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5
.gitignore
vendored
5
.gitignore
vendored
@ -26,3 +26,8 @@ cabal.project.local
|
||||
cabal.project.local~
|
||||
.HTF/
|
||||
.ghc.environment.*
|
||||
texput.log
|
||||
doc/output/
|
||||
doc/*.aux
|
||||
doc/*.log
|
||||
doc/*.out
|
@ -5,7 +5,7 @@ Written in Haskell.
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||||
# Cabal Commands
|
||||
run main
|
||||
```
|
||||
cabal run
|
||||
cabal run compiler <FILENAME>
|
||||
```
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||||
|
||||
run tests
|
||||
|
@ -1,7 +1,7 @@
|
||||
// compile all test files using:
|
||||
// ls Test/JavaSources/*.java | grep -v ".*Main.java" | xargs -I {} cabal run compiler {}
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// compile (in project root) using:
|
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// javac -g:none -sourcepath Test/JavaSources/ Test/JavaSources/Main.java
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// pushd Test/JavaSources; javac -g:none Main.java; popd
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// afterwards, run using
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// java -ea -cp Test/JavaSources/ Main
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||||
@ -11,9 +11,14 @@ public class Main {
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TestEmpty empty = new TestEmpty();
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TestFields fields = new TestFields();
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TestConstructor constructor = new TestConstructor(42);
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TestArithmetic arithmetic = new TestArithmetic();
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TestMultipleClasses multipleClasses = new TestMultipleClasses();
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TestRecursion recursion = new TestRecursion(10);
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TestMalicious malicious = new TestMalicious();
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TestLoop loop = new TestLoop();
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||||
TestMethodOverload overload = new TestMethodOverload();
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TestShenanigance shenanigance = new TestShenanigance();
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TestOptionalParameter optionalParameter = new TestOptionalParameter();
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||||
|
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// constructing a basic class works
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assert empty != null;
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@ -21,12 +26,24 @@ public class Main {
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assert fields.a == 0 && fields.b == 42;
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// constructor parameters override initializers
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assert constructor.a == 42;
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// basic arithmetics
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assert arithmetic.basic(1, 2, 3) == 2;
|
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// we have boolean logic as well
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assert arithmetic.logic(false, false, true) == true;
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// multiple classes within one file work. Referencing another classes fields/methods works.
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assert multipleClasses.a.a == 42;
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// self-referencing classes work.
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assert recursion.child.child.child.child.child.value == 5;
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// self-referencing methods work.
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assert recursion.fibonacci(15) == 610;
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assert loop.factorial(5) == 120;
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assert loop.weirdFor() == 5;
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// methods with the same name but different parameters work
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assert overload.MethodOverload() == 42;
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assert overload.MethodOverload(15) == 42 + 15;
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// constructor overloading works, too.
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assert (new TestConstructorOverload()).a == 42;
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assert (new TestConstructorOverload(12)).a == 12;
|
||||
// intentionally dodgy expressions work
|
||||
assert malicious.assignNegativeIncrement(42) == -42;
|
||||
assert malicious.tripleAddition(1, 2, 3) == 6;
|
||||
@ -34,5 +51,14 @@ public class Main {
|
||||
{
|
||||
assert malicious.cursedFormatting(i) == i;
|
||||
}
|
||||
// other syntactic sugar
|
||||
assert shenanigance.testAssignment() == 5;
|
||||
assert shenanigance.divEqual() == 234_343_000 / 4;
|
||||
assert shenanigance.testIf(5);
|
||||
// optional parameters
|
||||
assert optionalParameter.oneOptional() == 1;
|
||||
assert optionalParameter.oneOptional(2) == 2;
|
||||
assert optionalParameter.normalAndOptional(1) == 6;
|
||||
assert optionalParameter.normalAndOptional(1, 0) == 4;
|
||||
}
|
||||
}
|
||||
|
11
Test/JavaSources/TestArithmetic.java
Normal file
11
Test/JavaSources/TestArithmetic.java
Normal file
@ -0,0 +1,11 @@
|
||||
public class TestArithmetic {
|
||||
public int basic(int a, int b, int c)
|
||||
{
|
||||
return a + b - c * a / b % c;
|
||||
}
|
||||
|
||||
public boolean logic(boolean a, boolean b, boolean c)
|
||||
{
|
||||
return !a && (c || b);
|
||||
}
|
||||
}
|
12
Test/JavaSources/TestConstructorOverload.java
Normal file
12
Test/JavaSources/TestConstructorOverload.java
Normal file
@ -0,0 +1,12 @@
|
||||
public class TestConstructorOverload {
|
||||
|
||||
public int a = 42;
|
||||
|
||||
TestConstructorOverload() {
|
||||
// nothing here, so a will assume the default value 42.
|
||||
}
|
||||
|
||||
TestConstructorOverload(int a) {
|
||||
this.a = a;
|
||||
}
|
||||
}
|
19
Test/JavaSources/TestLoop.java
Normal file
19
Test/JavaSources/TestLoop.java
Normal file
@ -0,0 +1,19 @@
|
||||
public class TestLoop {
|
||||
public int factorial(int n)
|
||||
{
|
||||
int tally = 1;
|
||||
for(int i = 1; i <= n; i++)
|
||||
{
|
||||
tally *= i;
|
||||
}
|
||||
|
||||
return tally;
|
||||
}
|
||||
|
||||
int weirdFor() {
|
||||
int k = 0;
|
||||
for (; k < 5; k++) {
|
||||
}
|
||||
return k;
|
||||
}
|
||||
}
|
10
Test/JavaSources/TestMethodOverload.java
Normal file
10
Test/JavaSources/TestMethodOverload.java
Normal file
@ -0,0 +1,10 @@
|
||||
public class TestMethodOverload {
|
||||
|
||||
public int MethodOverload() {
|
||||
return 42;
|
||||
}
|
||||
|
||||
public int MethodOverload(int a) {
|
||||
return 42 + a;
|
||||
}
|
||||
}
|
10
Test/JavaSources/TestOptionalParameter.java
Normal file
10
Test/JavaSources/TestOptionalParameter.java
Normal file
@ -0,0 +1,10 @@
|
||||
class TestOptionalParameter {
|
||||
|
||||
int oneOptional(int p = 1) {
|
||||
return p;
|
||||
}
|
||||
|
||||
int normalAndOptional(int a, int b = 2, int c = 3) {
|
||||
return a + b + c;
|
||||
}
|
||||
}
|
@ -5,7 +5,7 @@ public class TestRecursion {
|
||||
|
||||
public TestRecursion(int n)
|
||||
{
|
||||
value = n;
|
||||
this.value = n;
|
||||
|
||||
if(n > 0)
|
||||
{
|
||||
@ -24,4 +24,11 @@ public class TestRecursion {
|
||||
return fibonacci(n - 1) + this.fibonacci(n - 2);
|
||||
}
|
||||
}
|
||||
|
||||
public int ackermann(int m, int n)
|
||||
{
|
||||
if (m == 0) return n + 1;
|
||||
if (n == 0) return ackermann(m - 1, 1);
|
||||
return ackermann(m - 1, ackermann(m, n - 1));
|
||||
}
|
||||
}
|
||||
|
25
Test/JavaSources/TestShenanigance.java
Normal file
25
Test/JavaSources/TestShenanigance.java
Normal file
@ -0,0 +1,25 @@
|
||||
class TestShenanigance {
|
||||
|
||||
int testAssignment() {
|
||||
int x = 1;
|
||||
int y = x = 5;
|
||||
return y;
|
||||
}
|
||||
|
||||
int divEqual() {
|
||||
int x = 234_343_000;
|
||||
x /= 4;
|
||||
return x;
|
||||
}
|
||||
|
||||
boolean testIf(int x) {
|
||||
if (true && x < 8) {
|
||||
char f = 'c';
|
||||
return f > x ;
|
||||
}
|
||||
ifn't {
|
||||
return false;
|
||||
}
|
||||
}
|
||||
|
||||
}
|
15
Test/JavaSources/TestSingleton.java
Normal file
15
Test/JavaSources/TestSingleton.java
Normal file
@ -0,0 +1,15 @@
|
||||
public class TestSingleton {
|
||||
|
||||
TestSingleton instance;
|
||||
|
||||
TestSingleton() {
|
||||
}
|
||||
|
||||
public TestSingleton getInstance() {
|
||||
if (instance == null) {
|
||||
instance = new TestSingleton();
|
||||
}
|
||||
return instance;
|
||||
}
|
||||
|
||||
}
|
@ -7,56 +7,56 @@ import Ast
|
||||
|
||||
|
||||
testSingleEmptyClass = TestCase $
|
||||
assertEqual "expect single empty class hello" [Class "Hello" [] []] $
|
||||
assertEqual "expect single empty class hello" [Class "Hello" [] [] []] $
|
||||
parse [CLASS, IDENTIFIER "Hello", LBRACKET, RBRACKET]
|
||||
testTwoEmptyClasses = TestCase $
|
||||
assertEqual "expect two empty classes" [Class "Class1" [] [], Class "Class2" [] []] $
|
||||
assertEqual "expect two empty classes" [Class "Class1" [] [] [], Class "Class2" [] [] []] $
|
||||
parse [CLASS,IDENTIFIER "Class1",LBRACKET,RBRACKET,CLASS,IDENTIFIER "Class2",LBRACKET,RBRACKET]
|
||||
testBooleanField = TestCase $
|
||||
assertEqual "expect class with boolean field" [Class "WithBool" [] [VariableDeclaration "boolean" "value" Nothing]] $
|
||||
assertEqual "expect class with boolean field" [Class "WithBool" [] [] [VariableDeclaration "boolean" "value" Nothing]] $
|
||||
parse [CLASS,IDENTIFIER "WithBool",LBRACKET,BOOLEAN,IDENTIFIER "value",SEMICOLON,RBRACKET]
|
||||
testIntField = TestCase $
|
||||
assertEqual "expect class with int field" [Class "WithInt" [] [VariableDeclaration "int" "value" Nothing]] $
|
||||
assertEqual "expect class with int field" [Class "WithInt" [] [] [VariableDeclaration "int" "value" Nothing]] $
|
||||
parse [CLASS,IDENTIFIER "WithInt",LBRACKET,INT,IDENTIFIER "value",SEMICOLON,RBRACKET]
|
||||
testCustomTypeField = TestCase $
|
||||
assertEqual "expect class with foo field" [Class "WithFoo" [] [VariableDeclaration "Foo" "value" Nothing]] $
|
||||
assertEqual "expect class with foo field" [Class "WithFoo" [] [] [VariableDeclaration "Foo" "value" Nothing]] $
|
||||
parse [CLASS,IDENTIFIER "WithFoo",LBRACKET,IDENTIFIER "Foo",IDENTIFIER "value",SEMICOLON,RBRACKET]
|
||||
testMultipleDeclarationSameLine = TestCase $
|
||||
assertEqual "expect class with two int fields" [Class "TwoInts" [] [VariableDeclaration "int" "num1" Nothing, VariableDeclaration "int" "num2" Nothing]] $
|
||||
assertEqual "expect class with two int fields" [Class "TwoInts" [] [] [VariableDeclaration "int" "num1" Nothing, VariableDeclaration "int" "num2" Nothing]] $
|
||||
parse [CLASS,IDENTIFIER "TwoInts",LBRACKET,INT,IDENTIFIER "num1",COMMA,IDENTIFIER "num2",SEMICOLON,RBRACKET]
|
||||
testMultipleDeclarations = TestCase $
|
||||
assertEqual "expect class with int and char field" [Class "Multiple" [] [VariableDeclaration "int" "value" Nothing, VariableDeclaration "char" "letter" Nothing]] $
|
||||
assertEqual "expect class with int and char field" [Class "Multiple" [] [] [VariableDeclaration "int" "value" Nothing, VariableDeclaration "char" "letter" Nothing]] $
|
||||
parse [CLASS,IDENTIFIER "Multiple",LBRACKET,INT,IDENTIFIER "value",SEMICOLON,CHAR,IDENTIFIER "letter",SEMICOLON,RBRACKET]
|
||||
testWithModifier = TestCase $
|
||||
assertEqual "expect class with int field" [Class "WithInt" [] [VariableDeclaration "int" "value" Nothing]] $
|
||||
assertEqual "expect class with int field" [Class "WithInt" [] [] [VariableDeclaration "int" "value" Nothing]] $
|
||||
parse [ABSTRACT,CLASS,IDENTIFIER "WithInt",LBRACKET,PUBLIC,INT,IDENTIFIER "value",SEMICOLON,RBRACKET]
|
||||
|
||||
testEmptyMethod = TestCase $
|
||||
assertEqual "expect class with method" [Class "WithMethod" [MethodDeclaration "int" "foo" [] (Block [])] []] $
|
||||
assertEqual "expect class with method" [Class "WithMethod" [] [MethodDeclaration "int" "foo" [] (Block [])] []] $
|
||||
parse [CLASS,IDENTIFIER "WithMethod",LBRACKET,INT,IDENTIFIER "foo",LBRACE,RBRACE,SEMICOLON,RBRACKET]
|
||||
testEmptyPrivateMethod = TestCase $
|
||||
assertEqual "expect class with method" [Class "WithMethod" [MethodDeclaration "int" "foo" [] (Block [])] []] $
|
||||
assertEqual "expect class with method" [Class "WithMethod" [] [MethodDeclaration "int" "foo" [] (Block [])] []] $
|
||||
parse [CLASS,IDENTIFIER "WithMethod",LBRACKET,PRIVATE,INT,IDENTIFIER "foo",LBRACE,RBRACE,LBRACKET,RBRACKET,RBRACKET]
|
||||
testEmptyVoidMethod = TestCase $
|
||||
assertEqual "expect class with method" [Class "WithMethod" [MethodDeclaration "void" "foo" [] (Block [])] []] $
|
||||
assertEqual "expect class with method" [Class "WithMethod" [] [MethodDeclaration "void" "foo" [] (Block [])] []] $
|
||||
parse [CLASS,IDENTIFIER "WithMethod",LBRACKET,VOID,IDENTIFIER "foo",LBRACE,RBRACE,LBRACKET,RBRACKET,RBRACKET]
|
||||
testEmptyMethodWithParam = TestCase $
|
||||
assertEqual "expect class with method with param" [Class "WithParam" [MethodDeclaration "void" "foo" [ParameterDeclaration "int" "param"] (Block [])] []] $
|
||||
assertEqual "expect class with method with param" [Class "WithParam" [] [MethodDeclaration "void" "foo" [ParameterDeclaration "int" "param"] (Block [])] []] $
|
||||
parse [CLASS,IDENTIFIER "WithParam",LBRACKET,VOID,IDENTIFIER "foo",LBRACE,INT,IDENTIFIER "param",RBRACE,SEMICOLON,RBRACKET]
|
||||
testEmptyMethodWithParams = TestCase $
|
||||
assertEqual "expect class with multiple params" [Class "WithParams" [MethodDeclaration "void" "foo" [ParameterDeclaration "int" "p1",ParameterDeclaration "Custom" "p2"] (Block [])] []] $
|
||||
assertEqual "expect class with multiple params" [Class "WithParams" [] [MethodDeclaration "void" "foo" [ParameterDeclaration "int" "p1",ParameterDeclaration "Custom" "p2"] (Block [])] []] $
|
||||
parse [CLASS,IDENTIFIER "WithParams",LBRACKET,VOID,IDENTIFIER "foo",LBRACE,INT,IDENTIFIER "p1",COMMA,IDENTIFIER "Custom",IDENTIFIER "p2",RBRACE,SEMICOLON,RBRACKET]
|
||||
testClassWithMethodAndField = TestCase $
|
||||
assertEqual "expect class with method and field" [Class "WithMethodAndField" [MethodDeclaration "void" "foo" [] (Block []), MethodDeclaration "int" "bar" [] (Block [])] [VariableDeclaration "int" "value" Nothing]] $
|
||||
assertEqual "expect class with method and field" [Class "WithMethodAndField" [] [MethodDeclaration "void" "foo" [] (Block []), MethodDeclaration "int" "bar" [] (Block [])] [VariableDeclaration "int" "value" Nothing]] $
|
||||
parse [CLASS,IDENTIFIER "WithMethodAndField",LBRACKET,VOID,IDENTIFIER "foo",LBRACE,RBRACE,LBRACKET,RBRACKET,INT,IDENTIFIER "value",SEMICOLON,INT,IDENTIFIER "bar",LBRACE,RBRACE,SEMICOLON,RBRACKET]
|
||||
testClassWithConstructor = TestCase $
|
||||
assertEqual "expect class with constructor" [Class "WithConstructor" [MethodDeclaration "void" "<init>" [] (Block [])] []] $
|
||||
assertEqual "expect class with constructor" [Class "WithConstructor" [ConstructorDeclaration "WithConstructor" [] (Block [])] [] []] $
|
||||
parse [CLASS,IDENTIFIER "WithConstructor",LBRACKET,IDENTIFIER "WithConstructor",LBRACE,RBRACE,LBRACKET,RBRACKET,RBRACKET]
|
||||
testConstructorWithParams = TestCase $
|
||||
assertEqual "expect constructor with params" [Class "WithParams" [MethodDeclaration "void" "<init>" [ParameterDeclaration "int" "p1"] (Block [])] []] $
|
||||
assertEqual "expect constructor with params" [Class "WithParams" [ConstructorDeclaration "WithParams" [ParameterDeclaration "int" "p1"] (Block [])] [] []] $
|
||||
parse [CLASS,IDENTIFIER "WithParams",LBRACKET,IDENTIFIER "WithParams",LBRACE,INT,IDENTIFIER "p1",RBRACE,LBRACKET,RBRACKET,RBRACKET]
|
||||
testConstructorWithStatements = TestCase $
|
||||
assertEqual "expect constructor with statement" [Class "WithConstructor" [MethodDeclaration "void" "<init>" [] (Block [Return Nothing])] []] $
|
||||
assertEqual "expect constructor with statement" [Class "WithConstructor" [ConstructorDeclaration "WithConstructor" [] (Block [Return Nothing])] [] []] $
|
||||
parse [CLASS,IDENTIFIER "WithConstructor",LBRACKET,IDENTIFIER "WithConstructor",LBRACE,RBRACE,LBRACKET,RETURN,SEMICOLON,RBRACKET,RBRACKET]
|
||||
|
||||
|
||||
@ -78,13 +78,13 @@ testExpressionIntLiteral = TestCase $
|
||||
assertEqual "expect IntLiteral" (IntegerLiteral 3) $
|
||||
parseExpression [INTEGERLITERAL 3]
|
||||
testFieldWithInitialization = TestCase $
|
||||
assertEqual "expect Class with initialized field" [Class "WithInitField" [] [VariableDeclaration "int" "number" $ Just $ IntegerLiteral 3]] $
|
||||
assertEqual "expect Class with initialized field" [Class "WithInitField" [] [] [VariableDeclaration "int" "number" $ Just $ IntegerLiteral 3]] $
|
||||
parse [CLASS,IDENTIFIER "WithInitField",LBRACKET,INT,IDENTIFIER "number",ASSIGN,INTEGERLITERAL 3,SEMICOLON,RBRACKET]
|
||||
testLocalBoolWithInitialization = TestCase $
|
||||
assertEqual "expect block with with initialized local var" [Block [LocalVariableDeclaration $ VariableDeclaration "boolean" "b" $ Just $ BooleanLiteral False]] $
|
||||
parseStatement [LBRACKET,BOOLEAN,IDENTIFIER "b",ASSIGN,BOOLLITERAL False,SEMICOLON,RBRACKET]
|
||||
testFieldNullWithInitialization = TestCase $
|
||||
assertEqual "expect Class with initialized field" [Class "WithInitField" [] [VariableDeclaration "Object" "bar" $ Just NullLiteral]] $
|
||||
assertEqual "expect Class with initialized field" [Class "WithInitField" [] [] [VariableDeclaration "Object" "bar" $ Just NullLiteral]] $
|
||||
parse [CLASS,IDENTIFIER "WithInitField",LBRACKET,IDENTIFIER "Object",IDENTIFIER "bar",ASSIGN,NULLLITERAL,SEMICOLON,RBRACKET]
|
||||
testReturnVoid = TestCase $
|
||||
assertEqual "expect block with return nothing" [Block [Return Nothing]] $
|
||||
@ -204,6 +204,13 @@ testExpressionConstructorCall = TestCase $
|
||||
assertEqual "expect constructor call" (StatementExpressionExpression (ConstructorCall "Foo" [])) $
|
||||
parseExpression [NEW,IDENTIFIER "Foo",LBRACE,RBRACE]
|
||||
|
||||
testExpresssionExternalMethodCall = TestCase $
|
||||
assertEqual "expect method call on sub" (StatementExpressionExpression (MethodCall (Reference "Obj") "foo" [])) $
|
||||
parseExpression [IDENTIFIER "Obj",DOT,IDENTIFIER "foo",LBRACE,RBRACE]
|
||||
testExpressionAssignWithThis = TestCase $
|
||||
assertEqual "expect assignment on Field" (StatementExpressionExpression (Assignment (BinaryOperation NameResolution (Reference "this") (Reference "x")) (Reference "y"))) $
|
||||
parseExpression [THIS,DOT,IDENTIFIER "x",ASSIGN,IDENTIFIER "y"]
|
||||
|
||||
testStatementIfThen = TestCase $
|
||||
assertEqual "expect empty ifthen" [If (Reference "a") (Block [Block []]) Nothing] $
|
||||
parseStatement [IF,LBRACE,IDENTIFIER "a",RBRACE,LBRACKET,RBRACKET]
|
||||
@ -231,6 +238,40 @@ testStatementPreIncrement = TestCase $
|
||||
assertEqual "expect increment" [StatementExpressionStatement $ PostIncrement $ Reference "a"] $
|
||||
parseStatement [IDENTIFIER "a",INCREMENT,SEMICOLON]
|
||||
|
||||
testForLoop = TestCase $
|
||||
assertEqual "expect for loop" [Block [
|
||||
LocalVariableDeclaration (VariableDeclaration "int" "i" (Just (IntegerLiteral 0))),
|
||||
While (BinaryOperation CompareLessThan (Reference "i") (IntegerLiteral 3)) (Block [Block [], StatementExpressionStatement (PostIncrement (Reference "i"))])
|
||||
]] $
|
||||
parseStatement [FOR,LBRACE,INT,IDENTIFIER "i",ASSIGN,INTEGERLITERAL 0,SEMICOLON,IDENTIFIER "i",LESS,INTEGERLITERAL 3,SEMICOLON,IDENTIFIER "i",INCREMENT,RBRACE,LBRACKET,RBRACKET]
|
||||
testForLoopExpressionlistInInit = TestCase $
|
||||
assertEqual "expect expressionlist in init part of for loop" [Block [
|
||||
StatementExpressionStatement (PostIncrement (Reference "i")),
|
||||
While (BinaryOperation CompareLessThan (Reference "i") (IntegerLiteral 3)) (Block [Block [], StatementExpressionStatement (PostIncrement (Reference "i"))])
|
||||
]] $
|
||||
parseStatement [FOR,LBRACE,IDENTIFIER "i",INCREMENT,SEMICOLON,IDENTIFIER "i",LESS,INTEGERLITERAL 3,SEMICOLON,IDENTIFIER "i",INCREMENT,RBRACE,LBRACKET,RBRACKET]
|
||||
testForLoopMultipleUpdateExpressions = TestCase $
|
||||
assertEqual "expect for loop with multiple update statements" [Block [
|
||||
LocalVariableDeclaration (VariableDeclaration "int" "i" (Just (IntegerLiteral 0))),
|
||||
While (BinaryOperation CompareLessThan (Reference "i") (IntegerLiteral 3)) (Block [Block [], StatementExpressionStatement (PostIncrement (Reference "i")), StatementExpressionStatement (PostIncrement (Reference "k"))])
|
||||
]] $
|
||||
parseStatement [FOR,LBRACE,INT,IDENTIFIER "i",ASSIGN,INTEGERLITERAL 0,SEMICOLON,IDENTIFIER "i",LESS,INTEGERLITERAL 3,SEMICOLON,IDENTIFIER "i",INCREMENT,COMMA,IDENTIFIER "k",INCREMENT,RBRACE,LBRACKET,RBRACKET]
|
||||
testForLoopEmptyFirstPart = TestCase $
|
||||
assertEqual "expect for loop with empty init part" [Block [
|
||||
While (BinaryOperation CompareLessThan (Reference "i") (IntegerLiteral 3)) (Block [Block [], StatementExpressionStatement (PostIncrement (Reference "i"))])
|
||||
]] $
|
||||
parseStatement [FOR,LBRACE,SEMICOLON,IDENTIFIER "i",LESS,INTEGERLITERAL 3,SEMICOLON,IDENTIFIER "i",INCREMENT,RBRACE,LBRACKET,RBRACKET]
|
||||
testForLoopEmtpySecondPart = TestCase $
|
||||
assertEqual "expect for loop with empty expresion part" [Block [
|
||||
While (BooleanLiteral True) (Block [Block [], StatementExpressionStatement (PostIncrement (Reference "i"))])
|
||||
]] $
|
||||
parseStatement [FOR,LBRACE,SEMICOLON,SEMICOLON,IDENTIFIER "i",INCREMENT,RBRACE,LBRACKET,RBRACKET]
|
||||
testForLoopEmtpy = TestCase $
|
||||
assertEqual "expect empty for loop" [Block [While (BooleanLiteral True) (Block [Block []])]] $
|
||||
parseStatement [FOR,LBRACE,SEMICOLON,SEMICOLON,RBRACE,LBRACKET,RBRACKET]
|
||||
|
||||
|
||||
|
||||
|
||||
tests = TestList [
|
||||
testSingleEmptyClass,
|
||||
@ -292,6 +333,8 @@ tests = TestList [
|
||||
testExpressionSimpleFieldAccess,
|
||||
testExpressionFieldSubAccess,
|
||||
testExpressionConstructorCall,
|
||||
testExpresssionExternalMethodCall,
|
||||
testExpressionAssignWithThis,
|
||||
testStatementIfThen,
|
||||
testStatementIfThenElse,
|
||||
testStatementWhile,
|
||||
@ -299,5 +342,11 @@ tests = TestList [
|
||||
testStatementMethodCallNoParams,
|
||||
testStatementConstructorCall,
|
||||
testStatementConstructorCallWithArgs,
|
||||
testStatementPreIncrement
|
||||
testStatementPreIncrement,
|
||||
testForLoop,
|
||||
testForLoopExpressionlistInInit,
|
||||
testForLoopMultipleUpdateExpressions,
|
||||
testForLoopEmptyFirstPart,
|
||||
testForLoopEmtpySecondPart,
|
||||
testForLoopEmtpy
|
||||
]
|
@ -1,69 +0,0 @@
|
||||
# Bytecodegenerierung
|
||||
|
||||
Die Bytecodegenerierung ist letztendlich eine zweistufige Transformation:
|
||||
|
||||
`Getypter AST -> [ClassFile] -> [[Word8]]`
|
||||
|
||||
Vom AST, der bereits den Typcheck durchlaufen hat, wird zunächst eine Abbildung in die einzelnen ClassFiles vorgenommen. Diese ClassFiles werden anschließend in deren Byte-Repräsentation serialisiert.
|
||||
|
||||
## Serialisierung
|
||||
|
||||
Damit Bytecode generiert werden kann, braucht es Strukturen, die die Daten halten, die letztendlich serialisiert werden. Die JVM erwartet den kompilierten Code in handliche Pakete verpackt. Die Struktur dieser Pakete ist [so definiert](https://docs.oracle.com/javase/specs/jvms/se7/html/jvms-4.html).
|
||||
|
||||
Jede Struktur, die in dieser übergreifenden Class File vorkommt, haben wir in Haskell abgebildet. Es gibt z.B die Struktur "ClassFile", die wiederum weitere Strukturen wie z.B Informationen über Felder oder Methoden der Klasse. Alle diese Strukturen implementieren folgendes TypeClass:
|
||||
|
||||
```
|
||||
class Serializable a where
|
||||
serialize :: a -> [Word8]
|
||||
```
|
||||
|
||||
Die Struktur ClassFile ruft für deren Kinder rekursiv diese `serialize` Funktion auf. Am Ende bleibt eine flache Word8-Liste übrig, die Serialisierung ist damit abgeschlossen.
|
||||
|
||||
## Codegenerierung
|
||||
|
||||
Für die erste der beiden Transformationen (`Getypter AST -> [ClassFile]`) werden die Konzepte der "Builder" und "Assembler" eingeführt. Sie sind wie folgt definiert:
|
||||
```
|
||||
type ClassFileBuilder a = a -> ClassFile -> ClassFile
|
||||
type Assembler a = ([ConstantInfo], [Operation], [String]) -> a -> ([ConstantInfo], [Operation], [String])
|
||||
```
|
||||
|
||||
Die Idee hinter beiden ist, dass sie jeweils zwei Inputs haben, wobei der Rückgabewert immer den gleichen Typ hat wie einer der inputs. Das erlaubt es, eine Faltung durchzuführen. Ein ClassFileBuilder z.B bekommt als ersten Parameter den AST, und als zweiten Parameter (und Rückgabewert) eine ClassFile. Soll nun eine Klasse gebaut werden, wird der ClassFileBuilder mit dem AST und einer leeren ClassFile aufgerufen. Der Zustand dieser anfangs leeren ClassFile wird durch alle folgenden Builder/Assembler durchgeschleift, was es erlaubt, nach und nach kleinere Transformationen auf sie anzuwenden.
|
||||
|
||||
Der Nutzer ruft beispielsweise die Funktion `classBuilder` auf. Diese wendet nach und nach folgende Transformationen an:
|
||||
|
||||
```
|
||||
|
||||
methodsWithInjectedConstructor = injectDefaultConstructor methods
|
||||
methodsWithInjectedInitializers = injectFieldInitializers name fields methodsWithInjectedConstructor
|
||||
|
||||
classFileWithFields = foldr fieldBuilder nakedClassFile fields
|
||||
classFileWithMethods = foldr methodBuilder classFileWithFields methodsWithInjectedInitializers
|
||||
classFileWithAssembledMethods = foldr methodAssembler classFileWithMethods methodsWithInjectedInitializers
|
||||
```
|
||||
|
||||
Zuerst wird (falls notwendig) ein leerer Defaultkonstruktor in die Classfile eingefügt. Anschließend wird der AST so modifiziert, dass die Initialisierungen für alle Klassenfelder in allen Konstruktoren stattfinden. Nun beginnen die Faltungen:
|
||||
|
||||
1. Hinzufügen aller Klassenfelder
|
||||
2. Hinzufügen aller Methoden (nur Prototypen)
|
||||
3. Hinzufügen des Bytecodes in allen Methoden
|
||||
|
||||
Die Unterteilung von Schritt 2 und 3 ist deswegen notwendig, weil der Code einer Methode auch eine andere, erst nachher deklarierte Methode aufrufen kann. Nach Schritt 2 sind alle Methoden der Klasse bekannt. Wie beschrieben wird auch hier der Zustand über alle Faltungen mitgenommen. Jeder Schritt hat Zugriff auf alle Daten, die aus dem vorherigen Schritt bleiben. Sukkzessive wird eine korrekte ClassFile aufgebaut.
|
||||
|
||||
Besonders interessant ist hierbei Schritt 3. Dort wird das Verhalten jeder einzelnen Methode in Bytecode übersetzt. In diesem Schritt werden zusätzlich zu den `Buildern` noch die `Assembler` verwendet (Definition siehe oben.) Die Assembler funktionieren ähnlich wie die Builder, arbeiten allerdings nicht auf einer ClassFile, sondern auf dem Inhalt einer Methode: Sie verarbeiten jeweils ein Tupel:
|
||||
|
||||
`([ConstantInfo], [Operation], [String])`
|
||||
|
||||
Dieses repräsentiert:
|
||||
|
||||
`(Konstantenpool, Bytecode, Lokale Variablen)`
|
||||
|
||||
In der Praxis werden oft nur Bytecode und Konstanten hinzugefügt. Prinzipiell können Assembler auch Code/Konstanten entfernen oder modifizieren. Als Beispiel dient hier der Assembler `assembleExpression`:
|
||||
|
||||
```
|
||||
assembleExpression (constants, ops, lvars) (TypedExpression _ NullLiteral) =
|
||||
(constants, ops ++ [Opaconst_null], lvars)
|
||||
```
|
||||
|
||||
Hier werden die Konstanten und lokalen Variablen des Inputs nicht berührt, dem Bytecode wird lediglich die Operation `aconst_null` hinzugefügt. Damit ist das Verhalten des gematchten Inputs - eines Nullliterals - abgebildet.
|
||||
|
||||
Die Assembler rufen sich teilweise rekursiv selbst auf, da ja auch der AST verschachteltes Verhalten abbilden kann. Der Startpunkt für die Assembly einer Methode ist der Builder `methodAssembler`. Dieser entspricht Schritt 3 in der obigen Übersicht.
|
107
doc/bytecode.tex
Normal file
107
doc/bytecode.tex
Normal file
@ -0,0 +1,107 @@
|
||||
\section{Bytecodegenerierung}
|
||||
Die Bytecodegenerierung ist letztendlich eine zweistufige Transformation:
|
||||
|
||||
\vspace{20px}
|
||||
\texttt{Getypter AST -> [ClassFile] -> [[Word8]]}
|
||||
\vspace{20px}
|
||||
|
||||
Vom AST, der bereits den Typcheck durchlaufen hat, wird zunächst eine Abbildung in die einzelnen ClassFiles vorgenommen.
|
||||
Diese ClassFiles werden anschließend in deren Byte-Repräsentation serialisiert.
|
||||
|
||||
\subsection{Codegenerierung}
|
||||
Für die erste der beiden Transformationen (\texttt{Getypter AST -> [ClassFile]}) werden die Konzepte der ``Builder'' und ``Assembler'' eingeführt.
|
||||
Sie sind wie folgt definiert:
|
||||
|
||||
\vspace{20px}
|
||||
\begin{lstlisting}[language=haskell]
|
||||
type ClassFileBuilder a = a -> ClassFile -> ClassFile
|
||||
type Assembler a = ([ConstantInfo], [Operation], [String]) -> a
|
||||
-> ([ConstantInfo], [Operation], [String])
|
||||
\end{lstlisting}
|
||||
\vspace{20px}
|
||||
|
||||
Die Idee hinter beiden ist, dass sie jeweils zwei Inputs haben, wobei der Rückgabewert immer den gleichen Typ hat wie einer der Inputs.
|
||||
Das erlaubt es, eine Faltung durchzuführen. Ein ClassFileBuilder z.B bekommt als ersten Parameter den AST,
|
||||
und als zweiten Parameter (und Rückgabewert) eine ClassFile. Soll nun eine Klasse gebaut werden,
|
||||
wird der ClassFileBuilder mit dem AST und einer leeren ClassFile aufgerufen.
|
||||
Der Zustand dieser anfangs leeren ClassFile wird durch alle folgenden Builder/Assembler durchgeschleift, was es erlaubt,
|
||||
nach und nach kleinere Transformationen auf sie anzuwenden. Der Nutzer ruft beispielsweise die Funktion \texttt{classBuilder} auf.
|
||||
Diese wendet nach und nach folgende Transformationen an:
|
||||
|
||||
\vspace{20px}
|
||||
\begin{enumerate}
|
||||
\item Allen Konstruktoren werden Initialisierer aller Felder hinzugefügt
|
||||
\item Für jedes Feld der Klasse wird ein Eintrag im Konstantenpool \& der Classfile erstellt
|
||||
\item Für jede Methode wird ein Eintrag im Konstantenpool \& der Classfile erstellt
|
||||
\item Allen Methoden wird der zugehörige Bytecode erstellt und zugewiesen
|
||||
\item Allen Konstruktoren wird der zugehörige Bytecode erstellt und zugewiesen
|
||||
\end{enumerate}
|
||||
\vspace{20px}
|
||||
|
||||
Die Unterteilung von Deklaration der Methoden/Konstruktoren und Bytecodeerzeugung ist deswegen notwendig,
|
||||
weil der Code einer Methode auch eine andere, erst nachher deklarierte Methode aufrufen kann.
|
||||
Nach dem Hinzufügen der Deklarationen sind alle Methoden/Konstruktoren der Klasse bekannt.
|
||||
Wie oben beschrieben wird auch hier der Zustand über alle Faltungen mitgenommen.
|
||||
Jeder Schritt hat Zugriff auf alle Daten, die aus dem vorherigen Schritt bleiben. Sukzessive wird eine korrekte ClassFile aufgebaut.
|
||||
Besonders interessant sind hierbei die beiden letzten Schritte. Dort wird das Verhalten jeder einzelnen Methode/Konstruktor in Bytecode übersetzt.
|
||||
In diesem Schritt werden zusätzlich zu den \texttt{Buildern} noch die \texttt{Assembler} verwendet (Definition siehe oben.).
|
||||
Die Assembler funktionieren ähnlich wie die Builder, arbeiten allerdings nicht auf einer ClassFile, sondern auf dem Inhalt einer Methode;
|
||||
Sie verarbeiten jeweils ein Tupel der Form:
|
||||
|
||||
\vspace{20px}
|
||||
\texttt{([ConstantInfo], [Operation], [String])}
|
||||
\vspace{20px}
|
||||
|
||||
Dieses repräsentiert:
|
||||
|
||||
\vspace{20px}
|
||||
\texttt{(Konstantenpool, Bytecode, Lokale Variablen)}
|
||||
\vspace{20px}
|
||||
|
||||
In der Praxis werden meist nur Bytecode und Konstanten hinzugefügt. Prinzipiell können Assembler auch Code/Konstanten entfernen oder modifizieren.
|
||||
Als Beispiel dient hier der Assembler \texttt{assembleExpression}:
|
||||
|
||||
\vspace{20px}
|
||||
\begin{lstlisting}[language=haskell]
|
||||
assembleExpression (constants, ops, lvars) (TypedExpression _ NullLiteral)
|
||||
= (constants, ops ++ [Opaconst_null], lvars)
|
||||
\end{lstlisting}
|
||||
\vspace{20px}
|
||||
|
||||
Hier werden die Konstanten und lokalen Variablen des Inputs nicht berührt, dem Bytecode wird lediglich die Operation \texttt{aconst\_null} hinzugefügt.
|
||||
Damit ist das Verhalten des gematchten Inputs - eines Nullliterals - abgebildet.
|
||||
Die Assembler rufen sich teilweise rekursiv selbst auf, da ja auch der AST verschachteltes Verhalten abbilden kann.
|
||||
Der Startpunkt für die Assembly einer Methode ist der Builder \texttt{methodAssembler}. Dieser entspricht Schritt 3 in der obigen Übersicht.
|
||||
|
||||
\subsection{Serialisierung}
|
||||
Damit Bytecode generiert werden kann, braucht es Strukturen, die die Daten halten, die letztendlich serialisiert werden.
|
||||
Die JVM erwartet den kompilierten Code in handliche Pakete verpackt.
|
||||
Die Struktur dieser Pakete ist \href{https://docs.oracle.com/javase/specs/jvms/se7/html/jvms-4.html}{hier dokumentiert}.
|
||||
Jede Struktur, die in dieser übergreifenden Class File vorkommt, haben wir in Haskell abgebildet.
|
||||
Es gibt z.B die Struktur "ClassFile", die wiederum weitere Strukturen wie z.B Informationen über Felder oder Methoden der Klasse beinhaltet.
|
||||
Alle diese Strukturen implementieren folgende TypeClass:
|
||||
|
||||
\vspace{20px}
|
||||
\begin{lstlisting}[language=haskell]
|
||||
class Serializable a where
|
||||
serialize :: a -> [Word8]
|
||||
\end{lstlisting}
|
||||
\vspace{20px}
|
||||
|
||||
Hier ist ein Beispiel anhand der Serialisierung der einzelnen Operationen:
|
||||
|
||||
\vspace{20px}
|
||||
\begin{lstlisting}[language=haskell]
|
||||
instance Serializable Operation where
|
||||
serialize Opiadd = [0x60]
|
||||
serialize Opisub = [0x64]
|
||||
serialize Opimul = [0x68]
|
||||
...
|
||||
serialize (Opgetfield index) = 0xB4 : unpackWord16 index
|
||||
\end{lstlisting}
|
||||
\vspace{20px}
|
||||
|
||||
Die Struktur ClassFile ruft für deren Kinder rekursiv diese \texttt{serialize} Funktion auf und konkateniert die Ergebnisse.
|
||||
Am Ende bleibt eine flache Word8-Liste übrig, die Serialisierung ist damit abgeschlossen.
|
||||
Da der Typecheck sicherstellt, dass alle referenzierten Methoden/Felder gültig sind,
|
||||
kann die Übersetzung der einzelnen Klassen voneinander unabhängig geschehen.
|
BIN
doc/documentation.pdf
Normal file
BIN
doc/documentation.pdf
Normal file
Binary file not shown.
67
doc/documentation.tex
Normal file
67
doc/documentation.tex
Normal file
@ -0,0 +1,67 @@
|
||||
\documentclass[12pt, parskip=half, headheight=12pt, BCOR=8mm, footheight=16pt]{extarticle}
|
||||
|
||||
% General document formatting
|
||||
\usepackage[margin=1.0in]{geometry}
|
||||
\usepackage[parfill]{parskip}
|
||||
\usepackage[utf8]{inputenc}
|
||||
\usepackage[german]{babel}
|
||||
\usepackage{enumitem}
|
||||
\usepackage{listings}
|
||||
\usepackage{hyperref}
|
||||
|
||||
\renewcommand\descriptionlabel[1]{$\bullet$ \textbf{#1}}
|
||||
\hypersetup{
|
||||
colorlinks=true,
|
||||
linkcolor=blue,
|
||||
filecolor=magenta,
|
||||
urlcolor=cyan,
|
||||
}
|
||||
|
||||
%for code listings
|
||||
\usepackage{listings}
|
||||
\usepackage{xcolor}
|
||||
\definecolor{ListingBackground}{HTML}{F8F8F8}
|
||||
\lstdefinestyle{mystyle}{
|
||||
language=Java, % default language
|
||||
numbers=left, % position of line numbers (left, right)
|
||||
stepnumber=1, % set number to each line
|
||||
numbersep=5pt, % 5pt between number and source code
|
||||
numberstyle=\tiny, % letter size of numbers
|
||||
breaklines=true, % break lines if necessary (true, false)
|
||||
breakautoindent=true, % indenting after break line (true, false)
|
||||
postbreak=\space, % break line after space
|
||||
tabsize=2, % tabulator size
|
||||
basicstyle=\ttfamily\footnotesize, % font style
|
||||
showspaces=false, % show space (true, false)
|
||||
extendedchars=true, % show all Latin1 characters (true, false)
|
||||
captionpos=b, % sets the caption-position to bottom
|
||||
backgroundcolor=\color{ListingBackground}, % source code background
|
||||
xleftmargin=10pt, % margin left
|
||||
xrightmargin=5pt, % margin right
|
||||
frame=single, % border settings
|
||||
frameround=ffff,
|
||||
rulecolor=\color{darkgray}, % border color
|
||||
fillcolor=\color{ListingBackground},
|
||||
aboveskip=20pt,
|
||||
keywordstyle=\color[rgb]{0.133,0.133,0.6},
|
||||
commentstyle=\color[rgb]{0.133,0.545,0.133},
|
||||
stringstyle=\color[rgb]{0.627,0.126,0.941}
|
||||
}
|
||||
\lstset{style=mystyle}
|
||||
|
||||
\let\clearpage\relax
|
||||
|
||||
\begin{document}
|
||||
|
||||
\include{features}
|
||||
\newpage
|
||||
\include{parser}
|
||||
\newpage
|
||||
\include{typecheck}
|
||||
\newpage
|
||||
\include{bytecode}
|
||||
\newpage
|
||||
\include{whodunit}
|
||||
\newpage
|
||||
|
||||
\end{document}
|
35
doc/features.tex
Normal file
35
doc/features.tex
Normal file
@ -0,0 +1,35 @@
|
||||
\section{Sprach-Features}
|
||||
\begin{itemize}
|
||||
\item Klassen
|
||||
\item Felder
|
||||
\item Methoden (mit Parametern)
|
||||
\item Konstruktoren (mit Parametern)
|
||||
\item Standardkonstruktoren
|
||||
\item Lokale Variablen
|
||||
\item Zuweisungen (Feld- und lokale Variablen)
|
||||
\item Arithmetik (\texttt{+, -, *, /, \%,} Klammern, Korrekte Operations-Präzedenz)
|
||||
\item Arithmetische Zuweisungen (\texttt{+=, -=, *=, /=, \%=, \&=, |=, \^{}=})
|
||||
\item Vergleichsoperationen (\texttt{<, >, <=, >=, ==, !=})
|
||||
\item Boolsche Operationen (\texttt{||, \&\&})
|
||||
\item Unäre Operationen (\texttt{-, ~})
|
||||
\item Binar-Operationen (\texttt{\&, |, \^})
|
||||
\item Pre/Post-Inkrement \& Dekrement
|
||||
\item Kontrollflussstrukturen:
|
||||
\begin{itemize}[noitemsep]
|
||||
\item If/Else
|
||||
\item While
|
||||
\item For
|
||||
\item Return (mit/ohne Rückgabewert)
|
||||
\end{itemize}
|
||||
\item Default-Werte für alle Klassenfelder
|
||||
\item Mehrere Klassen in einer Datei
|
||||
\item Implizites \texttt{this}
|
||||
\item Beliebig verschachtelte Namensketten
|
||||
\item Beliebige Deklarationsreihenfolge
|
||||
\item Literale für Integer, Characters, Booleans
|
||||
\item Platzhalter/Separatoren in Integerliteralen (z.B. \texttt{1\_000\_000})
|
||||
\item Deklaration und Zuweisung in einer Anweisung
|
||||
\item Beliebig verschachtelte Blöcke
|
||||
\item Überladung von Methoden \& Konstruktoren
|
||||
\item Parameter mit Standardwerten
|
||||
\end{itemize}
|
5
doc/generate.sh
Executable file → Normal file
5
doc/generate.sh
Executable file → Normal file
@ -1,4 +1 @@
|
||||
#!/usr/bin/sh
|
||||
|
||||
pandoc bytecode.md -o bytecode.docx
|
||||
pandoc bytecode.md -o bytecode.pdf
|
||||
pdflatex documentation.tex
|
88
doc/parser.tex
Normal file
88
doc/parser.tex
Normal file
@ -0,0 +1,88 @@
|
||||
\section{Lexer \& Parser}
|
||||
\subsection{Lexer}
|
||||
|
||||
Der Lexer wurde mit dem Alex tool implementiert. Dieser ist dafür zuständig den langen String in einzelne Tokens umzuwandeln. In der Alex Datei gibt es für jedes Token einen regulären Ausdruck. Bei den meisten Tokens ist das einfach das Schlüsselwort. Etwas komplexer waren Identifier, Integerliterale Strings und Chars. Für die Definition wurde sich eng an die offizielle Java Language Specification gehalten. Es ist beispielsweise auch möglich Unterstriche in Integerliterale einzubauen (Bsp.: \verb|234_343_000|) Es sind fast alle Schlüsselwörter von Java im Lexer implementiert, auch wenn nicht alle davon vom Parser geparst werden können. Whitespace und Kommentare werden direkt ignoriert und verworfen. Für Charliterale und Integerliterale gibt es auch spezielle Fehlermeldungen. Die meisten Tokens haben nur die Information, zu welchem Keyword sie gehören. Eine Ausnahme bilden der Identifier und die Literale. Für den Identifier wird noch der Name gespeichert und für die Literale der entsprechende Wert. Mit der Funktion alexScanTokens kann dann ein beliebiger String in Tokens umgewandelt werden.
|
||||
|
||||
Die komplexeren Tokens haben Unittests, welche mit dem Testframework HUnit geschrieben wurden. Es gibt Tests für Kommentare, Identifier, Literale und ein paar weitere Tokens.
|
||||
|
||||
\subsection{Parser}
|
||||
|
||||
Der Parser wurde mit dem Happy tool implementiert. Er baut aus einer Liste von Tokens einen ungetypten AST. Wir haben bereits eine Grammatik bekommen und mussten für die einzelnen Regeln noch die Rückgabewerte angeben.
|
||||
|
||||
Um den Parser aufzubauen wurde zuerst ein Großteil der Grammatik auskommentiert und Stück für Stück wurden die Rückgabewerte hinzugefügt. Immer wenn ein neues Feature umgesetzt wurde, wurde dafür ein weiterer Unit Test geschrieben. Es gibt also für jede komplexe Ableitungsregel mindestens einen Unittest.
|
||||
|
||||
\subsubsection{Klassenaufbau}
|
||||
Als erstes wurden leere Konstruktoren Methoden und Felder umgesetzt. Da in Java Konstruktoren, Methoden und Felder durcheinander vorkommen können geben die Ableitungsregeln einen Datentyp namens MemberDeclaration zurück, welcher eines von den drei enthalten kann. Die \verb|classbodydeclarations| Regel baut dann einen 3-Tupel mit einer Liste aus Konstruktoren, einer aus Methoden und einer aus Feldern. Über Pattern Matching werden diese Listen dann erweitert und in der darüberliegenden Regel schließlich extrahiert.
|
||||
|
||||
\pagebreak
|
||||
Bei folgender Klasse:
|
||||
\begin{lstlisting}[language=Java]
|
||||
class TestClass {
|
||||
int field;
|
||||
|
||||
TestClass() {}
|
||||
|
||||
void foo() {}
|
||||
}
|
||||
\end{lstlisting}
|
||||
würde die Regel folgendes Tupel zurückgeben:
|
||||
\begin{lstlisting}[language=Haskell]
|
||||
(
|
||||
[ConstructorDeclaration "TestClass" [] (Block [])],
|
||||
[MethodDeclaration "void" "foo" [] (Block [])],
|
||||
[VariableDeclaration "int" "field" Nothing]
|
||||
)
|
||||
\end{lstlisting}
|
||||
und folgende Klasse wird erstellt
|
||||
\begin{lstlisting}[language=Haskell]
|
||||
Class "TestClass"
|
||||
[ConstructorDeclaration "TestClass" [] (Block [])]
|
||||
[MethodDeclaration "void" "foo" [] (Block [])]
|
||||
[VariableDeclaration "int" "field" Nothing]
|
||||
\end{lstlisting}
|
||||
Das Nothing ist in diesem Fall ein Platzhalter für eine Zuweisung, da unser Compiler auch Zuweisung bei der Felddeklaration unterstützt.
|
||||
|
||||
\subsubsection{Syntactic Sugar}
|
||||
|
||||
In Java ist es möglich mehrere Variablen in einer Zeile zu deklarieren (Bsp.: \verb|int x, y;|). Beim Parsen ergibt sich dann die Schwierigkeit, dass man in dem Moment, in dem man die Variable parst, nicht weiß welchen Datentyp diese hat. Aus diesem Grund gibt es den Datentyp Declarator, welcher nur den Identifier und eventuell eine Zuweisung enthält. In den darüberliegenden Regeln \verb|fielddeclaration| und \verb|localvariabledeclaration| wird dann die Typinformation hinzugefügt mithilfe der Funktion \verb|convertDeclarator|.
|
||||
|
||||
Für die Zuweisung wird auch die Kombination mit Rechenoperatoren unterstützt. Das ganze ist durch Syntactic Sugar im Parser umgesetzt. Wenn es einen Zuweisungsoperator gibt, dann wird der Ausdruck in eine Zuweisung und Rechnung aufgeteilt. Bsp.: \verb|x += 3;| wird umgewandelt in \verb|x = x + 3|.
|
||||
|
||||
For-Schleifen wurden auch rein im Parser durch Syntactic Sugar implementiert. Eine For-Schleife wird dabei in eine While-Schleife umgewandelt. Dafür wird zuerst ein Block erstellt, sodass die deklarierten Variablen auch nur für den Bereich der Schleife gültig sind. Die Bedingung der For-Schleife kann in die While-Schleife übernommen werden. Innerhalb der While-Schleife folgen zuerst die Statements, die im Block der For-Schleife waren und danach die Update-Statements.
|
||||
|
||||
\begin{lstlisting}[language=Java]
|
||||
for (int i = 0; i < 9; i++) {
|
||||
foo();
|
||||
}
|
||||
\end{lstlisting}
|
||||
wird umgewandelt in:
|
||||
\begin{lstlisting}[language=Java]
|
||||
{
|
||||
int i = 0;
|
||||
while (i < 9) {
|
||||
foo();
|
||||
i++;
|
||||
}
|
||||
}
|
||||
\end{lstlisting}
|
||||
|
||||
Es wurden auch Parameter mit Standardwerten im Parser implementiert. Dieses Feature ist in der aktuellen Java Version (Java 22) noch nicht implementiert. Der Parser macht sich dafür das Überladen von Methoden zunutze. Er generiert für jedes Parameter mit Standardwert eine weitere Funktion, welche die ursprüngliche Funktion mit einem Standardwert aufruft.
|
||||
|
||||
%\lstinputlisting[language=Java,firstline=7,lastline=9]{../Test/JavaSources/TestOptionalParameter.java}
|
||||
\begin{lstlisting}[language=Java]
|
||||
int normalAndOptional(int a, int b = 2, int c = 3) {
|
||||
return a + b + c;
|
||||
}
|
||||
\end{lstlisting}
|
||||
wird umgewandelt in:
|
||||
\begin{lstlisting}
|
||||
int normalAndOptional(int a) {
|
||||
return normalAndOptional(a, 2);
|
||||
}
|
||||
int normalAndOptional(int a, int b) {
|
||||
return normalAndOptional(a, b, 3);
|
||||
}
|
||||
int normalAndOptional(int a, int b, int c) {
|
||||
return a + b + c;
|
||||
}
|
||||
\end{lstlisting}
|
@ -1,55 +0,0 @@
|
||||
# Typcheck (Fabian Noll)
|
||||
|
||||
## Überblick und Struktur
|
||||
|
||||
Die Typprüfung beginnt mit der Funktion `typeCheckCompilationUnit`, die eine Kompilationseinheit als Eingabe erhält. Diese Kompilationseinheit besteht aus einer Liste von Klassen. Jede Klasse wird einzeln durch die Funktion `typeCheckClass` überprüft. Innerhalb dieser Funktion wird eine Symboltabelle erstellt, die den Namen der Klasse als Typ und `this` als Identifier enthält. Diese Symboltabelle wird verwendet, um Typinformationen nach dem Lokalitätsprinzip während der Typprüfung zugänglich zu machen und zu verwalten.
|
||||
|
||||
Die Typprüfung einer Klasse umfasst die Überprüfung aller Methoden und Felder. Die Methode `typeCheckMethodDeclaration` ist für die Typprüfung einzelner Methodendeklarationen verantwortlich. Sie überprüft den Rückgabetyp der Methode, die Parameter und den Methodenrumpf. Der Methodenrumpf wird durch rekursive Aufrufe von `typeCheckStatement` überprüft, die verschiedene Arten von Anweisungen wie If-Anweisungen, While-Schleifen, Rückgabeanweisungen und Blockanweisungen behandelt.
|
||||
|
||||
## Ablauf und Symboltabellen
|
||||
|
||||
Eine zentrale Komponente des Typecheckers ist die Symboltabelle (symtab), die Informationen über die Bezeichner und ihre zugehörigen Datentypen speichert. Die Symboltabelle wird kontinuierlich angepasst, während der Typechecker die verschiedenen Teile des Programms durchläuft.
|
||||
|
||||
### Anpassung der Symboltabelle
|
||||
|
||||
- **Klassenkontext**:
|
||||
Beim Typcheck einer Klasse wird eine initiale Symboltabelle erstellt, die die `this`-Referenz enthält. Dies geschieht in der Funktion `typeCheckClass`.
|
||||
|
||||
- **Methodenkontext**:
|
||||
Innerhalb einer Methode wird die Symboltabelle um die Parameter der Methode erweitert sowie den Rückgabetyp der Methode, um die einzelnen Returns dagegen zu prüfen. Dies geschieht in `typeCheckMethodDeclaration`.
|
||||
|
||||
- **Blockkontext**:
|
||||
Bei der Überprüfung eines Blocks (`typeCheckStatement` für Block) wird die Symboltabelle für jede Anweisung innerhalb des Blocks aktualisiert. Lokale Variablen, die innerhalb des Blocks deklariert werden, werden zur Symboltabelle hinzugefügt. Das bedeutet, dass automatisch, sobald der Block zu Ende ist, alle dort deklarierten Variablen danach nicht mehr zugänglich sind.
|
||||
|
||||
### Unterscheidung zwischen lokalen und Feldvariablen
|
||||
|
||||
Bei der Typprüfung von Referenzen (`typeCheckExpression` für Reference) wird zuerst in der Symboltabelle nach dem Bezeichner gesucht. Sollte dieser gefunden werden, handelt es sich um eine lokale Variable. Wenn der Bezeichner nicht gefunden wird, wird angenommen, dass es sich um eine Feldvariable handelt. In diesem Fall wird die Klasse, zu der die `this`-Referenz gehört, durchsucht, um die Feldvariable zu finden. Dies ermöglicht die Unterscheidung zwischen lokalen Variablen und Feldvariablen. Dies ist auch nur möglich, da wir die Feldvariablen und Methoden nicht in die Symboltabelle gelegt haben und stattdessen nur die `this`-Referenz.
|
||||
|
||||
## Fehlerbehandlung
|
||||
|
||||
Ein zentraler Aspekt des Typecheckers ist die Fehlerbehandlung. Bei Typinkonsistenzen oder ungültigen Operationen werden aussagekräftige Fehlermeldungen generiert. Beispiele für solche Fehlermeldungen sind:
|
||||
|
||||
- **Typinkonsistenzen**:
|
||||
Wenn der Rückgabetyp einer Methode nicht mit dem deklarierten Rückgabetyp übereinstimmt. Oder aber auch die Anzahl der Parameter nicht übereinstimmt.
|
||||
|
||||
- **Ungültige Operationen**:
|
||||
Wenn eine arithmetische Operation auf inkompatiblen Typen durchgeführt wird.
|
||||
|
||||
- **Nicht gefundene Bezeichner**:
|
||||
Wenn eine Referenz auf eine nicht definierte Variable verweist.
|
||||
|
||||
Diese Fehlermeldungen helfen Entwicklern, die Ursachen von Typfehlern schnell zu identifizieren und zu beheben. Generell sind diese oftmals sehr spezifisch, was das Problem recht schnell identifizieren sollte. Z.B. falsche Reihenfolge / falsche Typen der Parameter beim Methodenaufruf sind direkt erkennbar.
|
||||
|
||||
## Typprüfung von Kontrollstrukturen und Blöcken
|
||||
|
||||
### If-Anweisungen
|
||||
|
||||
Bei der Typprüfung einer If-Anweisung (`typeCheckStatement` für If) wird zuerst der Typ der Bedingung überprüft, um sicherzustellen, dass es sich um einen booleschen Ausdruck handelt. Anschließend werden die Then- und Else-Zweige geprüft. Der Typ der If-Anweisung selbst wird durch die Vereinheitlichung der Typen der Then- und Else-Zweige bestimmt. Falls einer der Zweige keinen Rückgabewert hat, wird angenommen, dass der Rückgabewert `void` ist. Dies wurde so gelöst, um im Typchecker feststellen zu können, ob beide Zweige einen Return haben. Wenn nur einer der Zweige ein Return hat, wird im umliegenden Block ein weiteres benötigt, was durch den Typ `void` erzwungen wird. Dadurch weiß der Typchecker Bescheid.
|
||||
|
||||
### Block-Anweisungen
|
||||
|
||||
Die Typprüfung eines Blocks erfolgt in `typeCheckStatement` für Block. Jede Anweisung im Block wird nacheinander überprüft und die Symboltabelle wird entsprechend aktualisiert. Der Typ des Blocks wird durch die Vereinheitlichung der Typen aller Anweisungen im Block bestimmt. Wenn der Block keine Anweisungen hat, wird der Typ `void` angenommen.
|
||||
|
||||
### Rückgabeanweisungen
|
||||
|
||||
Die Typprüfung einer Rückgabeanweisung (`typeCheckStatement` für Return) überprüft, ob der Rückgabewert der Anweisung mit dem deklarierten Rückgabetyp der Methode übereinstimmt. Dafür wurde zu Beginn der Methodentypprüfung der Rückgabetyp der Methode in die Symboltabelle eingetragen. Wenn der Rückgabewert `null` ist, wird überprüft, ob der deklarierte Rückgabetyp ein Objekttyp ist. Dies stellt sicher, dass Methoden immer den korrekten Typ zurückgeben. Generell wird bei der Prüfung nach dem UpperBound geschaut und ebenfalls wird nachgeschaut, ob, wenn der Rückgabetyp `Object` ist, der Return-Wert auch eine tatsächlich existierende Klasse ist, indem in die Klassentabelle geschaut wird.
|
105
doc/typecheck.tex
Normal file
105
doc/typecheck.tex
Normal file
@ -0,0 +1,105 @@
|
||||
\section{Typecheck}
|
||||
\subsection{Überblick \& Struktur}
|
||||
|
||||
Die Typprüfung beginnt mit der Funktion \texttt{typeCheckCompilationUnit}, die eine Kompilationseinheit als Eingabe erhält.
|
||||
Diese Kompilationseinheit besteht aus einer Liste von Klassen. Jede Klasse wird einzeln durch die Funktion \texttt{typeCheckClass} überprüft.
|
||||
Innerhalb dieser Funktion wird eine Symboltabelle erstellt, die den Namen der Klasse als Typ und \texttt{this} als Identifier enthält.
|
||||
Diese Symboltabelle wird verwendet, um Typinformationen nach dem Lokalitätsprinzip während der Typprüfung zugänglich zu machen und zu verwalten.
|
||||
Die Typprüfung einer Klasse umfasst die Überprüfung aller Konstruktoren, Methoden und Felder.
|
||||
Die Methode \texttt{typeCheckConstructorDeclaration} ist für die Typprüfung einzelner Konstruktordeklarationen verantwortlich,
|
||||
während \texttt{typeCheckMethodDeclaration} für die Typprüfung einzelner Methodendeklarationen zuständig ist.
|
||||
Beide Funktionen überprüfen die Parameter und den Rumpf der jeweiligen Konstruktoren bzw. Methoden.
|
||||
Der Rumpf wird durch rekursive Aufrufe von \texttt{typeCheckStatement} überprüft, die verschiedene Arten von Anweisungen wie If-Anweisungen,
|
||||
While-Schleifen, Rückgabeanweisungen und Blockanweisungen behandelt.
|
||||
|
||||
\subsection{Ablauf \& Symboltabellen}
|
||||
|
||||
Eine zentrale Komponente des Typecheckers ist die Symboltabelle ("symtab"), die Informationen über die Bezeichner und ihre zugehörigen Datentypen speichert.
|
||||
Die Symboltabelle wird kontinuierlich angepasst, während der Typechecker die verschiedenen Teile des Programms durchläuft.
|
||||
|
||||
\subsubsection{Anpassung der Symboltabelle}
|
||||
|
||||
\begin{description}
|
||||
\item[Klassenkontext] Beim Typcheck einer Klasse wird eine initiale Symboltabelle erstellt, die die \texttt{this}-Referenz enthält.
|
||||
Dies geschieht in der Funktion \texttt{typeCheckClass}.
|
||||
\item[Konstruktorkontext] Innerhalb eines Konstruktors wird die Symboltabelle um die Parameter des Konstruktors erweitert.
|
||||
Dies geschieht in \texttt{typeCheckConstructorDeclaration}. Der Rückgabetyp eines Konstruktors ist implizit \texttt{void},
|
||||
was überprüft wird, um sicherzustellen, dass kein Wert zurückgegeben wird.
|
||||
\item[Methodenkontext] Innerhalb einer Methode wird die Symboltabelle um die Parameter der Methode erweitert sowie den Rückgabetyp der Methode,
|
||||
um die einzelnen Returns dagegen zu prüfen. Dies geschieht in \texttt{typeCheckMethodDeclaration}.
|
||||
\item[Blockkontext] Bei der Überprüfung eines Blocks (\texttt{typeCheckStatement} für Block) wird die Symboltabelle für jede Anweisung
|
||||
innerhalb des Blocks aktualisiert. Lokale Variablen, die innerhalb des Blocks deklariert werden, werden zur Symboltabelle hinzugefügt.
|
||||
Das bedeutet, dass automatisch, sobald der Block zu Ende ist, alle dort deklarierten Variablen danach nicht mehr zugänglich sind.
|
||||
\end{description}
|
||||
|
||||
\subsubsection{Unterscheidung zwischen lokalen und Feldvariablen}
|
||||
|
||||
Bei der Typprüfung von Referenzen (\texttt{typeCheckExpression} für Reference) wird zuerst in der Symboltabelle nach dem Bezeichner gesucht.
|
||||
Sollte dieser gefunden werden, handelt es sich um eine lokale Variable. Wenn der Bezeichner nicht gefunden wird, wird angenommen,
|
||||
dass es sich um eine Feldvariable handelt. In diesem Fall wird die Klasse, zu der die \texttt{this}-Referenz gehört, durchsucht,
|
||||
um die Feldvariable zu finden. Dies ermöglicht die Unterscheidung zwischen lokalen Variablen und Feldvariablen.
|
||||
Dies ist auch nur möglich, da wir die Feldvariablen und Methoden nicht in die Symboltabelle gelegt haben und stattdessen nur die \texttt{this}-Referenz.
|
||||
|
||||
\subsection{Fehlerbehandlung}
|
||||
|
||||
Ein zentraler Aspekt des Typecheckers ist die Fehlerbehandlung. Bei Typinkonsistenzen oder ungültigen Operationen werden
|
||||
aussagekräftige Fehlermeldungen generiert. Beispiele für solche Fehlermeldungen sind:
|
||||
|
||||
\begin{description}
|
||||
\item[Typinkonsistenzen] Wenn der Rückgabetyp einer Methode nicht mit dem deklarierten Rückgabetyp übereinstimmt oder die Anzahl der Parameter nicht übereinstimmt.
|
||||
\item[Ungültige Operationen] Wenn eine arithmetische Operation auf inkompatiblen Typen durchgeführt wird.
|
||||
\item[Nicht gefundene Bezeichner] Wenn eine Referenz auf eine nicht definierte Variable verweist.
|
||||
\end{description}
|
||||
|
||||
Diese Fehlermeldungen helfen Entwicklern, die Ursachen von Typfehlern schnell zu identifizieren und zu beheben.
|
||||
Generell sind diese oftmals sehr spezifisch, was das Problem recht schnell identifizieren sollte.
|
||||
Z.B. falsche Reihenfolge / falsche Typen der Parameter beim Methodenaufruf sind direkt erkennbar.
|
||||
|
||||
\subsection{Typprüfung von Kontrollstrukturen und Blöcken}
|
||||
\subsubsection{If-Anweisungen}
|
||||
Bei der Typprüfung einer If-Anweisung (\texttt{typeCheckStatement} für If) wird zuerst der Typ der Bedingung überprüft, um sicherzustellen,
|
||||
dass es sich um einen booleschen Ausdruck handelt. Anschließend werden die Then- und Else-Zweige geprüft.
|
||||
Der Typ der If-Anweisung selbst wird durch die Vereinheitlichung der Typen der Then- und Else-Zweige bestimmt.
|
||||
Falls einer der Zweige keinen Rückgabewert hat, wird angenommen, dass der Rückgabewert \texttt{void} ist.
|
||||
Dies wurde so gelöst, um im Typchecker feststellen zu können, ob beide Zweige einen Return haben.
|
||||
Wenn nur einer der Zweige ein Return hat, wird im umliegenden Block ein weiteres benötigt, was durch den Typ \texttt{void} erzwungen wird.
|
||||
Dadurch weiß der Typchecker Bescheid.
|
||||
|
||||
\subsubsection{Block-Anweisungen}
|
||||
Die Typprüfung eines Blocks erfolgt in \texttt{typeCheckStatement} für Block.
|
||||
Jede Anweisung im Block wird nacheinander überprüft und die Symboltabelle wird entsprechend aktualisiert.
|
||||
Der Typ des Blocks wird durch die Vereinheitlichung der Typen aller Anweisungen im Block bestimmt.
|
||||
Wenn der Block keine Anweisungen hat, wird der Typ \texttt{void} angenommen.
|
||||
|
||||
\subsubsection{Rückgabeanweisungen}
|
||||
Die Typprüfung einer Rückgabeanweisung (\texttt{typeCheckStatement} für Return) überprüft,
|
||||
ob der Rückgabewert der Anweisung mit dem deklarierten Rückgabetyp der Methode übereinstimmt.
|
||||
Dafür wurde zu Beginn der Methodentypprüfung der Rückgabetyp der Methode in die Symboltabelle eingetragen. Wenn der Rückgabewert \texttt{null} ist,
|
||||
wird überprüft, ob der deklarierte Rückgabetyp ein Objekttyp ist. Dies stellt sicher, dass Methoden immer den korrekten Typ zurückgeben.
|
||||
Generell wird bei der Prüfung nach dem UpperBound geschaut und ebenfalls wird nachgeschaut, ob, wenn der Rückgabetyp \texttt{Object} ist,
|
||||
der Return-Wert auch eine tatsächlich existierende Klasse ist, indem in die Klassentabelle geschaut wird.
|
||||
|
||||
\subsubsection{Konstruktorüberladung und -prüfung}
|
||||
Die Typprüfung unterstützt Konstruktorüberladung. Bei der Typprüfung von Konstruktoraufrufen (\texttt{typeCheckStatementExpression}
|
||||
für \texttt{ConstructorCall}) wird überprüft, ob es mehrere Konstruktoren mit derselben Anzahl von Parametern gibt.
|
||||
Falls mehrere passende Konstruktoren gefunden werden, wird ein Fehler gemeldet.
|
||||
|
||||
\begin{description}
|
||||
\item[Parameterabgleich] Die Parameter eines Konstruktors werden gegen die Argumente des Aufrufs abgeglichen.
|
||||
Dies umfasst die Prüfung der Typen und, falls es sich um \texttt{null} handelt, die Überprüfung, ob der Parameter ein Objekttyp ist.
|
||||
\item[Fehlerbehandlung] Wenn kein passender Konstruktor gefunden wird, wird eine detaillierte Fehlermeldung generiert,
|
||||
die die erwarteten Signaturen und die tatsächlichen Argumenttypen anzeigt. Wenn mehrere passende Konstruktoren gefunden werden,
|
||||
wird ebenfalls ein Fehler gemeldet.
|
||||
\end{description}
|
||||
|
||||
\subsubsection{Methodenüberladung und -prüfung}
|
||||
Die Typprüfung unterstützt auch Methodenüberladung. Bei der Typprüfung von Methodenaufrufen (\texttt{typeCheckStatementExpression} für \texttt{MethodCall})
|
||||
wird überprüft, ob es mehrere Methoden mit demselben Namen, aber unterschiedlichen Parametertypen gibt.
|
||||
|
||||
\begin{description}
|
||||
\item[Parameterabgleich] Die Parameter einer Methode werden gegen die Argumente des Aufrufs abgeglichen.
|
||||
Dies umfasst die Prüfung der Typen und, falls es sich um \texttt{null} handelt, die Überprüfung, ob der Parameter ein Objekttyp ist.
|
||||
\item[Fehlerbehandlung] Wenn keine passende Methode gefunden wird, wird eine detaillierte Fehlermeldung generiert,
|
||||
die die erwarteten Signaturen und die tatsächlichen Argumenttypen anzeigt. Wenn mehrere passende Methoden gefunden werden,
|
||||
wird ebenfalls ein Fehler gemeldet.
|
||||
\end{description}
|
19
doc/whodunit.tex
Normal file
19
doc/whodunit.tex
Normal file
@ -0,0 +1,19 @@
|
||||
\section{Aufgabenverteilung}
|
||||
\begin{description}
|
||||
\item[Marvin Schlegel] Parser \& Lexer
|
||||
\item[Fabian Noll] Semantik- \& Typcheck
|
||||
\item[Christian Brier] Bytecodegenerierung
|
||||
\item[Matthias Raba] Bytecodegenerierung
|
||||
\end{description}
|
||||
\vspace{20px}
|
||||
|
||||
Marvin Schlegel und Fabian Noll haben ihre Teilaufgaben eigenständig bearbeitet.
|
||||
|
||||
Die Bytecodegenerierung wurde von Matthias Raba und Christian Brier im Stile des Pair Programmings zu zweit erarbeitet.
|
||||
Durch bisher gute Erfahrungen in vorherigen Projekten, sowie dem Interesse, alle Teile der Bytecodegenerierung zu sehen,
|
||||
wurde diese Programmierungsform als die Beste ausgewählt.
|
||||
|
||||
Während der Implementierungsphase wurde viel zwischen den 3 einzelnen Teams kommuniziert.
|
||||
Wurden Fehler in einer der Komponenten gefunden, wurden die jeweiligen Verantwortlichen informiert um das Problem zu beheben.
|
||||
Jedes der Teams arbeitete auf einem eigenen Branch, die einzelnen Beiträge wurde regelmäßig auf dem master-Branch zusammengeführt.
|
||||
Insgesamt lief die Implementierungsphase wie geplant und ohne weitere Komplikationen ab.
|
@ -18,7 +18,6 @@ executable compiler
|
||||
other-modules: Parser.Lexer,
|
||||
Parser.JavaParser,
|
||||
Ast,
|
||||
Example,
|
||||
Typecheck,
|
||||
ByteCode.Util,
|
||||
ByteCode.ByteUtil,
|
||||
@ -42,10 +41,4 @@ test-suite tests
|
||||
Parser.JavaParser,
|
||||
Ast,
|
||||
TestLexer,
|
||||
TestParser,
|
||||
ByteCode.Util,
|
||||
ByteCode.ByteUtil,
|
||||
ByteCode.ClassFile,
|
||||
ByteCode.Assembler,
|
||||
ByteCode.Builder,
|
||||
ByteCode.Constants
|
||||
TestParser
|
||||
|
@ -6,8 +6,9 @@ type Identifier = String
|
||||
|
||||
data ParameterDeclaration = ParameterDeclaration DataType Identifier deriving (Show, Eq)
|
||||
data VariableDeclaration = VariableDeclaration DataType Identifier (Maybe Expression) deriving (Show, Eq)
|
||||
data Class = Class DataType [MethodDeclaration] [VariableDeclaration] deriving (Show, Eq)
|
||||
data Class = Class DataType [ConstructorDeclaration] [MethodDeclaration] [VariableDeclaration] deriving (Show, Eq)
|
||||
data MethodDeclaration = MethodDeclaration DataType Identifier [ParameterDeclaration] Statement deriving (Show, Eq)
|
||||
data ConstructorDeclaration = ConstructorDeclaration Identifier [ParameterDeclaration] Statement deriving (Show, Eq)
|
||||
|
||||
data Statement
|
||||
= If Expression Statement (Maybe Statement)
|
||||
@ -23,11 +24,11 @@ data StatementExpression
|
||||
= Assignment Expression Expression
|
||||
| ConstructorCall DataType [Expression]
|
||||
| MethodCall Expression Identifier [Expression]
|
||||
| TypedStatementExpression DataType StatementExpression
|
||||
| PostIncrement Expression
|
||||
| PostDecrement Expression
|
||||
| PreIncrement Expression
|
||||
| PreDecrement Expression
|
||||
| TypedStatementExpression DataType StatementExpression
|
||||
deriving (Show, Eq)
|
||||
|
||||
data BinaryOperator
|
||||
|
@ -12,12 +12,12 @@ type Assembler a = ([ConstantInfo], [Operation], [String]) -> a -> ([ConstantInf
|
||||
|
||||
assembleExpression :: Assembler Expression
|
||||
assembleExpression (constants, ops, lvars) (TypedExpression _ (BinaryOperation op a b))
|
||||
| elem op [Addition, Subtraction, Multiplication, Division, Modulo, BitwiseAnd, BitwiseOr, BitwiseXor, And, Or] = let
|
||||
| op `elem` [Addition, Subtraction, Multiplication, Division, Modulo, BitwiseAnd, BitwiseOr, BitwiseXor, And, Or] = let
|
||||
(aConstants, aOps, _) = assembleExpression (constants, ops, lvars) a
|
||||
(bConstants, bOps, _) = assembleExpression (aConstants, aOps, lvars) b
|
||||
in
|
||||
(bConstants, bOps ++ [binaryOperation op], lvars)
|
||||
| elem op [CompareEqual, CompareNotEqual, CompareLessThan, CompareLessOrEqual, CompareGreaterThan, CompareGreaterOrEqual] = let
|
||||
| op `elem` [CompareEqual, CompareNotEqual, CompareLessThan, CompareLessOrEqual, CompareGreaterThan, CompareGreaterOrEqual] = let
|
||||
(aConstants, aOps, _) = assembleExpression (constants, ops, lvars) a
|
||||
(bConstants, bOps, _) = assembleExpression (aConstants, aOps, lvars) b
|
||||
cmp_op = comparisonOperation op 9
|
||||
@ -60,7 +60,7 @@ assembleExpression (constants, ops, lvars) (TypedExpression _ (UnaryOperation Mi
|
||||
assembleExpression (constants, ops, lvars) (TypedExpression dtype (LocalVariable name))
|
||||
| name == "this" = (constants, ops ++ [Opaload 0], lvars)
|
||||
| otherwise = let
|
||||
localIndex = findIndex ((==) name) lvars
|
||||
localIndex = elemIndex name lvars
|
||||
isPrimitive = elem dtype ["char", "boolean", "int"]
|
||||
in case localIndex of
|
||||
Just index -> (constants, ops ++ if isPrimitive then [Opiload (fromIntegral index)] else [Opaload (fromIntegral index)], lvars)
|
||||
@ -69,7 +69,7 @@ assembleExpression (constants, ops, lvars) (TypedExpression dtype (LocalVariable
|
||||
assembleExpression (constants, ops, lvars) (TypedExpression dtype (StatementExpressionExpression stmtexp)) =
|
||||
assembleStatementExpression (constants, ops, lvars) stmtexp
|
||||
|
||||
assembleExpression _ expr = error ("unimplemented: " ++ show expr)
|
||||
assembleExpression _ expr = error ("Unknown expression: " ++ show expr)
|
||||
|
||||
assembleNameChain :: Assembler Expression
|
||||
assembleNameChain input (TypedExpression _ (BinaryOperation NameResolution (TypedExpression atype a) (TypedExpression _ (FieldVariable _)))) =
|
||||
@ -84,7 +84,7 @@ assembleStatementExpression
|
||||
target = resolveNameChain (TypedExpression dtype receiver)
|
||||
in case target of
|
||||
(TypedExpression dtype (LocalVariable name)) -> let
|
||||
localIndex = findIndex ((==) name) lvars
|
||||
localIndex = elemIndex name lvars
|
||||
(constants_a, ops_a, _) = assembleExpression (constants, ops, lvars) expr
|
||||
isPrimitive = elem dtype ["char", "boolean", "int"]
|
||||
in case localIndex of
|
||||
@ -99,7 +99,7 @@ assembleStatementExpression
|
||||
(constants_a, ops_a, _) = assembleExpression (constants_r, ops_r, lvars) expr
|
||||
in
|
||||
(constants_a, ops_a ++ [Opdup_x1, Opputfield (fromIntegral fieldIndex)], lvars)
|
||||
something_else -> error ("expected TypedExpression, but got: " ++ show something_else)
|
||||
something_else -> error ("Expected TypedExpression, but got: " ++ show something_else)
|
||||
|
||||
assembleStatementExpression
|
||||
(constants, ops, lvars)
|
||||
@ -107,12 +107,12 @@ assembleStatementExpression
|
||||
target = resolveNameChain (TypedExpression dtype receiver)
|
||||
in case target of
|
||||
(TypedExpression dtype (LocalVariable name)) -> let
|
||||
localIndex = findIndex ((==) name) lvars
|
||||
expr = (TypedExpression dtype (LocalVariable name))
|
||||
localIndex = elemIndex name lvars
|
||||
expr = TypedExpression dtype (LocalVariable name)
|
||||
(exprConstants, exprOps, _) = assembleExpression (constants, ops, lvars) expr
|
||||
in case localIndex of
|
||||
Just index -> (exprConstants, exprOps ++ [Opsipush 1, Opiadd, Opdup, Opistore (fromIntegral index)], lvars)
|
||||
Nothing -> error("No such local variable found in local variable pool: " ++ name)
|
||||
Nothing -> error ("No such local variable found in local variable pool: " ++ name)
|
||||
(TypedExpression dtype (FieldVariable name)) -> let
|
||||
owner = resolveNameChainOwner (TypedExpression dtype receiver)
|
||||
in case owner of
|
||||
@ -121,7 +121,7 @@ assembleStatementExpression
|
||||
(constants_r, ops_r, _) = assembleNameChain (constants_f, ops, lvars) (TypedExpression dtype receiver)
|
||||
in
|
||||
(constants_r, ops_r ++ [Opdup, Opgetfield (fromIntegral fieldIndex), Opsipush 1, Opiadd, Opdup_x1, Opputfield (fromIntegral fieldIndex)], lvars)
|
||||
something_else -> error ("expected TypedExpression, but got: " ++ show something_else)
|
||||
something_else -> error ("Expected TypedExpression, but got: " ++ show something_else)
|
||||
|
||||
assembleStatementExpression
|
||||
(constants, ops, lvars)
|
||||
@ -129,12 +129,12 @@ assembleStatementExpression
|
||||
target = resolveNameChain (TypedExpression dtype receiver)
|
||||
in case target of
|
||||
(TypedExpression dtype (LocalVariable name)) -> let
|
||||
localIndex = findIndex ((==) name) lvars
|
||||
expr = (TypedExpression dtype (LocalVariable name))
|
||||
localIndex = elemIndex name lvars
|
||||
expr = TypedExpression dtype (LocalVariable name)
|
||||
(exprConstants, exprOps, _) = assembleExpression (constants, ops, lvars) expr
|
||||
in case localIndex of
|
||||
Just index -> (exprConstants, exprOps ++ [Opsipush 1, Opisub, Opdup, Opistore (fromIntegral index)], lvars)
|
||||
Nothing -> error("No such local variable found in local variable pool: " ++ name)
|
||||
Nothing -> error ("No such local variable found in local variable pool: " ++ name)
|
||||
(TypedExpression dtype (FieldVariable name)) -> let
|
||||
owner = resolveNameChainOwner (TypedExpression dtype receiver)
|
||||
in case owner of
|
||||
@ -143,7 +143,7 @@ assembleStatementExpression
|
||||
(constants_r, ops_r, _) = assembleNameChain (constants_f, ops, lvars) (TypedExpression dtype receiver)
|
||||
in
|
||||
(constants_r, ops_r ++ [Opdup, Opgetfield (fromIntegral fieldIndex), Opsipush 1, Opisub, Opdup_x1, Opputfield (fromIntegral fieldIndex)], lvars)
|
||||
something_else -> error ("expected TypedExpression, but got: " ++ show something_else)
|
||||
something_else -> error ("Expected TypedExpression, but got: " ++ show something_else)
|
||||
|
||||
assembleStatementExpression
|
||||
(constants, ops, lvars)
|
||||
@ -151,12 +151,12 @@ assembleStatementExpression
|
||||
target = resolveNameChain (TypedExpression dtype receiver)
|
||||
in case target of
|
||||
(TypedExpression dtype (LocalVariable name)) -> let
|
||||
localIndex = findIndex ((==) name) lvars
|
||||
expr = (TypedExpression dtype (LocalVariable name))
|
||||
localIndex = elemIndex name lvars
|
||||
expr = TypedExpression dtype (LocalVariable name)
|
||||
(exprConstants, exprOps, _) = assembleExpression (constants, ops, lvars) expr
|
||||
in case localIndex of
|
||||
Just index -> (exprConstants, exprOps ++ [Opdup, Opsipush 1, Opiadd, Opistore (fromIntegral index)], lvars)
|
||||
Nothing -> error("No such local variable found in local variable pool: " ++ name)
|
||||
Nothing -> error ("No such local variable found in local variable pool: " ++ name)
|
||||
(TypedExpression dtype (FieldVariable name)) -> let
|
||||
owner = resolveNameChainOwner (TypedExpression dtype receiver)
|
||||
in case owner of
|
||||
@ -165,7 +165,7 @@ assembleStatementExpression
|
||||
(constants_r, ops_r, _) = assembleNameChain (constants_f, ops, lvars) (TypedExpression dtype receiver)
|
||||
in
|
||||
(constants_r, ops_r ++ [Opdup, Opgetfield (fromIntegral fieldIndex), Opdup_x1, Opsipush 1, Opiadd, Opputfield (fromIntegral fieldIndex)], lvars)
|
||||
something_else -> error ("expected TypedExpression, but got: " ++ show something_else)
|
||||
something_else -> error ("Expected TypedExpression, but got: " ++ show something_else)
|
||||
|
||||
assembleStatementExpression
|
||||
(constants, ops, lvars)
|
||||
@ -173,12 +173,12 @@ assembleStatementExpression
|
||||
target = resolveNameChain (TypedExpression dtype receiver)
|
||||
in case target of
|
||||
(TypedExpression dtype (LocalVariable name)) -> let
|
||||
localIndex = findIndex ((==) name) lvars
|
||||
expr = (TypedExpression dtype (LocalVariable name))
|
||||
localIndex = elemIndex name lvars
|
||||
expr = TypedExpression dtype (LocalVariable name)
|
||||
(exprConstants, exprOps, _) = assembleExpression (constants, ops, lvars) expr
|
||||
in case localIndex of
|
||||
Just index -> (exprConstants, exprOps ++ [Opdup, Opsipush 1, Opisub, Opistore (fromIntegral index)], lvars)
|
||||
Nothing -> error("No such local variable found in local variable pool: " ++ name)
|
||||
Nothing -> error ("No such local variable found in local variable pool: " ++ name)
|
||||
(TypedExpression dtype (FieldVariable name)) -> let
|
||||
owner = resolveNameChainOwner (TypedExpression dtype receiver)
|
||||
in case owner of
|
||||
@ -187,7 +187,7 @@ assembleStatementExpression
|
||||
(constants_r, ops_r, _) = assembleNameChain (constants_f, ops, lvars) (TypedExpression dtype receiver)
|
||||
in
|
||||
(constants_r, ops_r ++ [Opdup, Opgetfield (fromIntegral fieldIndex), Opdup_x1, Opsipush 1, Opisub, Opputfield (fromIntegral fieldIndex)], lvars)
|
||||
something_else -> error ("expected TypedExpression, but got: " ++ show something_else)
|
||||
something_else -> error ("Expected TypedExpression, but got: " ++ show something_else)
|
||||
|
||||
assembleStatementExpression
|
||||
(constants, ops, lvars)
|
||||
@ -221,26 +221,26 @@ assembleStatement (constants, ops, lvars) (TypedStatement _ (Block statements))
|
||||
|
||||
assembleStatement (constants, ops, lvars) (TypedStatement dtype (If expr if_stmt else_stmt)) = let
|
||||
(constants_cmp, ops_cmp, _) = assembleExpression (constants, [], lvars) expr
|
||||
(constants_ifa, ops_ifa, _) = assembleStatement (constants_cmp, [], lvars) if_stmt
|
||||
(constants_ifa, ops_ifa, lvars_ifa) = assembleStatement (constants_cmp, [], lvars) if_stmt
|
||||
(constants_elsea, ops_elsea, _) = case else_stmt of
|
||||
Nothing -> (constants_ifa, [], lvars)
|
||||
Just stmt -> assembleStatement (constants_ifa, [], lvars) stmt
|
||||
Nothing -> (constants_ifa, [], lvars_ifa)
|
||||
Just stmt -> assembleStatement (constants_ifa, [], lvars_ifa) stmt
|
||||
-- +6 because we insert 2 gotos, one for if, one for else
|
||||
if_length = sum (map opcodeEncodingLength ops_ifa)
|
||||
-- +3 because we need to account for the goto in the if statement.
|
||||
else_length = sum (map opcodeEncodingLength ops_elsea)
|
||||
in case dtype of
|
||||
"void" -> (constants_ifa, ops ++ ops_cmp ++ [Opsipush 0, Opif_icmpeq (if_length + 6)] ++ ops_ifa ++ [Opgoto (else_length + 3)] ++ ops_elsea, lvars)
|
||||
otherwise -> (constants_ifa, ops ++ ops_cmp ++ [Opsipush 0, Opif_icmpeq (if_length + 3)] ++ ops_ifa ++ ops_elsea, lvars)
|
||||
"void" -> (constants_ifa, ops ++ ops_cmp ++ [Opsipush 0, Opif_icmpeq (if_length + 6)] ++ ops_ifa ++ [Opgoto (else_length + 3)] ++ ops_elsea, lvars_ifa)
|
||||
_ -> (constants_ifa, ops ++ ops_cmp ++ [Opsipush 0, Opif_icmpeq (if_length + 3)] ++ ops_ifa ++ ops_elsea, lvars_ifa)
|
||||
|
||||
assembleStatement (constants, ops, lvars) (TypedStatement _ (While expr stmt)) = let
|
||||
(constants_cmp, ops_cmp, _) = assembleExpression (constants, [], lvars) expr
|
||||
(constants_stmta, ops_stmta, _) = assembleStatement (constants_cmp, [], lvars) stmt
|
||||
(constants_stmta, ops_stmta, lvars_stmta) = assembleStatement (constants_cmp, [], lvars) stmt
|
||||
-- +3 because we insert 2 gotos, one for the comparison, one for the goto back to the comparison
|
||||
stmt_length = sum (map opcodeEncodingLength ops_stmta) + 6
|
||||
entire_length = stmt_length + sum (map opcodeEncodingLength ops_cmp)
|
||||
in
|
||||
(constants_stmta, ops ++ ops_cmp ++ [Opsipush 0, Opif_icmpeq stmt_length] ++ ops_stmta ++ [Opgoto (-entire_length)], lvars)
|
||||
(constants_stmta, ops ++ ops_cmp ++ [Opsipush 0, Opif_icmpeq stmt_length] ++ ops_stmta ++ [Opgoto (-entire_length)], lvars_stmta)
|
||||
|
||||
assembleStatement (constants, ops, lvars) (TypedStatement _ (LocalVariableDeclaration (VariableDeclaration dtype name expr))) = let
|
||||
isPrimitive = elem dtype ["char", "boolean", "int"]
|
||||
@ -252,25 +252,25 @@ assembleStatement (constants, ops, lvars) (TypedStatement _ (LocalVariableDeclar
|
||||
in
|
||||
(constants_init, ops_init ++ storeLocal, lvars ++ [name])
|
||||
|
||||
assembleStatement (constants, ops, lvars) (TypedStatement _ (StatementExpressionStatement expr)) = let
|
||||
assembleStatement (constants, ops, lvars) (TypedStatement dtype (StatementExpressionStatement expr)) = let
|
||||
(constants_e, ops_e, lvars_e) = assembleStatementExpression (constants, ops, lvars) expr
|
||||
in
|
||||
(constants_e, ops_e ++ [Oppop], lvars_e)
|
||||
in case dtype of
|
||||
"void" -> (constants_e, ops_e, lvars_e)
|
||||
_ -> (constants_e, ops_e ++ [Oppop], lvars_e)
|
||||
|
||||
assembleStatement _ stmt = error ("Not yet implemented: " ++ show stmt)
|
||||
assembleStatement _ stmt = error ("Unknown statement: " ++ show stmt)
|
||||
|
||||
|
||||
assembleMethod :: Assembler MethodDeclaration
|
||||
assembleMethod (constants, ops, lvars) (MethodDeclaration returntype name _ (TypedStatement _ (Block statements)))
|
||||
| name == "<init>" = let
|
||||
(constants_a, ops_a, lvars_a) = foldl assembleStatement (constants, ops, lvars) statements
|
||||
init_ops = [Opaload 0, Opinvokespecial 2]
|
||||
in
|
||||
(constants_a, init_ops ++ ops_a ++ [Opreturn], lvars_a)
|
||||
(constants_a, [Opaload 0, Opinvokespecial 2] ++ ops_a ++ [Opreturn], lvars_a)
|
||||
| otherwise = case returntype of
|
||||
"void" -> let
|
||||
(constants_a, ops_a, lvars_a) = foldl assembleStatement (constants, ops, lvars) statements
|
||||
in
|
||||
(constants_a, ops_a ++ [Opreturn], lvars_a)
|
||||
otherwise -> foldl assembleStatement (constants, ops, lvars) statements
|
||||
_ -> foldl assembleStatement (constants, ops, lvars) statements
|
||||
assembleMethod _ (MethodDeclaration _ _ _ stmt) = error ("Typed block expected for method body, got: " ++ show stmt)
|
||||
|
@ -22,14 +22,14 @@ fieldBuilder (VariableDeclaration datatype name _) input = let
|
||||
]
|
||||
field = MemberInfo {
|
||||
memberAccessFlags = accessPublic,
|
||||
memberNameIndex = (fromIntegral (baseIndex + 2)),
|
||||
memberDescriptorIndex = (fromIntegral (baseIndex + 3)),
|
||||
memberNameIndex = fromIntegral (baseIndex + 2),
|
||||
memberDescriptorIndex = fromIntegral (baseIndex + 3),
|
||||
memberAttributes = []
|
||||
}
|
||||
in
|
||||
input {
|
||||
constantPool = (constantPool input) ++ constants,
|
||||
fields = (fields input) ++ [field]
|
||||
constantPool = constantPool input ++ constants,
|
||||
fields = fields input ++ [field]
|
||||
}
|
||||
|
||||
|
||||
@ -46,47 +46,53 @@ methodBuilder (MethodDeclaration returntype name parameters statement) input = l
|
||||
|
||||
method = MemberInfo {
|
||||
memberAccessFlags = accessPublic,
|
||||
memberNameIndex = (fromIntegral (baseIndex + 2)),
|
||||
memberDescriptorIndex = (fromIntegral (baseIndex + 3)),
|
||||
memberNameIndex = fromIntegral (baseIndex + 2),
|
||||
memberDescriptorIndex = fromIntegral (baseIndex + 3),
|
||||
memberAttributes = []
|
||||
}
|
||||
in
|
||||
input {
|
||||
constantPool = (constantPool input) ++ constants,
|
||||
methods = (methods input) ++ [method]
|
||||
constantPool = constantPool input ++ constants,
|
||||
methods = methods input ++ [method]
|
||||
}
|
||||
|
||||
constructorBuilder :: ClassFileBuilder ConstructorDeclaration
|
||||
constructorBuilder (ConstructorDeclaration name parameters statement) = methodBuilder (MethodDeclaration "void" "<init>" parameters statement)
|
||||
|
||||
|
||||
methodAssembler :: ClassFileBuilder MethodDeclaration
|
||||
methodAssembler (MethodDeclaration returntype name parameters statement) input = let
|
||||
methodConstantIndex = findMethodIndex input name
|
||||
methodConstantIndex = findMethodIndex input (MethodDeclaration returntype name parameters statement)
|
||||
in case methodConstantIndex of
|
||||
Nothing -> error ("Cannot find method entry in method pool for method: " ++ name)
|
||||
Just index -> let
|
||||
declaration = MethodDeclaration returntype name parameters statement
|
||||
paramNames = "this" : [name | ParameterDeclaration _ name <- parameters]
|
||||
in case (splitAt index (methods input)) of
|
||||
in case splitAt index (methods input) of
|
||||
(pre, []) -> input
|
||||
(pre, method : post) -> let
|
||||
(_, bytecode, _) = assembleMethod (constantPool input, [], paramNames) declaration
|
||||
(constants, bytecode, aParamNames) = assembleMethod (constantPool input, [], paramNames) declaration
|
||||
assembledMethod = method {
|
||||
memberAttributes = [
|
||||
CodeAttribute {
|
||||
attributeMaxStack = 420,
|
||||
attributeMaxLocals = 420,
|
||||
attributeMaxStack = fromIntegral $ maxStackDepth constants bytecode,
|
||||
attributeMaxLocals = fromIntegral $ length aParamNames,
|
||||
attributeCode = bytecode
|
||||
}
|
||||
]
|
||||
}
|
||||
in
|
||||
input {
|
||||
constantPool = constants,
|
||||
methods = pre ++ (assembledMethod : post)
|
||||
}
|
||||
|
||||
constructorAssembler :: ClassFileBuilder ConstructorDeclaration
|
||||
constructorAssembler (ConstructorDeclaration name parameters statement) = methodAssembler (MethodDeclaration "void" "<init>" parameters statement)
|
||||
|
||||
|
||||
classBuilder :: ClassFileBuilder Class
|
||||
classBuilder (Class name methods fields) _ = let
|
||||
classBuilder (Class name constructors methods fields) _ = let
|
||||
baseConstants = [
|
||||
ClassInfo 4,
|
||||
MethodRefInfo 1 3,
|
||||
@ -94,11 +100,12 @@ classBuilder (Class name methods fields) _ = let
|
||||
Utf8Info "java/lang/Object",
|
||||
Utf8Info "<init>",
|
||||
Utf8Info "()V",
|
||||
Utf8Info "Code"
|
||||
Utf8Info "Code",
|
||||
ClassInfo 9,
|
||||
Utf8Info name
|
||||
]
|
||||
nameConstants = [ClassInfo 9, Utf8Info name]
|
||||
nakedClassFile = ClassFile {
|
||||
constantPool = baseConstants ++ nameConstants,
|
||||
constantPool = baseConstants,
|
||||
accessFlags = accessPublic,
|
||||
thisClass = 8,
|
||||
superClass = 1,
|
||||
@ -107,11 +114,15 @@ classBuilder (Class name methods fields) _ = let
|
||||
attributes = []
|
||||
}
|
||||
|
||||
methodsWithInjectedConstructor = injectDefaultConstructor methods
|
||||
methodsWithInjectedInitializers = injectFieldInitializers name fields methodsWithInjectedConstructor
|
||||
-- for every constructor, prepend all initialization assignments for fields.
|
||||
constructorsWithInitializers = injectFieldInitializers name fields constructors
|
||||
|
||||
classFileWithFields = foldr fieldBuilder nakedClassFile fields
|
||||
classFileWithMethods = foldr methodBuilder classFileWithFields methodsWithInjectedInitializers
|
||||
classFileWithAssembledMethods = foldr methodAssembler classFileWithMethods methodsWithInjectedInitializers
|
||||
-- add fields, then method bodies, then constructor bodies to the classfile. After all referable names are known,
|
||||
-- assemble the methods and constructors into bytecode.
|
||||
fieldsAdded = foldr fieldBuilder nakedClassFile fields
|
||||
methodsAdded = foldr methodBuilder fieldsAdded methods
|
||||
constructorsAdded = foldr constructorBuilder methodsAdded constructorsWithInitializers
|
||||
methodsAssembled = foldr methodAssembler constructorsAdded methods
|
||||
constructorsAssembled = foldr constructorAssembler methodsAssembled constructorsWithInitializers
|
||||
in
|
||||
classFileWithAssembledMethods
|
||||
constructorsAssembled
|
@ -1,14 +1,4 @@
|
||||
module ByteCode.ClassFile(
|
||||
ConstantInfo(..),
|
||||
Attribute(..),
|
||||
MemberInfo(..),
|
||||
ClassFile(..),
|
||||
Operation(..),
|
||||
serialize,
|
||||
emptyClassFile,
|
||||
opcodeEncodingLength,
|
||||
className
|
||||
) where
|
||||
module ByteCode.ClassFile where
|
||||
|
||||
import Data.Word
|
||||
import Data.Int
|
||||
@ -99,47 +89,14 @@ emptyClassFile = ClassFile {
|
||||
|
||||
className :: ClassFile -> String
|
||||
className classFile = let
|
||||
classInfo = (constantPool classFile)!!(fromIntegral (thisClass classFile))
|
||||
classInfo = constantPool classFile !! fromIntegral (thisClass classFile)
|
||||
in case classInfo of
|
||||
Utf8Info className -> className
|
||||
otherwise -> error ("expected Utf8Info but got: " ++ show otherwise)
|
||||
unexpected_element -> error ("expected Utf8Info but got: " ++ show unexpected_element)
|
||||
|
||||
|
||||
opcodeEncodingLength :: Operation -> Word16
|
||||
opcodeEncodingLength Opiadd = 1
|
||||
opcodeEncodingLength Opisub = 1
|
||||
opcodeEncodingLength Opimul = 1
|
||||
opcodeEncodingLength Opidiv = 1
|
||||
opcodeEncodingLength Opirem = 1
|
||||
opcodeEncodingLength Opiand = 1
|
||||
opcodeEncodingLength Opior = 1
|
||||
opcodeEncodingLength Opixor = 1
|
||||
opcodeEncodingLength Opineg = 1
|
||||
opcodeEncodingLength Opdup = 1
|
||||
opcodeEncodingLength (Opnew _) = 3
|
||||
opcodeEncodingLength (Opif_icmplt _) = 3
|
||||
opcodeEncodingLength (Opif_icmple _) = 3
|
||||
opcodeEncodingLength (Opif_icmpgt _) = 3
|
||||
opcodeEncodingLength (Opif_icmpge _) = 3
|
||||
opcodeEncodingLength (Opif_icmpeq _) = 3
|
||||
opcodeEncodingLength (Opif_icmpne _) = 3
|
||||
opcodeEncodingLength Opaconst_null = 1
|
||||
opcodeEncodingLength Opreturn = 1
|
||||
opcodeEncodingLength Opireturn = 1
|
||||
opcodeEncodingLength Opareturn = 1
|
||||
opcodeEncodingLength Opdup_x1 = 1
|
||||
opcodeEncodingLength Oppop = 1
|
||||
opcodeEncodingLength (Opinvokespecial _) = 3
|
||||
opcodeEncodingLength (Opinvokevirtual _) = 3
|
||||
opcodeEncodingLength (Opgoto _) = 3
|
||||
opcodeEncodingLength (Opsipush _) = 3
|
||||
opcodeEncodingLength (Opldc_w _) = 3
|
||||
opcodeEncodingLength (Opaload _) = 4
|
||||
opcodeEncodingLength (Opiload _) = 4
|
||||
opcodeEncodingLength (Opastore _) = 4
|
||||
opcodeEncodingLength (Opistore _) = 4
|
||||
opcodeEncodingLength (Opputfield _) = 3
|
||||
opcodeEncodingLength (Opgetfield _) = 3
|
||||
opcodeEncodingLength op = fromIntegral . length . serialize $ op
|
||||
|
||||
class Serializable a where
|
||||
serialize :: a -> [Word8]
|
||||
@ -201,10 +158,10 @@ instance Serializable Attribute where
|
||||
serialize (CodeAttribute { attributeMaxStack = maxStack,
|
||||
attributeMaxLocals = maxLocals,
|
||||
attributeCode = code }) = let
|
||||
assembledCode = concat (map serialize code)
|
||||
assembledCode = concatMap serialize code
|
||||
in
|
||||
unpackWord16 7 -- attribute_name_index
|
||||
++ unpackWord32 (12 + (fromIntegral (length assembledCode))) -- attribute_length
|
||||
++ unpackWord32 (12 + fromIntegral (length assembledCode)) -- attribute_length
|
||||
++ unpackWord16 maxStack -- max_stack
|
||||
++ unpackWord16 maxLocals -- max_locals
|
||||
++ unpackWord32 (fromIntegral (length assembledCode)) -- code_length
|
||||
|
@ -1,32 +1,33 @@
|
||||
{-# OPTIONS_GHC -Wno-unrecognised-pragmas #-}
|
||||
{-# HLINT ignore "Use lambda-case" #-}
|
||||
module ByteCode.Util where
|
||||
|
||||
import Data.Int
|
||||
import Ast
|
||||
import ByteCode.ClassFile
|
||||
import Data.List
|
||||
import Data.Maybe (mapMaybe)
|
||||
import Data.Maybe (mapMaybe, isJust)
|
||||
import Data.Word (Word8, Word16, Word32)
|
||||
|
||||
-- walks the name resolution chain. returns the innermost Just LocalVariable/FieldVariable or Nothing.
|
||||
resolveNameChain :: Expression -> Expression
|
||||
resolveNameChain (TypedExpression _ (BinaryOperation NameResolution a b)) = resolveNameChain b
|
||||
resolveNameChain (TypedExpression dtype (LocalVariable name)) = (TypedExpression dtype (LocalVariable name))
|
||||
resolveNameChain (TypedExpression dtype (FieldVariable name)) = (TypedExpression dtype (FieldVariable name))
|
||||
resolveNameChain invalidExpression = error ("expected a NameResolution or Local/Field Variable but got: " ++ show(invalidExpression))
|
||||
resolveNameChain (TypedExpression dtype (LocalVariable name)) = TypedExpression dtype (LocalVariable name)
|
||||
resolveNameChain (TypedExpression dtype (FieldVariable name)) = TypedExpression dtype (FieldVariable name)
|
||||
resolveNameChain invalidExpression = error ("expected a NameResolution or Local/Field Variable but got: " ++ show invalidExpression)
|
||||
|
||||
-- walks the name resolution chain. returns the second-to-last item of the namechain.
|
||||
resolveNameChainOwner :: Expression -> Expression
|
||||
resolveNameChainOwner (TypedExpression _ (BinaryOperation NameResolution a (TypedExpression dtype (FieldVariable name)))) = a
|
||||
resolveNameChainOwner (TypedExpression _ (BinaryOperation NameResolution a b)) = resolveNameChain b
|
||||
resolveNameChainOwner invalidExpression = error ("expected a NameResolution or Local/Field Variable but got: " ++ show(invalidExpression))
|
||||
|
||||
resolveNameChainOwner invalidExpression = error ("expected a NameResolution or Local/Field Variable but got: " ++ show invalidExpression)
|
||||
|
||||
methodDescriptor :: MethodDeclaration -> String
|
||||
methodDescriptor (MethodDeclaration returntype _ parameters _) = let
|
||||
parameter_types = [datatype | ParameterDeclaration datatype _ <- parameters]
|
||||
in
|
||||
"("
|
||||
++ (concat (map datatypeDescriptor parameter_types))
|
||||
++ concatMap datatypeDescriptor parameter_types
|
||||
++ ")"
|
||||
++ datatypeDescriptor returntype
|
||||
|
||||
@ -35,49 +36,69 @@ methodDescriptorFromParamlist parameters returntype = let
|
||||
parameter_types = [datatype | TypedExpression datatype _ <- parameters]
|
||||
in
|
||||
"("
|
||||
++ (concat (map datatypeDescriptor parameter_types))
|
||||
++ concatMap datatypeDescriptor parameter_types
|
||||
++ ")"
|
||||
++ datatypeDescriptor returntype
|
||||
|
||||
memberInfoIsMethod :: [ConstantInfo] -> MemberInfo -> Bool
|
||||
memberInfoIsMethod constants info = elem '(' (memberInfoDescriptor constants info)
|
||||
-- recursively parses a given type signature into a list of parameter types and the method return type.
|
||||
-- As an initial parameter, you can supply ([], "void").
|
||||
parseMethodType :: ([String], String) -> String -> ([String], String)
|
||||
parseMethodType (params, returnType) ('(' : descriptor) = parseMethodType (params, returnType) descriptor
|
||||
parseMethodType (params, returnType) ('I' : descriptor) = parseMethodType (params ++ ["I"], returnType) descriptor
|
||||
parseMethodType (params, returnType) ('C' : descriptor) = parseMethodType (params ++ ["C"], returnType) descriptor
|
||||
parseMethodType (params, returnType) ('Z' : descriptor) = parseMethodType (params ++ ["Z"], returnType) descriptor
|
||||
parseMethodType (params, returnType) ('L' : descriptor) = let
|
||||
typeLength = elemIndex ';' descriptor
|
||||
in case typeLength of
|
||||
Just length -> let
|
||||
(typeName, semicolon : restOfDescriptor) = splitAt length descriptor
|
||||
in
|
||||
parseMethodType (params ++ [typeName], returnType) restOfDescriptor
|
||||
Nothing -> error $ "unterminated class type in function signature: " ++ show descriptor
|
||||
parseMethodType (params, _) (')' : descriptor) = (params, descriptor)
|
||||
parseMethodType _ descriptor = error $ "expected start of type name (L, I, C, Z) but got: " ++ descriptor
|
||||
|
||||
-- given a method index (constant pool index),
|
||||
-- returns the full type of the method. (i.e (LSomething;II)V)
|
||||
methodTypeFromIndex :: [ConstantInfo] -> Int -> String
|
||||
methodTypeFromIndex constants index = case constants !! fromIntegral (index - 1) of
|
||||
MethodRefInfo _ nameAndTypeIndex -> case constants !! fromIntegral (nameAndTypeIndex - 1) of
|
||||
NameAndTypeInfo _ typeIndex -> case constants !! fromIntegral (typeIndex - 1) of
|
||||
Utf8Info typeLiteral -> typeLiteral
|
||||
unexpectedElement -> error "Expected Utf8Info but got: " ++ show unexpectedElement
|
||||
unexpectedElement -> error "Expected NameAndTypeInfo but got: " ++ show unexpectedElement
|
||||
unexpectedElement -> error "Expected MethodRefInfo but got: " ++ show unexpectedElement
|
||||
|
||||
methodParametersFromIndex :: [ConstantInfo] -> Int -> ([String], String)
|
||||
methodParametersFromIndex constants index = parseMethodType ([], "V") (methodTypeFromIndex constants index)
|
||||
|
||||
memberInfoIsMethod :: [ConstantInfo] -> MemberInfo -> Bool
|
||||
memberInfoIsMethod constants info = '(' `elem` memberInfoDescriptor constants info
|
||||
|
||||
datatypeDescriptor :: String -> String
|
||||
datatypeDescriptor "void" = "V"
|
||||
datatypeDescriptor "int" = "I"
|
||||
datatypeDescriptor "char" = "C"
|
||||
datatypeDescriptor "boolean" = "B"
|
||||
datatypeDescriptor "boolean" = "Z"
|
||||
datatypeDescriptor x = "L" ++ x ++ ";"
|
||||
|
||||
|
||||
memberInfoDescriptor :: [ConstantInfo] -> MemberInfo -> String
|
||||
memberInfoDescriptor constants MemberInfo {
|
||||
memberAccessFlags = _,
|
||||
memberNameIndex = _,
|
||||
memberDescriptorIndex = descriptorIndex,
|
||||
memberAttributes = _ } = let
|
||||
descriptor = constants!!((fromIntegral descriptorIndex) - 1)
|
||||
memberInfoDescriptor constants MemberInfo { memberDescriptorIndex = descriptorIndex } = let
|
||||
descriptor = constants !! (fromIntegral descriptorIndex - 1)
|
||||
in case descriptor of
|
||||
Utf8Info descriptorText -> descriptorText
|
||||
_ -> ("Invalid Item at Constant pool index " ++ show descriptorIndex)
|
||||
|
||||
_ -> "Invalid Item at Constant pool index " ++ show descriptorIndex
|
||||
|
||||
memberInfoName :: [ConstantInfo] -> MemberInfo -> String
|
||||
memberInfoName constants MemberInfo {
|
||||
memberAccessFlags = _,
|
||||
memberNameIndex = nameIndex,
|
||||
memberDescriptorIndex = _,
|
||||
memberAttributes = _ } = let
|
||||
name = constants!!((fromIntegral nameIndex) - 1)
|
||||
memberInfoName constants MemberInfo { memberNameIndex = nameIndex } = let
|
||||
name = constants !! (fromIntegral nameIndex - 1)
|
||||
in case name of
|
||||
Utf8Info nameText -> nameText
|
||||
_ -> ("Invalid Item at Constant pool index " ++ show nameIndex)
|
||||
|
||||
_ -> "Invalid Item at Constant pool index " ++ show nameIndex
|
||||
|
||||
returnOperation :: DataType -> Operation
|
||||
returnOperation dtype
|
||||
| elem dtype ["int", "char", "boolean"] = Opireturn
|
||||
| dtype `elem` ["int", "char", "boolean"] = Opireturn
|
||||
| otherwise = Opareturn
|
||||
|
||||
binaryOperation :: BinaryOperator -> Operation
|
||||
@ -100,53 +121,31 @@ comparisonOperation CompareLessOrEqual branchLocation = Opif_icmple branchLoc
|
||||
comparisonOperation CompareGreaterThan branchLocation = Opif_icmpgt branchLocation
|
||||
comparisonOperation CompareGreaterOrEqual branchLocation = Opif_icmpge branchLocation
|
||||
|
||||
findFieldIndex :: [ConstantInfo] -> String -> Maybe Int
|
||||
findFieldIndex constants name = let
|
||||
fieldRefNameInfos = [
|
||||
-- we only skip one entry to get the name since the Java constant pool
|
||||
-- is 1-indexed (why)
|
||||
(index, constants!!(fromIntegral index + 1))
|
||||
| (index, FieldRefInfo classIndex _) <- (zip [1..] constants)
|
||||
]
|
||||
fieldRefNames = map (\(index, nameInfo) -> case nameInfo of
|
||||
Utf8Info fieldName -> (index, fieldName)
|
||||
something_else -> error ("Expected UTF8Info but got" ++ show something_else))
|
||||
fieldRefNameInfos
|
||||
fieldIndex = find (\(index, fieldName) -> fieldName == name) fieldRefNames
|
||||
in case fieldIndex of
|
||||
Just (index, _) -> Just index
|
||||
Nothing -> Nothing
|
||||
comparisonOffset :: Operation -> Maybe Int
|
||||
comparisonOffset (Opif_icmpeq offset) = Just $ fromIntegral offset
|
||||
comparisonOffset (Opif_icmpne offset) = Just $ fromIntegral offset
|
||||
comparisonOffset (Opif_icmplt offset) = Just $ fromIntegral offset
|
||||
comparisonOffset (Opif_icmple offset) = Just $ fromIntegral offset
|
||||
comparisonOffset (Opif_icmpgt offset) = Just $ fromIntegral offset
|
||||
comparisonOffset (Opif_icmpge offset) = Just $ fromIntegral offset
|
||||
comparisonOffset anything_else = Nothing
|
||||
|
||||
findMethodRefIndex :: [ConstantInfo] -> String -> Maybe Int
|
||||
findMethodRefIndex constants name = let
|
||||
methodRefNameInfos = [
|
||||
-- we only skip one entry to get the name since the Java constant pool
|
||||
-- is 1-indexed (why)
|
||||
(index, constants!!(fromIntegral index + 1))
|
||||
| (index, MethodRefInfo _ _) <- (zip [1..] constants)
|
||||
]
|
||||
methodRefNames = map (\(index, nameInfo) -> case nameInfo of
|
||||
Utf8Info methodName -> (index, methodName)
|
||||
something_else -> error ("Expected UTF8Info but got " ++ show something_else))
|
||||
methodRefNameInfos
|
||||
methodIndex = find (\(index, methodName) -> methodName == name) methodRefNames
|
||||
in case methodIndex of
|
||||
Just (index, _) -> Just index
|
||||
Nothing -> Nothing
|
||||
isComparisonOperation :: Operation -> Bool
|
||||
isComparisonOperation op = isJust (comparisonOffset op)
|
||||
|
||||
|
||||
findMethodIndex :: ClassFile -> String -> Maybe Int
|
||||
findMethodIndex classFile name = let
|
||||
findMethodIndex :: ClassFile -> MethodDeclaration -> Maybe Int
|
||||
findMethodIndex classFile (MethodDeclaration rtype name params stmt) = let
|
||||
constants = constantPool classFile
|
||||
descriptor = methodDescriptor (MethodDeclaration rtype name params stmt)
|
||||
in
|
||||
findIndex (\method -> ((memberInfoIsMethod constants method) && (memberInfoName constants method) == name)) (methods classFile)
|
||||
findIndex (\method -> memberInfoIsMethod constants method && memberInfoName constants method == name && memberInfoDescriptor constants method == descriptor) (methods classFile)
|
||||
|
||||
findClassIndex :: [ConstantInfo] -> String -> Maybe Int
|
||||
findClassIndex constants name = let
|
||||
classNameIndices = [(index, constants!!(fromIntegral nameIndex - 1)) | (index, ClassInfo nameIndex) <- (zip[1..] constants)]
|
||||
classNameIndices = [(index, constants!!(fromIntegral nameIndex - 1)) | (index, ClassInfo nameIndex) <- zip [1..] constants]
|
||||
classNames = map (\(index, nameInfo) -> case nameInfo of
|
||||
Utf8Info className -> (index, className)
|
||||
something_else -> error("Expected UTF8Info but got " ++ show something_else))
|
||||
something_else -> error ("Expected UTF8Info but got " ++ show something_else))
|
||||
classNameIndices
|
||||
desiredClassIndex = find (\(index, className) -> className == name) classNames
|
||||
in case desiredClassIndex of
|
||||
@ -157,10 +156,10 @@ getKnownMembers :: [ConstantInfo] -> [(Int, (String, String, String))]
|
||||
getKnownMembers constants = let
|
||||
fieldsClassAndNT = [
|
||||
(index, constants!!(fromIntegral classIndex - 1), constants!!(fromIntegral nameTypeIndex - 1))
|
||||
| (index, FieldRefInfo classIndex nameTypeIndex) <- (zip [1..] constants)
|
||||
| (index, FieldRefInfo classIndex nameTypeIndex) <- zip [1..] constants
|
||||
] ++ [
|
||||
(index, constants!!(fromIntegral classIndex - 1), constants!!(fromIntegral nameTypeIndex - 1))
|
||||
| (index, MethodRefInfo classIndex nameTypeIndex) <- (zip [1..] constants)
|
||||
| (index, MethodRefInfo classIndex nameTypeIndex) <- zip [1..] constants
|
||||
]
|
||||
|
||||
fieldsClassNameType = map (\(index, nameInfo, nameTypeInfo) -> case (nameInfo, nameTypeInfo) of
|
||||
@ -170,7 +169,7 @@ getKnownMembers constants = let
|
||||
|
||||
fieldsResolved = map (\(index, (nameInfo, fnameInfo, ftypeInfo)) -> case (nameInfo, fnameInfo, ftypeInfo) of
|
||||
(Utf8Info cname, Utf8Info fname, Utf8Info ftype) -> (index, (cname, fname, ftype))
|
||||
something_else -> error("Expected UTF8Infos but got " ++ show something_else))
|
||||
something_else -> error ("Expected UTF8Infos but got " ++ show something_else))
|
||||
fieldsClassNameType
|
||||
in
|
||||
fieldsResolved
|
||||
@ -179,7 +178,7 @@ getKnownMembers constants = let
|
||||
getClassIndex :: [ConstantInfo] -> String -> ([ConstantInfo], Int)
|
||||
getClassIndex constants name = case findClassIndex constants name of
|
||||
Just index -> (constants, index)
|
||||
Nothing -> (constants ++ [ClassInfo (fromIntegral (length constants)), Utf8Info name], fromIntegral (length constants))
|
||||
Nothing -> (constants ++ [ClassInfo (fromIntegral (length constants) + 2), Utf8Info name], fromIntegral (length constants) + 1)
|
||||
|
||||
-- get the index for a field within a class, creating it if it does not exist.
|
||||
getFieldIndex :: [ConstantInfo] -> (String, String, String) -> ([ConstantInfo], Int)
|
||||
@ -215,16 +214,11 @@ findMemberIndex constants (cname, fname, ftype) = let
|
||||
allMembers = getKnownMembers constants
|
||||
desiredMember = find (\(index, (c, f, ft)) -> (c, f, ft) == (cname, fname, ftype)) allMembers
|
||||
in
|
||||
fmap (\(index, _) -> index) desiredMember
|
||||
fmap fst desiredMember
|
||||
|
||||
injectDefaultConstructor :: [MethodDeclaration] -> [MethodDeclaration]
|
||||
injectDefaultConstructor pre
|
||||
| any (\(MethodDeclaration _ name _ _) -> name == "<init>") pre = pre
|
||||
| otherwise = pre ++ [MethodDeclaration "void" "<init>" [] (TypedStatement "void" (Block []))]
|
||||
|
||||
injectFieldInitializers :: String -> [VariableDeclaration] -> [MethodDeclaration] -> [MethodDeclaration]
|
||||
injectFieldInitializers classname vars pre = let
|
||||
initializers = mapMaybe (\(variable) -> case variable of
|
||||
injectFieldInitializers :: String -> [VariableDeclaration] -> [ConstructorDeclaration] -> [ConstructorDeclaration]
|
||||
injectFieldInitializers classname vars constructors = let
|
||||
initializers = mapMaybe (\variable -> case variable of
|
||||
VariableDeclaration dtype name (Just initializer) -> Just (
|
||||
TypedStatement dtype (
|
||||
StatementExpressionStatement (
|
||||
@ -239,7 +233,59 @@ injectFieldInitializers classname vars pre = let
|
||||
otherwise -> Nothing
|
||||
) vars
|
||||
in
|
||||
map (\(method) -> case method of
|
||||
MethodDeclaration "void" "<init>" params (TypedStatement "void" (Block statements)) -> MethodDeclaration "void" "<init>" params (TypedStatement "void" (Block (initializers ++ statements)))
|
||||
otherwise -> method
|
||||
) pre
|
||||
map (\con -> let
|
||||
ConstructorDeclaration classname params (TypedStatement "void" (Block statements)) = con
|
||||
in
|
||||
ConstructorDeclaration classname params (TypedStatement "void" (Block (initializers ++ statements)))
|
||||
) constructors
|
||||
|
||||
-- effect of one instruction/operation on the stack
|
||||
operationStackCost :: [ConstantInfo] -> Operation -> Int
|
||||
operationStackCost constants Opiadd = -1
|
||||
operationStackCost constants Opisub = -1
|
||||
operationStackCost constants Opimul = -1
|
||||
operationStackCost constants Opidiv = -1
|
||||
operationStackCost constants Opirem = -1
|
||||
operationStackCost constants Opiand = -1
|
||||
operationStackCost constants Opior = -1
|
||||
operationStackCost constants Opixor = -1
|
||||
operationStackCost constants Opineg = 0
|
||||
operationStackCost constants Opdup = 1
|
||||
operationStackCost constants (Opnew _) = 1
|
||||
operationStackCost constants (Opif_icmplt _) = -2
|
||||
operationStackCost constants (Opif_icmple _) = -2
|
||||
operationStackCost constants (Opif_icmpgt _) = -2
|
||||
operationStackCost constants (Opif_icmpge _) = -2
|
||||
operationStackCost constants (Opif_icmpeq _) = -2
|
||||
operationStackCost constants (Opif_icmpne _) = -2
|
||||
operationStackCost constants Opaconst_null = 1
|
||||
operationStackCost constants Opreturn = 0
|
||||
operationStackCost constants Opireturn = -1
|
||||
operationStackCost constants Opareturn = -1
|
||||
operationStackCost constants Opdup_x1 = 1
|
||||
operationStackCost constants Oppop = -1
|
||||
operationStackCost constants (Opinvokespecial idx) = let
|
||||
(params, returnType) = methodParametersFromIndex constants (fromIntegral idx)
|
||||
in (length params + 1) - fromEnum (returnType /= "V")
|
||||
operationStackCost constants (Opinvokevirtual idx) = let
|
||||
(params, returnType) = methodParametersFromIndex constants (fromIntegral idx)
|
||||
in (length params + 1) - fromEnum (returnType /= "V")
|
||||
operationStackCost constants (Opgoto _) = 0
|
||||
operationStackCost constants (Opsipush _) = 1
|
||||
operationStackCost constants (Opldc_w _) = 1
|
||||
operationStackCost constants (Opaload _) = 1
|
||||
operationStackCost constants (Opiload _) = 1
|
||||
operationStackCost constants (Opastore _) = -1
|
||||
operationStackCost constants (Opistore _) = -1
|
||||
operationStackCost constants (Opputfield _) = -2
|
||||
operationStackCost constants (Opgetfield _) = 0
|
||||
|
||||
simulateStackOperation :: (Int, Int) -> [ConstantInfo] -> Operation -> (Int, Int)
|
||||
simulateStackOperation (cd, md) constants op = let
|
||||
depth = cd + operationStackCost constants op
|
||||
in if depth < 0
|
||||
then error ("Consuming value off of empty stack: " ++ show op)
|
||||
else (depth, max depth md)
|
||||
|
||||
maxStackDepth :: [ConstantInfo] -> [Operation] -> Int
|
||||
maxStackDepth constants ops = snd $ foldl (`simulateStackOperation` constants) (0, 0) ops
|
||||
|
267
src/Example.hs
267
src/Example.hs
@ -1,267 +0,0 @@
|
||||
module Example where
|
||||
|
||||
import Ast
|
||||
import Typecheck
|
||||
import Control.Exception (catch, evaluate, SomeException, displayException)
|
||||
import Control.Exception.Base
|
||||
import System.IO (stderr, hPutStrLn)
|
||||
import Data.Maybe
|
||||
import Data.List
|
||||
|
||||
green, red, yellow, blue, magenta, cyan, white :: String -> String
|
||||
green str = "\x1b[32m" ++ str ++ "\x1b[0m"
|
||||
red str = "\x1b[31m" ++ str ++ "\x1b[0m"
|
||||
yellow str = "\x1b[33m" ++ str ++ "\x1b[0m"
|
||||
blue str = "\x1b[34m" ++ str ++ "\x1b[0m"
|
||||
magenta str = "\x1b[35m" ++ str ++ "\x1b[0m"
|
||||
cyan str = "\x1b[36m" ++ str ++ "\x1b[0m"
|
||||
white str = "\x1b[37m" ++ str ++ "\x1b[0m"
|
||||
|
||||
printSuccess :: String -> IO ()
|
||||
printSuccess msg = putStrLn $ green "Success:" ++ white msg
|
||||
|
||||
handleError :: SomeException -> IO ()
|
||||
handleError e = hPutStrLn stderr $ red ("Error: " ++ displayException e)
|
||||
|
||||
printResult :: Show a => String -> a -> IO ()
|
||||
printResult title result = do
|
||||
putStrLn $ green title
|
||||
print result
|
||||
|
||||
sampleClasses :: [Class]
|
||||
sampleClasses = [
|
||||
Class "Person" [
|
||||
MethodDeclaration "void" "setAge" [ParameterDeclaration "int" "newAge"]
|
||||
(Block [
|
||||
LocalVariableDeclaration (VariableDeclaration "int" "age" (Just (Reference "newAge")))
|
||||
]),
|
||||
MethodDeclaration "int" "getAge" [] (Return (Just (Reference "age"))),
|
||||
MethodDeclaration "Person" "Person" [ParameterDeclaration "int" "initialAge"] (Block [])
|
||||
] [
|
||||
VariableDeclaration "int" "age" (Just (IntegerLiteral 25))
|
||||
]
|
||||
]
|
||||
|
||||
initialSymtab :: [(DataType, Identifier)]
|
||||
initialSymtab = []
|
||||
|
||||
exampleExpression :: Expression
|
||||
exampleExpression = BinaryOperation NameResolution (Reference "bob") (Reference "age")
|
||||
|
||||
exampleAssignment :: Expression
|
||||
exampleAssignment = StatementExpressionExpression (Assignment (Reference "a") (IntegerLiteral 30))
|
||||
|
||||
exampleMethodCall :: Statement
|
||||
exampleMethodCall = StatementExpressionStatement (MethodCall (Reference "this") "setAge" [IntegerLiteral 30])
|
||||
|
||||
exampleConstructorCall :: Statement
|
||||
exampleConstructorCall = LocalVariableDeclaration (VariableDeclaration "Person" "bob" (Just (StatementExpressionExpression (ConstructorCall "Person" [IntegerLiteral 30]))))
|
||||
|
||||
exampleNameResolution :: Expression
|
||||
exampleNameResolution = BinaryOperation NameResolution (Reference "bob2") (Reference "age")
|
||||
|
||||
exampleBlockResolution :: Statement
|
||||
exampleBlockResolution = Block [
|
||||
LocalVariableDeclaration (VariableDeclaration "Person" "bob" (Just (StatementExpressionExpression (ConstructorCall "Person" [IntegerLiteral 30])))),
|
||||
LocalVariableDeclaration (VariableDeclaration "int" "age" (Just (StatementExpressionExpression (MethodCall (Reference "bob") "getAge" [])))),
|
||||
StatementExpressionStatement (MethodCall (Reference "bob") "setAge" [IntegerLiteral 30])
|
||||
]
|
||||
|
||||
exampleBlockResolutionFail :: Statement
|
||||
exampleBlockResolutionFail = Block [
|
||||
LocalVariableDeclaration (VariableDeclaration "Person" "bob" (Just (StatementExpressionExpression (ConstructorCall "Person" [IntegerLiteral 30])))),
|
||||
LocalVariableDeclaration (VariableDeclaration "bool" "age" (Just (StatementExpressionExpression (MethodCall (Reference "bob") "getAge" [])))),
|
||||
StatementExpressionStatement (MethodCall (Reference "bob") "setAge" [IntegerLiteral 30])
|
||||
]
|
||||
|
||||
exampleMethodCallAndAssignment :: Statement
|
||||
exampleMethodCallAndAssignment = Block [
|
||||
LocalVariableDeclaration (VariableDeclaration "Person" "bob" (Just (StatementExpressionExpression (ConstructorCall "Person" [IntegerLiteral 30])))),
|
||||
LocalVariableDeclaration (VariableDeclaration "int" "age" (Just (StatementExpressionExpression (MethodCall (Reference "bob") "getAge" [])))),
|
||||
StatementExpressionStatement (MethodCall (Reference "bob") "setAge" [IntegerLiteral 30]),
|
||||
LocalVariableDeclaration (VariableDeclaration "int" "a" Nothing),
|
||||
StatementExpressionStatement (Assignment (Reference "a") (Reference "age"))
|
||||
]
|
||||
|
||||
|
||||
exampleMethodCallAndAssignmentFail :: Statement
|
||||
exampleMethodCallAndAssignmentFail = Block [
|
||||
LocalVariableDeclaration (VariableDeclaration "Person" "bob" (Just (StatementExpressionExpression (ConstructorCall "Person" [IntegerLiteral 30])))),
|
||||
LocalVariableDeclaration (VariableDeclaration "int" "age" (Just (StatementExpressionExpression (MethodCall (Reference "bob") "getAge" [])))),
|
||||
StatementExpressionStatement (MethodCall (Reference "bob") "setAge" [IntegerLiteral 30]),
|
||||
StatementExpressionStatement (Assignment (Reference "a") (Reference "age"))
|
||||
]
|
||||
|
||||
exampleNameResolutionAssignment :: Statement
|
||||
exampleNameResolutionAssignment = Block [
|
||||
LocalVariableDeclaration (VariableDeclaration "Person" "bob" (Just (StatementExpressionExpression (ConstructorCall "Person" [IntegerLiteral 30])))),
|
||||
StatementExpressionStatement (Assignment (BinaryOperation NameResolution (Reference "bob") (Reference "age")) (IntegerLiteral 30))
|
||||
]
|
||||
|
||||
exampleCharIntOperation :: Expression
|
||||
exampleCharIntOperation = BinaryOperation Addition (CharacterLiteral 'a') (IntegerLiteral 1)
|
||||
|
||||
exampleNullDeclaration :: Statement
|
||||
exampleNullDeclaration = LocalVariableDeclaration (VariableDeclaration "Person" "bob" (Just NullLiteral))
|
||||
|
||||
exampleNullDeclarationFail :: Statement
|
||||
exampleNullDeclarationFail = LocalVariableDeclaration (VariableDeclaration "int" "a" (Just NullLiteral))
|
||||
|
||||
exampleNullAssignment :: Statement
|
||||
exampleNullAssignment = StatementExpressionStatement (Assignment (Reference "a") NullLiteral)
|
||||
|
||||
exampleIncrement :: Statement
|
||||
exampleIncrement = StatementExpressionStatement (PostIncrement (Reference "a"))
|
||||
|
||||
testClasses :: [Class]
|
||||
testClasses = [
|
||||
Class "Person" [
|
||||
MethodDeclaration "Person" "Person" [ParameterDeclaration "int" "initialAge"]
|
||||
(Block [
|
||||
Return (Just (Reference "this"))
|
||||
]),
|
||||
MethodDeclaration "void" "setAge" [ParameterDeclaration "int" "newAge"]
|
||||
(Block [
|
||||
LocalVariableDeclaration (VariableDeclaration "int" "age" (Just (Reference "newAge")))
|
||||
]),
|
||||
MethodDeclaration "int" "getAge" []
|
||||
(Return (Just (Reference "age")))
|
||||
] [
|
||||
VariableDeclaration "int" "age" Nothing -- initially unassigned
|
||||
],
|
||||
Class "Main" [
|
||||
MethodDeclaration "int" "main" []
|
||||
(Block [
|
||||
LocalVariableDeclaration (VariableDeclaration "Person" "bob" (Just (StatementExpressionExpression (ConstructorCall "Person" [IntegerLiteral 25])))),
|
||||
StatementExpressionStatement (MethodCall (Reference "bob") "setAge" [IntegerLiteral 30]),
|
||||
LocalVariableDeclaration (VariableDeclaration "int" "bobAge" (Just (StatementExpressionExpression (MethodCall (Reference "bob2") "getAge" [])))),
|
||||
Return (Just (Reference "bobAge"))
|
||||
])
|
||||
] [
|
||||
VariableDeclaration "Person" "bob2" Nothing
|
||||
]
|
||||
]
|
||||
|
||||
runTypeCheck :: IO ()
|
||||
runTypeCheck = do
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
evaluatedExpression <- evaluate (typeCheckExpression exampleExpression [("bob", "Person")] sampleClasses)
|
||||
printSuccess "Type checking of expression completed successfully"
|
||||
printResult "Result Expression:" evaluatedExpression
|
||||
) handleError
|
||||
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
evaluatedAssignment <- evaluate (typeCheckExpression exampleAssignment [("a", "int")] sampleClasses)
|
||||
printSuccess "Type checking of assignment completed successfully"
|
||||
printResult "Result Assignment:" evaluatedAssignment
|
||||
) handleError
|
||||
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
evaluatedMethodCall <- evaluate (typeCheckStatement exampleMethodCall [("this", "Person"), ("setAge", "Person"), ("getAge", "Person")] sampleClasses)
|
||||
printSuccess "Type checking of method call this completed successfully"
|
||||
printResult "Result MethodCall:" evaluatedMethodCall
|
||||
) handleError
|
||||
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
evaluatedConstructorCall <- evaluate (typeCheckStatement exampleConstructorCall [] sampleClasses)
|
||||
printSuccess "Type checking of constructor call completed successfully"
|
||||
printResult "Result Constructor Call:" evaluatedConstructorCall
|
||||
) handleError
|
||||
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
evaluatedNameResolution <- evaluate (typeCheckExpression exampleNameResolution [("this", "Main")] testClasses)
|
||||
printSuccess "Type checking of name resolution completed successfully"
|
||||
printResult "Result Name Resolution:" evaluatedNameResolution
|
||||
) handleError
|
||||
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
evaluatedBlockResolution <- evaluate (typeCheckStatement exampleBlockResolution [] sampleClasses)
|
||||
printSuccess "Type checking of block resolution completed successfully"
|
||||
printResult "Result Block Resolution:" evaluatedBlockResolution
|
||||
) handleError
|
||||
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
evaluatedBlockResolutionFail <- evaluate (typeCheckStatement exampleBlockResolutionFail [] sampleClasses)
|
||||
printSuccess "Type checking of block resolution failed"
|
||||
printResult "Result Block Resolution:" evaluatedBlockResolutionFail
|
||||
) handleError
|
||||
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
evaluatedMethodCallAndAssignment <- evaluate (typeCheckStatement exampleMethodCallAndAssignment [] sampleClasses)
|
||||
printSuccess "Type checking of method call and assignment completed successfully"
|
||||
printResult "Result Method Call and Assignment:" evaluatedMethodCallAndAssignment
|
||||
) handleError
|
||||
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
evaluatedMethodCallAndAssignmentFail <- evaluate (typeCheckStatement exampleMethodCallAndAssignmentFail [] sampleClasses)
|
||||
printSuccess "Type checking of method call and assignment failed"
|
||||
printResult "Result Method Call and Assignment:" evaluatedMethodCallAndAssignmentFail
|
||||
) handleError
|
||||
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
let mainClass = fromJust $ find (\(Class className _ _) -> className == "Main") testClasses
|
||||
case mainClass of
|
||||
Class _ [mainMethod] _ -> do
|
||||
let result = typeCheckMethodDeclaration mainMethod [("this", "Main")] testClasses
|
||||
printSuccess "Full program type checking completed successfully."
|
||||
printResult "Main method result:" result
|
||||
) handleError
|
||||
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
let typedProgram = typeCheckCompilationUnit testClasses
|
||||
printSuccess "Type checking of Program completed successfully"
|
||||
printResult "Typed Program:" typedProgram
|
||||
) handleError
|
||||
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
typedAssignment <- evaluate (typeCheckStatement exampleNameResolutionAssignment [] sampleClasses)
|
||||
printSuccess "Type checking of name resolution assignment completed successfully"
|
||||
printResult "Result Name Resolution Assignment:" typedAssignment
|
||||
) handleError
|
||||
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
evaluatedCharIntOperation <- evaluate (typeCheckExpression exampleCharIntOperation [] sampleClasses)
|
||||
printSuccess "Type checking of char int operation completed successfully"
|
||||
printResult "Result Char Int Operation:" evaluatedCharIntOperation
|
||||
) handleError
|
||||
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
evaluatedNullDeclaration <- evaluate (typeCheckStatement exampleNullDeclaration [] sampleClasses)
|
||||
printSuccess "Type checking of null declaration completed successfully"
|
||||
printResult "Result Null Declaration:" evaluatedNullDeclaration
|
||||
) handleError
|
||||
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
evaluatedNullDeclarationFail <- evaluate (typeCheckStatement exampleNullDeclarationFail [] sampleClasses)
|
||||
printSuccess "Type checking of null declaration failed"
|
||||
printResult "Result Null Declaration:" evaluatedNullDeclarationFail
|
||||
) handleError
|
||||
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
evaluatedNullAssignment <- evaluate (typeCheckStatement exampleNullAssignment [("a", "Person")] sampleClasses)
|
||||
printSuccess "Type checking of null assignment completed successfully"
|
||||
printResult "Result Null Assignment:" evaluatedNullAssignment
|
||||
) handleError
|
||||
|
||||
catch (do
|
||||
print "====================================================================================="
|
||||
evaluatedIncrement <- evaluate (typeCheckStatement exampleIncrement [("a", "int")] sampleClasses)
|
||||
printSuccess "Type checking of increment completed successfully"
|
||||
printResult "Result Increment:" evaluatedIncrement
|
||||
) handleError
|
11
src/Main.hs
11
src/Main.hs
@ -1,6 +1,5 @@
|
||||
module Main where
|
||||
|
||||
import Example
|
||||
import Typecheck
|
||||
import Parser.Lexer (alexScanTokens)
|
||||
import Parser.JavaParser
|
||||
@ -14,18 +13,18 @@ main = do
|
||||
args <- getArgs
|
||||
let filename = if null args
|
||||
then error "Missing filename, I need to know what to compile"
|
||||
else args!!0
|
||||
else head args
|
||||
let outputDirectory = takeDirectory filename
|
||||
print ("Compiling " ++ filename)
|
||||
file <- readFile filename
|
||||
|
||||
let untypedAST = parse $ alexScanTokens file
|
||||
let typedAST = (typeCheckCompilationUnit untypedAST)
|
||||
let assembledClasses = map (\(typedClass) -> classBuilder typedClass emptyClassFile) typedAST
|
||||
let typedAST = typeCheckCompilationUnit untypedAST
|
||||
let assembledClasses = map (`classBuilder` emptyClassFile) typedAST
|
||||
|
||||
mapM_ (\(classFile) -> let
|
||||
mapM_ (\classFile -> let
|
||||
fileContent = pack (serialize classFile)
|
||||
fileName = outputDirectory ++ "/" ++ (className classFile) ++ ".class"
|
||||
fileName = outputDirectory ++ "/" ++ className classFile ++ ".class"
|
||||
in Data.ByteString.writeFile fileName fileContent
|
||||
) assembledClasses
|
||||
|
||||
|
@ -1,5 +1,5 @@
|
||||
{
|
||||
module Parser.JavaParser (parse, parseStatement, parseExpression) where
|
||||
module Parser.JavaParser (parse, parseStatement, parseExpression, parseMethod) where
|
||||
import Ast
|
||||
import Parser.Lexer
|
||||
}
|
||||
@ -7,6 +7,7 @@ import Parser.Lexer
|
||||
%name parse
|
||||
%name parseStatement statement
|
||||
%name parseExpression expression
|
||||
%name parseMethod classbodydeclarations
|
||||
%tokentype { Token }
|
||||
%error { parseError }
|
||||
%errorhandlertype explist
|
||||
@ -75,6 +76,7 @@ import Parser.Lexer
|
||||
OREQUAL { OREQUAL }
|
||||
COLON { COLON }
|
||||
LESS { LESS }
|
||||
FOR { FOR }
|
||||
%%
|
||||
|
||||
compilationunit : typedeclarations { $1 }
|
||||
@ -91,10 +93,10 @@ qualifiedname : name DOT IDENTIFIER { BinaryOperation NameResolution $1 (Ref
|
||||
|
||||
simplename : IDENTIFIER { $1 }
|
||||
|
||||
classdeclaration : CLASS IDENTIFIER classbody { case $3 of (methods, fields) -> Class $2 methods fields }
|
||||
| modifiers CLASS IDENTIFIER classbody { case $4 of (methods, fields) -> Class $3 methods fields }
|
||||
classdeclaration : CLASS IDENTIFIER classbody { case $3 of (constructors, methods, fields) -> Class $2 constructors methods fields }
|
||||
| modifiers CLASS IDENTIFIER classbody { case $4 of (constructors, methods, fields) -> Class $3 constructors methods fields }
|
||||
|
||||
classbody : LBRACKET RBRACKET { ([], []) }
|
||||
classbody : LBRACKET RBRACKET { ([], [], []) }
|
||||
| LBRACKET classbodydeclarations RBRACKET { $2 }
|
||||
|
||||
modifiers : modifier { }
|
||||
@ -102,13 +104,15 @@ modifiers : modifier { }
|
||||
|
||||
classbodydeclarations : classbodydeclaration {
|
||||
case $1 of
|
||||
MethodDecl method -> ([method], [])
|
||||
FieldDecls fields -> ([], fields)
|
||||
ConstructorDecl constructor -> ([constructor], [], [])
|
||||
MethodDecl method -> ([], (convertMethodDeclarationWithOptionals method), [])
|
||||
FieldDecls fields -> ([], [], fields)
|
||||
}
|
||||
| classbodydeclarations classbodydeclaration {
|
||||
case ($1, $2) of
|
||||
((methods, fields), MethodDecl method) -> ((methods ++ [method]), fields)
|
||||
((methods, fields), FieldDecls newFields) -> (methods, (fields ++ newFields))
|
||||
((constructors, methods, fields), ConstructorDecl constructor) -> ((constructors ++ [constructor]), methods, fields)
|
||||
((constructors, methods, fields), MethodDecl method) -> (constructors, (methods ++ (convertMethodDeclarationWithOptionals method)), fields)
|
||||
((constructors, methods, fields), FieldDecls newFields) -> (constructors, methods, (fields ++ newFields))
|
||||
}
|
||||
|
||||
modifier : PUBLIC { }
|
||||
@ -127,19 +131,19 @@ classorinterfacetype : simplename { $1 }
|
||||
classmemberdeclaration : fielddeclaration { $1 }
|
||||
| methoddeclaration { $1 }
|
||||
|
||||
constructordeclaration : constructordeclarator constructorbody { MethodDecl $ MethodDeclaration "void" "<init>" $1 $2 }
|
||||
| modifiers constructordeclarator constructorbody { MethodDecl $ MethodDeclaration "void" "<init>" $2 $3 }
|
||||
constructordeclaration : constructordeclarator constructorbody { case $1 of (identifier, parameters) -> ConstructorDecl $ ConstructorDeclaration identifier parameters $2 }
|
||||
| modifiers constructordeclarator constructorbody { case $2 of (identifier, parameters) -> ConstructorDecl $ ConstructorDeclaration identifier parameters $3 }
|
||||
|
||||
fielddeclaration : type variabledeclarators SEMICOLON { FieldDecls $ map (convertDeclarator $1) $2 }
|
||||
| modifiers type variabledeclarators SEMICOLON { FieldDecls $ map (convertDeclarator $2) $3 }
|
||||
|
||||
methoddeclaration : methodheader methodbody { case $1 of (returnType, (name, parameters)) -> MethodDecl (MethodDeclaration returnType name parameters $2) }
|
||||
methoddeclaration : methodheader methodbody { case $1 of (returnType, (name, (parameters, optionalparameters))) -> MethodDecl (MethodDeclarationWithOptionals returnType name parameters optionalparameters $2) }
|
||||
|
||||
block : LBRACKET RBRACKET { Block [] }
|
||||
| LBRACKET blockstatements RBRACKET { Block $2 }
|
||||
|
||||
constructordeclarator : simplename LBRACE RBRACE { [] }
|
||||
| simplename LBRACE formalparameterlist RBRACE { $3 }
|
||||
constructordeclarator : simplename LBRACE RBRACE { ($1, []) }
|
||||
| simplename LBRACE formalparameterlist RBRACE { ($1, $3) }
|
||||
|
||||
constructorbody : LBRACKET RBRACKET { Block [] }
|
||||
-- | LBRACKET explicitconstructorinvocation RBRACKET { }
|
||||
@ -163,6 +167,10 @@ methodbody : block { $1 }
|
||||
blockstatements : blockstatement { $1 }
|
||||
| blockstatements blockstatement { $1 ++ $2}
|
||||
|
||||
formalandoptionalparameterlist : formalparameterlist { ($1, []) }
|
||||
| formalparameterlist COMMA optionalparameterlist { ($1, $3) }
|
||||
| optionalparameterlist { ([], $1) }
|
||||
|
||||
formalparameterlist : formalparameter { [$1] }
|
||||
| formalparameterlist COMMA formalparameter { $1 ++ [$3] }
|
||||
|
||||
@ -172,8 +180,13 @@ explicitconstructorinvocation : THIS LBRACE RBRACE SEMICOLON { }
|
||||
classtypelist : classtype { }
|
||||
| classtypelist COMMA classtype { }
|
||||
|
||||
methoddeclarator : IDENTIFIER LBRACE RBRACE { ($1, []) }
|
||||
| IDENTIFIER LBRACE formalparameterlist RBRACE { ($1, $3) }
|
||||
methoddeclarator : IDENTIFIER LBRACE RBRACE { ($1, ([], [])) }
|
||||
| IDENTIFIER LBRACE formalandoptionalparameterlist RBRACE { ($1, $3) }
|
||||
|
||||
optionalparameterlist : optionalparameter { [$1] }
|
||||
| optionalparameterlist COMMA optionalparameter { $1 ++ [$3] }
|
||||
|
||||
optionalparameter : type variabledeclaratorid ASSIGN variableinitializer { OptionalParameter $1 $2 $4 }
|
||||
|
||||
primitivetype : BOOLEAN { "boolean" }
|
||||
| numerictype { $1 }
|
||||
@ -204,6 +217,7 @@ statement : statementwithouttrailingsubstatement{ $1 } -- statement retu
|
||||
| ifthenstatement { [$1] }
|
||||
| ifthenelsestatement { [$1] }
|
||||
| whilestatement { [$1] }
|
||||
| forstatement { [$1] }
|
||||
|
||||
|
||||
expression : assignmentexpression { $1 }
|
||||
@ -224,6 +238,21 @@ ifthenelsestatement : IF LBRACE expression RBRACE statementnoshortif ELSE state
|
||||
|
||||
whilestatement : WHILE LBRACE expression RBRACE statement { While $3 (Block $5) }
|
||||
|
||||
forstatement : FOR LBRACE forinit optionalexpression forupdate statement { Block ($3 ++ [While ($4) (Block ($6 ++ $5))]) }
|
||||
|
||||
forinit : statementexpressionlist SEMICOLON { $1 }
|
||||
| localvariabledeclaration SEMICOLON { $1 }
|
||||
| SEMICOLON { [] }
|
||||
|
||||
optionalexpression : expression SEMICOLON { $1 }
|
||||
| SEMICOLON { BooleanLiteral True }
|
||||
|
||||
forupdate : statementexpressionlist RBRACE { $1 }
|
||||
| RBRACE { [] }
|
||||
|
||||
statementexpressionlist : statementexpression { [StatementExpressionStatement $1] }
|
||||
| statementexpressionlist COMMA statementexpression { $1 ++ [StatementExpressionStatement $3] }
|
||||
|
||||
assignmentexpression : conditionalexpression { $1 }
|
||||
| assignment { StatementExpressionExpression $1 }
|
||||
|
||||
@ -265,6 +294,7 @@ conditionalorexpression : conditionalandexpression { $1 }
|
||||
-- | conditionalorexpression LOGICALOR conditionalandexpression{ }
|
||||
|
||||
lefthandside : name { $1 }
|
||||
| primary DOT IDENTIFIER { BinaryOperation NameResolution $1 (Reference $3) }
|
||||
|
||||
assignmentoperator : ASSIGN { Nothing }
|
||||
| TIMESEQUAL { Just Multiplication }
|
||||
@ -287,8 +317,8 @@ postincrementexpression : postfixexpression INCREMENT { PostIncrement $1 }
|
||||
|
||||
postdecrementexpression : postfixexpression DECREMENT { PostDecrement $1 }
|
||||
|
||||
methodinvocation : simplename LBRACE RBRACE { MethodCall (Reference "this") $1 [] }
|
||||
| simplename LBRACE argumentlist RBRACE { MethodCall (Reference "this") $1 $3 }
|
||||
methodinvocation : name LBRACE RBRACE { let (exp, functionname) = extractFunctionName $1 in (MethodCall exp functionname []) }
|
||||
| name LBRACE argumentlist RBRACE { let (exp, functionname) = extractFunctionName $1 in (MethodCall exp functionname $3) }
|
||||
| primary DOT IDENTIFIER LBRACE RBRACE { MethodCall $1 $3 [] }
|
||||
| primary DOT IDENTIFIER LBRACE argumentlist RBRACE { MethodCall $1 $3 $5 }
|
||||
|
||||
@ -366,16 +396,34 @@ multiplicativeexpression : unaryexpression { $1 }
|
||||
|
||||
{
|
||||
|
||||
data MethodOrFieldDeclaration = MethodDecl MethodDeclaration
|
||||
| FieldDecls [VariableDeclaration]
|
||||
data MemberDeclaration = MethodDecl MethodDeclarationWithOptionals
|
||||
| ConstructorDecl ConstructorDeclaration
|
||||
| FieldDecls [VariableDeclaration] deriving (Show)
|
||||
|
||||
data Declarator = Declarator Identifier (Maybe Expression)
|
||||
|
||||
convertDeclarator :: DataType -> Declarator -> VariableDeclaration
|
||||
convertDeclarator dataType (Declarator id assigment) = VariableDeclaration dataType id assigment
|
||||
|
||||
data StatementWithoutSub = Statement
|
||||
extractFunctionName :: Expression -> (Expression, Identifier)
|
||||
extractFunctionName (BinaryOperation NameResolution exp (Reference functionname)) = (exp, functionname)
|
||||
extractFunctionName (Reference functionname) = ((Reference "this"), functionname)
|
||||
|
||||
data OptionalParameter = OptionalParameter DataType Identifier Expression deriving (Show)
|
||||
data MethodDeclarationWithOptionals = MethodDeclarationWithOptionals DataType Identifier [ParameterDeclaration] [OptionalParameter] Statement deriving (Show)
|
||||
convertMethodDeclarationWithOptionals :: MethodDeclarationWithOptionals -> [MethodDeclaration]
|
||||
convertMethodDeclarationWithOptionals (MethodDeclarationWithOptionals returnType id param [] stmt) = [MethodDeclaration returnType id param stmt]
|
||||
convertMethodDeclarationWithOptionals (MethodDeclarationWithOptionals returnType id param (opt : optRest) stmt) = generateHelperMethod returnType id param opt : convertMethodDeclarationWithOptionals (generateBaseMethod returnType id param opt optRest stmt)
|
||||
convertOptionalParameter :: OptionalParameter -> ParameterDeclaration
|
||||
convertOptionalParameter (OptionalParameter dtype id exp) = ParameterDeclaration dtype id
|
||||
generateHelperMethod :: DataType -> Identifier -> [ParameterDeclaration] -> OptionalParameter -> MethodDeclaration
|
||||
generateHelperMethod returnType methodName params (OptionalParameter dtype id exp) =
|
||||
let references = ((map (\(ParameterDeclaration paramType ident) -> (Reference ident)) params) ++ [exp])
|
||||
methodcall = (MethodCall (Reference "this") methodName references)
|
||||
lastStatement = if returnType == "void" then StatementExpressionStatement methodcall else Return $ Just $ StatementExpressionExpression methodcall
|
||||
in MethodDeclaration returnType methodName params $ Block [lastStatement]
|
||||
generateBaseMethod :: DataType -> Identifier -> [ParameterDeclaration] -> OptionalParameter -> [OptionalParameter] -> Statement -> MethodDeclarationWithOptionals
|
||||
generateBaseMethod returnType methodName params (OptionalParameter dtype id exp) optRest stmt = MethodDeclarationWithOptionals returnType methodName (params ++ [ParameterDeclaration dtype id]) optRest stmt
|
||||
|
||||
parseError :: ([Token], [String]) -> a
|
||||
parseError (errortoken, expected) = error ("parse error on token: " ++ show errortoken ++ "\nexpected one of: " ++ show expected)
|
||||
|
189
src/Typecheck.hs
189
src/Typecheck.hs
@ -3,18 +3,48 @@ import Data.List (find)
|
||||
import Data.Maybe
|
||||
import Ast
|
||||
|
||||
|
||||
typeCheckCompilationUnit :: CompilationUnit -> CompilationUnit
|
||||
typeCheckCompilationUnit classes = map (`typeCheckClass` classes) classes
|
||||
typeCheckCompilationUnit classes =
|
||||
let
|
||||
-- Helper function to add a default constructor if none are present
|
||||
ensureDefaultConstructor :: Class -> Class
|
||||
ensureDefaultConstructor (Class className constructors methods fields) =
|
||||
let
|
||||
defaultConstructor = ConstructorDeclaration className [] (Block [])
|
||||
constructorsWithDefault = if null constructors then [defaultConstructor] else constructors
|
||||
in Class className constructorsWithDefault methods fields
|
||||
|
||||
-- Inject default constructors into all classes
|
||||
classesWithDefaultConstructors = map ensureDefaultConstructor classes
|
||||
|
||||
in map (`typeCheckClass` classesWithDefaultConstructors) classesWithDefaultConstructors
|
||||
|
||||
typeCheckClass :: Class -> [Class] -> Class
|
||||
typeCheckClass (Class className methods fields) classes =
|
||||
typeCheckClass (Class className constructors methods fields) classes =
|
||||
let
|
||||
-- Fields and methods dont need to be added to the symtab because they are looked upon automatically under "this"
|
||||
-- if its not a declared local variable. Also shadowing wouldnt be possible then.
|
||||
initalSymTab = [("this", className)]
|
||||
checkedConstructors = map (\constructor -> typeCheckConstructorDeclaration constructor initalSymTab classes) constructors
|
||||
checkedMethods = map (\method -> typeCheckMethodDeclaration method initalSymTab classes) methods
|
||||
checkedFields = map (\field -> typeCheckVariableDeclaration field initalSymTab classes) fields
|
||||
in Class className checkedMethods checkedFields
|
||||
in Class className checkedConstructors checkedMethods checkedFields
|
||||
|
||||
typeCheckConstructorDeclaration :: ConstructorDeclaration -> [(Identifier, DataType)] -> [Class] -> ConstructorDeclaration
|
||||
typeCheckConstructorDeclaration (ConstructorDeclaration name params body) symtab classes =
|
||||
let
|
||||
constructorParams = [(identifier, dataType) | ParameterDeclaration dataType identifier <- params]
|
||||
initialSymtab = symtab ++ constructorParams
|
||||
className = fromMaybe (error "Constructor Declaration: 'this' not found in symtab") (lookup "this" symtab)
|
||||
checkedBody = typeCheckStatement body initialSymtab classes
|
||||
bodyType = getTypeFromStmt checkedBody
|
||||
in if name == className
|
||||
then if bodyType == "void"
|
||||
then ConstructorDeclaration name params checkedBody
|
||||
else error $ "Constructor Declaration: Return type mismatch in constructor " ++ name ++ ": expected void, found " ++ bodyType
|
||||
else error $ "Constructor Declaration: Constructor name " ++ name ++ " does not match class name " ++ className
|
||||
|
||||
|
||||
typeCheckMethodDeclaration :: MethodDeclaration -> [(Identifier, DataType)] -> [Class] -> MethodDeclaration
|
||||
typeCheckMethodDeclaration (MethodDeclaration retType name params body) symtab classes =
|
||||
@ -37,14 +67,18 @@ typeCheckVariableDeclaration (VariableDeclaration dataType identifier maybeExpr)
|
||||
-- Type check the initializer expression if it exists
|
||||
checkedExpr = fmap (\expr -> typeCheckExpression expr symtab classes) maybeExpr
|
||||
exprType = fmap getTypeFromExpr checkedExpr
|
||||
checkedExprWithType = case exprType of
|
||||
Just "null" | isObjectType dataType -> Just (TypedExpression dataType NullLiteral)
|
||||
_ -> checkedExpr
|
||||
in case (validType, redefined, exprType) of
|
||||
(False, _, _) -> error $ "Type '" ++ dataType ++ "' is not a valid type for variable '" ++ identifier ++ "'"
|
||||
(_, True, _) -> error $ "Variable '" ++ identifier ++ "' is redefined in the same scope"
|
||||
(_, _, Just t)
|
||||
| t == "null" && isObjectType dataType -> VariableDeclaration dataType identifier checkedExpr
|
||||
| t == "null" && isObjectType dataType -> VariableDeclaration dataType identifier checkedExprWithType
|
||||
| t /= dataType -> error $ "Type mismatch in declaration of '" ++ identifier ++ "': expected " ++ dataType ++ ", found " ++ t
|
||||
| otherwise -> VariableDeclaration dataType identifier checkedExpr
|
||||
(_, _, Nothing) -> VariableDeclaration dataType identifier checkedExpr
|
||||
| otherwise -> VariableDeclaration dataType identifier checkedExprWithType
|
||||
(_, _, Nothing) -> VariableDeclaration dataType identifier checkedExprWithType
|
||||
|
||||
|
||||
-- ********************************** Type Checking: Expressions **********************************
|
||||
|
||||
@ -59,9 +93,9 @@ typeCheckExpression (Reference id) symtab classes =
|
||||
Nothing ->
|
||||
case lookup "this" symtab of
|
||||
Just className ->
|
||||
let classDetails = find (\(Class name _ _) -> name == className) classes
|
||||
let classDetails = find (\(Class name _ _ _) -> name == className) classes
|
||||
in case classDetails of
|
||||
Just (Class _ _ fields) ->
|
||||
Just (Class _ _ _ fields) ->
|
||||
let fieldTypes = [dt | VariableDeclaration dt fieldId _ <- fields, fieldId == id]
|
||||
-- this case only happens when its a field of its own class so the implicit this will be converted to explicit this
|
||||
in case fieldTypes of
|
||||
@ -125,64 +159,80 @@ typeCheckStatementExpression (Assignment ref expr) symtab classes =
|
||||
ref' = typeCheckExpression ref symtab classes
|
||||
type' = getTypeFromExpr expr'
|
||||
type'' = getTypeFromExpr ref'
|
||||
typeToAssign = if type' == "null" && isObjectType type'' then type'' else type'
|
||||
exprWithType = if type' == "null" && isObjectType type'' then TypedExpression type'' NullLiteral else expr'
|
||||
in
|
||||
if type'' == type' || (type' == "null" && isObjectType type'') then
|
||||
TypedStatementExpression type'' (Assignment ref' expr')
|
||||
if type'' == typeToAssign then
|
||||
TypedStatementExpression type'' (Assignment ref' exprWithType)
|
||||
else
|
||||
error $ "Type mismatch in assignment to variable: expected " ++ type'' ++ ", found " ++ type'
|
||||
error $ "Type mismatch in assignment to variable: expected " ++ type'' ++ ", found " ++ typeToAssign
|
||||
|
||||
|
||||
typeCheckStatementExpression (ConstructorCall className args) symtab classes =
|
||||
case find (\(Class name _ _) -> name == className) classes of
|
||||
case find (\(Class name _ _ _) -> name == className) classes of
|
||||
Nothing -> error $ "Class '" ++ className ++ "' not found."
|
||||
Just (Class _ methods fields) ->
|
||||
-- Find constructor matching the class name with void return type
|
||||
case find (\(MethodDeclaration retType name params _) -> name == "<init>" && retType == "void") methods of
|
||||
-- If no constructor is found, assume standard constructor with no parameters
|
||||
Nothing ->
|
||||
if null args then
|
||||
TypedStatementExpression className (ConstructorCall className args)
|
||||
else
|
||||
error $ "No valid constructor found for class '" ++ className ++ "', but arguments were provided."
|
||||
Just (MethodDeclaration _ _ params _) ->
|
||||
Just (Class _ constructors _ _) ->
|
||||
let
|
||||
args' = map (\arg -> typeCheckExpression arg symtab classes) args
|
||||
-- Extract expected parameter types from the constructor's parameters
|
||||
expectedTypes = [dataType | ParameterDeclaration dataType _ <- params]
|
||||
argTypes = map getTypeFromExpr args'
|
||||
-- Check if the types of the provided arguments match the expected types
|
||||
typeMatches = zipWith (\expected actual -> if expected == actual then Nothing else Just (expected, actual)) expectedTypes argTypes
|
||||
mismatchErrors = map (\(exp, act) -> "Expected type '" ++ exp ++ "', found '" ++ act ++ "'.") (catMaybes typeMatches)
|
||||
in
|
||||
if length args /= length params then
|
||||
error $ "Constructor for class '" ++ className ++ "' expects " ++ show (length params) ++ " arguments, but got " ++ show (length args) ++ "."
|
||||
else if not (null mismatchErrors) then
|
||||
error $ unlines $ ("Type mismatch in constructor arguments for class '" ++ className ++ "':") : mismatchErrors
|
||||
else
|
||||
TypedStatementExpression className (ConstructorCall className args')
|
||||
matchParams (ParameterDeclaration paramType _) arg =
|
||||
let argTyped = typeCheckExpression arg symtab classes
|
||||
argType = getTypeFromExpr argTyped
|
||||
in if argType == "null" && isObjectType paramType
|
||||
then Just (TypedExpression paramType NullLiteral)
|
||||
else if argType == paramType
|
||||
then Just argTyped
|
||||
else Nothing
|
||||
|
||||
matchConstructor (ConstructorDeclaration name params _) =
|
||||
let matchedArgs = sequence $ zipWith matchParams params args
|
||||
in fmap (\checkedArgs -> (params, checkedArgs)) matchedArgs
|
||||
|
||||
validConstructors = filter (\(params, _) -> length params == length args) $ mapMaybe matchConstructor constructors
|
||||
|
||||
expectedSignatures = [ map (\(ParameterDeclaration t _) -> t) params | ConstructorDeclaration _ params _ <- constructors ]
|
||||
actualSignature = map (\arg -> getTypeFromExpr (typeCheckExpression arg symtab classes)) args
|
||||
mismatchDetails = "Constructor not found for class '" ++ className ++ "' with given arguments.\n" ++
|
||||
"Expected signatures:\n" ++ show expectedSignatures ++
|
||||
"\nActual arguments:" ++ show actualSignature
|
||||
|
||||
in case validConstructors of
|
||||
[(_, checkedArgs)] ->
|
||||
TypedStatementExpression className (ConstructorCall className checkedArgs)
|
||||
[] -> error mismatchDetails
|
||||
_ -> error $ "Multiple matching constructors found for class '" ++ className ++ "' with given arguments."
|
||||
|
||||
typeCheckStatementExpression (MethodCall expr methodName args) symtab classes =
|
||||
let objExprTyped = typeCheckExpression expr symtab classes
|
||||
in case objExprTyped of
|
||||
TypedExpression objType _ ->
|
||||
case find (\(Class className _ _) -> className == objType) classes of
|
||||
Just (Class _ methods _) ->
|
||||
case find (\(MethodDeclaration retType name params _) -> name == methodName) methods of
|
||||
Just (MethodDeclaration retType _ params _) ->
|
||||
let args' = map (\arg -> typeCheckExpression arg symtab classes) args
|
||||
expectedTypes = [dataType | ParameterDeclaration dataType _ <- params]
|
||||
argTypes = map getTypeFromExpr args'
|
||||
typeMatches = zipWith (\expType argType -> (expType == argType, expType, argType)) expectedTypes argTypes
|
||||
mismatches = filter (not . fst3) typeMatches
|
||||
where fst3 (a, _, _) = a
|
||||
in
|
||||
if null mismatches && length args == length params then
|
||||
TypedStatementExpression retType (MethodCall objExprTyped methodName args')
|
||||
else if not (null mismatches) then
|
||||
error $ unlines $ ("Argument type mismatches for method '" ++ methodName ++ "':")
|
||||
: [ "Expected: " ++ expType ++ ", Found: " ++ argType | (_, expType, argType) <- mismatches ]
|
||||
else
|
||||
error $ "Incorrect number of arguments for method '" ++ methodName ++ "'. Expected " ++ show (length expectedTypes) ++ ", found " ++ show (length args) ++ "."
|
||||
Nothing -> error $ "Method '" ++ methodName ++ "' not found in class '" ++ objType ++ "'."
|
||||
case find (\(Class className _ _ _) -> className == objType) classes of
|
||||
Just (Class _ _ methods _) ->
|
||||
let matchParams (ParameterDeclaration paramType _) arg =
|
||||
let argTyped = typeCheckExpression arg symtab classes
|
||||
argType = getTypeFromExpr argTyped
|
||||
in if argType == "null" && isObjectType paramType
|
||||
then Just (TypedExpression paramType NullLiteral)
|
||||
else if argType == paramType
|
||||
then Just argTyped
|
||||
else Nothing
|
||||
|
||||
matchMethod (MethodDeclaration retType name params _) =
|
||||
let matchedArgs = sequence $ zipWith matchParams params args
|
||||
in fmap (\checkedArgs -> (MethodDeclaration retType name params (Block []), checkedArgs)) matchedArgs
|
||||
|
||||
validMethods = filter (\(MethodDeclaration _ name params _, _) -> name == methodName && length params == length args) $ mapMaybe matchMethod methods
|
||||
|
||||
expectedSignatures = [ map (\(ParameterDeclaration t _) -> t) params | MethodDeclaration _ name params _ <- methods, name == methodName ]
|
||||
actualSignature = map (\arg -> getTypeFromExpr (typeCheckExpression arg symtab classes)) args
|
||||
mismatchDetails = "Method not found for class '" ++ objType ++ "' with given arguments.\n" ++
|
||||
"Expected signatures for method '" ++ methodName ++ "':\n" ++ unlines (map show expectedSignatures) ++
|
||||
"Actual arguments:\n" ++ show actualSignature
|
||||
|
||||
in case validMethods of
|
||||
[(MethodDeclaration retType _ params _, checkedArgs)] ->
|
||||
TypedStatementExpression retType (MethodCall objExprTyped methodName checkedArgs)
|
||||
[] -> error mismatchDetails
|
||||
_ -> error $ "Multiple matching methods found for class '" ++ objType ++ "' and method '" ++ methodName ++ "' with given arguments."
|
||||
|
||||
Nothing -> error $ "Class for object type '" ++ objType ++ "' not found."
|
||||
_ -> error "Invalid object type for method call. Object must have a class type."
|
||||
|
||||
@ -251,14 +301,18 @@ typeCheckStatement (LocalVariableDeclaration (VariableDeclaration dataType ident
|
||||
-- If there's an initializer expression, type check it
|
||||
let checkedExpr = fmap (\expr -> typeCheckExpression expr symtab classes) maybeExpr
|
||||
exprType = fmap getTypeFromExpr checkedExpr
|
||||
checkedExprWithType = case (exprType, dataType) of
|
||||
(Just "null", _) | isObjectType dataType -> Just (TypedExpression dataType NullLiteral)
|
||||
_ -> checkedExpr
|
||||
in case exprType of
|
||||
Just t
|
||||
| t == "null" && isObjectType dataType ->
|
||||
TypedStatement dataType (LocalVariableDeclaration (VariableDeclaration dataType identifier checkedExpr))
|
||||
TypedStatement dataType (LocalVariableDeclaration (VariableDeclaration dataType identifier checkedExprWithType))
|
||||
| t /= dataType -> error $ "Type mismatch in declaration of '" ++ identifier ++ "': expected " ++ dataType ++ ", found " ++ t
|
||||
| otherwise -> TypedStatement dataType (LocalVariableDeclaration (VariableDeclaration dataType identifier checkedExpr))
|
||||
| otherwise -> TypedStatement dataType (LocalVariableDeclaration (VariableDeclaration dataType identifier checkedExprWithType))
|
||||
Nothing -> TypedStatement dataType (LocalVariableDeclaration (VariableDeclaration dataType identifier checkedExpr))
|
||||
|
||||
|
||||
typeCheckStatement (While cond stmt) symtab classes =
|
||||
let cond' = typeCheckExpression cond symtab classes
|
||||
stmt' = typeCheckStatement stmt symtab classes
|
||||
@ -305,13 +359,17 @@ typeCheckStatement (Block statements) symtab classes =
|
||||
typeCheckStatement (Return expr) symtab classes =
|
||||
let methodReturnType = fromMaybe (error "Method return type not found in symbol table") (lookup "thisMeth" symtab)
|
||||
expr' = case expr of
|
||||
Just e -> Just (typeCheckExpression e symtab classes)
|
||||
Just e -> let eTyped = typeCheckExpression e symtab classes
|
||||
in if getTypeFromExpr eTyped == "null" && isObjectType methodReturnType
|
||||
then Just (TypedExpression methodReturnType NullLiteral)
|
||||
else Just eTyped
|
||||
Nothing -> Nothing
|
||||
returnType = maybe "void" getTypeFromExpr expr'
|
||||
in if returnType == methodReturnType || isSubtype returnType methodReturnType classes
|
||||
then TypedStatement returnType (Return expr')
|
||||
else error $ "Return: Return type mismatch: expected " ++ methodReturnType ++ ", found " ++ returnType
|
||||
|
||||
|
||||
typeCheckStatement (StatementExpressionStatement stmtExpr) symtab classes =
|
||||
let stmtExpr' = typeCheckStatementExpression stmtExpr symtab classes
|
||||
in TypedStatement (getTypeFromStmtExpr stmtExpr') (StatementExpressionStatement stmtExpr')
|
||||
@ -327,7 +385,7 @@ isSubtype subType superType classes
|
||||
| otherwise = False
|
||||
|
||||
isUserDefinedClass :: DataType -> [Class] -> Bool
|
||||
isUserDefinedClass dt classes = dt `elem` map (\(Class name _ _) -> name) classes
|
||||
isUserDefinedClass dt classes = dt `elem` map (\(Class name _ _ _) -> name) classes
|
||||
|
||||
isObjectType :: DataType -> Bool
|
||||
isObjectType dt = dt /= "int" && dt /= "boolean" && dt /= "char"
|
||||
@ -380,9 +438,14 @@ checkComparisonOperation op expr1' expr2' type1 type2
|
||||
|
||||
checkEqualityOperation :: BinaryOperator -> Expression -> Expression -> DataType -> DataType -> Expression
|
||||
checkEqualityOperation op expr1' expr2' type1 type2
|
||||
| type1 == type2 =
|
||||
| type1 == type2 || (type1 == "null" && isObjectType type2) || (type2 == "null" && isObjectType type1) =
|
||||
TypedExpression "boolean" (BinaryOperation op expr1' expr2')
|
||||
| otherwise = error $ "Equality operation " ++ show op ++ " requires operands of the same type"
|
||||
| type1 /= type2 =
|
||||
error $ "Equality operation " ++ show op ++ " requires operands of the same type. Found types: " ++ type1 ++ " and " ++ type2
|
||||
| (type1 == "null" && not (isObjectType type2)) || (type2 == "null" && not (isObjectType type1)) =
|
||||
error $ "Equality operation " ++ show op ++ " requires that null can only be compared with object types. Found types: " ++ type1 ++ " and " ++ type2
|
||||
| otherwise = error $ "Equality operation " ++ show op ++ " encountered unexpected types: " ++ type1 ++ " and " ++ type2
|
||||
|
||||
|
||||
checkLogicalOperation :: BinaryOperator -> Expression -> Expression -> DataType -> DataType -> Expression
|
||||
checkLogicalOperation op expr1' expr2' type1 type2
|
||||
@ -394,8 +457,8 @@ resolveNameResolution :: Expression -> Expression -> [(Identifier, DataType)] ->
|
||||
resolveNameResolution expr1' (Reference ident2) symtab classes =
|
||||
case getTypeFromExpr expr1' of
|
||||
objType ->
|
||||
case find (\(Class className _ _) -> className == objType) classes of
|
||||
Just (Class _ _ fields) ->
|
||||
case find (\(Class className _ _ _) -> className == objType) classes of
|
||||
Just (Class _ _ _ fields) ->
|
||||
let fieldTypes = [dt | VariableDeclaration dt id _ <- fields, id == ident2]
|
||||
in case fieldTypes of
|
||||
[resolvedType] -> TypedExpression resolvedType (BinaryOperation NameResolution expr1' (TypedExpression resolvedType (FieldVariable ident2)))
|
||||
|
Loading…
Reference in New Issue
Block a user