qprof stands for quantum profiler and aims at providing a
unique tool to profile quantum circuits.
For the moment, qprof is able to understand quantum circuits generated
with qiskit and myQLM
and can generate profiling results in
JSON and a
gprof compatible format.
qprof being a Python module, it is installable with pip.
git clone https://gitlab.com/qcomputing/qprof/qprof.git
pip install qprof/qprof is now available on PyPi! To download and install the last
version, just type
pip install qprofPlugins for library support are not installed by default in order to
avoid pulling silently huge dependencies like qiskit in your project.
In order to install the plugins you can either do it afterwards with
pip:
pip install qprof_qiskit # other libraries are supported tooor use the appropriate target when installing qprof:
pip install qprof[qiskit]
pip install qprof[myqlm]
pip install qprof[all_plugins]Developers might want to install qprof as an editable project. To do
so you need to clone the git repository and install the library in
editable mode with the -e option:
git clone https://gitlab.com/qcomputing/qprof/qprof.git
pip install -e qprof/Note that the dependencies will not be installed in editable mode.
If you want all the qprof stack in editable mode, you need to clone
and install everything "by hand":
git clone https://gitlab.com/qcomputing/qprof/qprof.git
# Plugins?
# git clone https://gitlab.com/qcomputing/qprof/qprof_qiskit.git
# git clone https://gitlab.com/qcomputing/qprof/qprof_myqlm.git
pip install -e qprof/
# Plugins?
# pip install -e qprof_qiskit/
# pip install -e qprof_myqlm/The qprof library is organised as follows:
- A main
qproflibrary containing all the code related to computing routine execution time, call graph, exporting, ... - A
qprof.plugins.frameworks.interfacesplugin providing interfaces for the data structures used byqprofto communicate with the other plugins. Thisinterfacesplugins is included in the mainqprofpackage. - Several
qprof_XXXlibraries that are used to adapt a libraryXXXtoqprofby implementing the interfaces ofqprof.plugins.frameworks.interfacesinqprof.plugins.frameworks.XXX.
Plugins are automatically discovered the first time qprof
is imported and are arranged in a dictionary-like data-structure with
the following structure:
frameworks = {
"interfaces": <module 'qprof.plugins.frameworks.interfaces' from '[path]'>, # always present
"plugin1": <module 'qprof.plugins.frameworks.plugin1' from '[path]'>,
# ...
"pluginN": <module 'qprof.plugins.frameworks.pluginN' from '[path]'>,
}Plugins are lazy-imported, meaning that the plugin module is imported at the first access to the dictionary key.
The profiling is performed with the qprof.profile function.
The qprof.profile function needs a quantum routine implemented with
one of the supported frameworks along with the "base" gate times,
provided as a dictionary, and an exporter, given either as a string or
as an instance of BaseExporter.
Example of profiling:
# Import the qprof tools
from qprof import profile
# Import the framework tools to generate a quantum routine
from qiskit.aqua.algorithms import Grover
from qiskit.aqua.components.oracles import LogicalExpressionOracle
# Generate the routine to benchmark.
input_3sat = """
c example DIMACS-CNF 3-SAT
p cnf 3 5
-1 -2 -3 0
1 -2 3 0
1 2 -3 0
1 -2 -3 0
-1 2 3 0
"""
oracle = LogicalExpressionOracle(input_3sat)
grover = Grover(oracle)
circuit = grover.construct_circuit()
# Hard-coded gate times retrieved by hand
gate_times = {"U1": 0, "U2": 89, "U3": 178, "CX": 930, "BARRIER": 0}
# Profile the resulting quantum routine and use the "gprof" exporter
qprof_out = profile(circuit, gate_times, "gprof")
# Print to stdout the analysis report
print(qprof_out)You should have the dot tool installed on your machine, along with the
gprof2dot tool that can be
installed with pip install gprof2dot.
Let save the code of the previous section in a file
profile.py.
You can generate the following graph with the command
python3 profile.py | gprof2dot -n 0 -e 0 | dot -Tpng -o profiling_result.png-
qprofis not able to analyse recursive routine calls yet. If your quantum circuit contains calls to recursive routines, expect the unexpected. -
The call-graph analysis is done as if all the quantum gates were executed sequentially. Parallel execution support is a work in progress in the parallel_support branch. The main issue that still needs to be solved is the output format.
If Unknown routines are showing up in the reports, check that you
named correctly all the routines you defined.
If the problem is still present, open an issue.
The gprof output format has a very limited precision of 10
milli-seconds when dealing with timings. This means that routines
running in less than 5 milli-seconds will, due to rounding error, appear
as taking 0 milli-seconds.
In order to circumvent this issue, the qprof.exporters.GprofExporter
takes an optional parameter default_time in its constructor. This
default_time will be used to scale all the execution times such that
the longest routine will take exactly default_time seconds on the
report.
By default, the value of default_time is 10 seconds. In order to
change it you need to instantiate the exporter yourself:
from qprof import profile
from qprof.exporters import GprofExporter
routine = # ...
gate_times = # ...
exporter = GprofExporter(default_time=100) # 100 seconds for default_time
result = profile(routine, gate_times, exporter)
Note that giving None to default_time will disable the execution
time scaling.
Here is a list of projects using qprof.
If you used qprof in your project and would like to appear in this
list, please let me know (open an issue, send me a mail, anything you
want).
