The Google Cloud Samples Style Guide is considered the primary guidelines for all Google Cloud samples. This section details some additional, Python-specific rules that will be merged into the Samples Style Guide in the near future.
We're happy you want to write a Python sample! Like a lot of Pythonistas, we're opinionated and fussy. This guide is a reference for the format and style expected of samples contributed to the python-docs-samples repo. The guidelines below are intended to ensure that all Python samples meet the following goals:
- Copy-paste-runnable. A developer should be able to copy and paste the code into their own environment and run it with as few modifications as possible.
- Teach through code. Each sample should demonstrate best practices for interacting with Google Cloud libraries, APIs, or services.
- Idiomatic. Each sample should follow widely accepted Python best practices as covered below.
We recommend referencing the following samples and sample tests:
See Folder Location. Samples live in this repository, python-docs-samples, or in a library repository.
Python libraries repositories live in https://github.com/googleapis/ in
repositories named python-API. Each repository contains one library. For
example, https://github.com/googleapis/python-bigquery contains the
google-cloud-bigquery
library.
This is a work in progress - in python-docs-samples, your PR will
automatically be assigned to one of the reviewers in
@GoogleCloudPlatform/python-samples-reviewers.
You can assign a new person using the blunderbuss:assign
label if your
assignee is OOO or busy. You can (and probably should) also assign a teammate in
addition to the auto-assigned owner to review your code for product-specific
needs.
In library repositories GitHub should automatically assign a reviewer from python-samples-reviewers. If no reviewer is automatically assigned, contact @googleapis/python-samples-reviewers.
Please reach out to your assigned reviewer if it's been more than 2 days and you haven't gotten a response!
You should install the latest patch version of each minor version listed in Python Versions.
We recommend using the Python version management tool Pyenv if you are using MacOS or Linux.
Googlers: See the internal Python policies doc.
Using MacOS?: See Setting up a Mac development environment with pyenv and pyenv-virtualenv.
Afterwards, see Test Environment Setup.
This section covers guidelines for Python samples. Note that Testing Guidelines are covered separately below.
Samples that primarily show the use of one client library should be placed in
the client library repository googleapis/python-{api}
. Other samples should be
placed in this repository python-docs-samples
.
Library repositories: Each sample should be in a folder under the top-level
samples folder samples
in the client library repository. See the
Text-to-Speech
samples
for an example.
python-docs-samples: Each sample should be in a folder under the top-level folder of python-docs-samples that corresponds to the Google Cloud service or API used by the sample. For example, a sample demonstrating how to work with Composer should be in a subfolder under the python-docs-samples/composer folder.
Conceptually related samples under a service or API should be grouped into a subfolder. For example, App Engine Standard samples are under the appengine/standard folder, and App Engine Flex samples are under the appengine/flexible folder.
If your sample is a set of discrete code snippets that each demonstrate a single
operation, these should be grouped into a snippets
folder. For example, see
the snippets in the
bigtable/snippets/writes
folder.
If your sample is a quickstart — intended to demonstrate how to quickly get started with using a service or API — it should be in a quickstart folder.
Samples should support Python 3.6, 3.7, 3.8, and 3.9.
If the API or service your sample works with has specific Python version requirements different from those mentioned above, the sample should support those requirements.
Source code files should always begin with an Apache 2.0 license header. See the instructions in the repo license file on how to apply the Apache license to your work. For example, see the license header for the Datastore client quickstart sample.
If, and only if, your sample application is a command-line application, then include a shebang as the first line. Separate the shebang line from the rest of the application with a blank line. The shebang line for a Python application should always be:
#!/usr/bin/env python
Don't include shebang lines in web applications or test files.
All Python samples should follow the best practices defined in the PEP 8 style guide and the Google Python Style Guide. The automated linting process for Python samples uses flake8 to verify conformance to common Python coding standards, so the use of flake8 is recommended.
If you prefer to use pylint, note that Python samples for this repo are not required to conform to pylint’s default settings outside the scope of PEP 8, such as the “too many arguments” or “too many local variables” warnings.
The use of Black to standardize code formatting and simplify diffs is recommended.
The default noxfile has blacken
session for convenience. Here are some
examples.
If you have pyenv configured:
nox -s blacken
If you only have docker:
cd proj_directory
../scripts/run_tests_local.sh . blacken
Owlbot is an automated tool that will run the blacken
session automatically on
new pull requests.
In addition to the syntax guidelines covered in PEP 8, samples should strive to follow the Pythonic philosophy outlined in the PEP 20 - Zen of Python as well as the readability tenets presented in Donald Knuth's Literate Programming. Notably, your sample program should be self-contained, readable from top to bottom, and fairly self-documenting. Prefer descriptive names, and use comments and docstrings only as needed to further clarify the code’s intent. Always introduce functions and variables before they are used. Prefer less indirection. Prefer imperative programming as it is easier to understand.
Follow this style for importing Google Cloud libraries:
from google.cloud import texttospeech_v1
All commonly used clients and types are exposed under texttospeech_v1
.
from google.cloud import texttospeech_v1
client = texttospeech_v1.TextToSpeechClient()
audio_config = texttospeech.AudioConfig(
audio_encoding=texttospeech.AudioEncoding.MP3
)
GAPIC libraries are generated from
protos that define the API surface
via a generator. GAPIC
libraries have library type GAPIC_AUTO
in .repo-metadata.json
located in the
root of the repository. Some GAPIC_COMBO
libraries will also expose
proto-plus
types.
Because they are generated, GAPIC libraries share a common interface. All API
proto messages are exposed as proto-plus
message classes.
proto-plus
provides a few ways to create
objects.
Strongly prefer instantiating library types through the constructor or by instantiating an empty object and initializing individual attributes. The dictionary construction method is discouraged as it is harder to use type checking and IDEs are not able to offer intellisense.
# To try this sample yourself, install `google-cloud-tasks==2.5.1`
from google.cloud import tasks_v2
# 1. Generated types via constructor
task_from_constructor = tasks_v2.Task(
http_request=tasks_v2.HttpRequest(
http_method=tasks_v2.HttpMethod.POST,
url="https://pubsub.googleapis.com/v1/projects/my-project/topics/testtopic:publish",
body=b"eyJtZXNzYWdlcyI6IFt7ImRhdGEiOiAiVkdocGN5QnBjeUJoSUhSbGMzUUsifV19Cg==",
oauth_token=tasks_v2.OAuthToken(
service_account_email='my-svc-acct@my-project.iam.gserviceaccount.com'
)
)
)
# 2. Instantiate object and then set attributes
http_request = tasks_v2.HttpRequest()
http_request.http_method = tasks_v2.HttpMethod.POST
http_request.url = "https://pubsub.googleapis.com/v1/projects/my-project/topics/testtopic:publish"
http_request.body = b"eyJtZXNzYWdlcyI6IFt7ImRhdGEiOiAiVkdocGN5QnBjeUJoSUhSbGMzUUsifV19Cg==",
http_request.oauth_token.service_account_email = "my-svc-acct@my-project.iam.gserviceaccount.com"
task = tasks_v2.Task()
task.http_request = http_request
# 2. Dictionary (NOT RECOMMENDED)
task_from_dict = {
"http_request": {
"http_method": "POST",
"url": "https://pubsub.googleapis.com/v1/projects/my-project/topics/testtopic:publish",
"body": b"eyJtZXNzYWdlcyI6IFt7ImRhdGEiOiAiVkdocGN5QnBjeUJoSUhSbGMzUUsifV19Cg==",
"oauth_token": {"service_account_email":"my-svc-acct@my-project.iam.gserviceaccount.com"},
}
}
Very few samples will require authoring classes. Prefer functions whenever possible. See this video for some insight into why classes aren't as necessary as you might think in Python. Classes also introduce cognitive load. If you do write a class in a sample, be prepared to justify its existence during code review.
Always prefer descriptive function names, even if they are long. For example
upload_file
, upload_encrypted_file
, and list_resource_records
. Similarly,
prefer long and descriptive parameter names. For example source_file_name
,
dns_zone_name
, and base64_encryption_key
.
Here's an example of a top-level function in a command-line application:
def list_blobs(bucket_name):
"""Lists all the blobs in the bucket."""
storage_client = storage.Client()
bucket = storage_client.get_bucket(bucket_name)
blobs = bucket.list_blobs()
for blob in blobs:
print(blob.name)
Notice the simple docstring and descriptive argument name (bucket_name
implying a string instead of just bucket
which could imply a class instance).
This particular function is intended to be the "top of the stack" - the function executed when the command-line sample is run by the user. As such, notice that it prints the blobs instead of returning. In general, top of the stack functions in command-line applications should print, but use your best judgment.
Here's an example of a more complicated top-level function in a command-line application:
def download_encrypted_blob(
bucket_name, source_blob_name, destination_file_name,
base64_encryption_key):
"""Downloads a previously-encrypted blob from Google Cloud Storage.
The encryption key provided must be the same key provided when uploading
the blob.
"""
storage_client = storage.Client()
bucket = storage_client.get_bucket(bucket_name)
blob = bucket.blob(source_blob_name)
# Encryption key must be an AES256 key represented as a bytestring with
# 32 bytes. Since it's passed in as a base64 encoded string, it needs
# to be decoded.
encryption_key = base64.b64decode(base64_encryption_key)
blob.download_to_filename(
destination_file_name, encryption_key=encryption_key)
print(f'Blob {source_blob_name} downloaded to {destination_file_name}.'
Note the verbose parameter names and the extended description that helps the
user form context. If there were more parameters or if the parameters had
complex context, then it might make sense to expand the docstring to include an
Args
section such as:
Args:
bucket_name: The name of the cloud storage bucket.
source_blob_name: The name of the blob in the bucket to download.
destination_file_name: The blob will be downloaded to this path.
base64_encryption_key: A base64-encoded RSA256 encryption key. Must be the
same key used to encrypt the file.
Generally, however, it's rarely necessary to exhaustively document the parameters this way. Lean towards unsurprising arguments with descriptive names, as having to resort to this kind of docstring might be extremely accurate but it comes at the cost of high redundancy, signal-to-noise ratio, and increased cognitive load.
Argument types should be documented using Python type annotations as introduced in PEP 484. For example:
def hello_world(name: str) -> None:
print(f"Hello {name}!")
def adder(a: int, b: int) -> int:
return a+b
Type hinting is enforced using
flake8-annotations
, which is
enabled by setting the enforce_type_hints
variable to True
in the
appropriate noxfile_config.py
. Type hinting is expected in all new samples,
and will gradually be added to all compatible existing samples.
If there is an Args
section within the function's docstring, consider
documenting the argument types there as well. For example:
Args:
credentials (google.oauth2.credentials.Credentials): Credentials
authorized for the current user.
When documenting primitive types, be sure to note if they have a particular set
of constraints. For example, A base64-encoded string
or Must be between 0 and 10
.
Always create timezone aware datetime objects. For libraries that use protobuf, omitting the timezone may lead to unexpected behavior when the datetime is converted to a protobuf timestamp.
import datetime
now = datetime.datetime.now(tz=datetime.timezone.utc)
For more information see the Python datetime documentation.
Each sample should have a README.md
file that provides instructions for how to
install, configure, and run the sample. Setup steps that cover creating Google
Cloud projects and resources should link to appropriate pages in the Google
Cloud Documentation, to avoid duplication and
simplify maintenance.
Every sample should include a requirements.txt file that lists all of its dependencies, to enable others to re-create the environment that was used to create and test the sample. All dependencies should be pinned to a specific version, as in this example:
Flask==1.1.1
PyMySQL==0.9.3
SQLAlchemy==1.3.12
If a sample has testing requirements that differ from its runtime requirements
(such as dependencies on pytest or other testing
libraries), the testing requirements may be listed in a separate
requirements-test.txt
file instead of the main requirements.txt
file.
Pip has VCS support. Use the branch name or commit hash instead of the package name.
pip install:
pip install git+https://github.com/googleapis/python-firestore.git@ee518b741eb5d7167393c23baa1e29ace861b253
requirements.txt:
Flask==1.1.1
PyMySQL==0.9.3
git+https://github.com/googleapis/python-firestore.git@ee518b741eb5d7167393c23baa1e29ace861b253
Sample code may be integrated into Google Cloud Documentation through the use of
region tags, which are comments added to the source code to identify code blocks
that correspond to specific topics covered in the documentation. For example,
see this
sample
— the region tags are the comments that begin with [START
or [END
.
The use of region tags is beyond the scope of this document, but if you’re using region tags they should start after the source code header (license/copyright information), but before imports and global configuration such as initializing constants.
Sample code should use standard Python exception handling techniques as covered in the Google Python Style Guide.
Samples should include tests to verify that the sample runs correctly and generates the intended output. Follow these guidelines while writing your tests:
- Use pytest-style tests and plain
asserts. Don't use
unittest
-style tests orassertX
methods. - Whenever possible, tests should allow for future changes or additions to APIs that are unrelated to the code being tested. For example, if a test is intended to verify a JSON payload returned from an endpoint, it should only check for the existence of the expected keys and values, and the test should continue to work correctly if the order of keys changes or new keys are added to the response in a future version of the API. In some cases, it may make sense for tests to simply verify that an API call was successful rather than checking the response payload.
- Samples that use App Engine Standard should use the App Engine testbed for system testing, as shown in this example.
- All tests should be independent of one another and order-independent.
- We use parallel processing for tests, so tests should be capable of running in parallel with one another.
- Use pytest's fixture for resource setup and teardown, instead of having them in the test itself.
- Avoid infinite loops.
- Retry RPCs
- You can enable running tests in parallel by adding
pytest-parallel
orpytest-xdist
to yourrequirements-test.txt
file.
Tests for samples should follow the “Arrange, Act, Assert” structure:
- Arrange — create and configure the components required for the test. Avoid nesting; prioritize readability and simplicity over efficiency. For Python tests, typical "arrange" steps include imports, copying environment variables to local variables, and so on.
- Act — execute the code to be tested, such as sending a request to an API and receiving a response.
- Assert — verify that the test results match what is expected, using an
assert
statement.
Whenever possible, tests should run against the live production version of cloud APIs and resources. This will assure that any breaking changes in those resources are identified by the tests.
External resources that must exist prior to the test (for example, a Cloud SQL instance) should be identified and passed in through an environment variable. If specific data needs to exist within such infrastructure resources, however, the test should create this data as part of its Arrange steps and then clean up when the test is completed.
Creating mocks for external resources is strongly discouraged. Tests should verify the validity of the sample against the APIs, and not against a mock that embodies assumptions about the behavior of the APIs.
When tests need temporary resources (such as a temp file or folder), they should
create reasonable names for these resources with a UUID attached to assure
uniqueness. Use the Python uuid
package from the standard library to
generate UUIDs for resource names. For example:
glossary_id = f'test-glossary-{uuid.uuid4()}'
or:
# If full uuid4 is too long, use its hex representation.
encrypted_disk_name = f'test-disk-{uuid.uuid4().hex}'
# If the hex representation is also too long, slice it.
encrypted_disk_name = f'test-disk-{uuid.uuid4().hex[:5]}'
All temporary resources should be explicitly deleted when testing is complete. Use pytest's fixture for cleaning up these resources instead of doing it in test itself.
We recommend using finally
to ensure that resource deletion occurs even if
there is an error on creation. For example, this fixture creates a Dataproc
cluster and tears it down regardless of errors during creation.
@pytest.fixture(scope="function")
def setup_and_teardown_cluster():
try:
# Create cluster using cluster client
cluster_client = dataproc.ClusterControllerClient(
client_options={
"api_endpoint": f"{CLUSTER_REGION}-dataproc.googleapis.com:443"
}
)
operation = cluster_client.create_cluster(
project_id=PROJECT_ID, region=CLUSTER_REGION, cluster=CLUSTER_CONFIG
)
# Wait for cluster to provision
operation.result()
yield
finally:
try:
# Delete cluster
operation = cluster_client.delete_cluster(
project_id=PROJECT_ID, region=CLUSTER_REGION, cluster_name=DATAPROC_CLUSTER
)
operation.result()
except NotFound:
print("Cluster already deleted")
If the sample prints output to the console, the test should capture stdout to a file and verify that the captured output contains the key information that is expected. Strive to verify the content of the output rather than the syntax. For example, the test might verify that a string is included in the output, without taking a dependency on where that string occurs in the output.
Never put potential infinite loops in the test code path. A typical example is
about gRPC's LongRunningOperations. Make sure you pass the timeout parameter to
the result()
call.
Good:
# will raise google.api_core.GoogleAPICallError after 60 seconds
operation.result(60)
Bad:
operation.result() # this could wait forever.
We recommend the timeout parameter to be around the number that gives you more than 90% success rate. Don't put too long a timeout.
Now this test is inevitably flaky, so consider marking the test as flaky
as
follows:
@pytest.mark.flaky(max_runs=3, min_passes=1)
def my_flaky_test():
# test that involves LRO poling with the timeout
This combination will give you very high success rate with fixed test execution time (0.999 success rate and 180 seconds operation wait time in the worst case in this example).
All the RPCs are inevitably flaky. It can fail for many reasons. The
google-cloud
Python client retries requests automatically for most cases.
The previous style of client library (api-client) doesn't retry automatically,
so consider using the Google API Core
@retry.Retry()
decorator. By default, it will retry transient
errors.
Here is an
example:
from google.api_core.retry import Retry
@Retry()
def test_quickstart_v2() -> None:
project_id = os.getenv("GOOGLE_CLOUD_PROJECT")
recognizer_id = "recognizer-" + str(uuid4())
response = quickstart_v2.quickstart_v2(
project_id, recognizer_id, os.path.join(RESOURCES, "audio.wav")
)
assert re.search(
r"how old is the Brooklyn Bridge",
response.results[0].alternatives[0].transcript,
re.DOTALL | re.I,
)
delete_recognizer(
f"projects/{project_id}/locations/global/recognizers/{recognizer_id}"
)
While @Retry
is preferred, backoff
also
supports retrying. Here is a simple example:
import backoff
from googleapiclient.errors import HttpError
@pytest.fixture(scope='module')
def test_resource():
@backoff.on_exception(backoff.expo, HttpError, max_time=60)
def create_resource():
try:
return client.projects().imaginaryResource().create(
name=resource_id, body=body).execute()
except HttpError as e:
if '409' in str(e):
# Ignore this case and get the existing one.
return client.projects().imaginaryResource().get(
name=resource_id).execute()
else:
raise
resource = create_resource()
yield resource
# cleanup
...
When writing a test for a list
method, consider filtering the possible
results. Listing all resources in the test project may take a considerable
amount of time. The exact way to do this depends on the API.
Some list
methods take a filter
/filter_
parameter:
from datetime import datetime
from google.cloud import logging_v2
client = logging_v2.LoggingServiceV2Client()
resource_names = [f"projects/{project}"]
# We add timestamp for making the query faster.
now = datetime.datetime.now(datetime.timezone.utc)
filter_date = now - datetime.timedelta(minutes=1)
filters = (
f"timestamp>=\"{filter_date.isoformat('T')}\" "
"resource.type=cloud_run_revision "
"AND severity=NOTICE "
)
entries = client.list_log_entries(resource_names, filter_=filters)
Others allow you to limit the result set with additional arguments to the request:
from google.cloud import asset_v1p5beta1
# TODO project_id = 'Your Google Cloud Project ID'
# TODO asset_types = 'Your asset type list, e.g.,
# ["storage.googleapis.com/Bucket","bigquery.googleapis.com/Table"]'
# TODO page_size = 'Num of assets in one page, which must be between 1 and
# 1000 (both inclusively)'
project_resource = "projects/{}".format(project_id)
content_type = asset_v1p5beta1.ContentType.RESOURCE
client = asset_v1p5beta1.AssetServiceClient()
# Call ListAssets v1p5beta1 to list assets.
response = client.list_assets(
request={
"parent": project_resource,
"read_time": None,
"asset_types": asset_types,
"content_type": content_type,
"page_size": page_size,
}
)
Because all tests are system tests that use live resources, running tests requires a Google Cloud project with billing enabled, as covered under Creating and Managing Projects.
Once you have your project created and configured, you'll need to set
environment variables to identify the project and resources to be used by tests.
See
testing/test-env.tmpl.sh
for a list of all environment variables that must be set manually. Not every
test needs all of these variables. All required environment variables are listed
in testing/test-env.tmpl.sh
. If you need to add a new secret, follow
instructions in Secrets.
We suggest that you copy this file as follows:
cp testing/test-env.tmpl.sh testing/test-env.sh
editor testing/test-env.sh # change the value of `GOOGLE_CLOUD_PROJECT`.
You can easily source
this file for exporting the environment variables.
This repository supports two ways to run tests locally.
-
nox
This is the recommended way. Setup takes little more efforts than the second one, but the test execution will be faster.
-
Docker
This is another way of running the tests. Setup is easier because you only need to instal Docker. The test execution will be bit slower than the first one. This option is also useful if you need to simulate the CI system.
Automated testing for samples is managed by nox. Nox allows us to run a variety of tests, including the flake8 linter, Python 2.7, Python 3.x, and App Engine tests, as well as automated README generation.
Sample tests are run through pytest. Do not use unittest.
Note:
Library repositories: If you are working on an existing project (meaning
that a samples
directory already exists), a noxfile.py
will already exist
within that samples
directory.
For new samples, create a new noxfile.py
and paste the contents of
noxfile-template.py.
Note - there may be a noxfile.py
in the repo already in the root directory,
but this is used for testing the libraries, not the samples, so you will still
need to make a samples noxfile.
python-docs-samples: As a temporary workaround, each project currently uses
first noxfile-template.py
found in a parent folder above the current sample.
In order to simulate this locally, you need to copy + rename the parent
noxfile-template.py
as noxfile.py
in the folder of the project (containing
the requirements.txt
for the file).
cd python-docs-samples
cp noxfile-template.py PATH/TO/YOUR/PROJECT/noxfile.py
cd PATH/TO/YOUR/PROJECT/
ℹ️ Note: Nox only detects tests in the tests
directory where the
noxfile_config.py
file is or for any files named *_test.py
or
test_*.py
in the same directory as the config file.
To use nox, install it globally with pip
:
pip install nox
To run style checks on your samples:
nox -s lint
To run tests with a python version, use the correct py-3.*
sessions:
nox -s py-3.6
To run a specific file:
nox -s py-3.7 -- snippets_test.py
To run a specific test from a specific following:
nox -s py-3.7 -- snippets_test.py::test_list_blobs
The noxfile_config.py
allows for customization of some
options:
- Ignore specific Python versions.
- Enforce type hints.
- Specify a different Google Cloud Project.
- Add additional environment variables. Also see Environment Variables.
- Override the version of
pip
used by nox
Options are documented inside the noxfile_config.py.
Note: This is currently only available for samples in python-docs-samples
.
If you have Docker installed and runnable by the local
user, you can use scripts/run_tests_local.sh
helper script to run the tests.
For example, let's say you want to modify the code in cdn
directory, then you
can do:
$ cd cdn
$ ../scripts/run_tests_local.sh .
# This will run the default sessions; lint, py-3.6, and py-3.7
$ ../scripts/run_tests_local.sh . lint
# Running only lint
If your test needs a service account, you have to create a service account and
download the JSON key to testing/service-account.json
.
On MacOS systems, you also need to install coreutils
to use
scripts/run_tests_local.sh
. Here is how to install it with brew
:
brew install coreutils
This section explains how to set environment variables that are needed by tests.
If a noxfile_config.py
does not exist, copy
noxfile_config.py
into the directory.
Add the new environment variables to the envs
dictionary.
TEST_CONFIG_OVERRIDE = {
# You can opt out from the test for specific Python versions.
"ignored_versions": ["2.7", "3.7", "3.9", "3.10", "3.11"],
# Old samples are opted out of enforcing Python type hints
# All new samples should feature them
"enforce_type_hints": True,
# An envvar key for determining the project id to use. Change it
# to 'BUILD_SPECIFIC_GCLOUD_PROJECT' if you want to opt in using a
# build specific Cloud project. You can also use your own string
# to use your own Cloud project.
"gcloud_project_env": "GOOGLE_CLOUD_PROJECT",
# 'gcloud_project_env': 'BUILD_SPECIFIC_GCLOUD_PROJECT',
# A dictionary you want to inject into your test. Don't put any
# secrets here. These values will override predefined values.
"envs": {"DJANGO_SETTINGS_MODULE": "mysite.settings"},
}
For setting up a local test environment, see Test Environment Setup.
Secrets (e.g., project names, API keys, passwords) are kept in Cloud Secret Manager. See python-docs-samples-test-env. If you are unable to access the link, reach out to your assigned pull request reviewer or someone in @GoogleCloudPlatform/python-samples-reviewers for assistance.
- Add the new environment variable to
testing/test-env.tmpl.sh
in your pull request. - Run
scripts/decrypt-secrets.sh
to fetch the secrets. A new filetesting/test-env.sh
will appear. - Add the new environment variable to
testing/test-env.sh
. - Run
scripts/encrypt-secrets.sh
to upload the secrets to secret manager.
Certain samples require integration with Google Cloud Storage (GCS), most
commonly for APIs that read files from GCS. To run the tests for these samples,
configure your GCS bucket name via the CLOUD_STORAGE_BUCKET
environment
variable.
The resources required by tests can usually be found in the ./resources
folder
inside the samples/snippets
directory in client libraries, as in this
example.
You can upload those resources to your own GCS bucket to run the tests with
gsutil. For example:
gsutil cp ./samples/snippets/resources/* gs://{$CLOUD_STORAGE_BUCKET}/
Yes, you can use pdb
or any Python debugger. For pdb, use import pdb; pdb.set_trace()
(<3.7) or breakpoint
(3.7+). See
https://docs.python.org/3/library/pdb.html.
These IDEs just inject the breakpoint above into the code, so it should work.