Welcome to pylero’s documentation!

Welcome to Pylero, the Python wrapper for the Polarion WSDL API. The Pylero wrapper enables native python access to Polarion objects and functionality using object oriented structure and functionality. This allows the developers to use Pylero in a natural fashion without being concerned about the Polarion details.

All Pylero objects inherit from BasePolarion. The objects used in the library are all generated from the SOAP factory class, using the python-suds library. The Pylero class attributes are generated dynamically as properties, based on a mapping dict between the pylero naming convention and the Polarion attribute names.

The use of properties allows the pylero object attributes to be virtual with no need for syncing between them and the Polarion objects they are based on.

The Polarion WSDL API does not implement validation/verification of data passed in, so the Pylero library takes care of this itself. All enums are validated before being sent to the server and raise an error if not using a valid value. A number of workflow implementations are also included, for example when creating a Document, it automatically creates the Heading work item at the same time.

Polarion Work Items are configured per installation, to give native workitem objects (such as TestCase), the library connects to the Polarion server, downloads the list of workitems and creates them.

Installation

Install from Pypi

Pylero package have been published to Pypi:

https://pypi.org/project/pylero/

Install Pylero Pypi package with:

$ pip install pylero

By default the latest package and dependencies will be installed.

Install from repo

Pylero is located in a git repository and can be cloned from:

$ git clone https://github.com/RedHatQE/pylero.git

From the root of the project, run:

$ pip install .

Install on Fedora & EPEL

If you are on Fedora or RHEL:

$ yum install python3-pylero

You could also use rpmbuild to build RPM with python-pylero.spec.

Pylero must be configured (see next section) before it can be used.

Configuration

A configuration file must be filled out, which must be located either in the current dir (the dir where the script is executed from) .pylero, in the user’s home dir ~/.pylero Default settings are stored in LIBDIR/etc/pylero.cfg. This file should not be modified, as it will be overwritten with any future updates. Certificates should be verified automatically, but if they aren’t, you can add the path to your CA to the cert_path config option. These are the configurable values:

[webservice]
url=https://{your polarion web URL}/polarion
svn_repo=https://{your polarion web URL}/repo
user={your username}
password={your password}
token={your personal access token}
default_project={your default project}
#cert_path=/dir/to/my/cert/ca

If the token is given it will be used for login by default, else if both user and password are given the password will be used for login, else if user is provided and password value is blank, it will prompt you for a password, else if none of them are provided it will prompt you for the token to login and access any of the pylero objects.

These can also be overridden with the following environment variables:

POLARION_URL
POLARION_REPO
POLARION_USERNAME
POLARION_PASSWORD
POLARION_TOKEN
POLARION_TIMEOUT
POLARION_PROJECT
POLARION_CERT_PATH

Requirements

The install_requires attribute in setup.py installs the following requirements

suds
requests>=2.6.0
click
readline; python_version <= '3.6'

There is a requirements.txt file in the root directory. All requirements can be installed by: pip install -r requirements.txt

Usage

There is a pylero script installed that opens a python shell with all the objects in the library already loaded:

$ pylero
>>> tr = TestRun("example", project_id="project_name")

Alternatively, you can open a python shell and import the objects that you want to use:

$ python
Python 2.6.6 (r266:84292, Nov 21 2013, 10:50:32)
[GCC 4.4.7 20120313 (Red Hat 4.4.7-4)] on linux2
Type "help", "copyright", "credits" or "license" for more information.
>>> from pylero.test_run import TestRun
>>> tr = TestRun("example", project_id="project_name")

Examples

There’s a possibility that Workitems mentioned in this example may not exactly match the types that your Polarion server was configured with.

In those cases, importing TestCase, Requirement etc will fail, to overcome that, you either need to reach out to your Polarion admin for knowing the workitem types that are configured or can find those from below code.



>>> from pylero.work_item import *
>>> globals()['workitems'].values()
dict_values(['TestCase', 'TestSuite', 'BusinessCase', 'Requirement', 'ChangeRequest', 'IncidentReport', 'Defect', 'Task', 'Risk'])

Note: This is only required once when you start using Pylero as the work item type don’t usually change. The dict_values from above listing are importable, ex: from pylero.work_item TesCase works for me and it may differ for you based on above returned values.

import datetime
from pylero.test_run import TestRun
from pylero.test_record import TestRecord
from pylero.work_item import TestCase, Requirement
from pylero.document import Document

# Creating a Test Run Template:
tr = TestRun.create_template("myproj",
                            "Static Query Test",
                            parent_template_id="Empty",
                            select_test_cases_by="staticQueryResult",
                            query="type:testcase AND status:approved")

# Creating a Test Run:
tr = TestRun.create("myproj", "My Test Run", "Static Query Test")

# changing status
tr.status = "inprogress"

# getting and changing a custom attribute in TestRun
arch = tr.get_custom_field("arch")
arch = "i386"
tr.set_custom_field("arch", arch)

# saving the data to the server
tr.update()

# Adding a test record
tr.add_test_record_by_fields(test_case_id="MYPROJ-1813",
                            test_result="passed",
                            test_comment="went smoothly",
                            executed_by="user1",
                            executed=datetime.datetime.now(),
                            duration=10.50,
                            defect_work_item_id="MYPROJ-1824")

# Getting specific WorkItems
tc = TestCase(project_id="myproj", work_item_id="MYPROJ-2015")
req = Requirement(project_id="myproj", work_item_id="MYPROJ-2019")

# Getting required custom fields for specific Work Items
reqs = TestCase.custom_fields("myproj")[1]
# returns [u'caseimportance', u'caselevel', u'caseautomation', u'caseposneg']

reqs = Requirement.custom_fields("myproj")[1]
# returns [u'reqtype']

# Getting the valid values for the custom enumerations
tc.get_valid_field_values("caseimportance")
# returns [critical, high, medium, low]

# Creating a specific Work Item
tc = TestCase.create("myproj",
                    "Title",
                    "Description",
                    caseimportance="high",
                    caselevel="component",
                    caseautomation="notautomated",
                    caseposneg="positive")

# Note if the custom required fields are not specified, an exception will be raised
# Custom field for work items are accessed like regular attributes
tc.caseimportance = "critical"

# to save changes
tc.update()

# Creating a document
doc = Document.create("myproj", "Testing", "API doc", "The API Document",
                      ["testcase"], document_type="testspecification")
# Adding a Functional Test Case work item to the document
wi = TestCase()
wi.tcmscaseid = "12345"
wi.title = "[GUI] Host Network QoS-'named'"
wi.author = "user1"
wi.tcmscategory = "Functional"
wi.caseimportance = "critical"
wi.status = "proposed"
wi.setup = "DC/Cluster/Host"
wi.teardown = """
Proceed with the VM Network QoS paradigm, that is creating Network QoS
entities that can be shared between different networks - let's refer to this
as ""named"" QoS. This QoS entities are created via DC> QoS > Host Network"
"""
steps = TestSteps()
steps.keys = ["step", "expectedResult"]
step1 = TestStep()
step1.values = ["This is step 1", "Step 1 expected result"]
step2 = TestStep()
step2.values = ["This is step 2", "Step 2 expected result"]
arr_step = [step1, step2]
steps.steps = arr_step
wi.test_steps = steps
wi.caseautomation = "notautomated"
wi.caseposneg = "positive"
wi.caselevel = "component"
new_wi = doc.create_work_item(None, wi)

# Getting a list of documents in a space.
docs = Document.get_documents(proj="myproj", space="Testing")

# Create template from document
TestRun.create_template("myproj",
                        "tpl_tp_12071",
                        select_test_cases_by="staticLiveDoc",
                        doc_with_space="Testing/tp_12071")

# create a test run based on the template
tr = TestRun.create("myproj", "tp_12071_1", "tpl_tp_12071")

# process a record
rec = tr.records[0]
rec.duration = "10.0"
rec.executed_by = "user1"
rec.executed = datetime.datetime.now()
rec.result = "passed"
wi = _WorkItem(uri=rec.test_case_id)
steps = wi.get_test_steps()
res1 = TestStepResult()
res1.comment = "This is the 1st result"
res1.result = "passed"
res2 = TestStepResult()
res2.comment = "This is the 2nd result"
res2.result = "failed"
rec.test_step_results = [res1, res2]
tr.add_test_record_by_object(rec)

# update the test record status
tr.status = "inprogress"
tr.update()

# Adding a linked Item
# TestCase MYPROJ-2828 verifies Requirement MYPROJ-11
tc = TestCase(project_id="MYPROJ", work_item_id="MYPROJ-2828")
tc.add_linked_item("MYPROJ-11", "verifies")

# Verify it on both objects:
tc = TestCase(project_id="myproj", work_item_id="MYPROJ-2828")
for linked in tc.linked_work_items:
    print "%s - %s" % (linked.work_item_id, linked.role)

req = Requirement(project_id="myproj", work_item_id="MYPROJ-11")
for linked in req.linked_work_items_derived:
    print "%s - %s" % (linked.work_item_id, linked.role)

Before you commit

In order to ensure you are able to pass the GitHub CI build, it is recommended that you run the following commands in the base of your pylero directory:

$ pip install pre-commit
$ pre-commit autoupdate && pre-commit run -a

Pre-commit will ensure that the changes you made are not in violation of PEP8 standards.

We recommend autopep8 to fix any pre-commit failures by running below or you are free to use any formatters which can resolve pre-commit failures with least possible diff:

$ pip install autopep8
$ autopep8 --in-place <edited_file.py>

Fedora RPM package build

Tito

Tito is a tool for managing RPM based projects using git for their source code repository.

The tito config dir is .tito

To create a new tag and automaticlly update pylero.spec with all changelog:

$ tito tag

After tag need push the tag:

$ git push --follow-tags

After tag been pushed a new Copr build will be automatically triggered.

Copr

Fedora Copr Build System help make building and managing third party package repositories easy.

Each pylero new release will trigger new copr build to fedora-all, EPEL8 and EPEL9.

The build is triggered by webhook defined in the project configuration.

The build project on Copr is pylero.

Check the target rpm package in the build to test locally.

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