doc / ch.tutteli.atrium.api.cc.de_CH / eintraege

eintraege

fun <E : Any, T : Iterable<E>> IterableContainsCheckerBuilder<E, T, IterableContainsInAnyOrderSearchBehaviour>.eintraege(assertionCreator: Assert<E>.() -> Unit, vararg otherAssertionCreators: Assert<E>.() -> Unit): AssertionPlant<T>

Finishes the specification of the sophisticated contains assertion where an entry shall be searched which holds all assertions assertionCreator might create and search for entries which hold (one by one) the assertions created by the otherAssertionCreators.

Parameters

assertionCreator - The lambda function which creates the assertions which the entry we are looking for has to hold; or in other words, the function which defines whether an entry is the one we are looking for or not. otherAssertionCreators - Additional lambda functions which each kind of identify (separately) an entry which we are looking for.

Exceptions

AssertionError - Might throw an AssertionError if the assertion made is not correct.

Return
The AssertionPlant for which the assertion was built to support a fluent API.

fun <E : Any, T : Iterable<E>> IterableContainsBuilder<E, T, IterableContainsInAnyOrderOnlySearchBehaviour>.eintraege(assertionCreator: Assert<E>.() -> Unit, vararg otherAssertionCreators: Assert<E>.() -> Unit): AssertionPlant<T>

Finishes the specification of the sophisticated contains assertion where the entry needs to be contained in the Iterable which holds all assertions assertionCreator might create -- equally an entry for each further otherAssertionCreators needs to be contained in the Iterable where it does not matter in which order the entries appear.

Notice, that a first-wins strategy applies which means your assertionCreator functions -- which kind of serve as identification functions -- should be ordered in such a way that the most specific identification function appears first, not that a less specific function wins. For instance, given a setOf(1, 2) you should not search for entries({ isGreaterThan(0) }, { toBe(1) }) but for entries({ toBe(1) }, { isGreaterThan(0) }) otherwise isGreaterThan(0) matches 1 before toBe(1) would match it. As a consequence toBe(1) could only match the entry which is left -- in this case 2 -- and of course this would fail.

Parameters

assertionCreator - The lambda function which creates the assertions which the entry we are looking for has to hold; or in other words, the function which defines whether an entry is the one we are looking for or not. otherAssertionCreators - Additional lambda functions which each kind of identify (separately) an entry which we are looking for.

Exceptions

AssertionError - Might throw an AssertionError if the assertion made is not correct.

Return
The AssertionPlant for which the assertion was built to support a fluent API.

fun <E : Any, T : Iterable<E>> IterableContainsBuilder<E, T, IterableContainsInOrderOnlySearchBehaviour>.eintraege(assertionCreator: Assert<E>.() -> Unit, vararg otherAssertionCreators: Assert<E>.() -> Unit): AssertionPlant<T>

Finishes the specification of the sophisticated contains assertion where the entry needs to be contained in the Iterable which holds all assertions assertionCreator might create -- equally an entry for each further otherAssertionCreators, following the specified order, needs to be contained in the Iterable

Parameters

assertionCreator - The lambda function which creates the assertions which the entry we are looking for has to hold; or in other words, the function which defines whether an entry is the one we are looking for or not. otherAssertionCreators - Additional lambda functions which each kind of identify (separately) an entry which we are looking for.

Exceptions

AssertionError - Might throw an AssertionError if the assertion made is not correct.

Return
The AssertionPlant for which the assertion was built to support a fluent API.