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# Copyright (c) 2023 Cisco and/or its affiliates.
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at:
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""The comparison tables.
"""
import pandas as pd
from numpy import mean, std
from copy import deepcopy
from ..utils.constants import Constants as C
from ..utils.utils import relative_change_stdev
def select_comparison_data(
data: pd.DataFrame,
selected: dict,
normalize: bool=False
) -> pd.DataFrame:
"""Select data for a comparison table.
:param data: Data to be filtered for the comparison table.
:param selected: A dictionary with parameters and their values selected by
the user.
:param normalize: If True, the data is normalized to CPU frequency
Constants.NORM_FREQUENCY.
:type data: pandas.DataFrame
:type selected: dict
:type normalize: bool
:returns: A data frame with selected data.
:rtype: pandas.DataFrame
"""
def _calculate_statistics(
data_in: pd.DataFrame,
ttype: str,
drv: str,
norm_factor: float
) -> pd.DataFrame:
"""Calculates mean value and standard deviation for provided data.
:param data_in: Input data for calculations.
:param ttype: The test type.
:param drv: The driver.
:param norm_factor: The data normalization factor.
:type data_in: pandas.DataFrame
:type ttype: str
:type drv: str
:type norm_factor: float
:returns: A pandas dataframe with: test name, mean value, standard
deviation and unit.
:rtype: pandas.DataFrame
"""
d_data = {
"name": list(),
"mean": list(),
"stdev": list(),
"unit": list()
}
for itm in data_in["test_id"].unique().tolist():
itm_lst = itm.split(".")
test = itm_lst[-1].rsplit("-", 1)[0]
df = data_in.loc[(data_in["test_id"] == itm)]
l_df = df[C.VALUE_ITER[ttype]].to_list()
if len(l_df) and isinstance(l_df[0], list):
tmp_df = list()
for l_itm in l_df:
tmp_df.extend(l_itm)
l_df = tmp_df
try:
mean_val = mean(l_df)
std_val = std(l_df)
except (TypeError, ValueError):
continue
d_data["name"].append(f"{test.replace(f'{drv}-', '')}-{ttype}")
d_data["mean"].append(int(mean_val * norm_factor))
d_data["stdev"].append(int(std_val * norm_factor))
d_data["unit"].append(df[C.UNIT[ttype]].to_list()[0])
return pd.DataFrame(d_data)
lst_df = list()
for itm in selected:
if itm["ttype"] in ("NDR", "PDR", "Latency"):
test_type = "ndrpdr"
elif itm["ttype"] in ("CPS", "RPS", "BPS"):
test_type = "hoststack"
else:
test_type = itm["ttype"].lower()
dutver = itm["dutver"].split("-", 1) # 0 -> release, 1 -> dut version
tmp_df = pd.DataFrame(data.loc[(
(data["passed"] == True) &
(data["dut_type"] == itm["dut"]) &
(data["dut_version"] == dutver[1]) &
(data["test_type"] == test_type) &
(data["release"] == dutver[0])
)])
drv = "" if itm["driver"] == "dpdk" else itm["driver"].replace("_", "-")
core = str() if itm["dut"] == "trex" else itm["core"].lower()
reg_id = \
f"^.*[.|-]{itm['nic']}.*{itm['frmsize'].lower()}-{core}-{drv}.*$"
tmp_df = tmp_df[
(tmp_df.job.str.endswith(itm["tbed"])) &
(tmp_df.test_id.str.contains(reg_id, regex=True))
]
if itm["driver"] == "dpdk":
for drv in C.DRIVERS:
tmp_df.drop(
tmp_df[tmp_df.test_id.str.contains(f"-{drv}-")].index,
inplace=True
)
# Change the data type from ndrpdr to one of ("NDR", "PDR", "Latency")
if test_type == "ndrpdr":
tmp_df = tmp_df.assign(test_type=itm["ttype"].lower())
if not tmp_df.empty:
if normalize:
if itm["ttype"] == "Latency":
norm_factor = C.FREQUENCY[itm["tbed"]] / C.NORM_FREQUENCY
else:
norm_factor = C.NORM_FREQUENCY / C.FREQUENCY[itm["tbed"]]
else:
norm_factor = 1.0
tmp_df = _calculate_statistics(
tmp_df,
itm["ttype"].lower(),
itm["driver"],
norm_factor
)
lst_df.append(tmp_df)
if len(lst_df) == 1:
df = lst_df[0]
elif len(lst_df) > 1:
df = pd.concat(
lst_df,
ignore_index=True,
copy=False
)
else:
df = pd.DataFrame()
return df
def comparison_table(
data: pd.DataFrame,
selected: dict,
normalize: bool,
format: str="html"
) -> tuple:
"""Generate a comparison table.
:param data: Iterative data for the comparison table.
:param selected: A dictionary with parameters and their values selected by
the user.
:param normalize: If True, the data is normalized to CPU frequency
Constants.NORM_FREQUENCY.
:param format: The output format of the table:
- html: To be displayed on html page, the values are shown in millions
of the unit.
- csv: To be downloaded as a CSV file the values are stored in base
units.
:type data: pandas.DataFrame
:type selected: dict
:type normalize: bool
:type format: str
:returns: A tuple with the tabe title and the comparison table.
:rtype: tuple[str, pandas.DataFrame]
"""
def _create_selection(sel: dict) -> list:
"""Transform the complex dictionary with user selection to list
of simple items.
:param sel: A complex dictionary with user selection.
:type sel: dict
:returns: A list of simple items.
:rtype: list
"""
l_infra = sel["infra"].split("-")
selection = list()
for core in sel["core"]:
for fsize in sel["frmsize"]:
for ttype in sel["ttype"]:
selection.append({
"dut": sel["dut"],
"dutver": sel["dutver"],
"tbed": f"{l_infra[0]}-{l_infra[1]}",
"nic": l_infra[2],
"driver": l_infra[-1].replace("_", "-"),
"core": core,
"frmsize": fsize,
"ttype": ttype
})
return selection
r_sel = deepcopy(selected["reference"]["selection"])
c_params = selected["compare"]
r_selection = _create_selection(r_sel)
if format == "html" and "Latency" not in r_sel["ttype"]:
unit_factor, s_unit_factor = (1e6, "M")
else:
unit_factor, s_unit_factor = (1, str())
# Create Table title and titles of columns with data
params = list(r_sel)
params.remove(c_params["parameter"])
lst_title = list()
for param in params:
value = r_sel[param]
if isinstance(value, list):
lst_title.append("|".join(value))
else:
lst_title.append(value)
title = "Comparison for: " + "-".join(lst_title)
r_name = r_sel[c_params["parameter"]]
if isinstance(r_name, list):
r_name = "|".join(r_name)
c_name = c_params["value"]
# Select reference data
r_data = select_comparison_data(data, r_selection, normalize)
# Select compare data
c_sel = deepcopy(selected["reference"]["selection"])
if c_params["parameter"] in ("core", "frmsize", "ttype"):
c_sel[c_params["parameter"]] = [c_params["value"], ]
else:
c_sel[c_params["parameter"]] = c_params["value"]
c_selection = _create_selection(c_sel)
c_data = select_comparison_data(data, c_selection, normalize)
if r_data.empty or c_data.empty:
return str(), pd.DataFrame()
l_name, l_r_mean, l_r_std, l_c_mean, l_c_std, l_rc_mean, l_rc_std, unit = \
list(), list(), list(), list(), list(), list(), list(), set()
for _, row in r_data.iterrows():
if c_params["parameter"] in ("core", "frmsize", "ttype"):
l_cmp = row["name"].split("-")
if c_params["parameter"] == "core":
c_row = c_data[
(c_data.name.str.contains(l_cmp[0])) &
(c_data.name.str.contains("-".join(l_cmp[2:])))
]
elif c_params["parameter"] == "frmsize":
c_row = c_data[c_data.name.str.contains("-".join(l_cmp[1:]))]
elif c_params["parameter"] == "ttype":
regex = r"^" + f"{'-'.join(l_cmp[:-1])}" + r"-.{3}$"
c_row = c_data[c_data.name.str.contains(regex, regex=True)]
else:
c_row = c_data[c_data["name"] == row["name"]]
if not c_row.empty:
unit.add(f"{s_unit_factor}{row['unit']}")
r_mean = row["mean"]
r_std = row["stdev"]
c_mean = c_row["mean"].values[0]
c_std = c_row["stdev"].values[0]
l_name.append(row["name"])
l_r_mean.append(r_mean / unit_factor)
l_r_std.append(r_std / unit_factor)
l_c_mean.append(c_mean / unit_factor)
l_c_std.append(c_std / unit_factor)
delta, d_stdev = relative_change_stdev(r_mean, c_mean, r_std, c_std)
l_rc_mean.append(delta)
l_rc_std.append(d_stdev)
s_unit = "|".join(unit)
df_cmp = pd.DataFrame.from_dict({
"Test Name": l_name,
f"{r_name} Mean [{s_unit}]": l_r_mean,
f"{r_name} Stdev [{s_unit}]": l_r_std,
f"{c_name} Mean [{s_unit}]": l_c_mean,
f"{c_name} Stdev [{s_unit}]": l_c_std,
"Relative Change Mean [%]": l_rc_mean,
"Relative Change Stdev [%]": l_rc_std
})
df_cmp.sort_values(
by="Relative Change Mean [%]",
ascending=False,
inplace=True
)
return (title, df_cmp)
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