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Scenario: When printing the instantiation we should use the right amount of spaces
Given the class:
public class A {
Object foo = new Object();
}
When the class is parsed by the Java parser
Then it is printed as:
public class A {
Object foo = new Object();
}
Scenario: When printing the lambda expression we should use the right indentation
Given the class:
public class B {
Runnable runnable = ()-> System.out.println("running");
Consumer<Integer> consumer = i->{ i+=1; System.out.println(i);};
}
When the class is parsed by the Java parser
Then it is printed as:
public class B {
Runnable runnable = () -> System.out.println("running");
Consumer<Integer> consumer = i -> {
i += 1;
System.out.println(i);
};
}
Scenario: Printing orphan comments in empty method
Given the class:
class A {
public void helloWorld(String greeting, String name) {
//sdfsdfsdf
//sdfds
/*
dgfdgfdgfdgfdgfd
*/
}
}
When the class is parsed by the Java parser
Then it is printed as:
class A {
public void helloWorld(String greeting, String name) {
// sdfsdfsdf
// sdfds
/*
dgfdgfdgfdgfdgfd
*/
}
}
Scenario: Printing orphan comments in empty method (issue 192)
Given the class:
public class StepImplementation {
@Step("A step")
public void contextStep() {
// Foo bar
}
}
When the class is parsed by the Java parser
Then it is printed as:
public class StepImplementation {
@Step("A step")
public void contextStep() {
// Foo bar
}
}
Scenario: Printing orphan comments in for loop (issue 192)
Given the class:
public class StepImplementation {
public void contextStep() {
for (int i = 0; i < 5; i++) {
// foo bar
}
}
}
When the class is parsed by the Java parser
Then it is printed as:
public class StepImplementation {
public void contextStep() {
for (int i = 0; i < 5; i++) {
// foo bar
}
}
}
Scenario: Printing orphan and attributed comments in for loop (issue 192)
Given the class:
public class StepImplementation {
public void contextStep() {
for (int i = 0; i < 5; i++) {
// foo bar
System.out.println();
// another foo bar
}
}
}
When the class is parsed by the Java parser
Then it is printed as:
public class StepImplementation {
public void contextStep() {
for (int i = 0; i < 5; i++) {
// foo bar
System.out.println();
// another foo bar
}
}
}
Scenario: An empty Enum is printed correctly
Given the compilation unit:
package test; enum XYZ {}
When the class is parsed by the Java parser
Then it is printed as:
package test;
enum XYZ {
}
Scenario: An enum without fields has no () on its members
Given the compilation unit:
package test; enum XYZ {A,B,C}
When the class is parsed by the Java parser
Then it is printed as:
package test;
enum XYZ {
A, B, C
}
Scenario: Strings with escaped newlines are parsed correctly
Given the class:
class A {
public void helloWorld(String greeting, String name) {
return "hello\nworld";
}
}
When the class is parsed by the Java parser
Then it is printed as:
class A {
public void helloWorld(String greeting, String name) {
return "hello\nworld";
}
}
Scenario: A multi-catch is printed correctly
Given the class:
class A {
public void a() {
try {
} catch (IndexOutOfBoundException | IOException e) {
}
}
}
When the class is parsed by the Java parser
Then it is printed as:
class A {
public void a() {
try {
} catch (IndexOutOfBoundException | IOException e) {
}
}
}
Scenario: An empty import does not fail
Given the class:
package a.b.c;
;
When the class is parsed by the Java parser
Then it is printed as:
package a.b.c;
Scenario: we can parse blocks
Given the block:
{
a=2;
b=3;
}
When the block is parsed by the Java parser
Then it is printed as:
{
a = 2;
b = 3;
}
Scenario: we can parse statements
Given the statement:
while (true) {
}
When the statement is parsed by the Java parser
Then it is printed as:
while (true) {
}
Scenario: we can parse static on demand imports
Given the import:
import static a.b.c.Abc.*;
When the import is parsed by the Java parser
Then it is printed as:
import static a.b.c.Abc.*;
Scenario: we can parse static type imports
Given the import:
import static a.b.c.Abc;
When the import is parsed by the Java parser
Then it is printed as:
import static a.b.c.Abc;
Scenario: we can parse on demand imports
Given the import:
import a.b.c.*;
When the import is parsed by the Java parser
Then it is printed as:
import a.b.c.*;
Scenario: we can parse type imports
Given the import:
import a.b.c.Abc;
When the import is parsed by the Java parser
Then it is printed as:
import a.b.c.Abc;
Scenario: we can parse annotations
Given the annotation:
@Abc
When the annotation is parsed by the Java parser
Then it is printed as:
@Abc
Scenario: we can parse body declarations
Given the body:
String author();
When the annotation body declaration is parsed by the Java parser
Then it is printed as:
String author();
Scenario: we can parse class body declarations
Given the body:
public int xyz() {}
When the class body declaration is parsed by the Java parser
Then it is printed as:
public int xyz() {
}
Scenario: we can parse interface body declarations
Given the body:
int xyz();
When the interface body declaration is parsed by the Java parser
Then it is printed as:
int xyz();
Scenario: It doesn't throw NPE when using a modifierVisitorAdapter
Given the class:
public class Example {
private String mString;
public Example(String arg) {
mString = arg;
}
}
When the class is parsed by the Java parser
When the class is visited by an empty ModifierVisitorAdapter
Then it is printed as:
public class Example {
private String mString;
public Example(String arg) {
mString = arg;
}
}
Scenario: JavaDoc OR comment is printed, not both.
Given the class:
public class Foo {
/** This line gets duplicated */
public void foo() {
}
}
When the class is parsed by the Java parser
Then it is printed as:
public class Foo {
/**
* This line gets duplicated
*/
public void foo() {
}
}
Scenario: various lamba casts (issue 418)
Given the class:
public class TestLambda {
void okMethod() {
return (ITF) () -> {
return true;
};
}
void faliingMethod() {
testThis(check ? null : (ITF) () -> {
return true;
});
}
}
When the class body declaration is parsed by the Java parser
Then it is printed as:
public class TestLambda {
void okMethod() {
return (ITF) () -> {
return true;
};
}
void faliingMethod() {
testThis(check ? null : (ITF) () -> {
return true;
});
}
}
Scenario: Duplicate methods are not a parsing error (#416)
Given the class:
public class Foo {
public void foo() {
}
public void foo() {
}
public void foo() {
}
}
When the class is parsed by the Java parser
Then it is printed as:
public class Foo {
public void foo() {
}
public void foo() {
}
public void foo() {
}
}
Scenario: Both array syntaxes are supported (#416)
Given the class:
public class Foo {
public void m1(boolean[] boolArray) {}
public void m1(boolean boolArray[]) {}
public void m1(boolean[] boolArray[]) {}
}
When the class is parsed by the Java parser
Then it is printed as:
public class Foo {
public void m1(boolean[] boolArray) {
}
public void m1(boolean[] boolArray) {
}
public void m1(boolean[][] boolArray) {
}
}
Scenario: Array parts can be annotated
Given the class:
class Foo {
void m1(@Boo boolean @Index1 [] @ Index2 [] boolArray) {}
}
When the class is parsed by the Java parser
Then it is printed as:
class Foo {
void m1(@Boo boolean @Index1 [] @Index2 [] boolArray) {
}
}
Scenario: Annotations are supported on annotations
Given the class:
@C @interface D {
}
When the class is parsed by the Java parser
Then it is printed as:
@C
@interface D {
}
Scenario: Annotations are supported on interfaces
Given the class:
@C interface Abc {
}
When the class is parsed by the Java parser
Then it is printed as:
@C
interface Abc {
}
Scenario: Annotations are supported on enums
Given the class:
@C enum Abc {
}
When the class is parsed by the Java parser
Then it is printed as:
@C
enum Abc {
}
Scenario: Annotations are supported on classes (issue 436 is the commented part)
Given the compilation unit:
@C
public class Abc<@C A, @C X extends @C String & @C Serializable> {
@C int @C[] @C []f;
@C
public Abc(@C int p, List<@C ? extends Object> aa){
@C int b;
}
public @C void a(@C int o) {
/* try {
throw new IOException();
} catch (@C NullPointerException | @C IOException e) {
}
*/ }
}
When the compilation unit is parsed by the Java parser
Then it is printed as:
@C
public class Abc<@C A, @C X extends @C String & @C Serializable> {
@C
int @C [] @C [] f;
@C
public Abc(@C int p, List<@C ? extends Object> aa) {
@C int b;
}
@C
public void a(@C int o) {
/* try {
throw new IOException();
} catch (@C NullPointerException | @C IOException e) {
}
*/
}
}
Scenario: Annotations are supported inside catch (issue 436)
Given the compilation unit:
public class Abc {
public void a() {
try {
} catch (@C NullPointerException | @C IOException e) {
}
}
}
When the compilation unit is parsed by the Java parser
Then it is printed as:
public class Abc {
public void a() {
try {
} catch (@C NullPointerException | @C IOException e) {
}
}
}
Scenario: Inner class notation does not confuse annotations (#107)
Given the class:
class A extends @Ann1 B.@Ann2 C {
}
When the class is parsed by the Java parser
Then it is printed as:
class A extends @Ann1 B.@Ann2 C {
}
Scenario: Make sure interface extends can be annotated
Given the class:
interface A extends @X B, @Y C, @Z D {
}
When the class is parsed by the Java parser
Then it is printed as:
interface A extends @X B, @Y C, @Z D {
}
Scenario: default modifier isn't printed twice
Given the class:
interface X {default String author(){}}
When the annotation body declaration is parsed by the Java parser
Then it is printed as:
interface X {
default String author() {
}
}
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