示例#1
0
def simulate(args):
    import hwlib.hcdc.hwenvs as hwenvs
    from hwlib.hcdc.hcdcv2_4 import make_board
    from hwlib.hcdc.globals import HCDCSubset
    dssim = DSProgDB.get_sim(args.program)
    path_handler = paths.PathHandler(args.subset, args.program)

    if args.reference:
        ref_prog = DSProgDB.get_prog(args.program)
        if args.runtime:
            result = ref_prog.execute_and_profile(dssim)
            print("runtime: %e seconds" % result)
        else:
            plot_reference_simulation(path_handler, ref_prog, dssim)

    if args.adp:
        board = make_board(HCDCSubset(args.subset), \
                                  load_conns=False)
        adp = AnalogDeviceProg.read(board, args.adp)
        init_conds,derivs =  \
                            buildsim.build_simulation(board, \
                                                      adp,
                                                      args.mode)
        V,T,Y = run_adp_simulation(board, \
                                   adp, \
                                   init_conds, \
                                   derivs, \
                                   dssim)
        plot_adp_simulation(path_handler, dssim, args.adp, V, T, Y)
示例#2
0
    def scan(self):
        for dirname, subdirlist, filelist in os.walk(CONFIG.LEGNO_PATH):
            for fname in filelist:
                if fname.endswith('.grendel'):
                    fargs = paths.PathHandler.path_to_args(dirname)
                    ph = paths.PathHandler(subset=fargs['subset'], \
                                           prog=fargs['prog'], \
                                           make_dirs=False)
                    gargs = \
                          ph.grendel_file_to_args(fname)
                    if self.experiment_tbl.has(  \
                                                 subset=fargs['subset'], \
                                                 prog=fargs['prog'], \
                                                 lgraph=gargs['lgraph'], \
                                                 lscale=gargs['lscale'], \
                                                 model=gargs['model'], \
                                                 obj=gargs['opt'], \
                                                 dssim=gargs['dssim'], \
                                                 hwenv=gargs['hwenv']):
                        continue

                    exp = self.add(ph, \
                                   subset=fargs['subset'], \
                                   prog=fargs['prog'], \
                                   lgraph=gargs['lgraph'], \
                                   lscale=gargs['lscale'], \
                                   model=gargs['model'], \
                                   obj=gargs['opt'], \
                                   dssim=gargs['dssim'], \
                                   hwenv=gargs['hwenv'])
                    if not exp is None:
                        yield exp
示例#3
0
def read_compile_times(subset):
    summary = {}

    for bmark in common.BenchmarkVisualization.benchmarks():
        ph = pathlib.PathHandler(subset, bmark, make_dirs=False)
        time_dir = ph.TIME_DIR
        for dirname, subdirlist, filelist in os.walk(time_dir):
            for fname in filelist:
                if not fname.endswith('.txt'):
                    continue

                fpath = "%s/%s" % (dirname, fname)
                with open(fpath, 'r') as fh:
                    lines = fh.read().split("\n")
                    comp_pass = lines[0]
                    nonempty_lines = filter(lambda l: l != "", lines[1:])
                    times = np.array(list(map(lambda l: float(l), \
                                              nonempty_lines)))
                    if not bmark in summary:
                        summary[bmark] = {}

                    if len(times) == 0:
                        summary[bmark][comp_pass] = (None, 0.0)
                    else:
                        avg_time = np.mean(times)
                        std_time = np.std(times)
                        summary[bmark][comp_pass] = (avg_time, std_time)

    return summary
示例#4
0
def analyze(entry, recompute=False):
    path_h = paths.PathHandler(entry.subset, entry.program)
    QUALITIES = []
    VARS = set(map(lambda o: o.variable, entry.outputs()))
    MODEL = None
    dssim = dsproglib.DSProgDB.get_sim(entry.program)
    no_reference = (dssim.real_time)
    for output in entry.outputs():
        variable = output.variable
        trial = output.trial

        TMEAS, YMEAS = read_meas_data(output.waveform)
        common.simple_plot(output, path_h, output.trial, 'meas', TMEAS, YMEAS)
        if no_reference:
            TFIT, YFIT = scale_obs_data(output, TMEAS, YMEAS, scale_time=False)
            common.simple_plot(output, path_h, output.trial, 'rec', TFIT, YFIT)
            QUALITIES.append(0)
            continue

        #if not output.quality is None:
        #  QUALITIES.append(output.quality)

        TREF, YREF = compute_ref(entry.program, entry.dssim, variable)
        #common.simple_plot(output,path_h,output.trial,'ref',TREF,YREF)

        TPRED, YPRED = scale_ref_data(output, TREF, YREF)
        #common.simple_plot(output,path_h,output.trial,'pred',TPRED,YPRED)

        fit(output, TPRED, YPRED, TMEAS, YMEAS)
        TFIT, YFIT = scale_obs_data(output, TMEAS, YMEAS)

        if TFIT is None or YFIT is None:
            QUALITIES.append(-1)
            continue

        #common.simple_plot(output,path_h,output.trial,'rec',TFIT,YFIT)
        common.compare_plot(output, path_h, output.trial, 'comp', TREF, YREF,
                            TFIT, YFIT)
        RESULT = compute_quality(output, TFIT, YFIT, TREF, YREF)
        if RESULT == -1:
            QUALITIES.append(RESULT)
            continue

        QUALITY, TERR, YERR = RESULT
        if QUALITY is None:
            QUALITIES.append(-1)
            continue
        #common.simple_plot(output,path_h,output.trial,'err',TERR,YERR)
        output.quality = QUALITY
        QUALITIES.append(QUALITY)

    if len(QUALITIES) > 0:
        QUALITY = np.median(QUALITIES)
        entry.set_quality(QUALITY)
示例#5
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def exec_lemul(args):
    from compiler import lsim

    path_handler = paths.PathHandler(args.subset, args.program)
    program = DSProgDB.get_prog(args.program)
    timer = util.Timer('emul', path_handler)

    if args.unscaled:
        direc = path_handler.lgraph_adp_dir()
    else:
        direc = path_handler.lscale_adp_dir()

    board = get_device(None)
    for dirname, subdirlist, filelist in \
        os.walk(direc):
        for adp_file in filelist:
            if adp_file.endswith('.adp'):
                with open(dirname + "/" + adp_file, 'r') as fh:
                    print("===== %s =====" % (adp_file))
                    adp = ADP.from_json(board, \
                                        json.loads(fh.read()))

                    if args.unscaled:
                        for cfg in adp.configs:
                            cfg.modes = [cfg.modes[0]]
                        plot_file = path_handler.adp_sim_plot(
                            paths.PlotType.SIMULATION, \
                            adp.metadata[ADPMetadata.Keys.DSNAME],
                            adp.metadata[ADPMetadata.Keys.LGRAPH_ID],
                            'na',
                            'na',
                            'na', \
                            per_variable=args.separate_figures)

                    else:
                        plot_file = path_handler.adp_sim_plot(
                            paths.PlotType.SIMULATION, \
                            adp.metadata[ADPMetadata.Keys.DSNAME],
                            adp.metadata[ADPMetadata.Keys.LGRAPH_ID],
                            adp.metadata[ADPMetadata.Keys.LSCALE_ID],
                            adp.metadata[ADPMetadata.Keys.LSCALE_SCALE_METHOD],
                            adp.metadata[ADPMetadata.Keys.LSCALE_OBJECTIVE], \
                            per_variable=args.separate_figures)

                    print(plot_file)

                    board = get_device(
                        adp.metadata[ADPMetadata.Keys.RUNTIME_PHYS_DB])
                    lsim.simulate_adp(board,adp,plot_file, \
                                      enable_quantization=not args.no_quantize, \
                                      enable_intervals=not args.no_operating_range, \
                                      enable_physical_model= not args.no_physdb, \
                                      enable_model_error =not args.no_model_error, \
                                      separate_figures=args.separate_figures)
示例#6
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def exec_lsim(args):
    from compiler import lsim

    board = get_device(None)
    path_handler = paths.PathHandler(args.subset, args.program)
    program = DSProgDB.get_prog(args.program)
    plot_file = path_handler.adp_sim_plot(
        paths.PlotType.SIMULATION, \
        program.name, \
        'REF',
        'na',
        'na',
        'na', \
        per_variable=args.separate_figures)
    lsim.simulate_reference(board,program,plot_file, \
                            separate_figures=args.separate_figures)
示例#7
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def save_data_from_arduino(dataset, board, dsprog, adp, sim_time, trial=0):

    ph = pathlib.PathHandler(adp.metadata[adplib.ADPMetadata.Keys.FEATURE_SUBSET], \
                             dsprog.name)

    calib_obj = llenums.CalibrateObjective(
        adp.metadata[adplib.ADPMetadata.Keys.RUNTIME_CALIB_OBJ])

    times, voltages_by_chan = unpack_arduino_waveform(dataset)
    # seconds per time unit
    tc = board.time_constant / adp.tau
    wc_time = get_wall_clock_time(board, dsprog, adp, sim_time)
    print("num-samps: %d" % len(times))
    print("wall-clock-time: [%f,%f]" % (min(times), max(times)))
    for var, scf, chans in adp.observable_ports(board):
        chan_id = get_ard_chan_for_pin(chans[llenums.Channels.POS].pin)
        voltages = voltages_by_chan[chan_id]
        #for i,(t,v) in enumerate(zip(times,voltages)):
        #    print("%d: %e\t%f" % (i,t,v))
        print("voltages[%s,%d]: [%f,%f]" % (var,chan_id, \
                                          min(voltages),max(voltages)))

        json_data = {'times':times,  \
                     'values':voltages,  \
                     'time_units': 'wall_clock_sec', \
                     'ampl_units': 'voltage', \
                     'runtime': wc_time,\
                     'variable':var, \
                     'time_scale':tc, \
                     'mag_scale':scf}
        print("<writing file>")
        filename = ph.measured_waveform_file(graph_index=adp.metadata[adplib.ADPMetadata.Keys.LGRAPH_ID], \
                                             scale_index=adp.metadata[adplib.ADPMetadata.Keys.LSCALE_ID], \
                                             model=adp.metadata[adplib.ADPMetadata.Keys.LSCALE_SCALE_METHOD], \
                                             opt=adp.metadata[adplib.ADPMetadata.Keys.LSCALE_OBJECTIVE], \
                                             phys_db=adp.metadata[adplib.ADPMetadata.Keys.RUNTIME_PHYS_DB], \
                                             calib_obj=calib_obj, \
                                             no_scale=adp.metadata[adplib.ADPMetadata.Keys.LSCALE_NO_SCALE], \
                                             one_mode=adp.metadata[adplib.ADPMetadata.Keys.LSCALE_ONE_MODE], \
                                             variable=var, \
                                             trial=trial)
        print(filename)
        with open(filename.format(variable=var), 'w') as fh:
            print("-> compressing data")
            strdata = util.compress_json(json_data)
            fh.write(strdata)
        print("<wrote file>")
示例#8
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def exec_lgraph(args):
    from compiler import lgraph

    board = get_device(args.model_number)
    path_handler = paths.PathHandler(args.subset, args.program)
    program = DSProgDB.get_prog(args.program)
    timer = util.Timer('lgraph', path_handler)
    timer.start()
    count = 0
    for index,adp in \
        enumerate(lgraph.compile(board,
                                 program,
                                 vadp_fragments=args.vadp_fragments,
                                 asm_frags=args.asm_fragments,
                                 synth_depth=args.synth_depth,
                                 vadps=args.vadps,
                                 adps=args.adps, \
                                 routes=args.routes)):
        timer.end()
        adp.metadata.set(ADPMetadata.Keys.DSNAME, \
                         args.program)
        adp.metadata.set(ADPMetadata.Keys.FEATURE_SUBSET, \
                         args.subset)

        adp.metadata.set(ADPMetadata.Keys.LGRAPH_ID, \
                         int(index))
        print("<<< writing circuit>>>")
        filename = path_handler.lgraph_adp_file(index)
        with open(filename, 'w') as fh:
            jsondata = adp.to_json()
            fh.write(json.dumps(jsondata, indent=4))

        print("<<< writing graph >>>")
        filename = path_handler.lgraph_adp_diagram_file(index)
        adprender.render(board, adp, filename)
        count += 1
        if count >= args.adps:
            break

        timer.start()

    print("<<< done >>>")
    timer.kill()
    print(timer)
    timer.save()
示例#9
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def save_data_from_oscilloscope(osc, board, dsprog, adp, sim_time, trial=0):

    ph = pathlib.PathHandler(adp.metadata[adplib.ADPMetadata.Keys.FEATURE_SUBSET], \
                             dsprog.name)
    calib_obj = llenums.CalibrateObjective(
        adp.metadata[adplib.ADPMetadata.Keys.RUNTIME_CALIB_OBJ])

    wc_time = get_wall_clock_time(board, dsprog, adp, sim_time)
    for var, scf, chans in adp.observable_ports(board):
        chan_pos = get_osc_chan_for_pin(chans[llenums.Channels.POS].pin)
        chan_neg = get_osc_chan_for_pin(chans[llenums.Channels.NEG].pin)
        times,voltages = oscliblib.get_waveform(osc, \
                                                chan_pos, \
                                                chan_neg, \
                                                differential=True)
        tc = board.time_constant / adp.tau
        json_data = {'times':times,  \
                     'values':voltages,  \
                     'time_units': 'wall_clock_sec', \
                     'ampl_units': 'voltage', \
                     'runtime': wc_time,\
                     'variable':var, \
                     'time_scale':tc, \
                     'mag_scale':scf}
        print("<writing file>")

        filename = ph.measured_waveform_file(graph_index=adp.metadata[adplib.ADPMetadata.Keys.LGRAPH_ID], \
                                             scale_index=adp.metadata[adplib.ADPMetadata.Keys.LSCALE_ID], \
                                             model=adp.metadata[adplib.ADPMetadata.Keys.LSCALE_SCALE_METHOD], \
                                             opt=adp.metadata[adplib.ADPMetadata.Keys.LSCALE_OBJECTIVE], \
                                             phys_db=adp.metadata[adplib.ADPMetadata.Keys.RUNTIME_PHYS_DB], \
                                             calib_obj=calib_obj, \
                                             no_scale=adp.metadata[adplib.ADPMetadata.Keys.LSCALE_NO_SCALE], \
                                             one_mode=adp.metadata[adplib.ADPMetadata.Keys.LSCALE_ONE_MODE], \
                                             variable=var, \
                                             trial=trial, \
                                             oscilloscope=True)
        print(filename)

        with open(filename.format(variable=var), 'w') as fh:
            print("-> compressing data")
            strdata = util.compress_json(json_data)
            fh.write(strdata)
        print("<wrote file>")
示例#10
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def exec_lexec(args):
    EXEC_CMD = "python3 grendel.py exec {adp_path} --model-number {model_number}"
    if args.scope:
        EXEC_CMD += " --osc"

    board = get_device(None)
    path_handler = paths.PathHandler(args.subset, args.program)
    program = DSProgDB.get_prog(args.program)
    timer = util.Timer('lexec', path_handler)
    for dirname, subdirlist, filelist in \
        os.walk(path_handler.lscale_adp_dir()):
        for adp_file in filelist:
            if adp_file.endswith('.adp'):
                adp_path = dirname + "/" + adp_file
                print(adp_path)
                with open(adp_path, 'r') as fh:
                    print("===== %s =====" % (adp_file))
                    adp = ADP.from_json(board, \
                                        json.loads(fh.read()))
                    kwargs = {
                        'adp_path':
                        adp_path,
                        'model_number':
                        adp.metadata[ADPMetadata.Keys.RUNTIME_PHYS_DB]
                    }
                    if not _lexec_already_ran(path_handler,board,adp,trial=0, \
                                              scope=args.scope) or \
                       args.force:
                        timer.start()
                        cmd = EXEC_CMD.format(**kwargs)
                        code = os.system(cmd)
                        timer.end()
                        #input("continue")
                        if code == signal.SIGINT or code != 0:
                            raise Exception("User terminated process")

        print(timer)
        timer.save()
示例#11
0
def exec_lcal(args):
    if args.model_number is None:
        raise Exception(
            "model number must be provided to calibration procedure")

    board = get_device(args.model_number)
    path_handler = paths.PathHandler(args.subset, args.program)
    program = DSProgDB.get_prog(args.program)
    for dirname, subdirlist, filelist in \
        os.walk(path_handler.lgraph_adp_dir()):
        for adp_file in filelist:
            if adp_file.endswith('.adp'):
                adp_path = dirname + "/" + adp_file
                if args.maximize_fit:
                    runt_meta_util.legacy_calibration(board, adp_path, \
                                                      llenums.CalibrateObjective.MAXIMIZE_FIT, \
                                                      widen=True,
                                                      logfile=None)
                if args.minimize_error:
                    runt_meta_util.legacy_calibration(board, adp_path, \
                                                      llenums.CalibrateObjective.MINIMIZE_ERROR, \
                                                      widen=True,
                                                      logfile=None)
示例#12
0
def exec_wav(args, trials=1):
    import compiler.lwav_pass.waveform as wavelib
    import compiler.lwav_pass.analyze as analyzelib

    path_handler = paths.PathHandler(args.subset, \
                                     args.program)
    program = DSProgDB.get_prog(args.program)

    # bin summary plots
    summary = {}
    summary_key = lambda adp : (
        adp.metadata[ADPMetadata.Keys.RUNTIME_CALIB_OBJ], \
        adp.metadata[ADPMetadata.Keys.LSCALE_SCALE_METHOD], \
        adp.metadata[ADPMetadata.Keys.LSCALE_OBJECTIVE], \
        adp.metadata[ADPMetadata.Keys.RUNTIME_PHYS_DB], \
        adp.metadata[ADPMetadata.Keys.LSCALE_NO_SCALE], \
        adp.metadata[ADPMetadata.Keys.LSCALE_ONE_MODE])

    def update_summary(adp, var, wave, has_scope=False):
        key = (summary_key(adp), var, has_scope)
        if not key in summary:
            summary[key] = []

        summary[key].append((adp, wave))

    assert (not args.scope_only or not args.adc_only)
    if args.scope_only:
        scope_options = [True]
    elif args.adc_only:
        scope_options = [False]
    else:
        scope_options = [True, False]

    for dirname, subdirlist, filelist in \
        os.walk(path_handler.lscale_adp_dir()):
        for adp_file in filelist:
            if adp_file.endswith('.adp'):
                with open(dirname + "/" + adp_file, 'r') as fh:
                    print("===== %s =====" % (adp_file))
                    adp_obj = json.loads(fh.read())
                    metadata = ADPMetadata.from_json(adp_obj['metadata'])
                    if not metadata.has(ADPMetadata.Keys.RUNTIME_PHYS_DB) or \
                       not metadata.has(ADPMetadata.Keys.RUNTIME_CALIB_OBJ):
                        continue

                    board = get_device(
                        metadata.get(ADPMetadata.Keys.RUNTIME_PHYS_DB))
                    adp = ADP.from_json(board, adp_obj)
                    calib_obj = llenums.CalibrateObjective(
                        adp.metadata[ADPMetadata.Keys.RUNTIME_CALIB_OBJ])
                    for trial in range(trials):
                        for var, _, _ in adp.observable_ports(board):
                            for has_scope in scope_options:
                                print("------- %s [has_scope=%s] ----" %
                                      (adp_file, has_scope))
                                waveform_file = path_handler.measured_waveform_file( \
                                                                                     graph_index=adp.metadata[ADPMetadata.Keys.LGRAPH_ID],
                                                                                     scale_index=adp.metadata[ADPMetadata.Keys.LSCALE_ID],
                                                                                     model=adp.metadata[ADPMetadata.Keys.LSCALE_SCALE_METHOD],
                                                                                     calib_obj=calib_obj, \
                                                                                     opt=adp.metadata[ADPMetadata.Keys.LSCALE_OBJECTIVE], \
                                                                                     phys_db=adp.metadata[ADPMetadata.Keys.RUNTIME_PHYS_DB] , \
                                                                                     no_scale=adp.metadata[ADPMetadata.Keys.LSCALE_NO_SCALE], \
                                                                                     one_mode=adp.metadata[ADPMetadata.Keys.LSCALE_ONE_MODE], \
                                                                                     variable=var, \
                                                                                     trial=trial, \
                                                                                     oscilloscope=has_scope)

                                if os.path.exists(waveform_file):
                                    with open(waveform_file, 'r') as fh:
                                        obj = util.decompress_json(fh.read())
                                        wave = wavelib.Waveform.from_json(obj)
                                        adp = ADP.from_json(board, adp_obj)
                                        update_summary(adp,
                                                       var,
                                                       wave,
                                                       has_scope=has_scope)
                                        for vis in analyzelib.plot_waveform(board,adp,wave, \
                                                                            emulate=args.emulate, \
                                                                            measured=args.measured):
                                            plot_file = path_handler.waveform_plot_file( \
                                                                                         graph_index=adp.metadata[ADPMetadata.Keys.LGRAPH_ID],
                                                                                         scale_index=adp.metadata[ADPMetadata.Keys.LSCALE_ID],
                                                                                         model=adp.metadata[ADPMetadata.Keys.LSCALE_SCALE_METHOD],
                                                                                         calib_obj=calib_obj, \
                                                                                         opt=adp.metadata[ADPMetadata.Keys.LSCALE_OBJECTIVE], \
                                                                                         phys_db=adp.metadata[ADPMetadata.Keys.RUNTIME_PHYS_DB],  \
                                                                                         no_scale=adp.metadata[ADPMetadata.Keys.LSCALE_NO_SCALE], \
                                                                                         one_mode=adp.metadata[ADPMetadata.Keys.LSCALE_ONE_MODE], \
                                                                                         variable=var, \
                                                                                         trial=trial, \
                                                                                         plot=vis.name, \
                                                                                         oscilloscope=has_scope)

                                            vis.plot(plot_file)

        if args.summary_plots:
            for (fields, var, has_scope), data in summary.items():
                adps = list(map(lambda d: d[0], data))
                waveforms = list(map(lambda d: d[1], data))
                board = get_device(adps[0].metadata.get(
                    ADPMetadata.Keys.RUNTIME_PHYS_DB))
                for vis in analyzelib.plot_waveform_summaries(
                        board, adps, waveforms):
                    adp = data[0][0]
                    calib_obj = llenums.CalibrateObjective(
                        adp.metadata[ADPMetadata.Keys.RUNTIME_CALIB_OBJ])
                    plot_file = path_handler.summary_plot_file( \
                                                                model=adp.metadata[ADPMetadata.Keys.LSCALE_SCALE_METHOD],
                                                                calib_obj=calib_obj, \
                                                                opt=adp.metadata[ADPMetadata.Keys.LSCALE_OBJECTIVE], \
                                                                phys_db=adp.metadata[ADPMetadata.Keys.RUNTIME_PHYS_DB], \
                                                                variable=var, \
                                                                plot=vis.name, \
                                                                oscilloscope=has_scope, \
                                                                no_scale=adp.metadata[ADPMetadata.Keys.LSCALE_NO_SCALE], \
                                                                one_mode=adp.metadata[ADPMetadata.Keys.LSCALE_ONE_MODE])
                    vis.plot(plot_file)
示例#13
0
def exec_stats(args, trials=1):
    import compiler.lwav_pass.waveform as wavelib
    import compiler.lwav_pass.analyze as analyzelib

    error_key = lambda adp : (
        adp.metadata[ADPMetadata.Keys.RUNTIME_CALIB_OBJ], \
        adp.metadata[ADPMetadata.Keys.LSCALE_SCALE_METHOD], \
        adp.metadata[ADPMetadata.Keys.LSCALE_OBJECTIVE], \
        adp.metadata[ADPMetadata.Keys.RUNTIME_PHYS_DB], \
        adp.metadata[ADPMetadata.Keys.LSCALE_NO_SCALE], \
        adp.metadata[ADPMetadata.Keys.LSCALE_ONE_MODE])

    error_summary = {}

    def update_error(adp, error):
        key = error_key(adp)
        if not key in error_summary:
            error_summary[key] = []

        error_summary[key].append(error)


    path_handler = paths.PathHandler(args.subset, \
                                     args.program)
    program = DSProgDB.get_prog(args.program)
    scope_options = [True, False]

    if args.runtimes_only:
        print("------------ runtime ----------------")
        print_runtime_stats(path_handler)
        return

    error = None
    best_adp = None
    best_adp_name = None


    for dirname, subdirlist, filelist in \
        os.walk(path_handler.lscale_adp_dir()):
        for adp_file in filelist:
            if adp_file.endswith('.adp'):
                with open(dirname + "/" + adp_file, 'r') as fh:
                    print("===== %s =====" % (adp_file))
                    adp_obj = json.loads(fh.read())
                    metadata = ADPMetadata.from_json(adp_obj['metadata'])
                    if not metadata.has(ADPMetadata.Keys.RUNTIME_PHYS_DB) or \
                       not metadata.has(ADPMetadata.Keys.RUNTIME_CALIB_OBJ):
                        continue

                    board = get_device(
                        metadata.get(ADPMetadata.Keys.RUNTIME_PHYS_DB))
                    adp = ADP.from_json(board, adp_obj)
                    calib_obj = llenums.CalibrateObjective(
                        adp.metadata[ADPMetadata.Keys.RUNTIME_CALIB_OBJ])
                    for trial in range(trials):
                        for var, _, _ in adp.observable_ports(board):
                            for has_scope in scope_options:
                                print("------- %s [has_scope=%s] ----" %
                                      (adp_file, has_scope))
                                waveform_file = path_handler.measured_waveform_file( \
                                                                                     graph_index=adp.metadata[ADPMetadata.Keys.LGRAPH_ID],
                                                                                     scale_index=adp.metadata[ADPMetadata.Keys.LSCALE_ID],
                                                                                     model=adp.metadata[ADPMetadata.Keys.LSCALE_SCALE_METHOD],
                                                                                     calib_obj=calib_obj, \
                                                                                     opt=adp.metadata[ADPMetadata.Keys.LSCALE_OBJECTIVE], \
                                                                                     phys_db=adp.metadata[ADPMetadata.Keys.RUNTIME_PHYS_DB] , \
                                                                                     no_scale=adp.metadata[ADPMetadata.Keys.LSCALE_NO_SCALE], \
                                                                                     one_mode=adp.metadata[ADPMetadata.Keys.LSCALE_ONE_MODE], \
                                                                                     variable=var, \
                                                                                     trial=trial, \
                                                                                     oscilloscope=has_scope)

                                if os.path.exists(waveform_file):
                                    with open(waveform_file, 'r') as fh:
                                        obj = util.decompress_json(fh.read())
                                        wave = wavelib.Waveform.from_json(obj)
                                        this_error = analyzelib.get_waveform_error(
                                            board, adp, wave)
                                        if this_error is None:
                                            continue

                                        update_error(adp, this_error)
                                        if error is None or this_error < error:
                                            error = this_error
                                            best_adp = adp
                                            best_adp_name = adp_file

    print("============ BEST EXECUTION SUMMARY ========")
    print(best_adp_name)
    print(
        "----------------------------------------------------------------------------"
    )
    analyzelib.print_summary(board, best_adp, error)
    print("------------ runtime ----------------")
    print_runtime_stats(path_handler)

    print("============ AVERAGE EXECUTION SUMMARY ========")
    for key, errors in error_summary.items():
        median = np.median(errors)
        q1 = np.percentile(errors, 25)
        med = np.percentile(errors, 50)
        q3 = np.percentile(errors, 75)
        min_err = min(errors)
        max_err = max(errors)

        print("%s min=%f q1=%f med=%f q3=%f max=%f n=%d" %
              (key, min_err, q1, med, q3, max_err, len(errors)))
示例#14
0
def exec_lscale(args):
    from compiler import lscale
    import compiler.lscale_pass.lscale_ops as scalelib

    board = get_device(args.model_number)
    path_handler = paths.PathHandler(args.subset, args.program)
    program = DSProgDB.get_prog(args.program)
    timer = util.Timer('lscale', path_handler)
    for dirname, subdirlist, filelist in \
        os.walk(path_handler.lgraph_adp_dir()):
        for lgraph_adp_file in filelist:
            if lgraph_adp_file.endswith('.adp'):
                with open(dirname + "/" + lgraph_adp_file, 'r') as fh:
                    print("===== %s =====" % (lgraph_adp_file))
                    adp = ADP.from_json(board, \
                                        json.loads(fh.read()))

                obj = scalelib.ObjectiveFun(args.objective)
                scale_method = scalelib.ScaleMethod(args.scale_method)
                calib_obj = get_calibrate_objective(args.calib_obj)

                if args.no_scale and not scale_method is scalelib.ScaleMethod.IDEAL:
                    raise Exception(
                        "cannot disable scaling transform if you're using the delta model database"
                    )

                timer.start()
                for idx,scale_adp in enumerate(lscale.scale(board, \
                                                            program, \
                                                            adp, \
                                                            objective=obj, \
                                                            scale_method=scale_method, \
                                                            calib_obj=calib_obj, \
                                                            no_scale=args.no_scale, \
                                                            one_mode=args.one_mode)):
                    timer.end()

                    print("<<< writing scaled circuit %d/%d>>>" %
                          (idx, args.scale_adps))
                    scale_adp.metadata.set(ADPMetadata.Keys.LSCALE_ID, idx)

                    calib_obj = llenums.CalibrateObjective(scale_adp \
                                                       .metadata[ADPMetadata.Keys.RUNTIME_CALIB_OBJ])
                    filename = path_handler.lscale_adp_file(
                        scale_adp.metadata[ADPMetadata.Keys.LGRAPH_ID],
                        scale_adp.metadata[ADPMetadata.Keys.LSCALE_ID],
                        scale_adp.metadata[ADPMetadata.Keys.LSCALE_SCALE_METHOD],
                        scale_adp.metadata[ADPMetadata.Keys.LSCALE_OBJECTIVE],
                        calib_obj,
                        scale_adp.metadata[ADPMetadata.Keys.RUNTIME_PHYS_DB], \
                        no_scale=scale_adp.metadata[ADPMetadata.Keys.LSCALE_NO_SCALE], \
                        one_mode=scale_adp.metadata[ADPMetadata.Keys.LSCALE_ONE_MODE] \
                    )

                    with open(filename, 'w') as fh:
                        jsondata = scale_adp.to_json()
                        fh.write(json.dumps(jsondata, indent=4))

                    print("<<< writing graph >>>")
                    filename = path_handler.lscale_adp_diagram_file(
                        scale_adp.metadata[ADPMetadata.Keys.LGRAPH_ID],
                        scale_adp.metadata[ADPMetadata.Keys.LSCALE_ID],
                        scale_adp.metadata[ADPMetadata.Keys.LSCALE_SCALE_METHOD],
                        scale_adp.metadata[ADPMetadata.Keys.LSCALE_OBJECTIVE],
                        calib_obj,
                        scale_adp.metadata[ADPMetadata.Keys.RUNTIME_PHYS_DB], \
                        no_scale=scale_adp.metadata[ADPMetadata.Keys.LSCALE_NO_SCALE], \
                        one_mode=scale_adp.metadata[ADPMetadata.Keys.LSCALE_ONE_MODE] \
                    )

                    adprender.render(board, scale_adp, filename)
                    if idx >= args.scale_adps:
                        break
                    timer.start()

    print("<<< done >>>")
    timer.kill()
    print(timer)
    timer.save()