tq42 sdk
Project description
Introduction to TQ42
The TQ42 Python SDK puts the power in your hands to accelerate delivery of custom, high-impact solutions. After installing the SDK and authenticating, access algorithms such as TetraOpt – a global optimization library based on tensor train (TT) decomposition.
With TQ42, there is no need to build or manage your own quantum circuits. Let our algorithms do the work. From the CLI or a Jupyter notebook:
- Specify your objective function, hyper parameters, and compute infrastructure
- Run and manage experiments
- Visualize results
Collaborate with your teams across organizations and projects, and visit tq42.com for web-based tools to help you manage your account, projects, and experiments.
TQ42 Features
Getting Started
System Requirements
Be sure your system can support TQ42, which requires the following:
- Any modern operating system, in particular, Mac OSX 12.0 (Ventura) or above, Windows 10+, Linux will do
- Python 3.8 or above
- x86 64-bit CPU (Intel / AMD architecture); ARM CPUs are not supported
- 4 GB RAM
- 5 GB free disk space
The following Python packages are hard dependencies, and will automatically be installed alongside TQ42:
Quick Start
List of commands to execute to have a conda environment ready to work with the sdk. After having installed conda:
conda create -n "my_env_name" python=3.9 # create the conda enviroment, it needs to be python 3.8 or higher
conda activate my_env_name # activate your conda enviroment
pip install -U tq42 # install the sdk using the newest available version
pip install jupyter # install jupyter if you work with notebook
pip install jupyter matplotlib # install matplotlib for visualization purpose
tq42 auth login # authenticate the user
tq42 -h # for visualizing the help
git clone git@github.com:terra-quantum-public/tq42sdk.git # cloning the repo in case you want to use the example's notebook
Installation
Prior to installing TQ42, create a virtual environment or conda environment.
TQ42 is published on pypi, so on x86_64, i686, ppc64le, s390x, and aarch64 Linux systems, x86_64 on Mac OSX, and 32 and 64 bit Windows installing is as simple as running the pip install tq42
command:
pip install tq42
NOTE: We will refer to pip
rather than pip3
. Depending on how your system is configured you may have to use pip3
rather than pip
if the alias is not set.
Authentication
After installing TQ42, authenticate by typing the tq42 auth login
CLI command:
tq42 auth login
Or use the Python command:
from tq42.client import TQ42Client
with TQ42Client() as client:
client.login()
This API call will open a window in your browser where you must confirm the MFA code, then enter your TQ42 username and password to authenticate.
The authentication validity will keep extending as long as you are using it within a 30 day period.
Create an exemplary experiment run
After a successful login the next step is to create an experiment run. A created experiment is necessary for this to work. This can be done via the Web UI.
To supply the experiment run the id of the created experiment is necessary. This can be either retrieved by the UI or, alternatively, can be queried via the TQ42 Python SDK like this:
from tq42.client import TQ42Client
from tq42.organization import list_all as list_all_organizations
from tq42.project import list_all as list_all_projects
from tq42.experiment import list_all as list_all_experiments
with TQ42Client() as client:
client.login()
org_list = list_all_organizations(client=client)
# gets the first organization we can find
org = org_list[0]
proj_list = list_all_projects(client=client, organization_id=org.id)
# gets the first project we can find
proj = proj_list[0]
exp_list = list_all_experiments(client=client, project_id=proj.id)
# gets the id for the first experiment we can find
exp_id = exp_list[0].id
After retrieving the experiment id the next step is to create the metadata for the algorithm to run.
For this example the toy algorithm and its corresponding metadata is chosen but any other algorithm can be used according to the general setup available here.
Importing the protobuf definitions of the metadata helps with typings and makes the development experience easier.
The TQ42 Python SDK however expects you to pass in the metadata as a dictionary and so using the MessageToDict
function
is helpful to create the perfect matching dictionary while getting type hints.
Note: You can find all types corresponding to the algorithms within tq42.algorithm
.
from google.protobuf.json_format import MessageToDict
from tq42.algorithm import (
ToyMetadataProto,
ToyParametersProto,
ToyInputsProto
)
toy_params = ToyMetadataProto(
parameters=ToyParametersProto(n=1, r=1.5, msg='This is my first experiment run'),
inputs=ToyInputsProto()
)
toy_params = MessageToDict(toy_params, preserving_proto_field_name=True)
After creating the available metadata and retrieving an experiment id the last step is to actually create the experiment run.
from tq42.client import TQ42Client
from tq42.experiment_run import ExperimentRun
from tq42.algorithm import AlgorithmProto
from tq42.compute import HardwareProto
with TQ42Client() as client:
run = ExperimentRun.create(
client=client,
# you can configure the algorithm to run here via the supplied enum
# be sure to choose matching algorithm and parameters as this will be validated by our backend
algorithm=AlgorithmProto.TOY,
# pass in your experiment id here
experiment_id=exp_id,
# you can configure the hardware choice here via the supplied enum
compute=HardwareProto.SMALL,
# choose your dictionary here
parameters=toy_params
)
The experiment run can now be found via the UI and checked for its status.
Alternatively, you can also use either the SDK or CLI to check on the experiment run. For more details om these two please take a look into the corresponding section of the documentation.
For more details on specific algorithms please take a look at the individual sections.
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