print 'RSCHED obliczanie :' print R1 print "IND0->IND" print IND0ToIND #print R3 print "i razem" #RSCHED = R1.union(IND0ToIND).coalesce() RSCHED = R1 #upraszczanie if (SIMPLIFY and 1 == 0): Rtmp = RSCHED.polyhedral_hull() if (Rtmp.subtract(RSCHED).coalesce().is_empty() and RSCHED.subtract(Rtmp).coalesce().is_empty()): print "upraszczanie" RSCHED = Rtmp #RSCHED = imperf_tile.SimplifyMap(RSCHED) print "### RSCHED" print RSCHED print "### Check " Check_set = RSCHED.domain().union(RSCHED.range()).coalesce() Check_set = IS.subtract(IND).subtract(Check_set).coalesce() if Check_set.is_empty(): print "OK" else: print "ERROR ! " + str(Check_set) sys.exit(0) # generowanie kodu D = RSCHED.domain() #if(SIMPLIFY): print "# DOMAIN RSCHED" print D D = D.apply(rap) D = imperf_tile.SimplifySlice(D) D = D.coalesce() print rap print D if (codegen == 'barvinok'): looprepr = iscc.iscc_communicate("L :=" + str(D) + "; codegen L;") else: # isl looprepr = iscc.isl_ast_codegen(D) for i in range(0, 20): looprepr = re.sub('\\b' + 'c' + str(i) + '\\b', 't' + str(i), looprepr) print looprepr looprepr = looprepr.split('\n') st_reg = re.compile('\s*\(.*\);') vecs = [] taby = [] for line in looprepr: if (st_reg.match(line)): vecs.append(line) #(isl.Set(iscc.s1_to_vec3(line, len(vecs)))) taby.append(iscc.correct.whites(line)) slices = [] for vec in vecs: #vec = isl.Set("[g1,g2,g3] -> {[g1,g2,g3]}") vec = GetConstraint(vec) slice = vec if (not RSCHED.is_empty()): slice_ = slice.apply(RSCHED) slice = slice.union(slice_).coalesce() slice = slice_ print '-------- IS --------' print IS slice = slice.intersect(IS).coalesce() print slice #if(SIMPLIFY): #slice = imperf_tile.SimplifySlice(slice) # EKSPERIMENTAL CODE wywal z RE instrukcje nie nalezace do RE if (1 == 0): temp = slice.intersect(W).coalesce() if (not temp.is_empty()): slice = temp slice = slice.apply(rap) wlen = len(sym_exvars) slice = slice.insert_dims(isl.dim_type.set, 2 * wlen, wlen * 2) print slice print isl_TILEbis slice = slice.intersect(isl_TILEbis) slices.append(slice.coalesce()) new_loop = [] i = 0 for line in looprepr: if (st_reg.match(line)): #print slices[i] if (codegen == 'barvinok'): petla = iscc.iscc_communicate("L :=" + str(slices[i]) + "; codegen L;") petla = petla.split('\n') else: #isl petla = iscc.isl_ast_codegen(slices[i]).split('\n') petla = correct.Korekta('', petla) # dodaj { } do for was_par = 0 # poprawic jak sie koncza petle i sa nowe for s in petla: if 'for (int c' in s and was_par == 0: new_loop.append(taby[i] + imperf_tile.get_tab(s) + '#pragma omp parallel for') if "{" in s: was_par = 1 new_loop.append(taby[i] + s) if was_par > 0: if "{" in s: was_par = was_par + 1 if "}" in s: was_par = was_par - 1 i = i + 1 else: new_loop.append(line) nloop = "" for line in new_loop: if line != '': # if 'for (int c1' in line: # c0 przy perf, c1 przy imperf # line = imperf_tile.get_tab(line) + "#pragma omp parallel for\n" +line nloop = nloop + line + "\n" nloop = nloop[:-1] nloop = nloop.split('\n') nloop = tiling_v3.postprocess_loop(nloop) lines = nloop.split('\n') loop = imperf_tile.RestoreStatements(lines, LPetit, dane, wlen, 1, []) #loop = imperf_tile.RestoreStatements(lines, LPetit, dane, maxl, step, permutate_list) print "==========================" print "OUTPUT CODE" print loop print UDS print UDS - REPR
if Lay0.is_empty() and Lay1.is_empty(): break Lay = Lay0.union(Lay1).coalesce() #Lay.card() crd = test_isl.StringToCard(str(Lay)) crd = crd.replace("[N] -> { ", "") crd = crd.replace(" : N = " + str(N) + " }", "") if (int(crd) < 1000): all = all + '// --------------\n' else: all = all + '// parallel -----\n' all = all + iscc.iscc_communicate("L :=" + str(Lay) + "; codegen L;") lines = all.split('\n') lines2 = [] pragma_par = 0 pragma_single = 0 single_block = 0 #lines2.append('#pragma acc kernels copyin(RNA) copy(S)') lines2.append("#pragma omp parallel shared(S,RNA)") lines2.append('{') for line in lines: if '(' in line and not 'if' in line and not 'for' in line:
def tile_par3(isl_TILEbis, sym_exvars, isl_rel, isl_relplus, isl_relclosure, Extend, _rap, Dodatek, SIMPLIFY, ii_SET): #print isl_TILEbis srepr, rucs = slicing.Create_Srepr(isl_rel, isl_relclosure) fs = 0 ir = isl_rel.domain().union(isl_rel.range()).coalesce() ir = ir.insert_dims(isl.dim_type.set, 0, len(sym_exvars)) for i in range(0, len(sym_exvars)): ir = ir.set_dim_name(isl.dim_type.set, i, sym_exvars[i]) if (Extend): for i in range(0, 2 * len(sym_exvars)): ir = ir.insert_dims(isl.dim_type.set, 2 * i, 1) srepr = srepr.insert_dims(isl.dim_type.set, 0, len(sym_exvars)) for i in range(0, len(sym_exvars)): srepr = srepr.set_dim_name(isl.dim_type.set, i, sym_exvars[i]) if (Extend): for i in range(0, 2 * len(sym_exvars)): srepr = srepr.insert_dims(isl.dim_type.set, 2 * i, 1) x = 1 if (Extend): x = 2 #relacja do obliczenia poczatkow Rel_Z = "{[" for i in range(0, 2 * x * len(sym_exvars)): Rel_Z = Rel_Z + "i" + str(i) + "," Rel_Z = Rel_Z + "m] -> [" for i in range(0, x * len(sym_exvars)): Rel_Z = Rel_Z + "i" + str(i) + "," Rel_Z = Rel_Z[:-1] + "] };" Rel_Z = isl.Map(Rel_Z) #relacja do wylapania instrukcji z blokow Rel_Y = "{[" for i in range(0, x * len(sym_exvars)): Rel_Y = Rel_Y + "i" + str(i) + "," for i in range(0, x * len(sym_exvars) + 1): Rel_Y = Rel_Y + "j" + str(i) + "," Rel_Y = Rel_Y[:-1] + "] -> [" for i in range(0, x * len(sym_exvars)): Rel_Y = Rel_Y + "i" + str(i) + "," for i in range(0, x * len(sym_exvars) + 1): Rel_Y = Rel_Y + "k" + str(i) + "," Rel_Y = Rel_Y[:-1] + "] };" Rel_Y = isl.Map(Rel_Y) Rel_W = "{[" for i in range(0, x * len(sym_exvars)): Rel_W = Rel_W + "i" + str(i) + "," Rel_W = Rel_W + "m1] -> [" for i in range(0, x * len(sym_exvars)): Rel_W = Rel_W + "o" + str(i) + "," Rel_W = Rel_W + "m2] : not (" for i in range(0, x * len(sym_exvars)): Rel_W = Rel_W + "i" + str(i) + " = " + "o" + str(i) + " and " Rel_W = Rel_W[:-4] + ")}" TILE_SOUR = isl_TILEbis.intersect(srepr).coalesce() TILE_IND = isl_TILEbis.subtract(isl_TILEbis.intersect(ir)).coalesce() indloop = iscc.iscc_communicate("L :=" + str(TILE_IND) + "; codegen L;") if (TILE_SOUR.lexmax() == TILE_SOUR.lexmin()): print "FS" fs = 1 else: print "=========================================================================" print "SLICING + TILING" if (rucs.is_empty()): isl_rel = isl_rel.union(rucs) isl_relclosure = isl_relclosure.union(rucs) isl_relplus = isl_relplus.union(rucs) rplus = tiling_v3.ExtendMap(isl_relplus, sym_exvars, Extend) rstar = tiling_v3.ExtendMap(isl_relclosure, sym_exvars, Extend) rel_ = tiling_v3.ExtendMap(isl_rel, sym_exvars, Extend) rucs = tiling_v3.ExtendMap(rucs, sym_exvars, Extend) rbis = isl.Map.from_domain_and_range(isl_TILEbis, isl_TILEbis) rs = rbis.intersect(rstar) rs = rs.union(rucs.transitive_closure()[0].intersect(rbis)).coalesce() Exp = True TMP2 = TILE_SOUR if (Exp and fs != 1): rel_simple = rbis.intersect(rel_) print rel_simple rel_simple = rel_simple.project_out(isl.dim_type.in_, x * len(sym_exvars), x * len(sym_exvars)) rel_simple = rel_simple.project_out(isl.dim_type.out, x * len(sym_exvars), x * len(sym_exvars)) relw = isl.Map(Rel_W) rel_simple = rel_simple.intersect(relw).coalesce() rel_simple = rel_simple.coalesce() print "RT" print rel_simple #independent tiles indt = rel_simple.domain().union(rel_simple.range()).coalesce() print indt #print II_SET #indt = ii_SET.subtract(indt).coalesce() # II_SET z Clana rel_simple_plus = rel_simple.transitive_closure()[0] print "RT+" print rel_simple_plus srepr, rucs = slicing.Create_Srepr(rel_simple, rel_simple_plus) print srepr # NAPRAWIC # !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! #add independent tiles for srepr #srepr = srepr.union(indt).coalesce() print "SREPR" print srepr print "RUCS" print rucs #sys.exit() # srepr = imperf_tile.SimplifySlice(srepr) srepr = srepr.insert_dims(isl.dim_type.set, x * len(sym_exvars), x * len(sym_exvars)) TILE_SOUR = isl_TILEbis.intersect(srepr).coalesce() TMP2 = TILE_SOUR if (fs != 1): if (rucs.is_empty()): TILE_SOUR = TILE_SOUR.subtract(TILE_SOUR.apply( rplus)).coalesce() # remove dependent blocks with srepr TILE_RUCS = slicing.Create_RUCS(rel_, rs, TILE_SOUR, TILE_SOUR, 1, Rel_Y) TILE_SOUR = TILE_SOUR.subtract(TILE_RUCS.range()).coalesce() print "TILE_RUCS" print TILE_RUCS print "TILE_SOUR" print TILE_SOUR TILE_SOUR = TMP2 z = TILE_SOUR.apply(Rel_Z).coalesce() if (SIMPLIFY): z = imperf_tile.SimplifySlice(z) srepr_loop = iscc.iscc_communicate("L :=" + str(z) + "; codegen L;") # albo omega #srepr_loop = iscc.oc_communicate(z) srepr_loop = srepr_loop.split('\n') for i in range(0, len(srepr_loop)): if "for" in srepr_loop[i]: srepr_loop.insert(i, "#pragma omp parallel for") break #print srepr_loop st_reg = re.compile('\s*\(.*\);') vecs = [] taby = [] for line in srepr_loop: if (st_reg.match(line)): vecs.append(isl.Set(iscc.s1_to_vec2(line, len(vecs)))) taby.append(iscc.correct.whites(line)) #print vecs permutate_maps = Dodatek[6] permutate_list = Dodatek[5] slices = [] for i in range(0, len(vecs)): vecs[i] = vecs[i].intersect(z).coalesce() for vec in vecs: vec = vec.insert_dims(isl.dim_type.set, x * len(sym_exvars), x * len(sym_exvars) + 1) #vec = vec.insert_dims(isl.dim_type.set, x*len(sym_exvars), 1) slice = vec #.apply(rs) slice = slice.apply(Rel_Y) slice = slice.apply(rs).coalesce() #print slice #print rs1 #slice = slice.apply(rs1).coalesce() #slice = slice.insert_dims(isl.dim_type.set, x*len(sym_exvars), x*len(sym_exvars)) #slice = slice.intersect(isl_TILEbis).coalesce() # experimental permutate if (len(permutate_list) > 0): print "Tiling + slicing + permutation - experimental" RP = permutate_maps[0] RIDENT = RP.identity(RP.get_space()) if (not RP.is_equal(RIDENT) ): #permute map is not an identity map strRP = str(RP) strh = "" for i in range(0, x * len(sym_exvars)): strh = strh + "xx" + str(i) + "," if (Extend): strkoma = strRP.split(",") strRP = "" for i in range(0, 2 * len(sym_exvars)): strRP = strRP + strkoma[i] + ", yy" + str( i % len(sym_exvars)) + ", " strRP = strRP + strkoma[2 * len(sym_exvars)] strRP = strRP.replace("[", "[" + strh) RP = isl.Map(strRP) slice = slice.apply(RP).coalesce() # --------------------------------------------------------- if (SIMPLIFY and False): slice = imperf_tile.SimplifySlice(slice) slices.append(slice) #print slice cmd = "" for i in range(0, len(vecs)): print "SLICE" print slices[i] cmd = cmd + "codegen " + str(slices[i]) + ';print "###";' cmd = iscc.iscc_communicate(cmd) cmd = cmd.split('"###"') new_loop = [] i = 0 for line in srepr_loop: if (st_reg.match(line)): petla = cmd[i].split('\n') for s in petla: new_loop.append(taby[i] + s) i = i + 1 else: new_loop.append(line) nloop = "" for line in new_loop: if line != '': nloop = nloop + line + "\n" nloop = nloop[:-1] nloop = nloop + "// independent statements \n" + indloop nloop = nloop.split('\n') # Dodatek = [LPetit, dane, maxl, step, nazwapar, permutate_list, permutate_maps] #permutate list nloop = tiling_v3.postprocess_loop(nloop) lines = nloop.split('\n') loop = imperf_tile.RestoreStatements(lines, Dodatek[0], Dodatek[1], Dodatek[2], Dodatek[3], Dodatek[5]) text_file = open(Dodatek[4], "w") text_file.write(loop) text_file.close() return "" else: rel_ = rbis.intersect(rel_) rel_ = rel_.project_out(isl.dim_type.in_, x * len(sym_exvars), x * len(sym_exvars)) rel_ = rel_.project_out(isl.dim_type.out, x * len(sym_exvars), x * len(sym_exvars)) rel_ = rel_.coalesce() relw = isl.Map(Rel_W) rel_ = rel_.intersect(relw).coalesce() print "REL" print rel_ #independent tiles #indt = rel_.domain().union(rel_.range()).coalesce() #indt = ii_SET.subtract(indt).coalesce() indt = "" # FS z RK sk = fs_rk.fs_rk1(rel_, SIMPLIFY, indt) # FS bez RK #sk = fs_karl.FSwithoutRG(rel_) sk = sk.insert_dims(isl.dim_type.set, x * len(sym_exvars) + 1, x * len(sym_exvars)) bis = isl_TILEbis.insert_dims(isl.dim_type.set, 0, 1) sk = bis.intersect(sk).coalesce() if (SIMPLIFY): sk = imperf_tile.SimplifySlice(sk) #sys.exit(0); print "SK" print sk print "Codegen now..." #fsloop = iscc.iscc_communicate("L :=" + str(sk) + "; codegen L;") fsloop = iscc.isl_ast_codegen(sk) print "Codegen done." nloop = fsloop.split('\n') nloop = tiling_v3.postprocess_loop(nloop) lines = fs_pragma(nloop) #Dodatek[2]+1 shift + 1 for k #if extend first shift shoud be one smaller if (Extend): sh = 1 else: sh = 0 loop = imperf_tile.RestoreStatements(lines, Dodatek[0], Dodatek[1], Dodatek[2] + 1, Dodatek[3], Dodatek[5], sh) text_file = open(Dodatek[4], "w") text_file.write(loop) text_file.close() return ""
def tile(plik, block, permute, output_file="", L="0", SIMPLIFY="False", perfect_mode=False, parallel_option=False, rplus_mode='', cpus=2): print '' print colored('/\__ _\ /\ == \ /\ __ \ /\ ___\ /\ __ \ ', 'green') print colored('\/_/\ \/ \ \ __< \ \ __ \ \ \ \____ \ \ \/\ \ ', 'green') print colored(' \ \_\ \ \_\ \_\ \ \_\ \_\ \ \_____\ \ \_____\ ', 'green') print colored(' \/_/ \/_/ /_/ \/_/\/_/ \/_____/ \/_____/ ', 'green') print '' print ' An Automatic Parallelizer and Optimizer' print 'based on the ' + colored('TRA', 'green') + 'nsitive ' + colored( 'C', 'green') + 'l' + colored('O', 'green') + 'sure of dependence graphs' print ' traco.sourceforge.net ' print '' print 'TIME SPACE TILING Module' LPetit = "tmp/tmp_petit" + L + ".t" BLOCK = block.split(',') BLOCK2 = BLOCK for i in range(len(BLOCK), 10): BLOCK.append(BLOCK[len(BLOCK) - 1]) linestring = open(plik, 'r').read() lines = linestring.split('\n') petit_loop = convert_loop.convert_loop(lines) file = open(LPetit, 'w') imperf = 0 endloop = 0 startloop = 0 for line in petit_loop: #sprawdz przy okazji jaka petla idealnie czy nie if 'for' in line and not 'endfor' in line: if startloop == 2: imperf = 1 startloop = 1 else: if startloop == 1: startloop = 2 if 'endfor' in line: endloop = 1 if endloop == 1 and 'endfor' not in line and not line.isspace( ) and line != '': imperf = 1 file.write(line + '\n') file.close() start = time.time() loop = Dependence.Kernel_Loop(LPetit, 1) loop.Load_Deps() loop.Load_instrukcje() loop.PreprocessPet() loop.Get_Arrays() end = time.time() elapsed = end - start print "Dependence analysis: time taken: ", elapsed, "seconds." print colored('R', 'green') print loop.isl_rel isl_symb = loop.Deps[0].Relation.get_var_names(isl.dim_type.param) symb_prefix = '' if len(isl_symb) > 0: symb_prefix = '[' + ','.join(isl_symb) + '] -> ' cl = clanpy.ClanPy() cl.loop_path = plik cl.Load() arr = map(int, loop.dane) arr = sorted(list(set(arr))) for i in range(0, len(cl.statements)): cl.statements[i].petit_line = arr[i] cl.statements[i].bounds = tiling_v5.GetBounds( petit_loop, cl.statements[i].petit_line, BLOCK2, 0) print cl.statements[i].scatering for i in range(0, len(cl.statements)): cl.statements[i].domainpet = isl.Set( symb_prefix + ' { S' + str(cl.statements[i].petit_line) + '[' + ','.join(cl.statements[i].original_iterators) + '] : ' + cl.statements[i].domain + '}') #print cl.statements[i].domainpet IS = isl.UnionSet(str(cl.statements[0].domainpet)) for i in range(1, len(cl.statements)): IS = IS.union(cl.statements[i].domainpet) IS = IS.coalesce() print colored('IS', 'green') print IS #isl schedule text = 'R:= ' + str(loop.isl_rel) + '; IS := ' + str( IS) + '; schedule IS respecting R minimizing R;' print colored('ISL output', 'green') sched_dump = iscc.iscc_communicate(text) print sched_dump lines = sched_dump.split('\n') sched_maps = sched_parser.parse(lines, cl, symb_prefix) print colored('ISL schedules', 'green') for m in sched_maps: print m SCHED = isl.UnionMap(str(sched_maps[0])) for i in range(1, len(sched_maps)): SCHED = SCHED.union(sched_maps[i]) SCHED = SCHED.coalesce() #SCHED = isl.UnionMap('[N] -> { S27[i, j] -> [-i + j, 2,j] : N > 0 and 0 <= i <= -2 + N and i < j < N; S20[i, j, k] -> [-i + j, 0,0,1,k] : N > 0 and 0 <= i <= -2 + N and 2 + i <= j < N and i < k < j; S23[i, j, k] -> [-i + j, 0,k,2, j] : N > 0 and 0 <= i <= -2 + N and 2 + i <= j < N and i < k <= -2 + j; S26[i, j] -> [-i + j, 1,j] : N > 0 and 0 <= i <= -2 + N and i < j < N; S16[i, j, k, m] -> [-i + j, 0,k, 0,m] : N > 0 and 0 <= i <= -2 + N and 2 + i <= j < N and i < k <= -2 + j and k < m <= -3 - i + j + k and m < j }') #SCHED = isl.UnionMap('[n, loop] -> { S12[l, i, k] -> [l,i,k] : n >= 2 and loop > 0 and 0 < l <= loop and 0 < i < n and 0 <= k < i }') print colored('SCHED', 'green') print SCHED #print colored('deltas R', 'green') # SPACE # wykryj liczbe na razie globalnie islR = Scatter(loop.isl_rel, cl, True) D = loop.isl_rel.deltas() spaces_num = sys.maxint for i in range(0, len(cl.statements)): depth = len(cl.statements[i].original_iterators) nums = 0 for j in range(0, depth): direct = ' < ' print cl.statements[i].bounds[j]['step'] # decrementation if cl.statements[i].bounds[j]['step'] == '-1': direct = ' > ' TEST = '{ S' + str(cl.statements[i].petit_line) + '[' + ','.join( cl.statements[i].original_iterators) + '] : ' + cl.statements[ i].original_iterators[j] + direct + ' 0 }' print TEST TEST = isl.Set(TEST) TEST = D.intersect(TEST) if (TEST.is_empty()): nums = nums + 1 else: break # sa ujemne # print nums if (nums < spaces_num): spaces_num = nums print colored('SPACES NUMBER', 'green') print spaces_num if spaces_num == 0 or 1 == 1: print 'No spaces or manually input calculated number' spaces_num = int(raw_input()) # vars vars = [] sym_exvars = [] for st in cl.statements: if (len(st.original_iterators) == loop.maxl): vars = st.original_iterators break for v in vars: sym_exvars.append(v * 2) ################################## SPACES = {} space = '' for st in cl.statements: tmpspaces = [] for i in range(0, spaces_num): space = st.domainpet space = space.insert_dims(isl.dim_type.param, 0, 1) space = space.set_dim_name(isl.dim_type.param, 0, sym_exvars[i]) space = str(space) space = space.replace( '}', MakesSpaceConstr(st, vars, sym_exvars, isl_symb, BLOCK, i)) print space space = isl.Set(space) tmpspaces.append(space) #print space SPACES["S" + str(st.petit_line)] = tmpspaces ################################## #experimental Rk if False: print "==============================================" spaceunion = None for s in SPACES: print s tmpspace = None for ss in SPACES[s]: if tmpspace is None: tmpspace = isl.UnionSet(str(ss)) else: tmpspace = tmpspace.union(ss).coalesce() if spaceunion is None: spaceunion = tmpspace else: spaceunion = spaceunion.union(tmpspace).coalesce() if (1 == 0): print "Experimental Rk" print "SPACE" print spaceunion print "new R" R = loop.isl_rel.from_domain_and_range(spaceunion, spaceunion).coalesce() print R #Rk = R.power() #print "Rk" print Rk print "==============================================" ################################### sched_maps_i = sched_maps #SCHED_1 SCHED_2 TIMES = [] if (spaces_num < cl.maxdim): print colored("SCHED_1:=SCHED^-1", 'green') for i in range(0, len(sched_maps_i)): sched_maps_i[i] = sched_maps_i[i].fixed_power_val(-1).coalesce() print sched_maps_i[i] #if i == 3: # sched_maps_i[i] = isl.Map('[N] -> {[i0, 0] -> S20[i, j = i0 + i]: N > 0 and 0 <= i <= -2 + N and i0=1}') TIMES.append(sched_maps_i[i]) tmp = '' if ("i0" in str(TIMES[i])): TIMES[i] = TIMES[i].insert_dims(isl.dim_type.param, 0, 1) TIMES[i] = TIMES[i].set_dim_name(isl.dim_type.param, 0, 'c') TIMES[i] = TIMES[i].insert_dims(isl.dim_type.param, 0, 1) TIMES[i] = TIMES[i].set_dim_name(isl.dim_type.param, 0, 'i0') tmp = str(TIMES[i]) if 'i1' in tmp: v = 'i1' else: v = 'i0' tmp = tmp.replace('}', " && " + str(BLOCK[spaces_num]) + "c<=" + v + "<=" + str(BLOCK[spaces_num]) + "*(c+1)-1 && i0=i0' }") # podmien na bloki else: tmp = str(TIMES[i]) TIMES[i] = isl.Map(tmp).range() print colored("TIMEi", 'green') for s in TIMES: print s print colored("TIME", 'green') else: print colored("TIME: all distance vectors elements are positive", 'green') for i in range(0, len(sched_maps_i)): TIMES.append(sched_maps_i[i].subtract( sched_maps_i[i]).complement().domain().coalesce()) ######################################### TIMES experimental code TIME = isl.UnionSet(str(TIMES[i])) for i in range(1, len(TIMES)): TIME = TIME.union(TIMES[i]) TIME = TIME.coalesce() print TIME ######################################### TILES = [] for i in range(0, len(TIMES)): TILES.append(TIMES[i]) for j in range(0, spaces_num): TILES[i] = TILES[i].intersect( SPACES['S' + str(cl.statements[i].petit_line)][j]).coalesce() TILE = isl.UnionSet(str(TILES[0])) for i in range(1, len(TILES)): TILE = TILE.union(TILES[i]) TILE = TILE.coalesce() print colored("TILE", 'green') print TILE print "Making MAP %%%" ########################################### # MAKE MAP TILE = str(TILE).split('->')[1] # j=i-i0 crazy thing #################################################### wstawia oryginalne iteratory, dodaje rownania i scattering strTILE = TILE.split(';') for st in cl.statements: s = 'S' + str(st.petit_line) for i in range(0, len(strTILE)): if s in strTILE[i]: res = re.findall(r'S\d+\[[^\]]+', strTILE[i]) a = st.scatering b = st.original_iterators[:] for k in range(0, st.getDim()): if st.bounds[k]['step'] == '-1': b[k] = '-' + b[k] if (len(a) < cl.maxdim + 1): for k in range(len(a), cl.maxdim + 1): #wyrownaj zerami a.append(u'0') if (len(b) < cl.maxdim): for k in range(len(b), cl.maxdim): #wyrownaj zerami b.append(u'0') c = a + b #scatter c[::2] = a c[1::2] = b strTILE[i] = strTILE[i].replace(res[0], s + '[' + ','.join(c)) res = res[0].split('[')[1].replace(' ', '').split(',') for r in res: if '=' in r: strTILE[i] = strTILE[i].replace( ':', ': ' + r + ' and ') break else: continue TILE = ';'.join(strTILE) print TILE ##################################################### arr = [] arr.append('t') timet = [] if spaces_num == 0: timet.append('0') for i in range(0, spaces_num): arr.append(sym_exvars[i]) timet.append(sym_exvars[i]) arr.append('i0') arr.append('c,') arr = ','.join(arr) TILE = TILE.replace('[', '[' + arr) timet = ' t = ' + '+'.join(timet) if (spaces_num >= cl.maxdim): # dodatnie wektory timet += ' and c = 0 and i0 = 0 ' TILE = symb_prefix + TILE.replace(':', ':' + timet + ' and ') for st in cl.statements: s = 'S' + str(st.petit_line) TILE = TILE.replace( s, s + '[' + ','.join(st.original_iterators) + '] -> ') print colored("MAP", 'green') print TILE print 'MAP in ISL' print isl.UnionMap(TILE).coalesce() #loop_x = iscc.iscc_communicate("L :=" + str(TILE) + "; codegen L;") #print loop_x print colored("ISL AST", 'green') loop_x = iscc.isl_ast_codegen_map(isl.UnionMap(TILE)) print loop_x # ************************************************************************** lines = loop_x.split('\n') # *********** post processing **************** print colored("POSTPROCESSING", 'green') loop_str = [] for line in lines: if line.endswith(');'): tab = imperf_tile.get_tab(line) line = line.replace(' ', '') line = line[:-2] line = line[1:] line = line.split('(') petit_st = line[0].replace('S', '') line = line[1] arr = line.split(',') s = '' for i in range(0, len(cl.statements)): # TODO if petit_st has 'c' get all statements make if from petit_line and insert to s, solution for loop over st if 'c' in petit_st: combo_st = '{' for j in range(0, len(cl.statements)): combo_st += '\n' + tab combo_st += 'if( ' + petit_st + ' == ' + str(cl.statements[j].petit_line) + ' ) ' + \ cl.statements[j].body s = combo_st + '\n' + tab + '}' elif cl.statements[i].petit_line == int( petit_st): # st.petit_line s = cl.statements[i].body for i in range( 0, len(vars) ): # todo oryginal iterators for loops with mixed indexes if (i + 1 > len(arr)): continue subt = arr[i] if (('+' in subt) or ('-' in subt)): subt = '(' + subt + ')' s = re.sub(r'\b' + vars[i] + r'\b', subt, s) loop_str.append(tab + s) else: line = line.replace('for (int', 'for(') loop_str.append(line) # *********** post processing end **************** if (1 == 1): for line in loop_str: if 'for( c1 ' in line and spaces_num < cl.maxdim: print imperf_tile.get_tab(line) + colored( '#pragma omp parallel for', 'green') print line # VALIDITY # Lex_Neg2:=[N]->{ [i0, i1]: (i0=0 and i1=0 ) or i0<0 or i0=0 and i1<0 }; # VALIDITY SCHED2 = Scatter(SCHED, cl, False) L = 2 * cl.maxdim + 1 lexvar = ["i%d" % i for i in range(0, L)] lexneg = '{[' + ','.join(lexvar) + '] : (' for i in range(0, L): lexneg += lexvar[i] + '=0' + ' and ' lexneg += '1=1) or ' for i in range(0, L): lexneg += lexvar[i] + ' < 0 and ' for j in range(0, i): lexneg += lexvar[j] + ' = 0 and ' lexneg += ' 1 = 1 or ' lexneg += ' 1 = 0 }' lexneg = isl.Set(lexneg) C = (SCHED2.fixed_power_val(-1).apply_range(islR)).apply_range(SCHED2) P = C.deltas().intersect(lexneg).coalesce() if P.is_empty(): print colored('VALIDATION OK', 'green') else: print colored('VALIDATION FAILED !!', 'red') print colored('lexneg', 'yellow') print lexneg print colored('C = (SCHED^-1(R))(SCHED)', 'yellow') print C print colored('P = C.deltas()', 'yellow') print C.deltas() print colored('P*C', 'yellow') print P for d in loop.Deps: del d.Relation
def tile_par2(isl_TILEbis, sym_exvars, isl_rel, isl_relplus, isl_relclosure, Extend, _rap, Dodatek, SIMPLIFY): #with open('sources_of_slices.txt') as f: # content = f.readlines() # srepr = content[0] #srepr = isl.Set(srepr) #with open('rucs.txt') as f: # content = f.readlines() # rucs = content[0] #_rel = _rel.remove_dims(isl.dim_type.in_, 0,1) #_rel = _rel.remove_dims(isl.dim_type.out, 0,1) #print _rel ''' ir = isl_rel print ir ir = ir.insert_dims(isl.dim_type.in_, 0, len(sym_exvars)) ir = ir.insert_dims(isl.dim_type.out, 0, len(sym_exvars)) print ir ir2 = ir.from_domain_and_range(isl_TILEbis, isl_TILEbis).coalesce() ir = ir2.intersect(ir).coalesce() print ir ir = ir.remove_dims(isl.dim_type.in_, len(sym_exvars),len(sym_exvars)) ir = ir.remove_dims(isl.dim_type.out, len(sym_exvars),len(sym_exvars)) ir = ir.coalesce() print ir sys.exit(0); ''' srepr, rucs = slicing.Create_Srepr(isl_rel, isl_relclosure) print srepr ir = isl_rel.domain().union(isl_rel.range()).coalesce() ir = ir.insert_dims(isl.dim_type.set, 0, len(sym_exvars)) for i in range(0, len(sym_exvars)): ir = ir.set_dim_name(isl.dim_type.set, i, sym_exvars[i]) if (Extend): for i in range(0, 2 * len(sym_exvars)): ir = ir.insert_dims(isl.dim_type.set, 2 * i + 1, 1) srepr = srepr.insert_dims(isl.dim_type.set, 0, len(sym_exvars)) for i in range(0, len(sym_exvars)): srepr = srepr.set_dim_name(isl.dim_type.set, i, sym_exvars[i]) if (Extend): for i in range(0, 2 * len(sym_exvars)): srepr = srepr.insert_dims(isl.dim_type.set, 2 * i + 1, 1) x = 1 if (Extend): x = 2 #relacja do obliczenia poczatkow Rel_Z = "{[" for i in range(0, 2 * x * len(sym_exvars)): Rel_Z = Rel_Z + "i" + str(i) + "," Rel_Z = Rel_Z + "m] -> [" for i in range(0, x * len(sym_exvars)): Rel_Z = Rel_Z + "i" + str(i) + "," Rel_Z = Rel_Z[:-1] + "] };" Rel_Z = isl.Map(Rel_Z) #relacja do wylapania instrukcji z blokow Rel_Y = "{[" for i in range(0, x * len(sym_exvars)): Rel_Y = Rel_Y + "i" + str(i) + "," for i in range(0, x * len(sym_exvars) + 1): Rel_Y = Rel_Y + "j" + str(i) + "," Rel_Y = Rel_Y[:-1] + "] -> [" for i in range(0, x * len(sym_exvars)): Rel_Y = Rel_Y + "i" + str(i) + "," for i in range(0, x * len(sym_exvars) + 1): Rel_Y = Rel_Y + "k" + str(i) + "," Rel_Y = Rel_Y[:-1] + "] };" Rel_Y = isl.Map(Rel_Y) TILE_SOUR = isl_TILEbis.intersect(srepr).coalesce() TILE_IND = isl_TILEbis.subtract(isl_TILEbis.intersect(ir)).coalesce() indloop = iscc.iscc_communicate("L :=" + str(TILE_IND) + "; codegen L;") fs = 0 if (TILE_SOUR.lexmax() == TILE_SOUR.lexmin()): print "FS" fs = 1 else: print "SLICING" if (rucs.is_empty()): isl_rel = isl_rel.union(rucs) isl_relclosure = isl_relclosure.union(rucs) isl_relplus = isl_relplus.union(rucs) rplus = tiling_v3.ExtendMap(isl_relplus, sym_exvars, Extend) rstar = tiling_v3.ExtendMap(isl_relclosure, sym_exvars, Extend) rel_ = tiling_v3.ExtendMap(isl_rel, sym_exvars, Extend) #rucs = tiling_v3.ExtendMap(rucs, sym_exvars, Extend) rbis = isl.Map.from_domain_and_range(isl_TILEbis, isl_TILEbis) rs = rbis.intersect(rstar) rt_red = rbis.intersect(rplus) if (fs != 1): if (rucs.is_empty()): TILE_SOUR = TILE_SOUR.subtract(TILE_SOUR.apply( rplus)).coalesce() # remove dependent blocks with srepr TILE_RUCS = slicing.Create_RUCS(rel_, rs, TILE_SOUR, TILE_SOUR, 1, Rel_Y) TILE_SOUR = TILE_SOUR.subtract(TILE_RUCS.range()).coalesce() z = TILE_SOUR.apply(Rel_Z).coalesce() if (SIMPLIFY): z = imperf_tile.SimplifySlice(z) srepr_loop = iscc.iscc_communicate("L :=" + str(z) + "; codegen L;") # albo omega #srepr_loop = iscc.oc_communicate(z) print srepr_loop srepr_loop = srepr_loop.split('\n') for i in range(0, len(srepr_loop)): if "for" in srepr_loop[i]: srepr_loop.insert(i, "#pragma omp parallel for") break st_reg = re.compile('\s*\(.*\);') vecs = [] taby = [] for line in srepr_loop: if (st_reg.match(line)): vecs.append(isl.Set(iscc.s1_to_vec2(line, len(vecs)))) taby.append(iscc.correct.whites(line)) #print vecs permutate_maps = Dodatek[6] permutate_list = Dodatek[5] slices = [] for i in range(0, len(vecs)): vecs[i] = vecs[i].intersect(z).coalesce() for vec in vecs: vec = vec.insert_dims(isl.dim_type.set, x * len(sym_exvars), x * len(sym_exvars) + 1) slice = vec #.apply(rs) slice = slice.apply(Rel_Y) slice = slice.apply(rs).coalesce() # experimental permutate if (len(permutate_list) > 0): print "Tiling + slicing + permutation - experimental" RP = permutate_maps[0] RIDENT = RP.identity(RP.get_space()) if (not RP.is_equal(RIDENT) ): #permute map is not an identity map strRP = str(RP) strh = "" for i in range(0, x * len(sym_exvars)): strh = strh + "xx" + str(i) + "," if (Extend): strkoma = strRP.split(",") strRP = "" for i in range(0, 2 * len(sym_exvars)): strRP = strRP + strkoma[i] + ", yy" + str( i % len(sym_exvars)) + ", " strRP = strRP + strkoma[2 * len(sym_exvars)] strRP = strRP.replace("[", "[" + strh) RP = isl.Map(strRP) slice = slice.apply(RP).coalesce() # --------------------------------------------------------- if (SIMPLIFY): slice = imperf_tile.SimplifySlice(slice) slices.append(slice) print slice cmd = "" for i in range(0, len(vecs)): cmd = cmd + "codegen " + str(slices[i]) + ';print "###";' cmd = iscc.iscc_communicate(cmd) cmd = cmd.split('"###"') new_loop = [] i = 0 for line in srepr_loop: if (st_reg.match(line)): petla = cmd[i].split('\n') for s in petla: new_loop.append(taby[i] + s) i = i + 1 else: new_loop.append(line) nloop = "" for line in new_loop: if line != '': nloop = nloop + line + "\n" nloop = nloop[:-1] #nloop = nloop + indloop nloop = nloop.split('\n') # Dodatek = [LPetit, dane, maxl, step, nazwapar, permutate_list, permutate_maps] #permutate list nloop = tiling_v3.postprocess_loop(nloop) lines = nloop.split('\n') loop = imperf_tile.RestoreStatements(lines, Dodatek[0], Dodatek[1], Dodatek[2], Dodatek[3], Dodatek[5]) text_file = open(Dodatek[4], "w") text_file.write(loop) text_file.close() return "" else: print "fs (EXPERIMENTAL) ..." sym_tmp = [] rlex = "{[" for s in sym_exvars: rlex = rlex + s + "," sym_tmp.append(s + "'") rlex = rlex[:-1] + '] -> [' for s in sym_exvars: rlex = rlex + s + "'," rlex = rlex[:-1] + '] : ' rlex = rlex + tiling_v3.CreateLex(sym_tmp, sym_exvars) + "};" rlex = isl.Map(rlex) rlex = rlex.insert_dims(isl.dim_type.in_, len(sym_exvars), len(sym_exvars) + 1) rlex = rlex.insert_dims(isl.dim_type.out, len(sym_exvars), len(sym_exvars) + 1) UDS = isl_rel.domain().subtract(isl_rel.range()) UDS = UDS.insert_dims(isl.dim_type.set, 0, len(sym_exvars)) for i in range(0, len(sym_exvars)): UDS = UDS.set_dim_name(isl.dim_type.set, i, sym_exvars[i]) if (Extend): for i in range(0, 2 * len(sym_exvars)): UDS = UDS.insert_dims(isl.dim_type.set, 2 * i + 1, 1) rlex = rlex.insert_dims(isl.dim_type.in_, 2 * i + 1, 1) rlex = rlex.insert_dims(isl.dim_type.out, 2 * i + 1, 1) tuds = UDS.intersect(isl_TILEbis).coalesce() #tuds = tuds.insert_dims(isl.dim_type.set, len(sym_exvars), len(sym_exvars)+1) rt_red = rt_red.intersect(rlex).coalesce() rk = rt_red.power() rk = rk[0] rk = isl.Map(iscc.RepairRk(str(rk), 0)) rp = rt_red.transitive_closure()[0] sk = tuds.apply(rk).subtract(tuds.apply(rk).apply(rp)).coalesce() sk = sk.apply(Rel_Y).intersect(isl_TILEbis) sk = sk.insert_dims(isl.dim_type.set, 0, 1) sk = sk.set_dim_name(isl.dim_type.set, 0, "ink") c = isl.Constraint.eq_from_names(sk.get_space(), {"k": -1, "ink": 1}) sk = sk.add_constraint(c) sk = tiling_v3.Project(sk, ["k"]) tuds = tuds.apply(Rel_Y).intersect(isl_TILEbis) tuds = tuds.insert_dims(isl.dim_type.set, 0, 1) tuds = tuds.set_dim_name(isl.dim_type.set, 0, "ink") c = isl.Constraint.eq_from_names(sk.get_space(), {1: 0, "ink": 1}) tuds = tuds.add_constraint(c) sk = sk.union(tuds) print sk fsloop = iscc.iscc_communicate("L :=" + str(sk) + "; codegen L;") nloop = fsloop.split('\n') nloop = tiling_v3.postprocess_loop(nloop) lines = fs_pragma(nloop) #Dodatek[2]+1 shift + 1 for k #if extend first shift shoud be one smaller if (Extend): sh = 1 else: sh = 0 loop = imperf_tile.RestoreStatements(lines, Dodatek[0], Dodatek[1], Dodatek[2] + 1, Dodatek[3], Dodatek[5], sh) text_file = open(Dodatek[4], "w") text_file.write(loop) text_file.close() return ""
def tile_par(isl_TILEprim, isl_TILEbis, sym_exvars, symb, isl_rel, isl_relplus, isl_relclosure): nloop = "" srepr = "" with open('sources_of_slices.txt') as f: content = f.readlines() srepr = content[0] srepr = isl.Set(srepr) srepr = srepr.insert_dims(isl.dim_type.set, 0, len(sym_exvars)) for i in range(0, len(sym_exvars)): srepr = srepr.set_dim_name(isl.dim_type.set, i, sym_exvars[i]) Rel_Z = "{[" for i in range(0, 2 * len(sym_exvars)): Rel_Z = Rel_Z + "i" + str(i) + "," Rel_Z = Rel_Z + "m] -> [" for i in range(0, len(sym_exvars)): Rel_Z = Rel_Z + "i" + str(i) + "," Rel_Z = Rel_Z[:-1] + "] };" Rel_Z = isl.Map(Rel_Z) Bis_Combo = isl_TILEbis[0] for j in range(1, len(isl_TILEbis)): Bis_Combo = Bis_Combo.union(isl_TILEbis[j]).coalesce() TILE_SOUR = Bis_Combo.intersect(srepr).coalesce() print TILE_SOUR fs = 0 if (TILE_SOUR.lexmax() == TILE_SOUR.lexmin()): print "FS" fs = 1 else: print "SLICING" rplus = tiling_v3.ExtendMap(isl_relplus, sym_exvars) rstar = tiling_v3.ExtendMap(isl_relclosure, sym_exvars) rt_red = tiling_v3.ExtendMap(isl_rel, sym_exvars) rs = isl.Map.from_domain_and_range(Bis_Combo, Bis_Combo) rs = rs.intersect(rplus) rt_red = rs.intersect(rs) if (fs != 1): z = TILE_SOUR.apply(Rel_Z) srepr_loop = iscc.iscc_communicate("L :=" + str(z) + "; codegen L;") rs = iscc.iscc_communicate(str(rs) + ";", 1).split('\n')[0] rs = iscc.RelationExists(rs, len(sym_exvars), symb) srepr_loop = srepr_loop.split('\n') for i in range(0, len(srepr_loop)): if "for" in srepr_loop[i]: srepr_loop.insert(i, "#pragma omp parallel for") break st_reg = re.compile('\s*\(.*\);') vecs = [] taby = [] for line in srepr_loop: if (st_reg.match(line)): vecs.append(iscc.s1_to_vec(line, len(vecs))) taby.append(iscc.correct.whites(line)) #R_T = iscc_communicate("RS := " + rs + ";RS;") cmd = "RT :=" + rs + ";" for i in range(0, len(vecs)): cmd = cmd + vecs[i] + "codegen RT(S" + str(i) + ');print "###";' cmd = iscc.iscc_communicate(cmd) cmd = cmd.split('"###"') new_loop = [] i = 0 for line in srepr_loop: if (st_reg.match(line)): petla = cmd[i].split('\n') for s in petla: new_loop.append(taby[i] + s) i = i + 1 else: new_loop.append(line) #print new_loop nloop = "" for line in new_loop: if line != '': nloop = nloop + line + "\n" nloop = nloop[:-1] isl_TILEprim_ = isl_TILEprim[0].union(isl_TILEprim[1]) bl_2half = iscc.iscc_communicate("L :=" + str(isl_TILEprim[0]) + "; codegen L;") slice_tiling(nloop, bl_2half, sym_exvars) else: I = isl.Map.identity( isl.Space.create_from_names(ctx, in_=sym_exvars, out=sym_exvars)).coalesce() sym_tmp = [] rlex = "{[" for s in sym_exvars: rlex = rlex + s + "," sym_tmp.append(s + "'") rlex = rlex[:-1] + '] -> [' for s in sym_exvars: rlex = rlex + s + "'," rlex = rlex[:-1] + '] : ' rlex = rlex + tiling_v3.CreateLex(sym_tmp, sym_exvars) + "};" rlex = isl.Map(rlex) UDS = isl_rel.domain().subtract(isl_rel.range()) UDS = UDS.insert_dims(isl.dim_type.set, 0, len(sym_exvars)) for i in range(0, len(sym_exvars)): UDS = UDS.set_dim_name(isl.dim_type.set, i, sym_exvars[i]) tuds = UDS.intersect(isl_TILEbis[0]).coalesce().apply(Rel_Z).coalesce() rt_red = iscc.iscc_communicate(str(rt_red) + ";", 1).split('\n')[0] rt_red = iscc.RelationExists(rt_red, len(sym_exvars), symb) #rk = iscc_communicate(rlex + 'RT_RED := ' + rt_red + "*RLEX;pow RT_RED;") rt_red = isl.Map(rt_red).intersect(rlex).coalesce() rk = rt_red.power() rk = rk[0] rk = isl.Map(iscc.RepairRk(str(rk), 0)) rp = rt_red.transitive_closure()[0] sk = tuds.apply(rk).subtract(tuds.apply(rk).apply(rp)).coalesce() sk = sk.insert_dims(isl.dim_type.set, 0, 1) sk = sk.set_dim_name(isl.dim_type.set, 0, "ink") c = isl.Constraint.eq_from_names(sk.get_space(), {"k": -1, "ink": 1}) sk = sk.add_constraint(c) sk = tiling_v3.Project(sk, ["k"]) tuds = tuds.insert_dims(isl.dim_type.set, 0, 1) tuds = tuds.set_dim_name(isl.dim_type.set, 0, "ink") c = isl.Constraint.eq_from_names(sk.get_space(), {1: 0, "ink": 1}) tuds = tuds.add_constraint(c) sk = sk.union(tuds) fsloop = iscc.iscc_communicate("L :=" + str(sk) + "; codegen L;") bl_2half = iscc.iscc_communicate("L :=" + str(isl_TILEprim[0]) + "; codegen L;") slice_tiling(fsloop, bl_2half, sym_exvars, 1)
def codegen(islSet, instrukcje, offset, vars, symexvars): # wyszukaj instrukcje z relacji # 0 0 # 1 0 # inkrementuj ostatni zeruj dalsze licznik = [0] * len(symexvars) isl_R = "" first = 1 for item in instrukcje: if (first != 1): licznik[len(item['path']) - 1] = licznik[len(item['path']) - 1] + 1 for i in range(len(item['path']), len(symexvars)): licznik[i] = 0 #print licznik # buduj relacje # R = {[vars, ..., v] -> [licznik, vars, licznik, vars, v] : v nalezy do st } R = "{[" + ','.join(symexvars) + "," + ','.join( vars) + ',v] -> [' + ','.join(symexvars) + "," for i in range(0, len(licznik)): R = R + str(licznik[i]) + ',' + vars[i] + ',' R = R + 'v] : ' for v in item['st']: R = R + 'v = ' + str(v) + ' or ' R = R[:-3] + "}" if (first == 1): isl_R = isl.Map(str(R)).coalesce() first = 0 else: isl_R = isl_R.union(isl.Map(str(R))).coalesce() isl_S = islSet.apply(isl_R).coalesce() loop = iscc.iscc_communicate("L :=" + str(isl_S) + "; codegen L;") # zamien z powrotem s1 lines = loop.split("\n")[:-1] loop2 = "" st = "" for i in range(0, len(lines)): tmp = lines[i] pattern = re.compile("^\W*\(") # w przyszlosci moga byc s1 S1 s2 S2 if pattern.match(tmp): tmp = tmp.split(",") count = len(symexvars) + len(vars) * 2 tmp2 = [] j = 0 for i in range(0, count + 1): if i >= len( symexvars) and i <= count - 1: # nie ruszaj symexvars j = j + 1 if (j % 2): continue # nie dodawaj tych else: tmp2.append(tmp[i]) else: tmp2.append(tmp[i]) loop2 = loop2 + ','.join(tmp2) + "\n" else: loop2 = loop2 + tmp + "\n" print loop2 return loop2
cmd += 'print RaW;' cmd += 'print "WaW deps";' cmd += 'print WaW;' cmd += 'print "WaR deps";' cmd += 'print WaR;' cmd += 'R := WaR + WaW + RaW;' cmd += 'print "R";' cmd += 'R;' cmd += 'LDR := domain R + range R;' cmd += 'IND := Domain - LDR;' cmd += 'print "IND";' cmd += 'print IND;' ####################################################################### # RESULT TO ISLPY output = loop_x = iscc.iscc_communicate(cmd) output = output.split('\n') schedule = output[1] ld = output[3] rel = output[11] ind = output[13] ld = isl.UnionSet(ld) ind = isl.UnionSet(ind) schedule = isl.UnionMap(schedule) strrel = rel rel = isl.UnionMap(rel) print rel
def tile(plik, block, permute, output_file="", L="0", SIMPLIFY="False", perfect_mode=False, parallel_option=False, rplus_file=''): SIMPLIFY = False DEBUG = True schedule_mode = parallel_option #print "********** another version **************" LPetit = "tmp/tmp_petit" + L + ".t" LDeps = "tmp/deps" + L + ".txt" # strong perfect if (DEBUG): if perfect_mode: print 'Perfectly nested loop mode: enabled' simpl_ub = False BLOCK = block.split(',') par_tiling = False for i in range(len(BLOCK), 10): BLOCK.append(BLOCK[len(BLOCK) - 1]) if (not BLOCK[1].isdigit()): par_tiling = True linestring = open(plik, 'r').read() lines = linestring.split('\n') if simpl_ub: petit_loop = convert_loop.convert_loop(lines, BLOCK) else: petit_loop = convert_loop.convert_loop(lines) file = open(LPetit, 'w') imperf = 0 endloop = 0 startloop = 0 for line in petit_loop: #sprawdz przy okazji jaka petla idealnie czy nie if 'for' in line and not 'endfor' in line: if startloop == 2: imperf = 1 startloop = 1 else: if startloop == 1: startloop = 2 if 'endfor' in line: endloop = 1 if endloop == 1 and 'endfor' not in line and not line.isspace( ) and line != '': imperf = 1 file.write(line + '\n') file.close() cmd = gen.path_petit + " " + LPetit + " > " + LDeps process = subprocess.Popen(cmd, shell=True, stdout=subprocess.PIPE) process.wait() lines = linestring.split('\n') stuff = [] for_level = 0 for line in lines: if 'endfor' in line: for_level = for_level - 1 else: if 'for' in line: if simpl_ub: stuff.append(functions.Loop(line, BLOCK[for_level])) else: stuff.append(functions.Loop(line)) for_level = for_level + 1 # na podstawie stuff zbuduj tablice inkrementacji i dekremnatacji poziomu #if(schedule_mode == 0): # flag = 1 #else: flag = 1 # Proba prywatyzacji zmiennych w instrukcjach w gniazdach priv_stuff = priv_engine.PrivEng(LDeps) priv_box = 1 if (imperf == 0): priv_box = 1 dane = [] sts = imperf_tile.Get_ST(LPetit, dane) dane = dane + sts combo = loop_tools.ReadStatementNests(LPetit, dane) instrukcje = combo[0] for pp in priv_stuff[3]: for i in instrukcje: a = set(i['st']) b = set(pp[1]) if (a & b) and ( b - a): # nie wszystkie instrukcje skalara sa w gniezdzie priv_box = 0 # ========== # jesli zmienne prywatne sa w obrebie jednego S1 to mozna start = time.time() if ((imperf == 0 and priv_box == 0)): dane = gen.RelPrint(LPetit, flag) else: if (len(priv_stuff[1]) > 0): dane = gen.RelPrint_WithPriv(LPetit, priv_stuff[1]) else: dane = gen.RelPrint(LPetit, flag) output = process.stdout.read() end = time.time() elapsed = end - start print "Dependence analysis: time taken: ", elapsed, "seconds." if (DEBUG): print dane dane = dane.split("#") rel = dane[0] rel2 = rel print rel dane.remove(rel) dane = list(set(dane)) if (DEBUG): print rel # Create LD Dependence.Create_LD_petit(L, petit_loop) # ------------------------------------------------------- # script for barvinok # gdy nie ma zaleznosci # problemy do rozwiazania # zmienne symboliczne nie wiadomo skad wziasc # numery instrukcji nodeps = 0 if (rel == ''): nodeps = 1 LD_inp = "tmp/LD_petit_loop_" + L + ".t" dane2 = gen.RelPrint(LD_inp, 1) dane2 = dane2.split("#") rel2 = dane2[0] try: isl_rel2 = isl.Map(str(rel2)) isl_symb = isl_rel2.get_var_names(isl.dim_type.param) symb = isl_symb except: print "Internal error." sys.exit() rel = "[" + ",".join(symb) + "] -> {[" for i in range(0, len(stuff)): rel = rel + "i" + str(i) + "," rel = rel + "v] -> [" for i in range(0, len(stuff)): rel = rel + "i" + str(i) + "'," rel = rel + "v'] : false }" #loop_tools.MakeLDPetit("tmp/tmp_petit.t", "tmp/tmp_ld_petit.t") #dane2.remove(rel2) #dane2 = list(set(dane2)) #for i in range(0, len(dane2)): # dane2[i] = str(int(dane2[i]) - 1) for s in dane: if "UNKNOWN" in s: dane.remove(s) # dodaj dane bez relacji sts = imperf_tile.Get_ST(LPetit, dane) dane = dane + sts combo = loop_tools.ReadStatementNests(LPetit, dane) instrukcje = combo[0] nest_loop = combo[1] if len(instrukcje) == 0: print 'blad - brak instrukcji' sys.exit() # wczytaj wszystkie # eksperymentalnie kasowanie innych poziomow stuff_reduced = stuff[:] #osobna kopia do_kas = [] for i in range(1, max(nest_loop) + 1): dups = duplicates(nest_loop, i) for s in dups: if s != min(dups): do_kas.append(s) for item in do_kas: stuff_reduced[item] = '!' for i in range(0, stuff_reduced.count('!')): stuff_reduced.remove('!') # remove # ------------------------------- global maxl maxl = 0 for item in instrukcje: if item['max_loop'] > maxl: maxl = item['max_loop'] start = time.time() tmp_st = [] if (perfect_mode): firstst = str(instrukcje[0]['st'][0]) #print rel rel = re.sub(r"v = \d+", "v = " + firstst, rel) rel = re.sub(r"v' = \d+", "v' = " + firstst, rel) #print rel tmp_st = instrukcje[0]['st'] instrukcje[0]['st'] = [instrukcje[0]['st'][0]] #print instrukcje[0]['st'] # wywal reszte zapisz gdzies tablice # exit(1) # strong perfect mode isl_rel = isl.Map(str(rel)) isl_ident = isl_rel.identity(isl_rel.get_space()) # k6 only #print isl_rel #rel_plus = isl_rel.transitive_closure()[0] #isl_rel = isl_rel.subtract(rel_plus.apply_range(isl_rel)) #rel = isl.Map(str("{[i,j,v]->[i,j',v]}")) #isl_rel = isl_rel.subtract(rel) #print isl_rel #exit(0) # ------------- if (perfect_mode): if (DEBUG): print "Removing internal dependences for perfect nested loop" isl_rel = isl_rel.subtract(isl_ident) if (DEBUG): print isl_rel z = isl_rel.dim(isl.dim_type.out) zz = maxl - z + 1 if (zz > 0): if (DEBUG): print "Error. Dimensions of dependencies are not equal to an amount of loop nests" print "Relations will be extended." isl_rel = isl_rel.insert_dims(isl.dim_type.in_, z - 1, zz) isl_rel = isl_rel.insert_dims(isl.dim_type.out, z - 1, zz) # jesli ktorys z blokow ma 1 wywal te zaleznosci # w slicgu mozna tak jesli zewn petla tylko zapisuje zmienne prywatne if (BLOCK[0] == '1' and schedule_mode == 0): z = isl_rel.dim(isl.dim_type.out) rtmp = "{[" for i in range(0, z): rtmp = rtmp + "i" + str(i) + "," rtmp = rtmp[:-1] + "] -> [" for i in range(0, z): rtmp = rtmp + "o" + str(i) + "," rtmp = rtmp[:-1] + "] : i0 = o0 };" rtmp = isl.Map(rtmp) isl_rel = isl_rel.intersect(rtmp).coalesce() # lata na petle ktore nie ma w relacjach #if maxl > isl_rel: start = time.time() if (DEBUG): print '!!!!!!!!!!' # ************************************************************************** exact_rplus = '-1' islrp = False isl_relclosure = isl_rel if (rplus_file != ''): with open(rplus_file, "r") as myfile: data = myfile.read().replace('\n', '') isl_relclosure = isl.Map(str(data)) else: if islrp: isl_relclosure = isl_rel.transitive_closure() exact_rplus = isl_relclosure[1] isl_relclosure = isl_relclosure[0] else: isl_relclosure = relation_util.oc_IterateClosure(isl_rel) exact_rplus = True isl_relplus = isl_relclosure end = time.time() elapsed = end - start print "Transitive closure: time taken: ", elapsed, "seconds." isl_ident = isl_rel.identity(isl_rel.get_space()) if (DEBUG): print 'R+' print isl_relclosure #isl_relclosure = rpp print "!! exact_rplus " + str(exact_rplus) isl_relclosure = isl_relclosure.union(isl_ident).coalesce() # R* = R+ u I if (_debug_): if (DEBUG): print "R*" print isl_relclosure print exact_rplus # ************************************************************************** isl_symb = isl_rel.get_var_names(isl.dim_type.param) symb = isl_symb end = time.time() if (DEBUG): print end - start vars = [] # i exvars = [] # ii' sym_exvars = [] # ii varsprim = [] # i' par_vars = [] # iib p_vars = [] #iib bez plusa lb p_symb = [] im_par_vars = [] # moze warto do iloczynu dodac lb a do floor N - lb # do testowania +'+'+s['lb'] i = 0 for s in stuff_reduced: vars.append(s['var']) sym_exvars.append(s['var'] * 2) exvars.append(s['var'] * 2 + "'") varsprim.append(s['var'] + "'") if par_tiling: par_vars.append(s['var'] * 2 + 'b' + '+' + s['lb']) p_vars.append(s['var'] * 2 + 'b') else: par_vars.append(s['var'] * 2 + "*" + BLOCK[i] + '+' + s['lb']) i = i + 1 # codegen.calculate_position(1, instrukcje, len(sym_exvars)) for s in stuff: if s['var'] in vars: i = vars.index(s['var']) if par_tiling: im_par_vars.append(s['var'] * 2 + 'b' + '+' + s['lb']) else: im_par_vars.append(s['var'] * 2 + "*" + BLOCK[i] + '+' + s['lb']) _SYM = "" for s in sym_exvars: _SYM = _SYM + s + "," for i in range(len(vars), 10): BLOCK.pop() if (par_tiling): for s in p_vars: _SYM = _SYM + s + "," p_symb.append(s) for s in set(BLOCK): #remove duplicates _SYM = _SYM + s + "," p_symb.append(s) for s in symb: _SYM = _SYM + s + "," # wektory same 0 - mozesz dac parallel # prywatyzuj calosc, tam gdzie zapis seq, same 0 to parallel bloki (tylko odczyt) par_tiled = 0 delta = isl_rel.deltas() chkc = isl.Set("{[0," + ",".join(vars) + "]}") delta = delta.subtract(chkc) if (delta.is_empty()): par_tiled = 1 if (DEBUG): print "Parallel tiling detected." ######################################################################## cl = clanpy.ClanPy() cl.loop_path = plik cl.Load() cl.RunCandl() j = 0 if (len(cl.statements) > 0): for i in range(0, len(instrukcje)): instrukcje[i]['scatter'] = cl.statements[j].scatering[:] j = j + len(instrukcje[i]['st']) Rapply = GetRapply(vars, sym_exvars, _SYM) isl_TILE = [] isl_TILE_LT = [] isl_TILE_GT = [] isl_TILE1 = [] isl_TILE2 = [] isl_TILEprim = [] isl_TILEbis = [] isl_TILEorig = [] permutate_list = [] permutate_maps = [] FFF_lines = [] FFF_idx = [] FFF_headers = [] FFF_headers_idx = [] for i in range(0, len(instrukcje)): Bij = MakeBij(_SYM, vars, sym_exvars, im_par_vars, stuff, BLOCK, instrukcje[i], par_tiling) print Bij print "oooooooooooooooooooooooooooooooooooooooooooooooooooo" isl_TILE.append(isl.Set(str(Bij).replace("_Bij := ", ""))) if (DEBUG): print 'T --------------------------------------------' print stuff print isl_TILE[i] # oblicz II_SET if (False): if (len(symb) > 0): ii_set = '[' + ','.join(symb) + '] -> ' else: ii_set = '' ii_set = ii_set + '{[' + ','.join(sym_exvars) + '] : ' for l in range(0, len(sym_exvars)): ii_set = ii_set + sym_exvars[l] + ' >= 0 and ' ii_set = ii_set + BLOCK[l] + '*' + sym_exvars[ l] + ' + ' + stuff[l]['lb'] + ' <= ' + stuff[l][ 'ub'] + ' and ' ii_set = ii_set + ' 1=1}' if (DEBUG): print ii_set ii_set = isl.Set(ii_set) if (DEBUG): print 'II_SET ' + str(ii_set) print 'CARD II_SET ' + test_isl.StringToCard(str(ii_set)) # ------------------------------ bltc = 0 # czy juz liczono blt bgtc = 0 # -- || -- bgt for j in range(0, len(instrukcje)): BLGT = MakeBLTandBGT_v2( _SYM, vars, sym_exvars, im_par_vars, varsprim, exvars, stuff, BLOCK, instrukcje[j], instrukcje[i], par_tiling) # porownaj zagniezdzenia instrukcji if (DEBUG): print '-------LT ----------' print BLGT[0] print '-------GT ----------' print BLGT[1] print BLGT[0] isltmp = isl.Set(str(BLGT[0]).replace("_BLT := ", "")) if (bltc == 0): print isltmp sys.exit(0) isl_TILE_LT.append(isltmp) bltc = 1 else: isl_TILE_LT[i] = isl_TILE_LT[i].union(isltmp).coalesce() isltmp = isl.Set(str(BLGT[1]).replace("_BGT := ", "")) if (bgtc == 0): isl_TILE_GT.append(isltmp) bgtc = 1 else: isl_TILE_GT[i] = isl_TILE_GT[i].union(isltmp).coalesce() if (DEBUG): print "s" + str(i) print "LT" print isl_TILE_LT[i] print "GT" print isl_TILE_GT[i] X = isl_TILE_GT[i].apply(isl_relclosure).coalesce() isl_BCUR = isl_TILE[i].subtract(X).coalesce() isl_TILE1.append(isl_BCUR) if (DEBUG): print '---------bcur-----' print isl_BCUR.apply(isl_relclosure) isl_BPREV = isl_BCUR.apply(isl_relclosure).intersect( isl_TILE_LT[i]).coalesce() isl_BPREV = isl_BPREV.subtract( X).coalesce() # changed according to ACM TOPLAS reviewer if (DEBUG): print isl_BPREV print '---' isl_TILE2.append(isl_BPREV) #isl_TILEprim.append(isl_TILE1[i]) isl_TILEprim.append(isl_TILE1[i].union(isl_TILE2[i]).coalesce()) #poprawka intersect z IS - EKSPERYMENTALNA !!!! IS = getIS(plik, isl_rel, dane) DOMRAN = isl_rel.domain().union(isl_rel.range()).coalesce() INDDD = IS.subtract(DOMRAN).coalesce() if (DEBUG): print '----------' print INDDD print IS #print IS # sys.exit(0) #isl_TILEprim[i] = isl_TILEprim[i].intersect(IS).coalesce() #for ll in range(0,i): # isl_TILEprim[i] = isl_TILEprim[i].subtract(isl_TILEprim[ll]).coalesce() ############################# print '^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^' #isl_TILEprim.append(isl_TILE[i]) # print isl_TILEprim[0] isl_TILEbis.append( Project(isl_TILEprim[i].apply(Rapply).coalesce(), sym_exvars).coalesce()) isl_TILEorig.append( Project(isl_TILE[i].apply(Rapply).coalesce(), sym_exvars).coalesce()) ############################################################################ if (par_tiling): idx_bylo = [] if (len(symb) > 0): S = "[" + ",".join(symb) + "," else: S = "[" S1 = "{[" + ",".join(sym_exvars) + "," + ",".join(vars) + ",v] :" for j in range(0, len(instrukcje[i]['path'])): idx = str(instrukcje[i]['path'][j]) liniabb = " = floord(" + stuff[instrukcje[i]['path'][j]][ 'ub'] + "-" + stuff[instrukcje[i]['path'] [j]]['lb'] + " ," + BLOCK[j] + ");" if 1 == 1 or liniabb not in FFF_headers: # always true, FFF_headers.append(liniabb) FFF_headers_idx.append(idx) linia = "int fff" + idx + liniabb linia = linia.replace("floord( ", "floord(") FFF_lines.append(linia) else: idx = FFF_headers_idx[FFF_headers.index(liniabb)] if str({'id': idx, 'j': j}) not in FFF_idx: FFF_idx.append({'id': idx, 'j': j}) if idx not in idx_bylo: S = S + "fff" + idx + "," idx_bylo.append(idx) S1 = S1 + " " + sym_exvars[j] + "<= fff" + idx + " and " S = S[:-1] + "] -> " + S1 + " true }" if (DEBUG): print S S = isl.Set(S) isl_TILEbis[i] = isl_TILEbis[i].intersect(S).coalesce() ######################################################################### if (permute): RP = imperf_tile.PermuteBlock(LDeps, isl_TILEprim[i], instrukcje[i], symb, len(sym_exvars), permutate_list) if (isinstance(RP, isl.Map)): print "Permutation experimental enabled:" permutate_maps.append(RP) isl_TILEprim[i] = isl_TILEprim[i].apply(RP) #print isl_TILEprim[i] if (_debug_): if (DEBUG): print "TILE" print isl_TILE[i] print "TILE_LT" print isl_TILE_LT[i] print "TILE_GT" print isl_TILE_GT[i] print "TILE_ITR (TILE1)" print isl_TILE1[i] print "TVLD_LT (TILE2)" print isl_TILE2[i] print "TILE_VLD (TILE')" print isl_TILEprim[i] # print "card" # print test_isl.StringToCard(str(isl_TILEprim[i])) print "TILE_VLD_ext (TILE'')" print isl_TILEbis[i] # correct upper bounds for simpl_ub if simpl_ub: cor_set = '' if (len(symb) > 0): cor_set = '[' + ','.join(symb) + '] -> ' else: cor_set = '' cor_set = cor_set + '{[' + ','.join(sym_exvars) + ',' + ','.join( vars) + ',' + 'v] : ' for j in range(0, len(instrukcje[i]['path'])): cor_set = cor_set + vars[j] + " <= " + stuff[ instrukcje[i]['path'][j]]['ub'] + " - " + BLOCK[j] + " && " cor_set = cor_set + "(" for v in instrukcje[i]['st']: cor_set = cor_set + " v = " + str(v) + " or" cor_set = cor_set[:-2] + ")}" cor_set = isl.Set(cor_set) #print cor_set #sys.exit(0) isl_TILEbis[i] = isl_TILEbis[i].intersect(cor_set).coalesce() isl_TILEorig[i] = isl_TILEorig[i].intersect(cor_set).coalesce() if (SIMPLIFY): isl_TILEbis[i] = imperf_tile.SimplifySlice(isl_TILEbis[i]) #print "TILE''" + "dla s" + str(i) + "\n" + str(isl_TILEbis[i]) #eksepeymentalnie dodaj pozycje do tilebis jesli wiele gniazd na roznych poziomach Extend = False if (imperf == 1): Extend = True #Extend = MultiNest(instrukcje) #Extend = True #print imperf #vis3dimperf.imperf_vis(isl_TILEbis, isl_rel) _rap = GetRapply4(vars, sym_exvars, _SYM, instrukcje, 0) print _rap #vis.Vis(isl_TILEbis[0], stuff, cl.deps, isl.Set(cl.statements[0].domain_map), True) #sys.exit(0) # zne takie jak z ale bez ext if (Extend): z = isl_TILEbis[0].apply(_rap) zne = isl_TILEbis[0] else: z = isl_TILEbis[0] for j in range(1, len(isl_TILEbis)): _rap = GetRapply4(vars, sym_exvars, _SYM, instrukcje, j) print _rap if (DEBUG): print _rap if (Extend): z = z.union(isl_TILEbis[j].apply(_rap)) zne = zne.union(isl_TILEbis[j]) else: z = z.union(isl_TILEbis[j]) if (not Extend): zne = z print z # ----------------------------------------------------------------- _rap = GetRapply4(vars, sym_exvars, _SYM, instrukcje, 0) if (Extend): zorig = isl_TILEorig[0].apply(_rap) else: zorig = isl_TILEorig[0] for j in range(1, len(isl_TILEorig)): _rap = GetRapply4(vars, sym_exvars, _SYM, instrukcje, j) if (Extend): zorig = zorig.union(isl_TILEorig[j].apply(_rap)) else: zorig = zorig.union(isl_TILEorig[j]) zorig = zorig.coalesce() # --------------------------------------------------------------- z = z.coalesce() z = z.remove_redundancies() z = z.detect_equalities() # z = imperf_tile.SimplifySlice(z) #calculate II_SET ii_SET = z.remove_dims(isl.dim_type.set, int(isl_TILEbis[i].dim(isl.dim_type.set) / 2), int(isl_TILEbis[i].dim(isl.dim_type.set) / 2)).coalesce() if (_debug_): print "II_SET" print ii_SET step = 0 if Extend: step = 1 nazwa = "" nazwapar = "" filePaths = glob.glob(plik) if (output_file != ""): nazwa = output_file nazwapar = output_file else: for filePath in filePaths: base = os.path.basename(filePath) nazwa = os.path.splitext(base)[0] + "_tiling" + os.path.splitext( base)[1] nazwapar = os.path.splitext( base)[0] + "_partiling" + os.path.splitext(base)[1] if (perfect_mode): if (DEBUG): print z chang = str(tmp_st[0]) + "]" if (DEBUG): print chang for i in range(1, len(tmp_st)): zz = str(z).replace(chang, str(tmp_st[i]) + "]") zz = isl.Set(zz) z = z.union(zz).coalesce() instrukcje[0]['st'] = tmp_st # correct statements #z1 = isl.Set('[n,b] -> {[i1,i2,i3,i4,i5,i6,i7,i8,i9,i10,i11,i12,i13] : n+2 = 2*b && b > 2 && n > 8 }') # z1 = isl.Set('[n,b] -> {[i3,i4,i5,i6,i9,i10,i11,i12,i13] : n+2 = 2*b && b > 2 && n > 8 }') #z = z.intersect(z1) if (not schedule_mode or par_tiled): print "Cloog start..." start = time.time() isl_ast = False barv = 1 if (barv == 1): if (isl_ast): loop_x = iscc.isl_ast_codegen(z) else: loop_x = iscc.iscc_communicate("L :=" + str(z) + "; codegen L;") else: #cloog #loop_x = codegen.tile_gen_short(vars, sym_exvars, symb,z,instrukcje, Extend) with open('loopx', "r") as myfile: loop_x = myfile.read() #loop_x = iscc.oc_communicate(z) #loop_x = codegen.tile_gen(vars, sym_exvars, symb, isl_TILEbis, instrukcje, "", [], stuff) end = time.time() elapsed = end - start print "Code generation: time taken: ", elapsed, "seconds." ######################################################################## loop_x = postprocess_loop(loop_x.split('\n')) loop = loop_x lines = loop.split('\n') loop = imperf_tile.RestoreStatements(lines, LPetit, dane, maxl, step, permutate_list) if par_tiled: loop = "#pragma omp parallel for\n" + loop for i in range(0, 5): if (loop[-1] == '\n'): loop = loop[:-1] loop = loop + "\n" new_gen = True if (not new_gen): gen.ParsePrint2("tmp/tmp_petit.t", len(sym_exvars)) if (new_gen): text_file = open(nazwa, "w") text_file.write(loop) text_file.close() if par_tiling: lines = FFF_lines + correct.Korekta(nazwa) for i in range(0, len(lines)): if "for" in lines[i] and "fff" in lines[i]: reg = re.compile("\=.*") linia = reg.sub("", lines[i]) reg = re.compile(".*\(") cc = reg.sub("", linia) cc = cc.replace(" ", "") for FF_item in FFF_idx: if "fff" + FF_item['id'] in lines[i]: lines[i] = lines[i] + "\n" + correct.whites( lines[i]) + " register int " + sym_exvars[ FF_item['j']] + "b = " + BLOCK[ FF_item['j']] + "*" + cc + ";" break lines[i] = lines[i] + "\n" text_file = open(nazwa, "w") text_file.writelines(lines) text_file.close() if schedule_mode: text_file = open(nazwapar, "w") text_file.writelines(lines) text_file.close() if (output_file != ""): return "" if (not schedule_mode and 1 == 0): rtile = tiling_schedule.get_RTILE(z, sym_exvars, isl_rel, Extend) print "RTILE:" print rtile tiling_schedule.get_RCYCLE(rtile, 0) rtileorig = tiling_schedule.get_RTILE(zorig, sym_exvars, isl_rel, Extend) print "RTILE_ORIG:" print rtileorig tiling_schedule.get_RCYCLE(rtileorig, 1) # ===================================================================================================================== # PARALLEL PARALLEL PARALLEL PARALLEL PARALLEL PARALLEL PARALLEL PARALLEL PARALLEL PARALLEL PARALLEL PARALLEL PARALLEL Dodatek = [ LPetit, dane, maxl, step, nazwapar, permutate_list, permutate_maps ] par_tiled = 0 if (DEBUG): print '!!!!' print zorig if (schedule_mode and par_tiled != 1): if (False): tiling_schedule.tile_par(isl_TILEprim, isl_TILEbis, sym_exvars, symb, isl_rel, isl_relplus, isl_relclosure) else: # Rk #tiling_schedule.tile_par3(z, sym_exvars, isl_rel, isl_relplus, isl_relclosure, Extend, _rap, Dodatek,SIMPLIFY, ii_SET) # fsnew rtile = tiling_schedule.get_RTILE(zne, sym_exvars, isl_rel, False) #rtileplus = rtile.transitive_closure() rapp = _rap rapp = rapp.remove_dims(isl._isl.dim_type.in_, 0, len(sym_exvars)) rapp = rapp.remove_dims(isl._isl.dim_type.out, 0, len(sym_exvars) * 2) if not Extend: z = z.apply(_rap) fsnew_tiletry.fs_new(isl_rel, isl_relplus, rtile, LPetit, dane, plik, SIMPLIFY, rapp, exact_rplus, z, sym_exvars, maxl, step, isl_TILEprim, vars) # przelec po blokach znajdz relacje jak nie ma to parallel
def TileGen(sym_exvars, vars, _SYM, symb, p_symb, par_tiling, rel, schedule, instrukcje, stuff_reduced, BLOCK, isl_TILEprim, varsprim, isl_IT, isl_REST_new): ctx = isl.Context() tileall = [] i = 0 for isl_BL in isl_TILEprim: TA = isl_BL # tak bylo oryginalnie #TA = RemoveOtherSt(isl_BL, instrukcje[i], sym_exvars) tileall.append(Project(TA, sym_exvars)) i = i + 1 R = "R := [" R = R + _SYM # dodaj zmienne symb ilorazow if(par_tiling): for i in range(0,len(sym_exvars)): R = R + " fff" + str(i) + "," R = R[:-1] + "] -> {[" for s in vars: R = R + s + "," R = R + "v] -> [" for s in sym_exvars: R = R + s + "," for s in vars: R = R + s + "," R = R + "v] : " if(par_tiling): for i in range(0,len(sym_exvars)): R = R + " " + sym_exvars[i] + "<= fff" + str(i)+ " and " R = R + " true };\n" isl_Rapply = isl.Map(R.replace('R := ','')) isl_TILEALL = tileall[0] for i in range(1, len(tileall)): isl_TILEALL = isl_TILEALL.union(tileall[i]) if(DEBUG): print "TILE_ALL" print isl_TILEALL isl_BL = [] i=0 for bl in isl_TILEprim: BLj1 = bl.apply(isl_Rapply).coalesce() # przepusc przez R BLj1 = Project(BLj1, sym_exvars) # wywal ii, jj z symb # wywal powtarzajace sie RA = "{[" + ",".join(sym_exvars) + "," + ",".join(vars) + ",v] -> [" + ",".join(varsprim) + "," + ",".join(vars) + ",v] : " + CreateLex(varsprim, sym_exvars) + "}" tmp1 = BLj1 .apply(isl.Map(RA)) tmp1 = BLj1.intersect(tmp1) BLj1 = BLj1.subtract(tmp1) isl_BL.append(BLj1) # mozna juz do gen code if(DEBUG): print "TILE_bis" + str(i) print BLj1 i = i + 1 for i in range(0, len(isl_REST_new)): isl_REST_new[i] = isl_REST_new[i].apply(isl_Rapply).coalesce() # przepusc przez R isl_REST_new[i] = Project(isl_REST_new[i], sym_exvars) # wywal ii, jj z symb isl_REST = [] for i in range(0, len(isl_TILEprim)): if(DEBUG): print "IT" + str(i) print isl_IT[i] tmp = isl_IT[i].subtract(isl_TILEALL) #tmp = SlowSimplify(tmp) isl_REST.append(tmp) if(DEBUG): print "REST" + str(i) print isl_REST[i] # na przyszlosc trzeba tutaj inaczej wyparsowac instrukcje oddzielic ### barv_cmds2 = "" for j in range(0, len(isl_REST)): #if(not "-> { }" in str(isl_REST[j])): if not isl_REST[j].is_empty(): W = isl_REST[j].apply(isl_Rapply) barv_cmds2 = barv_cmds2 + "REST" + str(j) + ":= " + str(W) + ";codegen REST"+str(j)+";" # isl_REST[j] bylo zamiast W start = time.time() loop = iscc.iscc_communicate(barv_cmds2) loop = "" with open("tmp/barv_tiling.txt", "a") as myfile: myfile.write(barv_cmds2) end = time.time() elapsed = end - start if(DEBUG): print "Time taken: ", elapsed, "seconds." loop = codegen.tile_gen(vars, sym_exvars, symb,isl_BL,instrukcje, loop, isl_REST_new) loops = [] loops.append(loop) return loops
# RTILE sym_exvars = ['ii', 'jj', 'kk'] rtile = get_RTILE(TILE_VLD_EXT, sym_exvars, Rel, True) print "RTILE:" print rtile sys.exit(0) # UDS UDS_TILE = rtile.domain().subtract(rtile.range()).coalesce() print UDS_TILE loop_x = iscc.iscc_communicate("L :=" + str(UDS_TILE) + "; codegen L;") print loop_x L1 = UDS_TILE.apply(rtile).coalesce() J = rtile.range().coalesce() Lay1 = L1.subtract(J).coalesce() loop_x = iscc.iscc_communicate("L :=" + str(Lay1) + "; codegen L;") print loop_x J = Lay1 L2 = Lay1.apply(rtile).coalesce()
def sfs(plik, L=0, SIMPLIFY=False, fs=0, acc=False): LPetit = "tmp/tmp_petit" + str(L) + ".t" LDeps = "tmp/deps" + str(L) + ".txt" linestring = open(plik, 'r').read() lines = linestring.split('\n') petit_loop = convert_loop.convert_loop(lines) petit_loop.insert(0, "! start") file = open(LPetit, 'w') for line in petit_loop: file.write(line + '\n') file.close() loop = Dependence.Kernel_Loop(LPetit) #cmd = gen.path_petit + " " + LPetit + " > " + LDeps #process = subprocess.Popen(cmd, shell=True, stdout=subprocess.PIPE) #process.wait() #dane = gen.RelPrint(LPetit, 1) dane = loop.dane isl_rel = loop.isl_rel new_rel = relation_util.ReduceR(isl_rel) #isl_rel = new_rel #experimental instrukcje = loop.instrukcje # ------------------------ #dane2 = [] #sts = imperf_tile.Get_ST(LPetit, dane2) #dane2 = dane2 + sts #combo = loop_tools.ReadStatementNests(LPetit, dane2) # Create LD # isl_rel2 = Dependence.Create_LD_petit(str(L), petit_loop) # ld_rel = isl_rel2.identity(isl_rel2.get_space()) # s1 = isl_rel2.domain() # s2 = isl_rel2.range() # s_all = s1.union(s2).coalesce() # s1 = isl_rel.domain() # s2 = isl_rel.range() # s_rel = s1.union(s2).coalesce() # ind = s_all.subtract(s_rel).coalesce() # print ind #sys.exit(0) # ------------------------ #print dane #dane = dane.split("#") #rel = dane[0] #dane.remove(rel) #dane = list(set(dane)) #isl_rel = isl.Map(str(rel)).coalesce() #print isl_rel SQ = False if (SQ): #print isl_rel RR = isl.Map("{[i,j,k,v] -> [i,j',k',v']}") isl_rel = isl_rel.intersect(RR).coalesce() #isl_rel = isl_rel.set_dim_name(isl.dim_type.in_, 0, "i") #isl_rel = isl_rel.set_dim_name(isl.dim_type.out, 0, "i'") #c= isl.Constraint.eq_from_names(isl_rel.get_space(), {"i": 1, "i'":-1}) #isl_rel = isl_rel.add_constraint(c).coalesce() #rel_= isl.Map(str('{[i,j,k,v]->[i,jj,kk,v]}')) #isl_rel = isl_rel.intersect(rel_).coalesce() isl_relclosure = isl_rel.transitive_closure() exact = isl_relclosure[1] isl_relclosure = isl_relclosure[0] isl_relplus = isl_relclosure isl_ident = isl_rel.identity(isl_rel.get_space()) isl_relclosure = isl_relclosure.union(isl_ident).coalesce() # R* = R+ u I # ------------------------------ vars = [] for i in range(0, isl_rel.dim(isl.dim_type.in_) - 1): vars.append('i' + str(i)) rap = GetRapply(vars, instrukcje, len(instrukcje) - 1) # ------------------------------ if (fs == 1): fs_rk.fs_rk(isl_rel, isl_relplus, Create_UDS(isl_rel), LPetit, dane, plik, SIMPLIFY, rap, acc, loop) sys.exit() if (fs == 2): # na samym R+ fs_new.fs_new(isl_rel, isl_relplus, isl_relclosure, Create_UDS(isl_rel), LPetit, dane, plik, SIMPLIFY, rap, acc, loop, exact) sys.exit() srepr = Create_Srepr(isl_rel, isl_relclosure) rucs = srepr[1] srepr = srepr[0] #experimetnal # !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! # srepr = srepr.union(ind).coalesce() srepr_loop = iscc.iscc_communicate("L :=" + str(srepr) + "; codegen L;") print srepr_loop srepr_loop = srepr_loop.split('\n') for i in range(0, len(srepr_loop)): if "for" in srepr_loop[i]: srepr_loop.insert(i, "#pragma omp parallel for") break st_reg = re.compile('\s*\(.*\);') vecs = [] taby = [] for line in srepr_loop: if (st_reg.match(line)): vecs.append(isl.Set(iscc.s1_to_vec2(line, len(vecs)))) taby.append(iscc.correct.whites(line)) #print srepr_loop rucs_s = rucs.transitive_closure()[0].coalesce() for i in range(0, len(vecs)): vecs[i] = isl_rel.domain().intersect(vecs[i]).coalesce() slices = [] for vec in vecs: slice = vec if (not rucs.is_empty()): slice_ = slice.apply(rucs_s) slice = slice.union(slice_).coalesce() slice = slice.apply(isl_relclosure) if (SIMPLIFY): slice = imperf_tile.SimplifySlice(slice) slice = slice.apply(rap) slices.append(slice.coalesce()) cmd = "" for i in range(0, len(vecs)): print slices[i] cmd = cmd + "codegen " + str(slices[i]) + ';print "###";' cmd = iscc.iscc_communicate(cmd) cmd = cmd.split('"###"') #print cmd new_loop = [] i = 0 for line in srepr_loop: if (st_reg.match(line)): petla = cmd[i].split('\n') for s in petla: new_loop.append(taby[i] + s) i = i + 1 else: new_loop.append(line) nloop = "" for line in new_loop: if line != '': nloop = nloop + line + "\n" nloop = nloop[:-1] nloop = nloop.split('\n') nloop = tiling_v3.postprocess_loop(nloop) print nloop lines = nloop.split('\n') if (acc): lines = openacc.CreateACCCode(lines, loop.var_st) loop = imperf_tile.RestoreStatements(lines, LPetit, dane, 0, 1, []) for i in range(0, 5): if (loop[-1] == '\n'): loop = loop[:-1] loop = loop + "\n" base = os.path.basename(plik) nazwa = os.path.splitext(base)[0] + "_slicing" + os.path.splitext(base)[1] text_file = open(nazwa, "w") text_file.write(loop) text_file.close() print nazwa + ' was created.'
print "UDS" print uds sk = uds.apply(Rpow).subtract(uds.apply(Rpow).apply(Rplus)).coalesce() sk = sk.insert_dims(isl.dim_type.set, 0, 1) sk = sk.set_dim_name(isl.dim_type.set, 0, "ink") c = isl.Constraint.eq_from_names(sk.get_space(), {"k": -1, "ink": 1}) sk = sk.add_constraint(c) sk = tiling_v3.Project(sk, ["k"]) uds = uds.insert_dims(isl.dim_type.set, 0, 1) uds = uds.set_dim_name(isl.dim_type.set, 0, "ink") c = isl.Constraint.eq_from_names(sk.get_space(), {1: 0, "ink": 1}) uds = uds.add_constraint(c) sk = sk.union(uds).coalesce() print 'Sk' print sk nloop = iscc.iscc_communicate("L :=" + str(sk) + "; codegen L;") print nloop print '--------------------------------------------------------' TILE_S1 = '[T,N,tt,ii,jj] -> ' TILE_S1 += '{[t,i,j,0] : ' tile_j_s1 = '0 + b1 * tt <= t <= b1*(tt+1) + 0 -1 ,T-1 && tt >=0 && ' tile_i_s1 = '1 + b2 * ii <= i <= b2*(ii+1) + 1 -1 ,N-2 && ii >=0 && ' tile_k_s1 = '1 + b3 * jj <= j <= b3*(jj+1) + 1 -1 ,N-2 && jj >=0 ' TILE_S1 += tile_j_s1 + tile_i_s1 + tile_k_s1 + '}' ####################################################################### B = ['64', '64', '64']
def fs_rk(rel, rel_plus, uds, LPetit, dane, plik, SIMPLIFY, rap, acc, loop): aprox = 0 rk = rel.power() #Rk if (rk[1] == 0): print "rk approximated..." aprox = 1 rk = rk[0].coalesce() rk = isl.Map(iscc.RepairRk(str(rk), 0)) # przesun k do symb sk = uds.apply(rk).subtract(uds.apply(rk).apply(rel_plus)).coalesce() sq_sk = sk sk = sk.insert_dims(isl.dim_type.set, 0, 1) sk = sk.set_dim_name(isl.dim_type.set, 0, "ink") c = isl.Constraint.eq_from_names(sk.get_space(), {"k": -1, "ink": 1}) sk = sk.add_constraint(c) sk = tiling_v3.Project(sk, ["k"]) sq_sk2 = sk SQ = False if (SQ): sk = get_sq(sq_sk, sq_sk2, uds) else: uds = uds.insert_dims(isl.dim_type.set, 0, 1) uds = uds.set_dim_name(isl.dim_type.set, 0, "ink") c = isl.Constraint.eq_from_names(sk.get_space(), {1: 0, "ink": 1}) uds = uds.add_constraint(c) sk = sk.union(uds).coalesce() #if(SIMPLIFY): sk = imperf_tile.SimplifySlice(sk) rap = rap.insert_dims(isl.dim_type.in_, 0, 1) rap = rap.insert_dims(isl.dim_type.out, 0, 1) rap = rap.set_dim_name(isl.dim_type.in_, 0, 'ik1') rap = rap.set_dim_name(isl.dim_type.out, 0, 'ok1') c = isl.Constraint.eq_from_names(rap.get_space(), {'ik1': -1, 'ok1': 1}) rap = rap.add_constraint(c) rap = rap.coalesce() #print rap sk = sk.apply(rap) print sk if (aprox == 1): if (sk.is_bounded()): print "Approximation (no perfect FS) but Sk is bounded" else: print "Sk is not bounded. The result may not be valid!" else: print 'Rk exact' if (sk.is_bounded()): print 'Sk bounded.' else: print 'Sk NOT bounded' nloop = iscc.iscc_communicate("L :=" + str(sk) + "; codegen L;") # CODEGEN nloop = tiling_v3.postprocess_loop(nloop.split('\n')) lines = tiling_schedule.fs_pragma(nloop) if (acc): lines = openacc.CreateACCCode(lines, loop.var_st) loop = imperf_tile.RestoreStatements(lines, LPetit, dane, 1, 1, [], 1) for i in range(0, 5): if (loop[-1] == '\n'): loop = loop[:-1] loop = loop + "\n" base = os.path.basename(plik) nazwa = os.path.splitext(base)[0] + "_fs" + os.path.splitext(base)[1] text_file = open(nazwa, "w") text_file.write(loop) text_file.close() print nazwa + ' was created.'
def tile(plik, block, permute, output_file="", L="0", SIMPLIFY="False", perfect_mode=False, parallel_option=False, rplus_mode='', cpus=2): print '' print colored('/\__ _\ /\ == \ /\ __ \ /\ ___\ /\ __ \ ', 'green') print colored('\/_/\ \/ \ \ __< \ \ __ \ \ \ \____ \ \ \/\ \ ', 'green') print colored(' \ \_\ \ \_\ \_\ \ \_\ \_\ \ \_____\ \ \_____\ ', 'green') print colored(' \/_/ \/_/ /_/ \/_/\/_/ \/_____/ \/_____/ ', 'green') print '' print ' An Automatic Parallelizer and Optimizer' print 'based on the ' + colored('TRA', 'green') + 'nsitive ' + colored( 'C', 'green') + 'l' + colored('O', 'green') + 'sure of dependence graphs' print ' traco.sourceforge.net ' print '' DEBUG = True AGGRESSIVE_SIMPLIFY = False # TODO simpl_ub VALIDATION = 0 # levels FSSCHEDULE = 1 # RTILE expermiental INVERSE_TILING = 0 LPetit = "tmp/tmp_petit" + L + ".t" BLOCK = block.split(',') for i in range(len(BLOCK), 10): BLOCK.append(BLOCK[len(BLOCK) - 1]) BLOCK2 = [0, 6, 6] # BLOCK2 = BLOCK linestring = open(plik, 'r').read() lines = linestring.split('\n') if AGGRESSIVE_SIMPLIFY: petit_loop = convert_loop.convert_loop(lines, BLOCK2) BLOCK2 = map(str, BLOCK2) else: petit_loop = convert_loop.convert_loop(lines) file = open(LPetit, 'w') imperf = 0 endloop = 0 startloop = 0 for line in petit_loop: #sprawdz przy okazji jaka petla idealnie czy nie if 'for' in line and not 'endfor' in line: if startloop == 2: imperf = 1 startloop = 1 else: if startloop == 1: startloop = 2 if 'endfor' in line: endloop = 1 if endloop == 1 and 'endfor' not in line and not line.isspace( ) and line != '': imperf = 1 file.write(line + '\n') file.close() start = time.time() loop = Dependence.Kernel_Loop(LPetit) loop.Load_Deps() loop.Load_instrukcje() loop.Preprocess('0') loop.Get_Arrays() end = time.time() elapsed = end - start print "Dependence analysis: time taken: ", elapsed, "seconds." print colored('R', 'green') print loop.isl_rel print colored('domain R', 'green') print loop.isl_rel.domain() print colored('range R', 'green') print loop.isl_rel.range() IS = loop.isl_rel.domain().union(loop.isl_rel.range()) #s = IS.compute_schedule(loop.isl_rel, loop.isl_rel) #print s #sys.exit(0) print loop.dane cl = clanpy.ClanPy() cl.loop_path = plik cl.Load() ################################## # move to clanpy # combine clan with Dependence arr = map(int, loop.dane) arr = sorted(list(set(arr))) i = 0 for i in range(0, len(cl.statements)): cl.statements[i].petit_line = arr[i] cl.statements[i].bounds = GetBounds(petit_loop, cl.statements[i].petit_line, BLOCK2, AGGRESSIVE_SIMPLIFY) i = i + 1 ############################################################ ### R^+ isl_rel = loop.isl_rel #for i in range(0, len(cl.statements)): # print cl.statements[i].petit_line start = time.time() # ************************************************************************** RPLUSUNION = True #RPLUSUNION = False # NESTED strong experimental with Pugh only Valid why? exact_rplus = '-1' isl_relclosure = isl_rel if (RPLUSUNION): islrp = True if (rplus_mode == 'iterate'): islrp = False exact_rplus = True if not isl_rel.is_empty() and rplus_mode != 'remote': if islrp: isl_relclosure = isl_rel.transitive_closure() exact_rplus = isl_relclosure[1] isl_relclosure = isl_relclosure[0] else: isl_relclosure = relation_util.oc_IterateClosure(isl_rel) exact_rplus = True else: #R_UNDER still experimental, requires testing ############################################################################# print colored('R_UNDER', 'green') stline = [] subgraphs = [] isl_relclosure = isl.Map('{[i]->[i] : 1=0}').coalesce() for st in cl.statements: stline.append(st.petit_line) stline.sort() for i in range(0, len(stline)): w = 0 for sg in subgraphs: if stline[i] in sg: # it was used w = 1 if (w == 1): continue mylist = [] mylist.append(stline[i]) for j in range(i + 1, len(stline)): cutrel = '{[' + ','.join([ "a%d" % l for l in range(0, loop.maxl) ]) + ',' + str(stline[i]) + ']->[' + ','.join([ "b%d" % l for l in range(0, loop.maxl) ]) + ',' + str(stline[j]) + '];' cutrel += '[' + ','.join([ "a%d" % l for l in range(0, loop.maxl) ]) + ',' + str(stline[j]) + ']->[' + ','.join([ "b%d" % l for l in range(0, loop.maxl) ]) + ',' + str(stline[i]) + ']}' cutrel = isl.Map(cutrel) cutrel = isl_rel.intersect(cutrel).coalesce() if not cutrel.is_empty(): mylist.append(stline[j]) #mylist.append(maxst) subgraphs.append(mylist) print subgraphs for item in stline: count = 0 for sg in subgraphs: if item in sg: count = count + 1 if count > 1 and item != max(stline): print 'R_UNDER untested, switch RPLUSUNION to true' #exit(1) ii = 0 for sg in subgraphs: # calculate R_UNDER and its R+ ii = ii + 1 print str(ii) + "/" + str(len(subgraphs)) grel = '{' for i in sg: for j in sg: grel += '[' + ','.join([ "a%d" % l for l in range(0, loop.maxl) ]) + ',' + str(i) + ']->[' + ','.join( ["b%d" % l for l in range(0, loop.maxl)]) + ',' + str(j) + '];' grel += '}' grel = isl.Map(grel) grel = isl_rel.intersect(grel).coalesce() gp = grel.transitive_closure() if not gp[1]: print "NOT EXEACT R+" # print "iterate required" # gp = relation_util.oc_IterateClosure(grel) # iterate #else: gp = gp[0] if isl_relclosure.is_empty(): isl_relclosure = gp else: isl_relclosure = isl_relclosure.union(gp).coalesce() ############################################################################# if rplus_mode == 'remote': isl_relclosure, exact_rplus = agent.remote_tc(isl_rel) # ************************************************************************** isl_relplus = isl_relclosure print 'Rplus before' print isl_relplus # lata Pugh - eksperymentalnie #isl_rel = isl_rel.subtract(isl_relplus.apply_range(isl_rel)) print isl_rel #isl_relclosure = isl_rel.transitive_closure()[0] #isl_relplus = isl_relclosure # --------- print 'Rplus after' print isl_relplus end = time.time() elapsed = end - start print "Transitive closure: time taken: ", elapsed, "seconds." isl_ident = isl_rel if not isl_rel.is_empty: isl_ident = isl_rel.identity(isl_rel.get_space()) if (DEBUG and 1 == 0): print 'R+' print isl_relclosure #isl_relclosure = rpp if (DEBUG): color = 'red' if (exact_rplus): color = 'yellow' print colored("!! exact_rplus " + str(exact_rplus), color) isl_relclosure = isl_relclosure.union(isl_ident).coalesce() # R* = R+ u I if (INVERSE_TILING): isl_relclosure = isl_relclosure.fixed_power_val(-1).coalesce() if (DEBUG): print colored("R*", 'green') print isl_relclosure # ************************************************************************** start = time.time() B = (["b%d" % i for i in range(0, loop.maxl)]) vars = [] for st in cl.statements: if (len(st.original_iterators) == loop.maxl): vars = st.original_iterators break if (len(vars) == 0): print 'error 12, propably clan does not work' exit(12) # TODO to make abstract variubles bounds with variables must be also corrected sym_exvars = [] sym_exvars_p = [] print vars for v in vars: sym_exvars.append(v * 2) sym_exvars_p.append(v * 2 + 'p') if (DEBUG and 1 == 0): print sym_exvars print vars isl_symb = isl_rel.get_var_names(isl.dim_type.param) BLOCK = block.split(',') for i in range(len(BLOCK), 10): BLOCK.append(BLOCK[len(BLOCK) - 1]) # ************************************************************************** TILE = [] #isl TILE_STR = [] #string for st in cl.statements: if len(isl_symb) == 0: isl_symb = isl.Map(st.domain_map).get_var_names(isl.dim_type.param) tile = MakeTile(st, vars, sym_exvars, isl_symb, B) tile = ReplaceB(tile, BLOCK) TILE_STR.append(tile) tile = isl.Set(tile) # if statements before st domainv = isl.Set(st.domain_map) print domainv #if len(TILE) == 0: # domainv = isl.Set('[N] -> {[i, j, k, m]: N > 0 and 0 <= i <= -2 + N and 2 + i <= j < N and i < k <= -2 + j and k < m <= -3 - i + j + k and m < j and k < m and j-m < 30}') dimdom = domainv.dim(isl.dim_type.set) domainv = domainv.insert_dims(isl.dim_type.set, dimdom, loop.maxl + 1 - dimdom) tile = tile.intersect(domainv).coalesce() TILE.append(tile) if (DEBUG): DebugPrint('TILE', TILE, cl.statements) # ************************************************************************** TILE_LT = [] TILE_GT = [] for i in range(0, len(cl.statements)): TILE_LT_I = '' TILE_GT_I = '' for j in range(0, len(cl.statements)): l = CompareScat(cl.statements[i].scatering, cl.statements[j].scatering, len(vars)) tile_j = TILE_STR[j] PARTS = tile_j.split(':') for k in range(0, len(sym_exvars)): PARTS[1] = PARTS[1].replace(sym_exvars[k], sym_exvars_p[k]) PARTS[1] = PARTS[1].replace('}', ')}') lex_s_lt = MakeCustomLex( sym_exvars, sym_exvars_p, 'LT', l, cl.statements[i].petit_line > cl.statements[j].petit_line) lex_s_gt = MakeCustomLex( sym_exvars, sym_exvars_p, 'GT', l, cl.statements[i].petit_line < cl.statements[j].petit_line) join_LT = ': exists ' + ','.join( sym_exvars_p) + ' : ( ' + lex_s_lt join_GT = ': exists ' + ','.join( sym_exvars_p) + ' : ( ' + lex_s_gt TILE_LT_IJ = PARTS[0] + join_LT + PARTS[1] TILE_GT_IJ = PARTS[0] + join_GT + PARTS[1] #print TILE_LT_IJ TILE_LT_IJ = isl.Set(TILE_LT_IJ) TILE_GT_IJ = isl.Set(TILE_GT_IJ) if (j == 0): TILE_LT_I = TILE_LT_IJ TILE_GT_I = TILE_GT_IJ else: TILE_LT_I = TILE_LT_I.union(TILE_LT_IJ).coalesce() TILE_GT_I = TILE_GT_I.union(TILE_GT_IJ).coalesce() TILE_LT.append(TILE_LT_I) TILE_GT.append(TILE_GT_I) if (DEBUG): DebugPrint('TILE_LT', TILE_LT, cl.statements) DebugPrint('TILE_GT', TILE_GT, cl.statements) if (INVERSE_TILING): tmpx = TILE_LT[:] TILE_LT = TILE_GT TILE_GT = tmpx # ************************************************************************** TILE_ITR = [] for i in range(0, len(cl.statements)): if not isl_relclosure.is_empty(): TILE_ITRI = TILE[i].subtract( TILE_GT[i].apply(isl_relclosure)).coalesce() else: TILE_ITRI = TILE[i] if (SIMPLIFY): TILE_ITRI = imperf_tile.SimplifySlice(TILE_ITRI) TILE_ITR.append(TILE_ITRI) #print 'R+(TILE_GT)*TILE[i]' #print i # print TILE_GT[i].apply(isl_relclosure).intersect(TILE[i]) if (DEBUG): DebugPrint('TILE_ITR', TILE_ITR, cl.statements) # ************************************************************************** TVLD_LT = [] if not isl_relclosure.is_empty(): for i in range(0, len(cl.statements)): TVLD_LTI = (TILE_LT[i].intersect( TILE_ITR[i].apply(isl_relclosure))).subtract( TILE_GT[i].apply(isl_relclosure)).coalesce() TVLD_LT.append(TVLD_LTI) if (DEBUG): DebugPrint('TVLD_LT', TVLD_LT, cl.statements) # ************************************************************************** TILE_VLD = [] for i in range(0, len(cl.statements)): if not isl_relclosure.is_empty(): TILE_VLDI = TVLD_LT[i].union(TILE_ITR[i]).coalesce() else: TILE_VLDI = TILE_ITR[i] if (SIMPLIFY): TILE_VLDI = imperf_tile.SimplifySlice(TILE_VLDI) TILE_VLD.append(TILE_VLDI) if (DEBUG): DebugPrint('TILE_VLD', TILE_VLD, cl.statements) # ************************************************************************** TILE_VLD_EXT = [] Rapply = tiling_v3.GetRapply(vars, sym_exvars, ','.join(isl_symb + sym_exvars) + ',') for i in range(0, len(cl.statements)): TILE_VLD_EXTI = tiling_v3.Project(TILE_VLD[i].apply(Rapply).coalesce(), sym_exvars) ##################################################################################################################### if AGGRESSIVE_SIMPLIFY: cor_set = '' if (len(isl_symb) > 0): cor_set = '[' + ','.join(isl_symb) + '] -> ' else: cor_set = '' cor_set = cor_set + '{[' + ','.join(sym_exvars) + ',' + ','.join( vars) + ',' + 'v] : ' for k in range(0, i + 1): for j in range(0, len(cl.statements[k].bounds)): compar = ' <= ' add1 = ' - ' add2 = ' + ' if cl.statements[k].bounds[j]['step'] == '-1': add1 = ' + ' add2 = ' - ' compar = ' >= ' cor_set = cor_set + vars[j] + compar + cl.statements[ k].bounds[j]['ub'] + add1 + BLOCK2[j] + " && " cor_set = cor_set + cl.statements[k].bounds[j][ 'lb'] + add2 + BLOCK2[j] + compar + vars[j] + " && " cor_set = cor_set + "(" cor_set = cor_set + " v = " + str( cl.statements[i].petit_line) + " " cor_set = cor_set + ")}" print cor_set cor_set = isl.Set(cor_set) print '**************************' TILE_VLD_EXTI = TILE_VLD_EXTI.intersect(cor_set) ##################################################################################################################### TILE_VLD_EXT.append(TILE_VLD_EXTI) if (DEBUG): DebugPrint('TILE_VLD_EXT', TILE_VLD_EXT, cl.statements) # ************************************************************************** # TIME TO SCATTER - TO HONOUR ORDER OF STATEMENTS IN IMPERFECTLY NESTED LOOPS RMaps = [] for i in range(0, len(cl.statements)): RMap = '{' lbx = 0 ubx = i + 1 if (INVERSE_TILING): lbx = i ubx = len(cl.statements) for j in range(lbx, ubx): # to przy odwrotnym tilngu moze trzeba poprawic RMap = RMap + '[' + ','.join(sym_exvars + vars) + ',' + str( cl.statements[j].petit_line) + '] -> [' scati = fix_scat(cl.statements[i].scatering, loop.maxl) scatj = fix_scat(cl.statements[j].scatering, loop.maxl) combo = [ x for t in zip(scati + scatj, sym_exvars + vars) for x in t ] # obled RMap = RMap + ','.join(combo) + ',' + str( cl.statements[j].petit_line) + ']; ' # normalize j RMap = RMap[:-2] + '}' Rmap = isl.Map(RMap) RMaps.append(Rmap) if (DEBUG): DebugPrint('RMaps', RMaps, cl.statements) # ************************************************************************** for i in range(0, len(cl.statements)): TILE_VLD_EXT[i] = TILE_VLD_EXT[i].apply(RMaps[i]).coalesce() if (DEBUG): DebugPrint('TILE_VLD_EXT after Map', TILE_VLD_EXT, cl.statements) TILE_VLD_EXT_union = TILE_VLD_EXT[0] for i in range(1, len(cl.statements)): TILE_VLD_EXT_union = TILE_VLD_EXT_union.union( TILE_VLD_EXT[i]).coalesce() if (DEBUG): print colored('TILE_VLD_EXT to CodeGen', 'green') print TILE_VLD_EXT_union #if(SIMPLIFY): #TILE_VLD_EXT_union= imperf_tile.SimplifySlice(TILE_VLD_EXT_union) # ************************************************************************** # Optional Schedule s = ','.join(["i%d" % i for i in range(1, loop.maxl * 4 + 2)]) # RFS ss = s in_ = s.split(',') symb = '' if (len(isl_symb) > 0): symb += '[' + ','.join(isl_symb) + ']' + '->' RSched = symb + '{[' + s + '] -> [' RValid = RSched # RFS RFS = RSched # ***************************************************** LOOP SKEWING print colored('Loop skewing testing...', 'green') sdel = isl_rel.deltas() inp = [] for i in range(0, sdel.dim(isl.dim_type.set)): inp.append("i" + str(i)) stest = "{[" + ",".join(inp) + "] : " + inp[1] + " < 0 }" stest = isl.Set(stest) sdel = stest.intersect(sdel).coalesce() if (sdel.is_empty()): print colored('Found: i2 -> i2 + i4', 'yellow') s = s.replace('i2', 'i2 + i4') else: print colored('Failed.', 'yellow') #s = s.replace('i4', 'i6') #s = s.replace('i2', 'i2 + 2*i4') #s = s.replace('i', 'i8') #s = s.replace('i10', 'i10 + i8') #s = s.replace('i6', '2*i2 + i4 + i6') # ***************************************************** LOOP SKEWING # ***************************************************** DECREMENTATION index_arr = numpy.zeros(shape=(len(cl.statements), loop.maxl)) for k in range(0, loop.maxl): for i in range(0, len(cl.statements)): if (k < len(cl.statements[i].bounds)): index_arr[i][k] = cl.statements[i].bounds[k]['step'] print colored('step array (st,loop)', 'green') print numpy.matrix(index_arr) for k in range(0, loop.maxl): vec = index_arr[:, k] dec = 1 for i in range(0, len(cl.statements)): if (vec[i] != -1): dec = 0 break if (dec == 0): continue ind = str(2 * loop.maxl + 2 * (k + 1)) print colored('decrementation on ' + str(k + 1) + ' loop', 'yellow') s = s.replace('i' + ind, '-i' + ind) # TODO rozdzielic na gniazda i v w przyszlosci # ***************************************************** RSched += s + '] : ' RFS += ss + '] : 1=1 }' RSched = RSched + copyconstr.GetConstrSet(in_, TILE_VLD_EXT_union) + " }" print 'RSCHEDULE' print RSched Rsched = isl.Map(RSched) print 'VALIDATION CHECKING ' if (not isl_rel.is_empty() and 1 == 1): s_in = ','.join(["i%d" % i for i in range(1, loop.maxl * 4 + 2)]) sout = ','.join(["i%d'" % i for i in range(1, loop.maxl * 4 + 2)]) out_ = sout.split(',') i1 = in_[2 * loop.maxl + 1:4 * loop.maxl + 1:2] + [in_[loop.maxl * 4]] i2 = out_[2 * loop.maxl + 1:4 * loop.maxl + 1:2] + [in_[loop.maxl * 4]] RValid += sout + '] : ' DomR = isl_rel.domain() RValid += copyconstr.GetConstrSet( i1, DomR) + ' && ' + copyconstr.GetConstr(i1, i2, isl_rel) s_in_ex = ','.join(["ex%d" % i for i in range(1, loop.maxl * 4 + 2)]) s_out_ex = ','.join(["ex%d'" % i for i in range(1, loop.maxl * 4 + 2)]) ex_sin = s_in_ex.split(',') ex_sout = s_out_ex.split(',') RValid += ' && exists ' + s_in_ex + ',' + s_out_ex + ' : (' RValid += ' ( ' + tiling_v3.CreateLex(ex_sin, ex_sout) + ' ) && ' RValid += ' ( ' + copyconstr.GetConstr(in_, ex_sin, Rsched) + ' ) && ' RValid += ' ( ' + copyconstr.GetConstr(out_, ex_sout, Rsched) + ' ) ' RValid += ' ) }' RValid = isl.Map(RValid).coalesce() if (RValid.is_empty()): print colored('*** VALIDATION OK ***', 'green') else: print colored('*** VALIDADION FAILED ***', 'red') print colored(RValid, 'green') if (FSSCHEDULE == 0): print RValid sys.exit(0) for st in cl.statements: z = st.domain_map z = isl.Set(z) # czy wszystkie z domain sa w TVLD_EXT VLDUNION RELATION == v # I nalezy do TVLD_EXT and exists i,j,v i nalezy do domain_map i i,j,v != I ma byc pusty VLD_VAL = Rsched.range() if (VALIDATION > 0): tiling5_valid.Valid1(Rsched, symb, in_, out_, s_in, sout, loop) else: print "OK" # ************************************************************************** #### DISCOVER PARALLELISM -- empty # ii, jj -> ii, jj' : not jj = jj' print colored('Parallelism searching', 'green') s = ','.join(["i%d" % i for i in range(1, loop.maxl * 4 + 2)]) in_ = s.split(',') sprim = ','.join(["i%d'" % i for i in range(1, loop.maxl * 4 + 2)]) out_ = sprim.split(',') Rel_base = symb + '{[' + s + '] -> [' + sprim + '] : ' #i1 = domain R 12 = R(i1) ii,i1 nalezy do VLD_EXT i'i',i2 nalezy do VLDEXT i ogr. ponizej np ii2 <> ii2' ii1 = ii1' relacja par_loop = [] if (not isl_rel.is_empty() and 1 == 1): delta = isl_rel.deltas() chkc = isl.Set("{[0," + ",".join(vars) + "]}") delta = delta.subtract(chkc) for i in range(0, loop.maxl * 4, 2): j = -1 print 'c' + str(i + 1), Rel = Rel_base tmp = '' for j in range(0, i): tmp += in_[j] + ' = ' + out_[j] + ' && ' tmp += ' not ( ' + in_[j + 1] + ' = ' + out_[ j + 1] + ' && ' + in_[j + 2] + ' = ' + out_[j + 2] + ' ) && ' Rel += tmp Rel += copyconstr.GetConstrSet( i1, DomR) + ' && ' + copyconstr.GetConstr(i1, i2, isl_rel) Rel += ' && ( ' + copyconstr.GetConstrSet(in_, VLD_VAL) + ' ) && ' Rel += ' ( ' + copyconstr.GetConstrSet(out_, VLD_VAL) + ' ) ' Rel += ' }' #print Rel Rel = isl.Map(Rel) if (i == 0): Rel = delta if (Rel.is_empty()): print colored('found!', 'green') par_loop.append('c' + str(i + 1)) # break else: print 'no!' end = time.time() elapsed = end - start print "Algorithm: time taken: ", elapsed, "seconds." # ************************************************************************** vars = map(str, vars) start = time.time() ast = 0 if (ast == 1): loop_x = iscc.isl_ast_codegen_map(Rsched) else: loop_x = iscc.iscc_communicate("L :=" + str(Rsched) + "; codegen L;") print loop_x # ************************************************************************** lines = loop_x.split('\n') loop_str = [] for line in lines: if line.endswith(');'): tab = imperf_tile.get_tab(line) line = line.replace(' ', '') line = line[:-2] line = line[1:] arr = line.split(',') petit_st = arr[4 * loop.maxl] s = '' for i in range(0, len(cl.statements)): # TODO if petit_st has 'c' get all statements make if from petit_line and insert to s, solution for loop over st if 'c' in petit_st: combo_st = '{' for j in range(0, len(cl.statements)): combo_st += '\n' + tab combo_st += 'if( ' + petit_st + ' == ' + str( cl.statements[j].petit_line ) + ' ) ' + cl.statements[j].body s = combo_st + '\n' + tab + '}' elif cl.statements[i].petit_line == int( petit_st): # st.petit_line s = cl.statements[i].body for i in range( 0, len(vars) ): # todo oryginal iterators for loops with mixed indexes subt = arr[2 * loop.maxl + 2 * i + 1] if (('+' in subt) or ('-' in subt)): subt = '(' + subt + ')' s = re.sub(r'\b' + vars[i] + r'\b', subt, s) loop_str.append(tab + s) else: line = line.replace('for (int', 'for(') loop_str.append(line) end = time.time() elapsed = end - start print "Code Generation: time taken: ", elapsed, "seconds.\n\n" #loop_str = '\n'.join(loop_str) filePaths = glob.glob(plik) if (output_file != ""): nazwa = output_file else: for filePath in filePaths: base = os.path.basename(filePath) nazwa = os.path.splitext(base)[0] + "_tiling" + os.path.splitext( base)[1] text_file = open(nazwa, "w") for line in loop_str: if (len(par_loop) > 0): if ('for( ' + par_loop[0] + ' ' in line): print imperf_tile.get_tab(line) + colored( '#pragma omp parallel for', 'green') text_file.write( imperf_tile.get_tab(line) + '#pragma omp parallel for' + '\n') print line text_file.write(line + '\n') text_file.close() print 'Output written to: ' + nazwa for d in loop.Deps: del d.Relation sys.exit(0) ################################################################################################### if (FSSCHEDULE): rtile = tiling_schedule.get_RTILE(TILE_VLD_EXT_union, sym_exvars, isl_rel, True) #Rsched.Range() rtile_ii = rtile #print rtile_ii for i in range(0, loop.maxl): rtile_ii = rtile_ii.remove_dims(isl.dim_type.in_, 2 * loop.maxl - i * 2 - 2, 1) rtile_ii = rtile_ii.remove_dims(isl.dim_type.out, 2 * loop.maxl - i * 2 - 2, 1) print colored('RTILE', 'green') print rtile sys.exit(0) if islrp: rtileplus, exact = rtile.transitive_closure() else: rtileplus = relation_util.oc_IterateClosure(rtile) exact = 1 print colored('RTILE+', 'green') print rtileplus if (exact != 1): print colored('RTILE+ approx', 'yellow') else: print colored('RTILE+ exact', 'green') # tiling_v2.DynamicRTILE(rtile, Rsched.range(), loop.maxl, cl, vars, RFS) try: p = int(cpus) # or int except ValueError: print 'Bad cpus parameter. ' sys.exit(0) FI = symb + ' {[' + ','.join( sym_exvars) + ',v] -> [p] : (exists k : (' item = '' for i in range(0, p): item = item + ' (p=' + str(i) + ' ' + ' && ' + sym_exvars[ 0] + ' - (2k + ' + str(i) + ') = 0 ) || ' FI += item[:-3] + ' )) &&' vv = ["i%d" % i for i in range(1, loop.maxl * 4 + 2)] s_in = ','.join(vv) s_out = ','.join(["i%d" % i for i in range(2, loop.maxl * 2 + 1, 2) ]) + ',' + vv[len(vv) - 1] rmap_fi = '{[' + s_in + '] -> [' + s_out + ']}' rmap_fi = isl.Map(rmap_fi) II_SET = TILE_VLD_EXT_union.apply(rmap_fi).coalesce() print colored('II_SET', 'green') print II_SET FI += copyconstr.GetConstrSet(sym_exvars + ['v'], II_SET) + '}' FI = isl.Map(FI).coalesce() print colored('FI', 'green') print FI RPROC = symb + '{[' + ','.join(sym_exvars) + ',v] -> [' + ','.join( sym_exvars_p) + ',vp] : ' domRTILE = rtile_ii.domain().coalesce() RPROC += copyconstr.GetConstrSet( sym_exvars + ['v'], domRTILE) + ' && ' + copyconstr.GetConstr( sym_exvars + ['v'], sym_exvars_p + ['vp'], rtile_ii) RPROC += ' && exists p,pp : ( not(p=pp) && ' + copyconstr.GetConstr( sym_exvars + ['v'], ['p'], FI) + ' && ' + copyconstr.GetConstr( sym_exvars_p + ['vp'], ['pp'], FI) + ' ) }' #print RPROC RPROC = isl.Map(RPROC).coalesce() print colored('RPROC', 'green') print RPROC s = ','.join(["i%d" % i for i in range(0, loop.maxl + 1)]) sv = s.split(',') s1 = ','.join(["o%d" % i for i in range(0, loop.maxl + 1)]) sv1 = s1.split(',') s2 = ','.join(["ex%d" % i for i in range(0, loop.maxl + 1)]) sve = s2.split(',') R_RESIDUAL = symb + '{[' + s + '] -> [' + s1 + '] : ' R_RESIDUAL += copyconstr.GetConstrSet( sv, RPROC.domain().coalesce()) + '&& ' R_RESIDUAL += copyconstr.GetConstr( sv, sv1, RPROC) + '&& not exists ' + s2 + ' : (' R_RESIDUAL += tiling_v3.CreateLex( sve, sv) + ' && ' + copyconstr.GetConstr(sve, sv1, RPROC) + ')}' R_RESIDUAL = isl.Map(R_RESIDUAL).coalesce() print colored('R_RESIDUAL', 'green') print R_RESIDUAL irp = R_RESIDUAL.fixed_power_val(-1) R_P_RESIDUAL = symb + '{[' + ','.join( sym_exvars) + ',v] -> [p,' + ','.join(sym_exvars_p) + ',vp] : ' R_P_RESIDUAL += copyconstr.GetConstr( sym_exvars_p + ['vp'], ['p'], FI) + ' && ' + copyconstr.GetConstr( sym_exvars + ['v'], sym_exvars_p + ['vp'], irp) + ' }' R_P_RESIDUAL = isl.Map(R_P_RESIDUAL) print colored('R_P_RESIDUAL', 'green') print R_P_RESIDUAL