CATS – REST API Fuzzer And Negative Testing Tool For OpenAPI Endpoints
REST API fuzzer and negative testing tool. Run thousands of self-healing API tests within minutes with no coding effort!
- Comprehensive: tests are generated automatically based on a large number scenarios and cover every field and header
- Intelligent: tests are generated based on data types and constraints; each Fuzzer have specific expectations depending on the scenario under test
- Highly Configurable: high amount of customization: you can exclude specific Fuzzers, HTTP response codes, provide business context and a lot more
- Self-Healing: as tests are generated, any OpenAPI spec change is picked up automatically
- Simple to Learn: flat learning curve, with intuitive configuration and syntax
- Fast: automatic process for write, run and report tests which covers thousands of scenarios within minutes
Overview
By using a simple and minimal syntax, with a flat learning curve, CATS (Contract Auto-generated Tests for Swagger) enables you to generate thousands of API tests within minutes with no coding effort. All tests are generated, run and reported automatically based on a pre-defined set of 89 Fuzzers. The Fuzzers cover a wide range of input data from fully random large Unicode values to well crafted, context dependant values based on the request data types and constraints. Even more, you can leverage the fact that CATS generates request payloads dynamically and write simple end-to-end functional tests.
Please check the Slicing Strategies section for making CATS run fast and comprehensive in the same time.
Tutorials on how to use CATS
This is a list of articles with step-by-step guides on how to use CATS:
- Testing the GitHub API with CATS
- How to write self-healing functional tests with no coding effort
Some bugs found by CATS
- hashicorp/vault#13274 | hashicorp/vault#13273
- hashicorp/vault#13225 | hashicorp/vault#13232
- go-gitea/gitea#19397 | go-gitea/gitea#19398
- go-gitea/gitea#19399
Installation
Homebrew
> brew tap endava/tap
> brew install cats
Manual
CATS is bundled both as an executable JAR or a native binary. The native binaries do not need Java installed.
After downloading your OS native binary, you can add it in classpath so that you can execute it as any other command line tool:
sudo cp cats /usr/local/bin/cats
You can also get autocomplete by downloading the cats_autocomplete script and do:
source cats_autocomplete
To get persistent autocomplete, add the above line in ~/.zshrc
or ./bashrc
, but make sure you put the fully qualified path for the cats_autocomplete
script.
You can also check the cats_autocomplete
source for alternative setup.
There is no native binary for Windows, but you can use the uberjar version. This requires Java 11+ to be installed.
You can run it as java -jar cats.jar
.
Head to the releases page to download the latest versions: https://github.com/Endava/cats/releases.
Build
You can build CATS from sources on you local box. You need Java 11+. Maven is already bundled.
Before running the first build, please make sure you do a ./mvnw clean
. CATS uses a fork ok OKHttpClient
which will install locally under the 4.9.1-CATS
version, so don’t worry about overriding the official versions.
You can use the following Maven command to build the project:
./mvnw package -Dquarkus.package.type=uber-jar
cp target/
You will end up with a cats.jar
in the target
folder. You can run it wih java -jar cats.jar ...
.
You can also build native images using a GraalVM Java version.
./mvnw package -Pnative
Note: You will need to configure Maven with a Github PAT with read-packages
scope to get some dependencies for the build.
Notes on Unit Tests
You may see some ERROR
log messages while running the Unit Tests. Those are expected behaviour for testing the negative scenarios of the Fuzzers
.
Running CATS
Blackbox mode
Blackbox mode means that CATS doesn’t need any specific context. You just need to provide the service URL, the OpenAPI spec and most probably authentication headers.
> cats --contract=openapy.yaml --server=http://localhost:8080 --headers=headers.yml --blackbox
In blackbox mode CATS will only report ERRORs
if the received HTTP response code is a 5XX
. Any other mismatch between what the Fuzzer expects vs what the service returns (for example service returns 400
and service returns 200
) will be ignored.
The blackbox mode is similar to a smoke test. It will quickly tell you if the application has major bugs that must be addressed immediately.
Context mode
The real power of CATS relies on running it in a non-blackbox mode also called context mode. Each Fuzzer has an expected HTTP response code based on the scenario under test and will also check if the response is matching the schema defined in the OpenAPI spec specific to that response code. This will allow you to tweak either your OpenAPI spec or service behaviour in order to create good quality APIs and documentation and also to avoid possible serious bugs.
Running CATS in context mode usually implies providing it a –refData file with resource identifiers specific to the business logic. CATS cannot create data on its own (yet), so it’s important that any request field or query param that requires pre-existence of those entities/resources to be created in advance and added to the reference data file.
> cats --contract=openapy.yaml --server=http://localhost:8080 --headers=headers.yml --refData=referenceData.yml
Notes on skipped Tests
You may notice a significant number of tests marked as skipped
. CATS will try to apply all Fuzzers
to all fields, but this is not always possible. For example the BooleanFieldsFuzzer
cannot be applied to String
fields. This is why that test attempt will be marked as skipped. It was an intentional decision to also report the skipped
tests in order to show that CATS actually tries all the Fuzzers
on all the fields/paths/endpoints.
Additionally, CATS support a lot more arguments that allows you to restrict the number of fuzzers, provide timeouts, limit the number of requests per minute and so on.
Understanding how CATS works and reports results
CATS generates tests based on configured Fuzzer
s. Each Fuzzer
has a specific scenario and a specific expected result. The CATS engine will run the scenario, get the result from the service and match it with the Fuzzer
expected result. Depending on the matching outcome, CATS will report as follows:
INFO
/SUCCESS
is expected and documented behaviour. No need for action.WARN
is expected but undocumented behaviour or some misalignment between the contract and the service. This will ideally be actioned.ERROR
is abnormal/unexpected behaviour. This must be actioned.
CATS will iterate through all endpoints, all HTTP methods and all the associated requests bodies and parameters (including multiple combinations when dealing with oneOf
/anyOf
elements) and fuzz their values considering their defined data type and constraints. The actual fuzzing depends on the specific Fuzzer
executed. Please see the list of fuzzers and their behaviour. There are also differences on how the fuzzing works depending on the HTTP method:
- for methods with request bodies like POST, PUT the fuzzing will be applied at the request body data models level
- for methods without request bodies like GET, DELETE the fuzzing will be applied at the URL parameters level
This means that for methods with request bodies (POST,PUT
) that have also URL/path parameters, you need to supply the path
parameters via urlParams
or the referenceData
file as failure to do so will result in Illegal character in path at index ...
errors.
Interpreting Results
HTML_JS
HTML_JS
is the default report produced by CATS. The execution report in placed a folder called cats-report/TIMESTAMP
or cats-report
depending on the --timestampReports
argument. The folder will be created inside the current folder (if it doesn’t exist) and for each run a new subfolder will be created with the TIMESTAMP
value when the run started. This allows you to have a history of the runs. The report itself is in the index.html
file, where you can:
- filter test runs based on the result:
All
,Success
,Warn
andError
- filter based on the
Fuzzer
so that you can only see the runs for that specificFuzzer
- see summary with all the tests with their corresponding path against they were run, and the result
- have ability to click on any tests and get details about the Scenario being executed, Expected Result, Actual result as well as request/response details
Along with the summary from index.html
each individual test will have a specific TestXXX.html
page with more details, as well as a json version of the test which can be latter replayed using > cats replay TestXXX.json
.
Understanding the Result Reason
values:
Unexpected Exception
– reported aserror
; this might indicate a possible bug in the service or a corner case that is not handled correctly by CATSNot Matching Response Schema
– reported as awarn
; this indicates that the service returns an expected response code and a response body, but the response body does not match the schema defined in the contractUndocumented Response Code
– reported as awarn
; this indicates that the service returns an expected response code, but the response code is not documented in the contractUnexpected Response Code
– reported as anerror
; this indicates a possible bug in the service – the response code is documented, but is not expected for this scenarioUnexpected Behaviour
– reported as anerror
; this indicates a possible bug in the service – the response code is neither documented nor expected for this scenarioNot Found
– reported as anerror
in order to force providing more context; this indicates that CATS needs additional business context in order to run successfully – you can do this using the--refData
and/or--urlParams
arguments
This is the summary page:
And this is what you get when you click on a specific test:
HTML_ONLY
This format is similar with HTML_JS
, but you cannot do any filtering or sorting.
JUNIT
CATS also supports JUNIT output. The output will be a single testsuite
that will incorporate all tests grouped by Fuzzer
name. As the JUNIT format does not have the concept of warning
the following mapping is used:
- CATS
error
is reported as JUNITerror
- JUNIT
failure
is not used at all - CATS
warn
is reported as JUNITskipped
- CATS
skipped
is reported as JUNITdisabled
The JUNIT report is written as junit.xml
in the cats-report
folder. Individual tests, both as .html
and .json
will also be created.
Slicing Strategies for Running Cats
CATS has a significant number of Fuzzers
. Currently, 89 and growing. Some of the Fuzzers
are executing multiple tests for every given field within the request. For example the ControlCharsOnlyInFieldsFuzzer
has 63 control chars values that will be tried for each request field. If a request has 15 fields for example, this will result in 1020 tests. Considering that there are additional Fuzzers
with the same magnitude of tests being generated, you can easily get to 20k tests being executed on a typical run. This will result in huge reports and long run times (i.e. minutes, rather than seconds).
Below are some recommended strategies on how you can separate the tests in chunks which can be executed as stages in a deployment pipeline, one after the other.
Split by Endpoints
You can use the --paths=PATH
argument to run CATS sequentially for each path.
Split by Fuzzer Category
You can use the --checkXXX
arguments to run CATS only with specific Fuzzers
like: --checkHttp
, -checkFields
, etc.
Split by Fuzzer Type
You can use various arguments like --fuzzers=Fuzzer1,Fuzzer2
or -skipFuzzers=Fuzzer1,Fuzzer2
to either include or exclude specific Fuzzers
. For example, you can run all Fuzzers
except for the ControlChars
and Whitespaces
ones like this: --skipFuzzers=ControlChars,Whitesspaces
. This will skip all Fuzzers containing these strings in their name. After, you can create an additional run only with these Fuzzers
: --fuzzers=ControlChars,Whitespaces
.
These are just some recommendations on how you can split the types of tests cases. Depending on how complex your API is, you might go with a combination of the above or with even more granular splits.
Please note that due to the fact that ControlChars, Emojis and Whitespaces
generate huge number of tests even for small OpenAPI contracts, they are disabled by default. You can enable them using the --includeControlChars
, --includeWhitespaces
and/or --includeEmojis
arguments. The recommendation is to run them in separate runs so that you get manageable reports and optimal running times.
Ignoring Specific HTTP Responses
By default, CATS will report WARNs
and ERRORs
according to the specific behaviour of each Fuzzer. There are cases though when you might want to focus only on critical bugs. You can use the --ignoreResponseXXX
arguments to supply a list of response codes, response sizes, word counts, line counts or response body regexes that should be ignored as issues (overriding the Fuzzer behaviour) and report those cases as success instead or WARN
or ERROR
. For example, if you want CATS to report ERRORs
only when there is an Exception or the service returns a 500
, you can use this: --ignoreResultCodes="2xx,4xx"
.
Ignoring Undocumented Response Code Checks
You can also choose to ignore checks done by the Fuzzers. By default, each Fuzzer has an expected response code, based on the scenario under test and will report and WARN
the service returns the expected response code, but the response code is not documented inside the contract. You can make CATS ignore the undocumented response code checks (i.e. checking expected response code inside the contract) using the --ignoreResponseCodeUndocumentedCheck
argument. CATS with now report these cases as SUCCESS
instead of WARN
.
Ignoring Response Body Checks
Additionally, you can also choose to ignore the response body checks. By default, on top of checking the expected response code, each Fuzzer will check if the response body matches what is defined in the contract and will report an WARN
if not matching. You can make CATS ignore the response body checks using the --ingoreResponseBodyCheck
argument. CATS with now report these cases as SUCCESS
instead of WARN
.
Replaying Tests
When CATS runs, for each test, it will export both an HTML file that will be linked in the final report and individual JSON files. The JSON files can be used to replay that test. When replaying a test (or a list of tests), CATS won’t produce any report. The output will be solely available in the console. This is useful when you want to see the exact behaviour of the specific test or attach it in a bug report for example.
The syntax for replaying tests is the following:
> cats replay "Test1,Test233,Test15.json,dir/Test19.json"
Some notes on the above example:
- test names can be separated by comma
,
- if you provide a json extension to a test name, that file will be search as a path i.e. it will search for
Test15.json
in the current folder andTest19.json
in thedir
folder - if you don’t provide a json extension to a test name, it will search for that test in the
cats-report
folder i.e.cats-report/Test1.json
andcats-report/Test233.json
Available Commands
To list all available commands, run:
> cats -h
All available subcommands are listed below:
-
> cats help
orcats -h
will list all available options -
> cats list --fuzzers
will list all the existing fuzzers, grouped on categories -
> cats list --fieldsFuzzingStrategy
will list all the available fields fuzzing strategies -
> cats list --paths --contract=CONTRACT
will list all the paths available within the contract -
> cats replay "test1,test2"
will replay the given teststest1
andtest2
-
> cats fuzz
will fuzz based on a given request template, rather than an OpenAPI contract -
> cats run
will run functional and targeted security tests written in the CATS YAML format -
> cats lint
will run OpenAPI contract linters, also calledContractInfoFuzzers
Available arguments
--contract=LOCATION_OF_THE_CONTRACT
supplies the location of the OpenApi or Swagger contract.--server=URL
supplies the URL of the service implementing the contract.--basicauth=USR:PWD
supplies ausername:password
pair, in case the service uses basic auth.--fuzzers=LIST_OF_FUZZERS
supplies a comma separated list of fuzzers. The supplied list of Fuzzers can be partial names, not full Fuzzer names. CATS which check for all Fuzzers containing the supplied strings. If the argument is not supplied, all fuzzers will be run.--log=PACKAGE:LEVEL
can configure custom log level for a given package. You can provide a comma separated list of packages and levels. This is helpful when you want to see full HTTP traffic:--log=org.apache.http.wire:debug
or suppress CATS logging:--log=com.endava.cats:warn
--paths=PATH_LIST
supplies a comma separated list of OpenApi paths to be tested. If no path is supplied, all paths will be considered.--skipPaths=PATH_LIST
a comma separated list of paths to ignore. If no path is supplied, no path will be ignored--fieldsFuzzingStrategy=STRATEGY
specifies which strategy will be used for field fuzzing. Available strategies areONEBYONE
,SIZE
andPOWERSET
. More information on field fuzzing can be found in the sections below.--maxFieldsToRemove=NUMBER
specifies the maximum number of fields to be removed when using theSIZE
fields fuzzing strategy.--refData=FILE
specifies the file containing static reference data which must be fixed in order to have valid business requests. This is a YAML file. It is explained further in the sections below.--headers=FILE
specifies a file containing headers that will be added when sending payloads to the endpoints. You can use this option to add oauth/JWT tokens for example.--edgeSpacesStrategy=STRATEGY
specifies how to expect the server to behave when sending trailing and prefix spaces within fields. Possible values aretrimAndValidate
andvalidateAndTrim
.--sanitizationStrategy=STRATEGY
specifies how to expect the server to behave when sending Unicode Control Chars and Unicode Other Symbols within the fields. Possible values aresanitizeAndValidate
andvalidateAndSanitize
--urlParams
A comma separated list of ‘name:value’ pairs of parameters to be replaced inside the URLs. This is useful when you have static parameters in URLs (like ‘version’ for example).--functionalFuzzerFile
a file used by theFunctionalFuzzer
that will be used to create user-supplied payloads.--skipFuzzers=LIST_OF_FIZZERs
a comma separated list of fuzzers that will be skipped for all paths. You can either provide fullFuzzer
names (for example:--skippedFuzzers=VeryLargeStringsFuzzer
) or partialFuzzer
names (for example:--skipFuzzers=VeryLarge
).CATS
will check if theFuzzer
names contains the string you provide in the arguments value.--skipFields=field1,field2#subField1
a comma separated list of fields that will be skipped by replacement Fuzzers like EmptyStringsInFields, NullValuesInFields, etc.--httpMethods=PUT,POST,etc
a comma separated list of HTTP methods that will be used to filter which http methods will be executed for each path within the contract--securityFuzzerFile
A file used by theSecurityFuzzer
that will be used to inject special strings in order to exploit possible vulnerabilities--printExecutionStatistics
If supplied (no value needed), prints a summary of execution times for each endpoint and HTTP method. By default this will print a summary for each endpoint: max, min and average. If you want detailed reports you must supply--printExecutionStatistics=detailed
--timestampReports
If supplied (no value needed), it will output the report still inside thecats-report
folder, but in a sub-folder with the current timestamp--reportFormat=FORMAT
Specifies the format of the CATS report. Supported formats:HTML_ONLY
,HTML_JS
orJUNIT
. You can useHTML_ONLY
if you want the report to not contain any Javascript. This is useful in CI environments due to Javascript content security policies. Default isHTML_JS
which includes some sorting and filtering capabilities.--useExamples
Iftrue
(default value when not supplied) then CATS will use examples supplied in the OpenAPI contact. Iffalse
CATS will rely only on generated values--checkFields
If supplied (no value needed), it will only run the Field Fuzzers--checkHeaders
If supplied (no value needed), it will only run the Header Fuzzers--checkHttp
If supplied (no value needed), it will only run the HTTP Fuzzers--includeWhitespaces
If supplied (no value needed), it will include the Whitespaces Fuzzers--includeEmojis
If supplied (no value needed), it will include the Emojis Fuzzers--includeControlChars
If supplied (no value needed), it will include the ControlChars Fuzzers--includeContract
If supplied (no value needed), it will includeContractInfoFuzzers
--sslKeystore
Location of the JKS keystore holding certificates used when authenticating calls using one-way or two-way SSL--sslKeystorePwd
The password of thesslKeystore
--sslKeyPwd
The password of the private key from thesslKeystore
--proxyHost
The proxy server’s host name (if running behind proxy)--proxyPort
The proxy server’s port number (if running behind proxy)--maxRequestsPerMinute
Maximum number of requests per minute; this is useful when APIs have rate limiting implemented; default is 10000--connectionTimeout
Time period in seconds which CATS should establish a connection with the server; default is 10 seconds--writeTimeout
Maximum time of inactivity in seconds between two data packets when sending the request to the server; default is 10 seconds--readTimeout
Maximum time of inactivity in seconds between two data packets when waiting for the server’s response; default is 10 seconds--dryRun
If provided, it will simulate a run of the service with the supplied configuration. The run won’t produce a report, but will show how many tests will be generated and run for each OpenAPI endpoint--ignoreResponseCodes
HTTP_CODES_LIST a comma separated list of HTTP response codes that will be considered as SUCCESS, even if the Fuzzer will typically report it as WARN or ERROR. You can use response code families as2xx
,4xx
, etc. If provided, all Contract Fuzzers will be skipped.--ignoreResponseSize
SIZE_LIST a comma separated list of response sizes that will be considered as SUCCESS, even if the Fuzzer will typically report it as WARN or ERROR--ignoreResponseWords
COUNT_LIST a comma separated list of words count in the response that will be considered as SUCCESS, even if the Fuzzer will typically report it as WARN or ERROR--ignoreResponseLines
LINES_COUNT a comma separated list of lines count in the response that will be considered as SUCCESS, even if the Fuzzer will typically report it as WARN or ERROR--ignoreResponseRegex
a REGEX that will match against the response that will be considered as SUCCESS, even if the Fuzzer will typically report it as WARN or ERROR--tests
TESTS_LIST a comma separated list of executed tests in JSON format from the cats-report folder. If you supply the list without the .json extension CATS will search the test in the cats-report folder--ignoreResponseCodeUndocumentedCheck
If supplied (not value needed) it won’t check if the response code received from the service matches the value expected by the fuzzer and will return the test result as SUCCESS instead of WARN--ignoreResponseBodyCheck
If supplied (not value needed) it won’t check if the response body received from the service matches the schema supplied inside the contract and will return the test result as SUCCESS instead of WARN--blackbox
If supplied (no value needed) it will ignore all response codes except for 5XX which will be returned as ERROR. This is similar to--ignoreResponseCodes="2xx,4xx"
--contentType
A custom mime type if the OpenAPI spec uses content type negotiation versioning.--outoput
The path where the CATS report will be written. Default iscats-report
in the current directory--skipReportingForIgnoredCodes
Skip reporting entirely for the any ignored arguments provided in--ignoreResponseXXX
> cats --contract=my.yml --server=https://locathost:8080 --checkHeaders
This will run CATS against http://localhost:8080
using my.yml
as an API spec and will only run the HTTP headers Fuzzers
.
Available Fuzzers
To get a list of fuzzers run cats list --fuzzers
. A list of all available fuzzers will be returned, along with a short description for each.
There are multiple categories of Fuzzers
available:
Field Fuzzers
which target request body fields or path parametersHeader Fuzzers
which target HTTP headersHTTP Fuzzers
which target just the interaction with the service (without fuzzing fields or headers)
Additional checks which are not actually using any fuzzing, but leverage the CATS internal model of running the tests as Fuzzers
:
ContractInfo Fuzzers
which checks the contract for API good practicesSpecial Fuzzers
a special category which need further configuration and are focused on more complex activities like functional flow, security testing or supplying your own request templates, rather than OpenAPI specs
Field Fuzzers
CATS
has currently 42 registered Field Fuzzers
:
BooleanFieldsFuzzer
– iterate through each Boolean field and send random strings in the targeted fieldDecimalFieldsLeftBoundaryFuzzer
– iterate through each Number field (either float or double) and send requests with outside the range values on the left side in the targeted fieldDecimalFieldsRightBoundaryFuzzer
– iterate through each Number field (either float or double) and send requests with outside the range values on the right side in the targeted fieldDecimalValuesInIntegerFieldsFuzzer
– iterate through each Integer field and send requests with decimal values in the targeted fieldEmptyStringValuesInFieldsFuzzer
– iterate through each field and send requests with empty String values in the targeted fieldExtremeNegativeValueDecimalFieldsFuzzer
– iterate through each Number field and send requests with the lowest value possible (-999999999999999999999999999999999999999999.99999999999 for no format, -3.4028235E38 for float and -1.7976931348623157E308 for double) in the targeted fieldExtremeNegativeValueIntegerFieldsFuzzer
– iterate through each Integer field and send requests with the lowest value possible (-9223372036854775808 for int32 and -18446744073709551616 for int64) in the targeted fieldExtremePositiveValueDecimalFieldsFuzzer
– iterate through each Number field and send requests with the highest value possible (999999999999999999999999999999999999999999.99999999999 for no format, 3.4028235E38 for float and 1.7976931348623157E308 for double) in the targeted fieldExtremePositiveValueInIntegerFieldsFuzzer
– iterate through each Integer field and send requests with the highest value possible (9223372036854775807 for int32 and 18446744073709551614 for int64) in the targeted fieldIntegerFieldsLeftBoundaryFuzzer
– iterate through each Integer field and send requests with outside the range values on the left side in the targeted fieldIntegerFieldsRightBoundaryFuzzer
– iterate through each Integer field and send requests with outside the range values on the right side in the targeted fieldInvalidValuesInEnumsFieldsFuzzer
– iterate through each ENUM field and send invalid valuesLeadingWhitespacesInFieldsTrimValidateFuzzer
– iterate through each field and send requests with Unicode whitespaces and invisible separators prefixing the current value in the targeted fieldLeadingControlCharsInFieldsTrimValidateFuzzer
– iterate through each field and send requests with Unicode control chars prefixing the current value in the targeted fieldLeadingSingleCodePointEmojisInFieldsTrimValidateFuzzer
– iterate through each field and send values prefixed with single code points emojisLeadingMultiCodePointEmojisInFieldsTrimValidateFuzzer
– iterate through each field and send values prefixed with multi code points emojisMaxLengthExactValuesInStringFieldsFuzzer
– iterate through each String fields that have maxLength declared and send requests with values matching the maxLength size/value in the targeted fieldMaximumExactValuesInNumericFieldsFuzzer
– iterate through each Number and Integer fields that have maximum declared and send requests with values matching the maximum size/value in the targeted fieldMinLengthExactValuesInStringFieldsFuzzer
– iterate through each String fields that have minLength declared and send requests with values matching the minLength size/value in the targeted fieldMinimumExactValuesInNumericFieldsFuzzer
– iterate through each Number and Integer fields that have minimum declared and send requests with values matching the minimum size/value in the targeted fieldNewFieldsFuzzer
– send a ‘happy’ flow request and add a new field inside the request called ‘catsFuzzyField’NullValuesInFieldsFuzzer
– iterate through each field and send requests with null values in the targeted fieldOnlyControlCharsInFieldsTrimValidateFuzzer
– iterate through each field and send values with control chars onlyOnlyWhitespacesInFieldsTrimValidateFuzzer
– iterate through each field and send values with unicode separators onlyOnlySingleCodePointEmojisInFieldsTrimValidateFuzzer
– iterate through each field and send values with single code point emojis onlyOnlyMultiCodePointEmojisInFieldsTrimValidateFuzzer
– iterate through each field and send values with multi code point emojis onlyRemoveFieldsFuzzer
– iterate through each request fields and remove certain fields according to the supplied ‘fieldsFuzzingStrategy’StringFieldsLeftBoundaryFuzzer
– iterate through each String field and send requests with outside the range values on the left side in the targeted fieldStringFieldsRightBoundaryFuzzer
– iterate through each String field and send requests with outside the range values on the right side in the targeted fieldStringFormatAlmostValidValuesFuzzer
– iterate through each String field and get its ‘format’ value (i.e. email, ip, uuid, date, datetime, etc); send requests with values which are almost valid (i.e. email@yhoo. for email, 888.1.1. for ip, etc) in the targeted fieldStringFormatTotallyWrongValuesFuzzer
– iterate through each String field and get its ‘format’ value (i.e. email, ip, uuid, date, datetime, etc); send requests with values which are totally wrong (i.e. abcd for email, 1244. for ip, etc) in the targeted fieldStringsInNumericFieldsFuzzer
– iterate through each Integer (int, long) and Number field (float, double) and send requests having thefuzz
string value in the targeted fieldTrailingWhitespacesInFieldsTrimValidateFuzzer
– iterate through each field and send requests with trailing with Unicode whitespaces and invisible separators in the targeted fieldTrailingControlCharsInFieldsTrimValidateFuzzer
– iterate through each field and send requests with trailing with Unicode control chars in the targeted fieldTrailingSingleCodePointEmojisInFieldsTrimValidateFuzzer
– iterate through each field and send values trailed with single code point emojisTrailingMultiCodePointEmojisInFieldsTrimValidateFuzzer
– iterate through each field and send values trailed with multi code point emojisVeryLargeStringsFuzzer
– iterate through each String field and send requests with very large values (40000 characters) in the targeted fieldWithinControlCharsInFieldsSanitizeValidateFuzzer
– iterate through each field and send values containing unicode control charsWithinSingleCodePointEmojisInFieldsTrimValidateFuzzer
– iterate through each field and send values containing single code point emojisWithinMultiCodePointEmojisInFieldsTrimValidateFuzzer
– iterate through each field and send values containing multi code point emojisZalgoTextInStringFieldsValidateSanitizeFuzzer
– iterate through each field and send values containing zalgo text
You can run only these Fuzzers
by supplying the --checkFields
argument.
Header Fuzzers
CATS
has currently 28 registered Header Fuzzers
:
AbugidasCharsInHeadersFuzzer
– iterate through each header and send requests with abugidas chars in the targeted headerCheckSecurityHeadersFuzzer
– check all responses for good practices around Security related headers like: [{name=Cache-Control, value=no-store}, {name=X-XSS-Protection, value=1; mode=block}, {name=X-Content-Type-Options, value=nosniff}, {name=X-Frame-Options, value=DENY}]DummyAcceptHeadersFuzzer
– send a request with a dummy Accept header and expect to get 406 codeDummyContentTypeHeadersFuzzer
– send a request with a dummy Content-Type header and expect to get 415 codeDuplicateHeaderFuzzer
– send a ‘happy’ flow request and duplicate an existing headerEmptyStringValuesInHeadersFuzzer
– iterate through each header and send requests with empty String values in the targeted headerExtraHeaderFuzzer
– send a ‘happy’ flow request and add an extra field inside the request called ‘Cats-Fuzzy-Header’LargeValuesInHeadersFuzzer
– iterate through each header and send requests with large values in the targeted headerLeadingControlCharsInHeadersFuzzer
– iterate through each header and prefix values with control charsLeadingWhitespacesInHeadersFuzzer
– iterate through each header and prefix value with unicode separatorsLeadingSpacesInHeadersFuzzer
– iterate through each header and send requests with spaces prefixing the value in the targeted headerRemoveHeadersFuzzer
– iterate through each header and remove different combinations of themOnlyControlCharsInHeadersFuzzer
– iterate through each header and replace value with control charsOnlySpacesInHeadersFuzzer
– iterate through each header and replace value with spacesOnlyWhitespacesInHeadersFuzzer
– iterate through each header and replace value with unicode separatorsTrailingSpacesInHeadersFuzzer
– iterate through each header and send requests with trailing spaces in the targeted headerTrailingControlCharsInHeadersFuzzer
– iterate through each header and trail values with control charsTrailingWhitespacesInHeadersFuzzer
– iterate through each header and trail values with unicode separatorsUnsupportedAcceptHeadersFuzzer
– send a request with an unsupported Accept header and expect to get 406 codeUnsupportedContentTypesHeadersFuzzer
– send a request with an unsupported Content-Type header and expect to get 415 codeZalgoTextInHeadersFuzzer
– iterate through each header and send requests with zalgo text in the targeted header
You can run only these Fuzzers
by supplying the --checkHeaders
argument.
HTTP Fuzzers
CATS
has currently 6 registered HTTP Fuzzers
:
BypassAuthenticationFuzzer
– check if an authentication header is supplied; if yes try to make requests without itDummyRequestFuzzer
– send a dummy json request {‘cats’: ‘cats’}HappyFuzzer
– send a request with all fields and headers populatedHttpMethodsFuzzer
– iterate through each undocumented HTTP method and send an empty requestMalformedJsonFuzzer
– send a malformed json request which has the String ‘bla’ at the endNonRestHttpMethodsFuzzer
– iterate through a list of HTTP method specific to the WebDav protocol that are not expected to be implemented by REST APIs
You can run only these Fuzzers
by supplying the --checkHttp
argument.
ContractInfo Fuzzers or OpenAPI Linters
Usually a good OpenAPI contract must follow several good practices in order to make it easy digestible by the service clients and act as much as possible as self-sufficient documentation:
- follow good practices around naming the contract elements like paths, requests, responses
- always use plural for the path names, separate paths words through hyphens/underscores, use camelCase or snake_case for any
json
types and properties - provide tags for all operations in order to avoid breaking code generation on some languages and have a logical grouping of the API operations
- provide good description for all paths, methods and request/response elements
- provide meaningful responses for
POST
,PATCH
andPUT
requests - provide examples for all requests/response elements
- provide structural constraints for (ideally) all request/response properties (min, max, regex)
- heaver some sort of
CorrelationIds/TraceIds
within headers - have at least a security schema in place
- avoid having the API version part of the paths
- document response codes for both “happy” and “unhappy” flows
- avoid using
xml
payload unless there is a really good reason (like documenting an old API for example) - json types and properties do not use the same naming (like having a
Pet
with a property namedpet
)
CATS
has currently 9 registered ContractInfo Fuzzers
:
HttpStatusCodeInValidRangeFuzzer
– verifies that all HTTP response codes are within the range of 100 to 599NamingsContractInfoFuzzer
– verifies that all OpenAPI contract elements follow REST API naming good practicesPathTagsContractInfoFuzzer
– verifies that all OpenAPI paths contain tags elements and checks if the tags elements match the ones declared at the top levelRecommendedHeadersContractInfoFuzzer
– verifies that all OpenAPI contract paths contain recommended headers like: CorrelationId/TraceId, etc.RecommendedHttpCodesContractInfoFuzzer
– verifies that the current path contains all recommended HTTP response codes for all operationsSecuritySchemesContractInfoFuzzer
– verifies if the OpenApi contract contains valid security schemas for all paths, either globally configured or per pathTopLevelElementsContractInfoFuzzer
– verifies that all OpenAPI contract level elements are present and provide meaningful information: API description, documentation, title, version, etc.VersionsContractInfoFuzzer
– verifies that a given path doesn’t contain versioning informationXmlContentTypeContractInfoFuzzer
– verifies that all OpenAPI contract paths responses and requests does not offerapplication/xml
as a Content-Type
You can run only these Fuzzers
using > cats lint --contract=CONTRACT
.
Special Fuzzers
FunctionalFuzzer
Writing Custom Tests
You can leverage CATS super-powers of self-healing and payload generation in order to write functional tests. This is achieved using the so called FunctionaFuzzer
, which is not a Fuzzer
per se, but was named as such for consistency. The functional tests are written in a YAML file using a simple DSL. The DSL supports adding identifiers, descriptions, assertions as well as passing variables between tests. The cool thing is that, by leveraging the fact that CATS generates valid payload, you only need to override values for specific fields. The rest of the information will be populated by CATS
using valid data, just like a ‘happy’ flow request.
It’s important to note that reference data
won’t get replaced when using the FunctionalFuzzer
. So if there are reference data fields, you must also supply those in the FunctionalFuzzer
.
The FunctionalFuzzer
will only trigger if a valid functionalFuzzer.yml
file is supplied. The file has the following syntax:
/path:
testNumber:
description: Short description of the test
prop: value
prop#subprop: value
prop7:
- value1
- value2
- value3
oneOfSelection:
element#type: "Value"
expectedResponseCode: HTTP_CODE
httpMethod: HTTP_NETHOD
And a typical run will look like:
> cats run functionalFuzzer.yml -c contract.yml -s http://localhost:8080
This is a description of the elements within the functionalFuzzer.yml
file:
- you can supply a
description
of the test. This will be set as theScenario
description. If you don’t supply adescription
thetestNumber
will be used instead. - you can have multiple tests under the same path:
test1
,test2
, etc. expectedResponseCode
is mandatory, otherwise theFuzzer
will ignore this test. TheexpectedResponseCode
tells CATS what to expect from the service when sending this test.- at most one of the properties can have multiple values. When this situation happens, that test will actually become a list of tests one for each of the values supplied. For example in the above example
prop7
has 3 values. This will actually result in 3 tests, one for each value. - test within the file are executed in the declared order. This is why you can have outputs from one test act as inputs for the next one(s) (see the next section for details).
- if the supplied
httpMethod
doesn’t exist in the OpenAPI given path, awarning
will be issued and no test will be executed - if the supplied
httpMethod
is not a valid HTTP method, awarning
will be issued and no test will be executed - if the request payload uses a
oneOf
element to allow multiple request types, you can control which of the possible types theFunctionalFuzzer
will apply to using theoneOfSelection
keyword. The value of theoneOfSelection
keyword must match the fully qualified name of thediscriminator
. - if no
oneOfSelection
is supplied, and the request payload accepts multipleoneOf
elements, than a custom test will be created for each type of payload - the file uses Json path syntax for all the properties you can supply; you can separate elements through
#
as in the example above instead of.
Dealing with oneOf, anyOf
When you have request payloads which can take multiple object types, you can use the oneOfSelection
keyword to specify which of the possible object types is required by the FunctionalFuzzer
. If you don’t provide this element, all combinations will be considered. If you supply a value, this must be exactly the one used in the discriminator
.
Correlating Tests
As CATs mostly relies on generated data with small help from some reference data, testing complex business scenarios with the pre-defined Fuzzers
is not possible. Suppose we have an endpoint that creates data (doing a POST
), and we want to check its existence (via GET
). We need a way to get some identifier from the POST call and send it to the GET call. This is now possible using the FunctionalFuzzer
. The functionalFuzzerFile
can have an output
entry where you can state a variable name, and its fully qualified name from the response in order to set its value. You can then refer the variable using ${variable_name}
from another test in order to use its value.
Here is an example:
/pet:
test_1:
description: Create a Pet
httpMethod: POST
name: "My Pet"
expectedResponseCode: 200
output:
petId: pet#id
/pet/{id}:
test_2:
description: Get a Pet
id: ${petId}
expectedResponseCode: 200
Suppose the test_1
execution outputs:
{
"pet":
{
"id" : 2
}
}
When executing test_1
the value of the pet id will be stored in the petId
variable (value 2
). When executing test_2
the id
parameter will be replaced with the petId
variable (value 2
) from the previous case.
Please note: variables are visible across all custom tests; please be careful with the naming as they will get overridden.
Verifying responses
The FunctionalFuzzer
can verify more than just the expectedResponseCode
. This is achieved using the verify
element. This is an extended version of the above functionalFuzzer.yml
file.
/pet:
test_1:
description: Create a Pet
httpMethod: POST
name: "My Pet"
expectedResponseCode: 200
output:
petId: pet#id
verify:
pet#name: "Baby"
pet#id: "[0-9]+"
/pet/{id}:
test_2:
description: Get a Pet
id: ${petId}
expectedResponseCode: 200
Considering the above file:
- the
FunctionalFuzzer
will check if the response has the 2 elementspet#name
andpet#id
- if the elements are found, it will check that the
pet#name
has theBaby
value and that thepet#id
is numeric
The following json response will pass test_1
:
{
"pet":
{
"id" : 2,
"name": "Baby"
}
}
But this one won’t (pet#name
is missing):
{
"pet":
{
"id" : 2
}
}
You can also refer to request fields in the verify
section by using the ${request#..}
qualifier. Using the above example, by having the following verify
section:
/pet:
test_1:
description: Create a Pet
httpMethod: POST
name: "My Pet"
expectedResponseCode: 200
output:
petId: pet#id
verify:
pet#name: "${request#name}"
pet#id: "[0-9]+"
It will verify if the response contains a pet#name
element and that its value equals My Pet
as sent in the request.
Some notes:
verify
parameters support Java regexes as values- you can supply more than one parameter to check (as seen above)
- if at least one of the parameters is not present in the response,
CATs
will report an error - if all parameters are found and have valid values, but the response code is not matched,
CATs
will report a warning - if all the parameters are found and match their values, and the response code is as expected,
CATs
will report a success
Working with additionalProperties in FunctionalFuzzer
You can also set additionalProperties
fields through the functionalFuzzerFile
using the same syntax as for Setting additionalProperties in Reference Data.
FunctionalFuzzer Reserved keywords
The following keywords are reserved in FunctionalFuzzer
tests: output
, expectedResponseCode
, httpMethod
, description
, oneOfSelection
, verify
, additionalProperties
, topElement
and mapValues
.
Security Fuzzer
Although CATs
is not a security testing tool, you can use it to test basic security scenarios by fuzzing specific fields with different sets of nasty strings. The behaviour is similar to the FunctionalFuzzer
. You can use the exact same elements for output variables, test correlation, verify responses and so forth, with the addition that you must also specify a targetFields
and/or targetFieldTypes
and a stringsList
element. A typical securityFuzzerFile
will look like this:
/pet:
test_1:
description: Run XSS scenarios
name: "My Pet"
expectedResponseCode: 200
httpMethod: all
targetFields:
- pet#id
- pet#description
stringsFile: xss.txt
And a typical run:
> cats run securityFuzzerFile.yml -c contract.yml -s http://localhost:8080
You can also supply output
, httpMethod
, oneOfSelection
and/or verify
(with the same behaviour as within the FunctionalFuzzer
) if they are relevant to your case.
The file uses Json path syntax for all the properties you can supply; you can separate elements through #
as in the example instead of .
.
This is what the SecurityFuzzer
will do after parsing the above securityFuzzerFile
:
- it will add the fixed value “My Pet” to all the request for the field
name
- for each field specified in the
targetFields
i.e.pet#id
andpet#description
it will create requests for each line from thexss.txt
file and supply those values in each field - if you consider the
xss.txt
sample file included in theCATs
repo, this means that it will send 21 requests targetingpet#id
and 21 requests targetingpet#description
i.e. a total of 42 tests - for each of these 42 tests, the
SecurityFuzzer
will expect a200
response code. If another response code is returned, thenCATs
will report the test aserror
.
If you want the above logic to apply to all paths, you can use all
as the path name:
all:
test_1:
description: Run XSS scenarios
name: "My Pet"
expectedResponseCode: 200
httpMethod: all
targetFields:
- pet#id
- pet#description
stringsFile: xss.txt
Instead of specifying the field names, you can broader to scope to target certain fields types. For example, if we want to test for XSS in all string
fields, you can have the following securityFuzzerFile
:
all:
test_1:
description: Run XSS scenarios
name: "My Pet"
expectedResponseCode: 200
httpMethod: all
targetFieldTypes:
- string
stringsFile: xss.txt
As an idea on how to create security tests, you can split the nasty strings into multiple files of interest in your particular context. You can have a sql_injection.txt
, a xss.txt
, a command_injection.txt
and so on. For each of these files, you can create a test entry in the securityFuzzerFile
where you include the fields you think are meaningful for these types of tests. (It was a deliberate choice (for now) to not include all fields by default.) The expectedResponseCode
should be tweaked according to your particular context. Your service might sanitize data before validation, so might be perfectly valid to expect a 200
or might validate the fields directly, so might be perfectly valid to expect a 400
. A 500
will usually mean something was not handled properly and might signal a possible bug.
Working with additionalProperties in SecurityFuzzer
You can also set additionalProperties
fields through the functionalFuzzerFile
using the same syntax as for Setting additionalProperties in Reference Data.
SecurityFuzzer Reserved keywords
The following keywords are reserved in SecurityFuzzer
tests: output
, expectedResponseCode
, httpMethod
, description
, verify
, oneOfSelection
, targetFields
, targetFieldTypes
, stringsFile
, additionalProperties
, topElement
and mapValues
.
TemplateFuzzer
The TemplateFuzzer
can be used to fuzz non-OpenAPI endpoints. If the target API does not have an OpenAPI spec available, you can use a request template to run a limited set of fuzzers. The syntax for running the TemplateFuzzer
is as follows (very similar to curl
:
> cats fuzz -H header=value -X POST -d '{"field1":"value1","field2":"value2","field3":"value3"}' -t "field1,field2,header" -i "2XX,4XX" http://service-url
The command will:
- send a
POST
request tohttp://service-url
- use the
{"field1":"value1","field2":"value2","field3":"value3"}
as a template - replace one by one
field1,field2,header
with fuzz data and send each request to the service endpoint - ignore
2XX,4XX
response codes and report an error when the received response code is not in this list
It was a deliberate choice to limit the fields for which the Fuzzer
will run by supplying them using the -t
argument. For nested objects, supply fully qualified names: field.subfield
.
Headers can also be fuzzed using the same mechanism as the fields.
This Fuzzer
will send the following type of data:
- null values
- empty values
- zalgo text
- abugidas characters
- large random unicode data
- very large strings (80k characters)
- single and multi code point emojis
- unicode control characters
- unicode separators
- unicode whitespaces
For a full list of options run > cats fuzz -h
.
You can also supply your own dictionary of data using the -w file
argument.
HTTP methods with bodies will only be fuzzed at the request payload and headers level.
HTTP methods without bodies will be fuzzed at path and query parameters and headers level. In this case you don’t need to supply a -d
argument.
This is an example for a GET
request:
> cats fuzz -X GET -t "path1,query1" -i "2XX,4XX" http://service-url/paths1?query1=test&query2
Reference Data File
There are often cases where some fields need to contain relevant business values in order for a request to succeed. You can provide such values using a reference data file specified by the --refData
argument. The reference data file is a YAML-format file that contains specific fixed values for different paths in the request document. The file structure is as follows:
/path/0.1/auth:
prop#subprop: 12
prop2: 33
prop3#subprop1#subprop2: "test"
/path/0.1/cancel:
prop#test: 1
For each path you can supply custom values for properties and sub-properties which will have priority over values supplied by any other Fuzzer
. Consider this request payload:
{
"address": {
"phone": "123",
"postCode": "408",
"street": "cool street"
},
"name": "Joe"
}
and the following reference data file file:
/path/0.1/auth:
address#street: "My Street"
name: "John"
This will result in any fuzzed request to the /path/0.1/auth
endpoint being updated to contain the supplied fixed values:
{
"address": {
"phone": "123",
"postCode": "408",
"street": "My Street"
},
"name": "John"
}
The file uses Json path syntax for all the properties you can supply; you can separate elements through #
as in the example above instead of .
.
You can use environment (system) variables in a ref data file using: $$VARIABLE_NAME
. (notice double $$
)
Setting additionalProperties
As additional properties are maps i.e. they don’t actually have a structure, CATS cannot currently generate valid values. If the elements within such a data structure are essential for a request, you can supply them via the refData
file using the following syntax:
/path/0.1/auth:
address#street: "My Street"
name: "John"
additionalProperties:
topElement: metadata
mapValues:
test: "value1"
anotherTest: "value2"
The additionalProperties
element must contain the actual key-value pairs to be sent within the requests and also a top element if needed. topElement
is not mandatory. The above example will output the following json (considering also the above examples):
{
"address": {
"phone": "123",
"postCode": "408",
"street": "My Street"
},
"name": "John",
"metadata": {
"test": "value1",
"anotherTest": "value2"
}
}
RefData reserved keywords
The following keywords are reserved in a reference data file: additionalProperties
, topElement
and mapValues
.
Sending ref data for ALL paths
You can also have the ability to send the same reference data for ALL paths (just like you do with the headers). You can achieve this by using all
as a key in the refData
file:
all:
address#zip: 123
This will try to replace address#zip
in all requests (if the field is present).
Removing fields
There are (rare) cases when some fields may not make sense together. Something like: if you send firstName
and lastName
, you are not allowed to also send name
. As OpenAPI does not have the capability to send request fields which are dependent on each other, you can use the refData
file to instruct CATS to remove fields before sending a request to the service. You can achieve this by using the cats_remove_field
as a value for the fields you want to remove. For the above case the refData
field will look as follows:
all:
name: "cats_remove_field"
Creating a Ref Data file with the FunctionalFuzzer
You can leverage the fact that the FunctionalFuzzer
can run functional flows in order to create dynamic --refData
files which won’t need manual setting the reference data values. The --refData
file must be created with variables ${variable}
instead of fixed values and those variables must be output variables in the functionalFuzzer.yml
file. In order for the FunctionalFuzzer
to properly replace the variables names with their values you must supply the --refData
file as an argument when the FunctionalFuzzer
runs.
> cats run functionalFuzzer.yml -c contract.yml -s http://localhost:8080 --refData=refData.yml
The functionalFuzzer.yml
file:
/pet:
test_1:
description: Create a Pet
httpMethod: POST
name: "My Pet"
expectedResponseCode: 200
output:
petId: pet#id
The refData.yml
file:
/pet-type:
id: ${petId}
After running CATS using the command and the 2 files above, you will get a refData_replace.yml
file where the id
will get the value returned into the petId
variable.
The refData_replaced.yml
:
/pet-type:
id: 123
You can now use the refData_replaced.yml
as a --refData
file for running CATS with the rest of the Fuzzers.
Headers File
This can be used to send custom fixed headers with each payload. It is useful when you have authentication tokens you want to use to authenticate the API calls. You can use path specific headers or common headers that will be added to each call using an all
element. Specific paths will take precedence over the all
element. Sample headers file:
all:
Accept: application/json
/path/0.1/auth:
jwt: XXXXXXXXXXXXX
/path/0.2/cancel:
jwt: YYYYYYYYYYYYY
This will add the Accept
header to all calls and the jwt
header to the specified paths. You can use environment (system) variables in a headers file using: $$VARIABLE_NAME
. (notice double $$
)
DELETE requests
DELETE
is the only HTTP verb that is intended to remove resources and executing the same DELETE
request twice will result in the second one to fail as the resource is no longer available. It will be pretty heavy to supply a large list of identifiers within the --refData
file and this is why the recommendation was to skip the DELETE
method when running CATS.
But starting with version 7.0.2 CATS has some intelligence in dealing with DELETE
. In order to have enough valid entities CATS will save the corresponding POST
requests in an internal Queue, and everytime a DELETE
request it will be executed it will poll data from there. In order to have this actually working, your contract must comply with common sense conventions:
- the
DELETE
path is actually thePOST
path plus an identifier: if POST is/pets
, then DELETE is expected to be/pets/{petId}
. - CATS will try to match the
{petId}
parameter within the body returned by thePOST
request while doing various combinations of thepetId
name. It will try to search for the following entries:petId, id, pet-id, pet_id
with different cases. - If any of those entries is found within a stored
POST
result, it will replace the{petId}
with that value
For example, suppose that a POST to /pets
responds with:
{
"pet_id": 2,
"name": "Chuck"
}
When doing a DELETE
request, CATS will discover that {petId}
and pet_id
are used as identifiers for the Pet
resource, and will do the DELETE
at /pets/2
.
If these conventions are followed (which also align to good REST naming practices), it is expected that DELETE
and POST
requests will be on-par for most of the entities.
Content Negotiation
Some APIs might use content negotiation versioning which implies formats like application/v11+json
in the Accept
header.
You can handle this in CATS as follows:
- if the OpenAPI contract defines its content as:
requestBody:
required: true
content:
application/v5+json:
schema:
$ref: '#/components/RequestV5'
application/v6+json:
schema:
$ref: '#/components/RequestV6'
by having clear separation between versions, you can pass the --contentType
argument with the version you want to test: cats ... --contentType="application/v6+json"
.
If the OpenAPI contract is not version aware (you already exported it specific to a version) and the content looks as:
requestBody:
required: true
content:
application/json:
schema:
$ref: '#/components/RequestV5'
and you still need to pass the application/v5+json
Accept
header, you can use the --headers
file to add it:
all:
Accept: "application/v5+json"
Edge Spaces Strategy
There isn’t a consensus on how you should handle situations when you trail or prefix valid values with spaces. One strategy will be to have the service trimming spaces before doing the validation, while some other services will just validate them as they are. You can control how CATS should expect such cases to be handled by the service using the --edgeSpacesStrategy
argument. You can set this to trimAndValidate
or validateAndTrim
depending on how you expect the service to behave:
trimAndValidate
means that the service will first trim the spaces and after that run the validationvalidateAndTrim
means that the service runs the validation first without any trimming of spaces
This is a global setting i.e. configured when CATS starts and all Fuzzer
expects a consistent behaviour from all the service endpoints.
URL Parameters
There are cases when certain parts of the request URL are parameterized. For example a case like: /{version}/pets
. {version}
is supposed to have the same value for all requests. This is why you can supply actual values to replace such parameters using the --urlParams
argument. You can supply a ;
separated list of name:value
pairs to replace the name
parameters with their corresponding value
. For example supplying --urlParams=version:v1.0
will replace the version
parameter from the above example with the value v1.0
.
Dealing with AnyOf, AllOf and OneOf
CATS also supports schemas with oneOf
, allOf
and anyOf
composition. CATS wil consider all possible combinations when creating the fuzzed payloads.
Dynamic values in configuration files
The following configuration files: securityFuzzerFile, functionalFuzzerFile, refData
support setting dynamic values for the inner fields. For now the support only exists for java.time.*
and org.apache.commons.lang3.*
, but more types of elements will come in the near future.
Let’s suppose you have a date/date-time field, and you want to set it to 10 days from now. You can do this by setting this as a value T(java.time.OffsetDateTime).now().plusDays(10)
. This will return an ISO compliant time in UTC format.
A functionalFuzzer
using this can look like:
/path:
testNumber:
description: Short description of the test
prop: value
prop#subprop: "T(java.time.OffsetDateTime).now().plusDays(10)"
prop7:
- value1
- value2
- value3
oneOfSelection:
element#type: "Value"
expectedResponseCode: HTTP_CODE
httpMethod: HTTP_NETHOD
You can also check the responses using a similar syntax and also accounting for the actual values returned in the response. This is a syntax than can test if a returned date is after the current date: T(java.time.LocalDate).now().isBefore(T(java.time.LocalDate).parse(expiry.toString()))
. It will check if the expiry
field returned in the json response, parsed as date, is after the current date.
The syntax of dynamically setting dates is compliant with the Spring Expression Language specs.
Running behind proxy
If you need to run CATS behind a proxy, you can supply the following arguments: --proxyHost
and --proxyPort
. A typical run with proxy settings on localhost:8080
will look as follows:
> cats --contract=YAML_FILE --server=SERVER_URL --proxyHost=localhost --proxyPort=8080
Dealing with Authentication
HTTP header(s) based authentication
CATS supports any form of HTTP header(s) based authentication (basic auth, oauth, custom JWT, apiKey, etc) using the headers mechanism. You can supply the specific HTTP header name and value and apply to all
endpoints. Additionally, basic auth is also supported using the --basicauth=USR:PWD
argument.
One-Way or Two-Way SSL
By default, CATS trusts all server certificates and doesn’t perform hostname verification.
For two-way SSL you can specify a JKS file (Java Keystore) that holds the client’s private key using the following arguments:
--sslKeystore
Location of the JKS keystore holding certificates used when authenticating calls using one-way or two-way SSL--sslKeystorePwd
The password of thesslKeystore
--sslKeyPwd
The password of the private key within thesslKeystore
For details on how to load the certificate and private key into a Java Keystore you can use this guide: https://mrkandreev.name/blog/java-two-way-ssl/.
Limitations
Native Binaries
When using the native binaries (not the uberjar) there might be issues when using dynamic values in the CATS files. This is due to the fact that GraalVM only bundles whatever can discover at compile time. The following classes are currently supported:
java.util.Base64.Encoder.class, java.util.Base64.Decoder.class, java.util.Base64.class, org.apache.commons.lang3.RandomUtils.class, org.apache.commons.lang3.RandomStringUtils.class,
org.apache.commons.lang3.DateFormatUtils.class, org.apache.commons.lang3.DateUtils.class,
org.apache.commons.lang3.DurationUtils.class, java.time.LocalDate.class, java.time.LocalDateTime.class, java.time.OffsetDateTime.class
API specs
At this moment, CATS only works with OpenAPI specs and has limited functionality using template payloads through the cats fuzz ...
subcommand.
Media types and HTTP methods
The Fuzzers
has the following support for media types and HTTP methods:
application/json
andapplication/x-www-form-urlencoded
media types only- HTTP methods:
POST
,PUT
,PATCH
,GET
andDELETE
Additional Parameters
If a response contains a free Map specified using the additionalParameters
tag CATS will issue a WARN
level log message as it won’t be able to validate that the response matches the schema.
Regexes within ‘pattern’
CATS uses RgxGen in order to generate Strings based on regexes. This has certain limitations mostly with complex patterns.
Custom Files General Info
All custom files that can be used by CATS (functionalFuzzerFile
, headers
, refData
, etc) are in a YAML format. When setting or getting values to/from JSON for input and/or output variables, you must use a JsonPath syntax using either #
or .
as separators. You can find some selector examples here: JsonPath.
Contributing
Please refer to CONTRIBUTING.md.
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