core

package
v0.0.0-...-f6bc33c Latest Latest
Warning

This package is not in the latest version of its module.

Go to latest
Published: Apr 28, 2023 License: MIT Imports: 0 Imported by: 0

README

Integration Tests

This is the home of the system integrations tests.

Running the tests

They can be run from the root of zeta with:

make integrationtest

or

go test ./...
Running just the integration tests

The integration tests have been hooked up to run as regular unit tests, so you can run just the integration tests with a simple command:

go test ./integration/...

When running these tests, you'll probably want to get a more verbose output (showing which steps of the tests passed and failed), which can be done by adding 2 flags:

go test -v ./integration/... --godog.format=pretty

The -v flag tells go test to run with verbose output (sending logging to stdout). The -godog.format=pretty flag ( which must be put at the end) instructs godog to print out the scenario's and, in case an assertion fails, show which particular step of a given scenario didn't work.

Running specific scenario's

To run only certain tests (feature files), you can simply add the paths to a given feature file to the command:

go test -v ./integration/... --godog.format=pretty $(pwd)/integration/features/my-feature.feature
Race detection and cache

For performance reasons, go test will check whether the source of a package has changed, and reuse compiled objects or even test results in case it determines nothing has changed. Because the integration tests are tucked away in their own package, changes to other packages might not be compiled, and tests could possibly pass without changes being applied. To ensure no cached results are used, the -count flag can be used:

go test -v -count=1 ./integration/... --godog.format=pretty

Should there be tests that are intermittently failing, this could indicate a data race somewhere in the code. To use the race detector to check for this, you can add the -race flag to the command. The full commands then would be:

# Run all integration tests, verbose mode, ensure recompiled binaries, enable race detection, and use godog pretty formatting
go test -v -count=1 -race ./integration/... --godog.format=pretty

# Same as above, but only run a specific feature file:
go test -v -count=1 -race ./integration/... --godog.format=pretty $(pwd)/integration/feature/my-feature.feature

Race detection is a complex thing to do, so it will make running tests significantly slower. The pipeline runs the tests with race detection, so this shouldn't be required to do locally.

Reproducing/replicating system tests

The system tests run on a higher level. They submit a new market proposal, get said market accepted through governance, and then start trading. They use a LogNormal risk model, and specific fee parameters. David kindly provided the long/short risk factors for a simple risk model that result in the same margin requirements and same fees being applied to the trades. To create an integration test that replicates the system test results (transfers, balances, fees, etc...) , simply start your feature file with the following:

Feature: A feature that reproduces some system test

  Background:
    Given the markets:
      | id        | quote name | asset | risk model                | margin calculator         | auction duration | price monitoring | data source config      |
      | ETH/DEC20 | ETH        | ETH   | default-simple-risk-model | default-margin-calculator | 1                | default-none     | default-for-future |
    And the initial insurance pool balance is "0" for all the markets
Debug problems with VSCode

You might have a situation where you need to closely investigate the state of a tested application or the tests script itself. You might want to set some breakpoints, at which test execution stops, and you can view that state.

This process is called debugging, and we have an initial/template configuration for you. Please follow these steps:

  1. Open and edit .vscode/launch.json config file (do not commit changes to this file):
  • to run one .feature file, then edit Debug .feature test section and point to your .feature file,
  • to run single Scenario in a .feature file, then change .feature file path and specify the line of a Scenario in that file. All in section Debug single Scenario in .feature test,
  1. Set breakpoints in tests code or application code (note: it has to be in .go files, no .feature),
  2. In VSCode switch to Run and Debug view (an icon with a bug from left side-bar),
  3. From top drop-down select which option you want to run, e.g. Debug .feature test,
  4. Click green Play button,
  5. Observe results in Debug Console tab at bottom.

Life cycle

To get a market up and running, here is the process:

  1. Configuration of network parameters. They have default values so it's not required, but if we want to override them, it should be done in the first step.
  2. Configuration of market.
  3. Declaration of the traders and their general account balance.
  4. Placement of orders by the traders, so the market can have a mark price.

Once these steps are done, the market should be in a proper state.

Steps

The list of steps is located in ./main_test.go.

Market instantiation

Setting up a market is complex and the base for everything. As a result, we created a "lego-like" system to help us strike the balance between flexibility and re-usability.

Flexibility with steps

A market is composed of several sets of parameters grouped by domain, such as margin, risk model, fees, and so on.

Each set of parameters is declared in its own step into which a custom name is given. In our "lego" analogy, these named sets would be the "blocks".

To declare a market, we tell to our market which "blocks" to use.

Here is an example where we declare a risk model named "simple-risk-model-1". Then, we declare a "BTC" market, to which we associate the risk model "simple-risk-model-1".

Given the simple risk model named "simple-risk-model-1":
| long | short | max move up | min move down | probability of trading |
| 0.1  | 0.1   | 10          | -10           | 0.1                    |
And the markets:
| id        | quote name | asset | risk model          |
| ETH/DEC21 | BTC        | BTC   | simple-risk-model-1 |
Re-usability with defaults

Because markets are tedious to instantiate, most of the time, we instantiate them using defaults stored in JSON files inside the folder steps/market/defaults.

Each sub-folders contain the defaults for their domain. Referencing a default for the price monitoring that is not in the price-monitoring folder will result in failure.

Using defaults works just like the named set, except that the file name will be used as the name. As a result, if the file containing the defaults is named default-basic.json, then the name to fill in will be default-basic.

This is the recommended way. It's also fine to introduce a new defaults as long as it's used more than a couple of times.

You can mix the use of steps and defaults in market declaration.

Debug

Sometimes, you need to log some state. For this, you can use the debug ... steps.

Convention

Glossary

We should move toward building our ubiquitous language and use domain language and avoid the use of synonyms.

If we talk about submitting an order, we avoid using placing an order.

Structuring a feature test
File

A feature test's file should be named by the feature / command it's testing, such has: maintenance_call_for_margin_account.go.

The file name should match, or at least be close to, the description of the Feature keyword.

To be avoided:

  • A prefix with a pull-request or an issue number, such as 4284-cancel-order.go.
  • A vague name, or context, such as orders.go or cancellation.go
Feature

The Feature keyword should describe the feature to be tested in proper sentences, with context.

It should match, or at least be close to, the name of the file it lives in.

Examples

Let's assume, we have a file called trader_cancels_orders.go

Good
Feature: Traders can cancel his orders under certain conditions

By reading this, we get to know who's the main actor, the action and the target. Saying "Under certain conditions" is vague, but it's enough as that's the purpose of the Scenario to be more specific. At least, we know there are conditions.

Bad
Feature: cancel orders

This is too vague.

Feature: Should monitor prices

This seems completely unrelated to what the file name mentions.

Scenario

The Scenario keyword should describe the tested case of the command, and, thus, should never be empty.

A file can contain multiple scenarios if they test the same feature. Unrelated tests should live in a dedicated file.

If the feature to be tested is order cancellation, we could have:

Examples
Good
Feature: Trader can cancel orders under certain condition

  Scenario: Trader can cancel his order if not matched
  ...

  Scenario: Trader cannot cancel another trader's order
  ...

We know who is doing what on what.

Bad
Scenario: Works
...

Scenario: fail !
...

Oh yeah ?

Scenario:
...

Okay...

Given

Given should only be used for prerequisite declaration. Arguably, it's a bit tricky to distinguish a prerequisite from what's not. For now, as a rule of thumb, we consider market declaration and traders initial deposit to the general account to be the pre-requisites. Other steps should use the keywords below.

Examples
Good
Given the market ...
And the traders general account balance ...
When

When should only be used when issuing a command. It shouldn't be used for assertions. The preferred construct of command steps is:

<actor> <action verb> <target>

Construction with passive voice is accepted, if it makes more sense than the active voice.

Examples
Good
When traders submit the following orders

We know who does what.

When an oracle data is submitted

The passive voice sounds better The system receives the following oracle data.

Then

Then should only be used when asserting a state. It shouldn't be use for commands. The preferred construct of assertion steps is:

<actor> should <state verb> <target>
Examples
Good
Then trader trader-1 should have a balance of 100 ETH

We know what we expect from whom.

Bad
Then trader trader-1 have a balance of 100 ETH

We miss the should that emphasize the expectation.

Then the orders should fails

This is too vague.

Then the trader places an order

It's a command. The keywords should be used to help the reader to distinguish a command from an assertion. Even if the above sentence makes sense, it breaks the structure When command > Then assertion, and we might end up with a list of Then:

Then the trader places an order
Then the trader should have balance ...
Then an oracle data is sent
Then the settlement data should be updated

We are no longer be able to sort out the commands from the assertions at first glance.

And / But

And can be used by any of the previous keywords and should follow the sentence construction of the keyword it is backing. Use But for negative outcomes.

Step
Text
  • The first word should start we a lower-case letter.
  • Words (and table columns) should be lower-case with space separation, like plain human style. No upper-case location to be remembered.
  • Acronyms should be lower-case, like the rest, without trailing dot. We want to avoid interrogation such as : ID or Id or Id. ?
Good
When the market id should contain the asset "..."

All lower-case.

Bad
Then The Market Id should appears in U.R.L with QuoteName
Single-line step
Error

We should verify the error message on every expected failure using because followed by the error message.

Good
Then the order "1234" should be rejected because "....."

We ensure the error is the expected one, and the context is clear, no need for additional comments.

Bad
Then the order "1234" should be rejected

It may have not failed for the reason we expected. And, we may be tempted to add a comment to explain the reason of the failure.

Table step
Error

The column to verify the error should always be named error.

Date

Prefer expiration date over expires at or started at.

Documentation

Index

Constants

This section is empty.

Variables

This section is empty.

Functions

func Noop

func Noop()

Noop ... this is just here so this package contains actual go code (not only test files) and can and lsp go does not fail with: go build github.com/zeta-protocol/zeta/core/integration: no non-test Go files in .../zeta/integration.

Types

This section is empty.

Directories

Path Synopsis

Jump to

Keyboard shortcuts

? : This menu
/ : Search site
f or F : Jump to
y or Y : Canonical URL