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Gonkey will test your services using their API. It can bomb the service with prepared requests and check the responses. Test scenarios are described in YAML-files.
Capabilities:
- works with REST/JSON API
- tests service API for compliance with OpenAPI-specs
- seeds the DB with fixtures data (supports PostgreSQL, MySQL, Aerospike, Redis)
- provides mocks for external services
- can be used as a library and ran together with unit-tests
- stores the results as an Allure report
- there is a JSON-schema to add autocomletion and validation for gonkey YAML files
- Using the CLI
- Using gonkey as a library
- Test scenario example
- Test status
- HTTP-request
- HTTP-response
- Variables
- Files uploading
- Fixtures
- Mocks
- Shell scripts usage
- A DB query
To test a service located on a remote host, use gonkey as a console util.
./gonkey -host <...> -tests <...> [-spec <...>] [-db_dsn <...> -fixtures <...>] [-allure] [-v]
-spec <...>
path to a file or URL with the swagger-specs for the service-host <...>
service host:port-tests <...>
test file or directory-db-type <...>
- database type. PostgreSQL, Aerospike, Redis are currently supported.-aerospike_host <...>
when using Aerospike - connection URL in a form ofhost:port/namespace
-redis_url <...>
when using Redis - connection address, for exampleredis://user:password@localhost:6789/1?dial_timeout=1&db=1&read_timeout=6s&max_retries=2
-db_dsn <...>
DSN for the test DB (the DB will be cleared before seeding!), supports only PostgreSQL-fixtures <...>
fixtures directory-allure
generate an Allure-report-v
verbose output-debug
debug output
You can't use mocks in this mode.
To integrate functional and native Go tests and run them together, use gonkey as a library.
Create a test file, for example func_test.go
.
Import gonkey as a dependency to your project in this file.
import (
"github.com/lamoda/gonkey/runner"
"github.com/lamoda/gonkey/mocks"
)
Create a test function.
package test
import (
"testing"
"github.com/lamoda/gonkey/fixtures"
"github.com/lamoda/gonkey/mocks"
"github.com/lamoda/gonkey/runner"
)
func TestFuncCases(t *testing.T) {
// init the mocks if needed (details below)
// m := mocks.NewNop(...)
// init the DB to load the fixtures if needed (details below)
// db := ...
// init Aerospike to load the fixtures if needed (details below)
// aerospikeClient := ...
// create a server instance of your app
srv := server.NewServer()
defer srv.Close()
// run test cases from your dir with Allure report generation
runner.RunWithTesting(t, &runner.RunWithTestingParams{
Server: srv,
TestsDir: "cases",
Mocks: m,
DB: db,
Aerospike: runner.Aerospike{
Client: aerospikeClient,
Namespace: "test",
},
// Type of database, can be fixtures.Postgres, fixtures.Mysql, fixtures.CustomLoader
// if DB parameter present, by default uses fixtures.Postgres database type
DbType: fixtures.Postgres,
FixturesDir: "fixtures",
})
}
Starts from version 1.18.3, externally written fixture loader may be used for loading test data, if gonkey used as a library. To start using the custom loader, you need to import the custom module, that contains implementation of fixtures.Loader interface.
Example with a redis fixtures loader:
package test
import (
"net/http"
"net/http/httptest"
"testing"
"github.com/lamoda/gonkey/fixtures"
redisLoader "github.com/lamoda/gonkey/fixtures/redis"
// redisLoader "custom_module/gonkey-redis" // custom implementation of a fixtures.Loader interface
redisClient "github.com/go-redis/redis/v9"
"github.com/lamoda/gonkey/runner"
)
func TestFuncCases(t *testing.T) {
serveMux := http.NewServeMux()
serveMux.HandleFunc("/", func(w http.ResponseWriter, r *http.Request) {
_, _ = w.Write([]byte("ok"))
})
srv := httptest.NewServer(serveMux)
clientOptions, err := redisClient.ParseURL("redis://user:password@localhost:6789/1?dial_timeout=1&db=1&read_timeout=6s&max_retries=2")
if err != nil {
panic(err)
}
redisFixtureLoader := redisLoader.New(redisLoader.LoaderOptions{
FixtureDir: "./fixtures",
Redis: clientOptions,
})
runner.RunWithTesting(t, &runner.RunWithTestingParams{
Server: srv,
TestsDir: "./cases",
DbType: fixtures.CustomLoader,
FixtureLoader: redisFixtureLoader,
})
}
The tests can be now ran with go test
, for example: go test ./...
.
- name: WHEN the list of orders is requested MUST successfully response
method: GET
status: ""
path: /jsonrpc/v2/order.getBriefList
query: ?id=550e8400-e29b-41d4-a716-446655440000&jsonrpc=2.0&user_id=00001
fixtures:
- order_0001
- order_0002
response:
200: |
{
"id": "550e8400-e29b-41d4-a716-446655440000",
"jsonrpc": "2.0",
"result": {
"data": [
"ORDER0001",
"ORDER0002"
],
"meta": {
"items": 0,
"limit": 50,
"page": 0,
"pages": 0
}
}
}
- name: WHEN one order is requested MUST response with user and sum
method: POST
path: /jsonrpc/v2/order.getOrder
headers:
Authorization: Bearer HsHG67d38hJKJFdfjj==
Content-Type: application/json
cookies:
sid: ZmEwZDkwYzgwMmQzMGIzOGIxODM3ZmFiOTGJhMzU=
lid: AAAEAFu/TdhHBg7UAgA=
comparisonParams:
ignoreValues: false
ignoreArraysOrdering: false
disallowExtraFields: false
request: |
{
"jsonrpc": "2.0",
"id": "550e8400-e29b-41d4-a716-446655440000",
"method": "order.getOrder",
"params": [
{
"order_nr": {{ .orderNr }}
}
]
}
response:
200: |
{
"id": "550e8400-e29b-41d4-a716-446655440000",
"jsonrpc": "2.0",
"result": {
"user_id": {{ .userId }},
"amount": {{ .amount }},
"token": "$matchRegexp(^\\w{16}$)"
}
}
responseHeaders:
200:
Content-Type: "application/json"
Cache-Control: "no-store, must-revalidate"
Set-Cookie: "mycookie=123; Path=/; Domain=mydomain.com", "mycookie=456; Path=/; Domain=.mydomain.com"
cases:
- requestArgs:
orderNr: ORDER0001
responseArgs:
200:
userId: '0001'
amount: 1000
- requestArgs:
orderNr: ORDER0002
responseArgs:
200:
userId: '0001'
amount: 72000
As you can see in this example, you can use Regexp for checking response body. It can be used for all body (if it's plaint text):
response:
200: "$matchRegexp(^xy+z$)"
or for elements of map/array (if it's JSON):
response:
200: |
{
"id": "$matchRegexp([\\w-]+)",
"jsonrpc": "$matchRegexp([12].0)",
"result": [
"data": [
"$matchRegexp(ORDER[0]{3}[0-9])",
"$matchRegexp(ORDER[0]{3}[0-9])"
],
]
}
Also, "?" in query is optional
status
- a parameter, for specially mark tests, can have following values:
broken
- do not run test, only mark it as brokenskipped
- do not run test, skip itfocus
- run only this specific test, and mark all other tests with unset status asskipped
method
- a parameter for HTTP request type, the format is in the example above.
path
- a parameter for URL path, the format is in the example above.
headers
- a parameter for HTTP headers, the format is in the example above.
cookies
- a parameter for cookies, the format is in the example above.
response
- the HTTP response body for the specified HTTP status codes.
responseHeaders
- all HTTP response headers for the specified HTTP status codes.
You can use variables in the description of the test, the following fields are supported:
- method
- description
- path
- query
- headers
- request
- response
- dbQuery
- dbResponse
- mocks body
- mocks headers
- mocks requestConstraints
Example:
- method: "{{ $method }}"
description: "{{ $description }}"
path: "/some/path/{{ $pathPart }}"
query: "{{ $query }}"
headers:
header1: "{{ $header }}"
request: '{"reqParam": "{{ $reqParam }}"}'
response:
200: "{{ $resp }}"
mocks:
server_mock:
strategy: constant
body: >
{
"message": "{{ $mockParam }}"
}
statusCode: 200
dbQuery: >
SELECT id, name FROM testing_tools WHERE id={{ $sqlQueryParam }}
dbResponse:
- '{"id": {{ $sqlResultParam }}, "name": "gonkey"}'
You can assign values to variables in the following ways (priorities are from top to bottom):
- in the description of the test
- from the response of the previous test
- from the response of currently running test
- from environment variables or from env-file
Example:
- method: "{{ $method }}"
path: "/some/path/{{ $pathPart }}"
variables:
reqParam: "reqParam_value"
method: "POST"
pathPart: "part_of_path"
query: "query_val"
header: "header_val"
resp: "resp_val"
query: "{{ $query }}"
headers:
header1: "{{ $header }}"
request: '{"reqParam": "{{ $reqParam }}"}'
response:
200: "{{ $resp }}"
Example:
# if the response is plain text
- name: "get_last_post_id"
...
variables_to_set:
200: "id"
# if the response is JSON
- name: "get_last_post_info"
variables_to_set:
200:
id: "id"
title: "title"
authorId: "author_info.id"
You can access nested fields like this:
"author_info.id"
Any nesting levels are supported.
Example:
- name: Get info with database
method: GET
path: "/info/1"
variables_to_set:
200:
golang_id: query_result.0.0
response:
200: '{"result_id": "1", "query_result": [[ {{ $golang_id }} , "golang"], [2, "gonkey"]]}'
dbQuery: >
SELECT id, name FROM testing_tools WHERE id={{ $golang_id }}
dbResponse:
- '{"id": {{ $golang_id}}, "name": "golang"}'
Gonkey automatically checks if variable exists in the environment variables (case-sensitive) and loads a value from there, if it exists.
If an env-file is specified, variables described in it will be added or will replace the corresponding environment variables.
Example of an env file (standard syntax):
jwt=some_jwt_value
secret=my_secret
password=private_password
env-file can be convenient to hide sensitive information from a test (passwords, keys, etc.)
You can describe variables in cases section of a test.
Example:
- name: Get user info
method: GET
path: "/user/1"
response:
200: '{ "user_id": "1", "name": "{{ $name }}", "surname": "{{ $surname }}" }'
cases:
- variables:
name: John
surname: Doe
Variables like these will be available through another cases if not redefined.
You can upload files in test request. For this you must specify the type of request - POST and header:
Content-Type: multipart/form-data
Example:
- name: "upload-files"
method: POST
form:
files:
file1: "testdata/upload-files/file1.txt"
file2: "testdata/upload-files/file2.log"
headers:
Content-Type: multipart/form-data # case-sensitive, can be omitted
response:
200: |
{
"status": "OK"
}
To seed the DB before the test, gonkey uses fixture files.
- You can use schema in PostreSQL: schema.table_name
File example:
# fixtures/comments.yml
inherits:
- another_fixture
- yet_another_fixture
tables:
posts:
- $name: janes_post
title: New post
text: Post text
author: Jane Dow
created_at: 2016-01-01 12:30:12
updated_at: 2016-01-01 12:30:12
- $name: apples_post
title: Morning digest
text: Text
author: Apple Seed
created_at: 2016-01-01 12:30:12
updated_at: 2016-01-01 12:30:12
comments:
- post_id: $janes_post.id
content: A comment...
author_name: John Doe
author_email: [email protected]
created_at: 2016-01-01 12:30:12
updated_at: 2016-01-01 12:30:12
- post_id: $apples_post.id
content: Another comment...
author_name: John Doe
author_email: [email protected]
created_at: 2016-01-01 12:30:12
updated_at: 2016-01-01 12:30:12
another_table:
...
...
Records in fixtures can use templates, inherit and reference each other.
To clear the table before the test put square brackets next to the table name.
Example:
# fixtures/empty_posts_table.yml
tables:
posts: []
Usually, to insert a record to a DB, it's necessary to list all the fields without default values. Oftentimes, many of those fields are not important for the test, and their values repeat from one fixture to another, creating unnecessary visual garbage and making the maintenance harder.
With templates you can inherit the fields from template record redefining only the fields that are important for the test.
Template definition example:
templates:
dummy_client:
name: Dummy Client Name
age: 35
ip: 127.0.0.1
is_deleted: false
dummy_deleted_client:
$extend: dummy_client
is_deleted: true
tables:
...
Example of using a template in a fixture:
templates:
...
tables:
clients:
- $extend: dummy_client
- $extend: dummy_client
name: Josh
- $extend: dummy_deleted_client
name: Jane
As you might have noticed, templates can be inherited as well with $extend
keyword, but only if by the time of the dependent template definition the parent template is already defined (in this file or any other referenced with inherits
).
Records can be inherited as well using $extend
.
To inherit a record, first you need to assign this record a name using $name
:
# fixtures/post.yaml
tables:
posts:
- $name: regular_post
title: Post title
text: Some text
Names assigned to records must be unique among all loaded fixture files, as well as they must not interfere with template names.
In another fixture file you need to declare that a certain record inherits an earlier defined record with $extend
, just like with the templates:
# fixtures/deleted_post.yaml
inherits:
- post
tables:
posts:
- $extend: regular_post
is_deleted: true
Don't forget to declare the dependency between files in inherits
, to make sure that one file is always loaded together with the other one.
It's important to note that record inheritance only works with different fixture files. It's not possible to declare inheritance within one file.
Despite the fact that fixture files allow you to set values for autoincrement columns (usually id
), it's not recommended doing it. It's very difficult to control that all the values for id
are correct between different files and that they never interfere. In order to let the DB assign autoincrement values its enough to not set the value explicitly.
However, if the value for id
is not set explicitly, how is it possible to link several entities that should reference each other with ids? Fixtures let us to reference previously inserted records by their name, using $refName.fieldName
.
Let's declare a named record:
# fixtures/post.yaml
tables:
posts:
- $name: regular_post
title: Post title
text: Some text
Now, in order to link posts
and comments
tables, we can address the record using its name ($regular_post
) and pass the field where the value should be taken from (id
):
# fixtures/comment.yaml
tables:
comments:
- post_id: $regular_post.id
content: A comment...
author_name: John Doe
You can only reference fields of a previously inserted record. It's impossible to reference template fields, when trying to do that you'll get an undefined reference
error.
Take a note of a limitation: you can't reference records within one table of one file.
When you need to write an expression execution result to the DB and not a static value, you can use $eval()
construct. Everything inside the brackets will be inserted into the DB as raw, non-escaped data. This way, within $eval()
you can write everything you would in a regular query.
For instance, this construct allows the insertion of current date and time as a field value:
tables:
comments:
- created_at: $eval(NOW())
Fixtures for Aerospike are also supported. While using gonkey as CLI application do not forget the flag -db-type aerospike
; add DbType: fixtures.Aerospike
to runner's configuration if gonkey is used as library.
Fixtures files format is a bit different, yet the same basic principles applies:
sets:
set1:
key1:
bin1: "value1"
bin2: 1
key2:
bin1: "value2"
bin2: 2
bin3: 2.569947773654566473
set2:
key1:
bin4: false
bin5: null
bin1: '"'
key2:
bin1: "'"
bin5:
- 1
- '2'
Fixtures templates are also supported:
templates:
base_tmpl:
bin1: value1
extended_tmpl:
$extend: base_tmpl
bin2: value2
sets:
set1:
key1:
$extend: base_tmpl
bin1: overwritten
set2:
key1:
$extend: extended_tmpl
bin2: overwritten
Records linking and expressions are currently not supported.
Supports loading test data with fixtures for redis key/value storage.
While using gonkey as a CLI application do not forget the flag -db-type redis
.
List of supported data structures:
- Plain key/value
- Set
- Hash
- List
- ZSet (sorted set)
Fixture file example:
inherits:
- template1
- template2
- other_fixture
templates:
keys:
- $name: parentKeyTemplate
values:
baseKey:
expiration: 1s
value: 1
- $name: childKeyTemplate
$extend: parentKeyTemplate
values:
otherKey:
value: 2
sets:
- $name: parentSetTemplate
expiration: 10s
values:
- value: a
- $name: childSetTemplate
$extend: parentSetTemplate
values:
- value: b
hashes:
- $name: parentHashTemplate
values:
- key: a
value: 1
- key: b
value: 2
- $name: childHashTemplate
$extend: parentHashTemplate
values:
- key: c
value: 3
- key: d
value: 4
lists:
- $name: parentListTemplate
values:
- value: 1
- value: 2
- $name: childListTemplate
values:
- value: 3
- value: 4
zsets:
- $name: parentZSetTemplate
values:
- value: 1
score: 2.1
- value: 2
score: 4.3
- $name: childZSetTemplate
value:
- value: 3
score: 6.5
- value: 4
score: 8.7
databases:
1:
keys:
$extend: childKeyTemplate
values:
key1:
value: value1
key2:
expiration: 10s
value: value2
sets:
values:
set1:
$extend: childSetTemplate
expiration: 10s
values:
- value: a
- value: b
set3:
expiration: 5s
values:
- value: x
- value: y
hashes:
values:
map1:
$extend: childHashTemplate
values:
- key: a
value: 1
- key: b
value: 2
map2:
values:
- key: c
value: 3
- key: d
value: 4
lists:
values:
list1:
$extend: childListTemplate
values:
- value: 1
- value: 100
- value: 200
zsets:
values:
zset1:
$extend: childZSetTemplate
values:
- value: 5
score: 10.1
2:
keys:
values:
key3:
value: value3
key4:
expiration: 5s
value: value4
In order to imitate responses from external services, use mocks.
A mock is a web server that is running on-the-fly, and is populated with certain logic before the execution of each test. The logic defines what the server responses to a certain request. It's defined in the test file.
Before running tests, all planned mocks are started. It means that gonkey spins up the given number of servers and each one of them gets a random port assigned.
// create empty server mocks
m := mocks.NewNop(
"cart",
"loyalty",
"catalog",
"madmin",
"okz",
"discounts",
)
// spin up mocks
err := m.Start()
if err != nil {
t.Fatal(err)
}
defer m.Shutdown()
After spinning up the mock web-servers, we can get their addresses (host and port). Using those addresses, you can configure your service to send their requests to mocked servers instead of real ones.
// configuring and running the service
srv := server.NewServer(&server.Config{
CartAddr: m.Service("cart").ServerAddr(),
LoyaltyAddr: m.Service("loyalty").ServerAddr(),
CatalogAddr: m.Service("catalog").ServerAddr(),
MadminAddr: m.Service("madmin").ServerAddr(),
OkzAddr: m.Service("okz").ServerAddr(),
DiscountsAddr: m.Service("discounts").ServerAddr(),
})
defer srv.Close()
As soon as you spinned up your mocks and configured your service, you can run the tests.
runner.RunWithTesting(t, &runner.RunWithTestingParams{
Server: srv,
Directory: "tests/cases",
Mocks: m, // passing the mocks to the test runner
})
Each test communicates a configuration to the mock-server before running. This configuration defines the responses for specific requests in the mock-server. The configuration is defined in a YAML-file with test in the mocks
section.
The test file can contain any number of mock service definitions:
- name: Test with mocks
...
mocks:
service1:
...
service2:
...
service3:
...
request:
...
Each mock-service definition consists of:
requestConstraints
- an array of constraints that are applied on a received request. If at least one constraint is not satisfied, the test is considered failed. The list of all possible checks is provided below.
strategy
- the strategy of mock responses. The list of all possible strategies is provided below.
The rest of the keys on the first nesting level are parameters to the strategy. Their variety is different for each strategy.
A configuration example for one mock-service:
...
mocks:
service1:
requestConstraints:
- ...
- ...
strategy: strategyName
strategyParam1: ...
strategyParam2: ...
...
The request to the mock-service can be validated using one or more constraints defined below.
The definition of each constraint contains of the kind
parameter that indicates which constraint will be applied.
All other keys on this level are constraint parameters. Each constraint has its own parameter set.
Empty constraint. Always successful.
No parameters.
Example:
...
mocks:
service1:
requestConstraints:
- kind: nop
...
Checks that the request body is JSON, and it corresponds to the JSON defined in the body
parameter.
Parameters:
body
(mandatory) - expected JSON. All keys on all levels defined in this parameter must be present in the request body.
Example:
...
mocks:
service1:
requestConstraints:
# this check will demand that the request contains keys key1, key2 and subKey1
# and their values set to value1 and value2. However, it's fine if the request has
# other keys not mentioned here.
- kind: bodyMatchesJSON
body: >
{
"key1": "value1",
"key2": {
"subKey1": "value2",
}
}
...
When request body is JSON, checks that value of particular JSON-field is string-packed JSON
that matches to JSON defined in value
parameter.
Parameters:
path
(mandatory) - path to string field, containing JSON to check.value
(mandatory) - expected JSON.
Example:
Origin request that contains string-packed JSON
{
"field1": {
"field2": "{\"stringpacked\": \"json\"}"
}
}
...
mocks:
service1:
requestConstraints:
- kind: bodyJSONFieldMatchesJSON
path: field1.field2
value: |
{
"stringpacked": "json"
}
...
Checks that the request path corresponds to the expected one.
Parameters:
path
- a string with the expected request path value;regexp
- a regular expression to check the path value against.
Example:
...
mocks:
service1:
requestConstraints:
- kind: pathMatches
path: /api/v1/test/somevalue
service2:
requestConstraints:
- kind: pathMatches
regexp: ^/api/v1/test/.*$
...
Checks that the GET request parameters correspond to the ones defined in the query
parameter.
Parameters:
expectedQuery
(mandatory) - a list of parameters to compare the parameter string to. The order of parameters is not important.
Examples:
...
mocks:
service1:
requestConstraints:
# this check will demand that the request contains key1 и key2
# and the values are key1=value1, key1=value11 и key2=value2.
# Keys not mentioned here are omitted while running the check.
- kind: queryMatches
expectedQuery: key1=value1&key2=value2&key1=value11
...
Expands queryMatches
so it can be used with regexp pattern matching.
Parameters:
expectedQuery
(mandatory) - a list of parameters to compare the parameter string to. The order of parameters is not important.
Example:
...
mocks:
service1:
requestConstraints:
# works similarly to queryMatches with an addition of $matchRegexp usage
- kind: queryMatchesRegexp
expectedQuery: key1=value1&key2=$matchRegexp(\\d+)&key1=value11
...
Checks that the request method corresponds to the expected one.
Parameters:
method
(mandatory) - string to compare the request method to.
There are also 2 short variations that don't require method
parameter:
methodIsGET
methodIsPOST
Example:
...
mocks:
service1:
requestConstraints:
- kind: methodIs
method: PUT
service2:
requestConstraints:
- kind: methodIsPOST
...
Checks that the request has the defined header and (optional) that its value either equals the pre-defined one or falls under the definition of a regular expression.
Parameters:
header
(mandatory) - name of the header that is expected with the request;value
- a string with the expected request header value;regexp
- a regular expression to check the header value against.
Examples:
...
mocks:
service1:
requestConstraints:
- kind: headerIs
header: Content-Type
value: application/json
service2:
requestConstraints:
- kind: headerIs
header: Content-Type
regexp: ^(application/json|text/plain)$
...
Checks that the request has the defined body text, or it falls under the definition of a regular expression.
Parameters:
body
- a string with the expected request body value;regexp
- a regular expression to check the body value against.
Examples:
...
mocks:
service1:
requestConstraints:
- kind: bodyMatchesText
body: |-
query HeroNameAndFriends {
hero {
name
friends {
name
}
}
}
service2:
requestConstraints:
- kind: bodyMatchesText
regexp: (HeroNameAndFriends)
...
Checks that the request body is XML, and it matches to the XML defined in the body
parameter.
Parameters:
body
(mandatory) - expected XML.
Example:
...
mocks:
service1:
requestConstraints:
- kind: bodyMatchesXML
body: |
<Person>
<Company>Hogwarts School of Witchcraft and Wizardry</Company>
<FullName>Harry Potter</FullName>
<Email where="work">[email protected]</Email>
<Email where="home">[email protected]</Email>
<Addr>4 Privet Drive</Addr>
<Group>
<Value>Hexes</Value>
<Value>Jinxes</Value>
</Group>
</Person>
...
Response strategies define what mock will response to incoming requests.
Empty strategy. All requests are served with 204 No Content
and empty body.
No parameters.
Example:
...
mocks:
service1:
strategy: nop
...
Returns a response read from a file.
Parameters:
filename
(mandatory) - name of the file that contains the response body;statusCode
- HTTP-code of the response, the default value is200
;headers
- response headers.
Example:
...
mocks:
service1:
strategy: file
filename: responses/service1_success.json
statusCode: 500
headers:
Content-Type: application/json
...
Returns a defined response.
Parameters:
body
(mandatory) - sets the response body;statusCode
- HTTP-code of the response, the default value is200
;headers
- response headers.
Example:
...
mocks:
service1:
strategy: constant
body: >
{
"status": "error",
"errorCode": -32884,
"errorMessage": "Internal error"
}
statusCode: 500
...
This strategy gives ability to use incoming request data into mock response.
Implemented with package text/template.
Automatically preload incoming request into variable named request
.
Parameters:
body
(mandatory) - sets the response body, must be validtext/template
string;statusCode
- HTTP-code of the response, the default value is200
;headers
- response headers.
Example:
...
mocks:
service1:
strategy: template
body: >
{
"value-from-query": {{ .request.Query "value" }},
"data-from-body": {{ default 10 .request.Json.data }}
}
statusCode: 200
...
Uses different response strategies, depending on a path of a requested resource.
When receiving a request for a resource that is not defined in the parameters, the test will be considered failed.
Parameters:
uris
(mandatory) - a list of resources, each resource can be configured as a separate mock-service using any available request constraints and response strategies (see example)basePath
- common base route for all resources, empty by default
Example:
...
mocks:
service1:
strategy: uriVary
basePath: /v2
uris:
/shelf/books:
strategy: file
filename: responses/books_list.json
statusCode: 200
/shelf/books/1:
strategy: constant
body: >
{
"error": "book not found"
}
statusCode: 404
...
Uses various response strategies, depending on the request method.
When receiving a request with a method not defined in methodVary, the test will be considered failed.
Parameters:
methods
(mandatory) - a list of methods, each method can be configured as a separate mock-service using any available request constraints and response strategies (see example)
Example:
...
mocks:
service1:
strategy: methodVary
methods:
GET:
# nothing stops us from using `uriVary` strategy here
# this way we can form different responses to different
# method+resource combinations
strategy: constant
body: >
{
"error": "book not found"
}
statusCode: 404
POST:
strategy: nop
statusCode: 204
...
With this strategy for each consequent request you will get a reply defined by a consequent nested strategy.
If no nested strategy specified for a request, i.e. arrived more requests than nested strategies specified, the test will be considered failed.
Parameters:
sequence
(mandatory) - list of nested strategies.
Example:
...
mocks:
service1:
strategy: sequence
sequence:
# Responds with a different text on each consequent request:
# "1" for first call, "2" for second call and so on.
# For 5th and later calls response will be 404 Not Found.
- strategy: constant
body: '1'
- strategy: constant
body: '2'
- strategy: constant
body: '3'
- strategy: constant
body: '4'
...
Allows multiple requests with same request path. Concurrent safe.
When receiving a request for a resource that is not defined in the parameters, the test will be considered failed.
Parameters:
uris
(mandatory) - a list of resources, each resource can be configured as a separate mock-service using any available request constraints and response strategies (see example)
Example:
...
mocks:
service1:
strategy: basedOnRequest
uris:
- strategy: constant
body: >
{
"ok": true
}
requestConstraints:
- kind: queryMatches
expectedQuery: "key=value1"
- kind: pathMatches
path: /request
- strategy: constant
body: >
{
"ok": true
}
requestConstraints:
- kind: queryMatches
expectedQuery: "key=value2"
- kind: pathMatches
path: /request
...
The strategy that by default drops the connection on any request. Used to emulate the network problems.
No parameters.
Example:
...
mocks:
service1:
strategy: dropRequest
...
You can define, how many times each mock or mock resource must be called (using uriVary
). If the actual number of calls is different from expected, the test will be considered failed.
Example:
...
mocks:
service1:
# must be called exactly one time
calls: 1
strategy: file
filename: responses/books_list.json
...
...
mocks:
service1:
strategy: uriVary
uris:
/shelf/books:
# must be called exactly one time
calls: 1
strategy: file
filename: responses/books_list.json
...
When the test is ran, operations are performed in the following order:
- Fixtures load
- Mocks setup
- beforeScript execute
- HTTP-request sent
- afterRequestScript execute
- The checks are ran
To define the script you need to provide 2 parameters:
path
(mandatory) - string with a path to the script file.timeout
- time in seconds, is responsible for stopping the script on timeout. The default value is3
.
Example:
...
afterRequestScript:
path: './cli_scripts/cmd_recalculate.sh'
# the timeout will be equal 10s
timeout: 10
...
...
beforeScript:
path: './cli_scripts/cmd_recalculate.sh'
# the timeout will be equal 10s
timeout: 10
...
...
beforeScript:
path: './cli_scripts/cmd_recalculate.sh'
# the timeout will equal 3s
...
When tests use parameterized requests, it's possible to use different scripts for each test run.
Example:
...
beforeScript:
path: |
./cli_scripts/{{.file_name}}
...
cases:
- requestArgs:
customer_id: 1
customer_email: "[email protected]"
responseArgs:
200:
rrr: 1
in_transit: 1
beforeScriptArgs:
file_name: "cmd_recalculate_customer_1.sh"
After HTTP request execution you can run an SQL query to DB to check the data changes. The response can contain several records. Those records are compared to the expected list of records.
You can use legacy style for run sql queries, like this:
- name: my test
...
dbQuery: >
SELECT ...
dbResponse:
- ...
- ...
But, for now, already acceptable style is:
- name: my test
...
dbChecks:
- dbQuery: >
SELECT ...
dbResponse:
- ...
With second variant, you can run any amount of needed queries, after test case runned. NOTE: All mentioned below techniques are still work with both variants of query format.
Query is a SELECT that returns any number of strings.
dbQuery
- a string that contains an SQL query.
Example:
...
dbQuery: >
SELECT code, purchase_date, partner_id FROM mark_paid_schedule AS m WHERE m.code = 'GIFT100000-000002'
...
The response is a list of JSON objects that the DB request should return.
dbResponse
- a string that contains a list of JSON objects.
Example:
...
dbResponse:
- '{"code":"GIFT100000-000002","purchase_date":"2330-02-02T13:15:11.912874","partner_id":1}'
- '{"code":"GIFT100000-000003","purchase_date":"2330-02-02T13:15:11.912874","partner_id":1}'
- '{"code":"$matchRegexp(GIFT([0-9]{6})-([0-9]{6}))","purchase_date":"2330-02-02T13:15:11.912874","partner_id":1}'
As you can see in this example, you can use Regexp for checking db response body.
...
dbResponse:
# empty list
As well as with the HTTP request body, we can use parameterized requests.
Example:
...
dbQuery: >
SELECT code, partner_id FROM mark_paid_schedule AS m WHERE DATE(m.purchase_date) BETWEEN '{{ .fromDate }}' AND '{{ .toDate }}'
dbResponse:
- '{"code":"{{ .cert1 }}","partner_id":1}'
- '{"code":"{{ .cert2 }}","partner_id":1}'
...
cases:
...
dbQueryArgs:
fromDate: "2330-02-01"
toDate: "2330-02-05"
dbResponseArgs:
cert1: "GIFT100000-000002"
cert2: "GIFT100000-000003"
When different tests contain different number of records, you can redefine the response for a specific test as a whole, while continuing to use a template with parameters in others.
Example:
...
dbQuery: >
SELECT code, partner_id FROM mark_paid_schedule AS m WHERE DATE(m.purchase_date) BETWEEN '{{ .fromDate }}' AND '{{ .toDate }}'
dbResponse:
- '{"code":"{{ .cert1 }}","partner_id":1}'
...
cases:
...
dbQueryArgs:
fromDate: "2330-02-01"
toDate: "2330-02-05"
dbResponseArgs:
cert1: "GIFT100000-000002"
...
dbQueryArgs:
fromDate: "2330-02-01"
toDate: "2330-02-05"
dbResponseFull:
- '{"code":"GIFT100000-000002","partner_id":1}'
- '{"code":"GIFT100000-000003","partner_id":1}'
You can use ignoreDbOrdering
flag in comparisonParams
section to toggle DB response ordering ignore feature.
This can be used to bypass using ORDER BY
operators in query.
ignoreDbOrdering
- true/false value.
Example:
comparisonParams:
ignoreDbOrdering: true
...
dbQuery: >
SELECT id, name, surname FROM users LIMIT 2
dbResponse:
- '{ "id": 2, "name": "John", "surname": "Doe" }'
- '{ "id": 1, "name": "Jane", "surname": "Doe" }'
Use file with schema to add syntax highlight to your favourite IDE and write Gonkey tests more easily.
It adds in-line documentation and auto-completion to any IDE that supports it.
Download file with schema. Open preferences File->Preferences In Languages & Frameworks > Schemas and DTDs > JSON Schema Mappings
Add new schema
Specify schema name, schema file, and select Schema version: Draft 7
After that add mapping. You can choose from single file, directory, or file mask.
Choose what suits you best.
Save your preferences. If you done everything right, you should not see No JSON Schema in bottom right corner
Instead, you should see your schema name
At first, you need to download YAML Language plugin Open Extensions by going to Code(File)->Preferences->Extensions
Look for YAML and install YAML Language Support by Red Hat
Open Settings by going to Code(File)->Preferences->Settings
Open Schema Settings by typing YAML:Schemas and click on Edit in settings.json
Add file match to apply the JSON on YAML files.
"yaml.schemas": {
"C:\\Users\\Leo\\gonkey.json": ["*.gonkey.yaml"]
}
In the example above the JSON schema stored in C:\Users\Leo\gonkey.json will be applied on all the files that ends with .gonkey.yaml