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import os import csv import numpy as np import seaborn as sns import matplotlib.pyplot as plt
output_path = "./plots" prefetch_result = "./evaluation-results/qdp-xeonmax-simple-prefetch-tca4-tcb1-tcj2-tmul8-wl4294967296-cs8388608.csv" dram_result = "./evaluation-results/qdp-xeonmax-simple-dram-tca2-tcb0-tcj1-tmul16-wl4294967296-cs2097152.csv"
tt_name = "rt-ns" function_names = [ "scana-run", "scana-load", "scanb-run", "aggrj-run", "aggrj-load" ] fn_nice = [ "Scan A, Filter", "Scan A, Load", "Scan B", "Aggregate, Project + Sum", "Aggregate, Load" ]
def read_timings_from_csv(fname) -> tuple[list[float], list[str]]: t = {} total_time = 0
# Read data from CSV file with open(fname, newline='') as csvfile: reader = csv.DictReader(csvfile, delimiter=';') for row in reader: total_time += int(row[tt_name]) for i in range(len(function_names)): t[fn_nice[i]] = t.get(fn_nice[i], 0) + int(row[function_names[i]])
t = {key: value * 100 / total_time for key, value in t.items() if value != 0}
total = sum(list(t.values())) if total < 100.0: t["Waiting / Other"] = 100.0 - total
return list(t.values()), list(t.keys())
def get_data_prefetch_cache_access() -> tuple[list[float], list[str]]: total = 1.14 data = [ 0.05, 0.02, 0.17, 0.40, 0.36, 0.13 ] data = [ x * 100 / total for x in data ] keys = ["Cache::GetCacheNode", "Cache::GetFromCache", "dml::handler::constructor", "Cache::AllocOnNode", "dml::make_task", "dml::submit"]
return data,keys
def get_data_prefetch_total() -> tuple[list[float], list[str]]: return read_timings_from_csv(prefetch_result)
def get_data_dram_total() -> tuple[list[float], list[str]]: return read_timings_from_csv(dram_result)
# loops over all possible configuration combinations and calls # process_file_to_dataset for them in order to build a dataframe # which is then displayed and saved def main(data: tuple[list[float], list[str]], fname): palette_color = sns.color_palette('mako') fig, ax = plt.subplots(figsize=(6, 3), subplot_kw=dict(aspect="equal"))
wedges, texts = ax.pie(data[0], wedgeprops=dict(width=0.5), startangle=-40, colors=palette_color)
bbox_props = dict(boxstyle="square,pad=0.3", fc="w", ec="k", lw=0.72) kw = dict(arrowprops=dict(arrowstyle="-"), bbox=bbox_props, zorder=0, va="center")
for i, p in enumerate(wedges): ang = (p.theta2 - p.theta1)/2. + p.theta1 y = np.sin(np.deg2rad(ang)) x = np.cos(np.deg2rad(ang)) horizontalalignment = {-1: "right", 1: "left"}[int(np.sign(x))] connectionstyle = f"angle,angleA=0,angleB={ang}" kw["arrowprops"].update({"connectionstyle": connectionstyle}) ax.annotate(f"{data[1][i]} - {data[0][i]:2.1f}%", xy=(x, y), xytext=(1.35*np.sign(x), 1.4*y), horizontalalignment=horizontalalignment, **kw) fig.savefig(os.path.join(output_path, fname), bbox_inches='tight')
if __name__ == "__main__": main(get_data_prefetch_cache_access(), "plot-timing-prefetch-cacheaccess.pdf") main(get_data_prefetch_total(), "plot-timing-prefetch-totalexec.pdf") main(get_data_dram_total(), "plot-timing-dram-totalexec.pdf")
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