This contains my bachelors thesis and associated tex files, code snippets and maybe more. Topic: Data Movement in Heterogeneous Memories with Intel Data Streaming Accelerator
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  1. import os
  2. import pandas as pd
  3. import seaborn as sns
  4. import matplotlib.pyplot as plt
  5. from common import calc_throughput, load_time_mesurements, get_task_count
  6. result_path = "benchmark-results/"
  7. output_path = "benchmark-plots/"
  8. runid = "Run ID"
  9. x_label = "Destination Node"
  10. y_label = "Throughput in GiB/s"
  11. title_allnodes = \
  12. """Copy Throughput in GiB/s tested for 1GiB Elements\n
  13. Using all 8 DSA Chiplets available on the System"""
  14. title_smartnodes = \
  15. """Copy Throughput in GiB/s tested for 1GiB Elements\n
  16. Using Cross-Copy for Intersocket and all 4 Chiplets of Socket for Intrasocket"""
  17. title_difference = \
  18. """Gain in Copy Throughput in GiB/s of All-DSA vs. Smart Assignment"""
  19. description_smartnodes = \
  20. """Copy Throughput in GiB/s tested for 1GiB Elements\n
  21. Nodes of {8...15} are HBM accessors for their counterparts (minus 8)\n
  22. Using all 4 DSA Chiplets of a Socket for Intra-Socket Operation\n
  23. And using only the Source and Destination Nodes DSA for Inter-Socket"""
  24. description_allnodes = \
  25. """Copy Throughput in GiB/s tested for 1GiB Elements\n
  26. Nodes of {8...15} are HBM accessors for their counterparts (minus 8)\n
  27. Using all 8 DSA Chiplets available on the System"""
  28. index = [ runid, x_label, y_label]
  29. data = []
  30. # loads the measurements from a given file and processes them
  31. # so that they are normalized, meaning that the timings returned
  32. # are nanoseconds per element transfered
  33. def get_timing(file_path):
  34. divisor = get_task_count(file_path)
  35. return [ x / divisor for x in load_time_mesurements(file_path)]
  36. # procceses a single file and appends the desired timings
  37. # to the global data-array, handles multiple runs with a runid
  38. # and ignores if the given file is not found as some
  39. # configurations may not be benchmarked
  40. def process_file_to_dataset(file_path, src_node, dst_node):
  41. size = 1024*1024*1024
  42. timing = get_timing(file_path)
  43. run_idx = 0
  44. for t in timing:
  45. tp = calc_throughput(size, t)
  46. data.append({ runid : run_idx, x_label : dst_node, y_label : tp})
  47. run_idx = run_idx + 1
  48. def plot_bar(table,title,node_config):
  49. plt.figure(figsize=(2, 3))
  50. sns.barplot(x=x_label, y=y_label, data=table, palette="mako", errorbar="sd")
  51. plt.ylim(0, 75)
  52. plt.savefig(os.path.join(output_path, f"plot-{node_config}-throughput.pdf"), bbox_inches='tight')
  53. plt.show()
  54. # loops over all possible configuration combinations and calls
  55. # process_file_to_dataset for them in order to build a dataframe
  56. # which is then displayed and saved
  57. def main(node_config,title):
  58. src_node = 0
  59. for dst_node in {8,11,12,15}:
  60. file = os.path.join(result_path, f"copy-n{src_node}ton{dst_node}-1gib-{node_config}.json")
  61. process_file_to_dataset(file, src_node, dst_node)
  62. df = pd.DataFrame(data)
  63. data.clear()
  64. df.set_index(index, inplace=True)
  65. plot_bar(df, title, node_config)
  66. return df
  67. if __name__ == "__main__":
  68. dall = main("allnodes", title_allnodes)
  69. dsmart = main("smart", title_smartnodes)