Make TypeMap work exacly with anons.

tests/ExactStrings.hx

@@ -1,4 +1,3 @@
-import haxe.macro.Context;
 import haxe.macro.Context.typeof;
 using tink.MacroApi;
 
@@ -12,6 +11,8 @@ class ExactStrings extends Base {
     expect('Dummy.Private', macro Dummy.p);
     expect('nested.Dummy.Private', macro nested.Dummy.p);
     expect('{ @foo var x:Int; }', macro (null:{@foo var x:Int;}));
+    expect('{ @foo @bar var x:Int; }', macro (null:{@foo @bar var x:Int;}));
+    expect('{ @bar @foo var x:Int; }', macro (null:{@bar @foo var x:Int;}));// not 100% sure this is always the best choice, but let's roll with it
     expect('{ @bar var x:Int; }', macro (null:{@bar var x:Int;}));
     expect('{ var x:Int; var y:Int; }', macro (null:{x:Int,y:Int}));
     expect('{ var x:Int; var y:Int; }', macro (null:{y:Int,x:Int}));

tests/TypeMapTest.hx

@@ -11,6 +11,8 @@ class TypeMapTest extends TestCase {
     var t = new TypeMap();
     var t1 = (macro [{ foo: [{ bar: '5' }]}]).typeof().sure();
     var t2 = (macro [{ foo: [{ bar: 5 }]}]).typeof().sure();
+    var t3 = (macro [{ foo: [{ bar: 5 }]}]).typeof().sure();
+    var t4 = (macro [{ foo: [({ bar: 5 }:{ @foo var bar:Int; })]}]).typeof().sure();
 
     t.set(t1, 0);
     assertEquals(Lambda.count(t), 1);
@@ -19,7 +21,10 @@ class TypeMapTest extends TestCase {
     t.set(t1, 2);
     assertEquals(Lambda.count(t), 2);
     t.set(t2, 3);
+    t.set(t3, 3);
     assertEquals(Lambda.count(t), 2);
+    t.set(t4, 4);
+    assertEquals(Lambda.count(t), 3);
 
     assertEquals(t.get(t1), 2);
     assertEquals(t.get(t2), 3);

tests/Types.hx

@@ -10,36 +10,35 @@ using tink.MacroApi;
 class Types extends Base {
   function type(c:ComplexType)
     return c.toType().sure();
-    
+
   function resolve(type:String)
     return Context.getType(type);
-    
+
   inline function assertSuccess<S, F>(o:Outcome<S, F>)
     assertTrue(o.isSuccess());
-    
+
   inline function assertFailure<S, F>(o:Outcome<S, F>)
     assertFalse(o.isSuccess());
-    
+
   function testIs() {
-    
     assertSuccess(resolve('Int').isSubTypeOf(resolve('Float')));
     assertFailure(resolve('Float').isSubTypeOf(resolve('Int')));
-  }  
-  
+  }
+
   function testFields() {
     var expected = type(macro : Void -> Iterator<Arrayish>),
       iterator = type(macro : haxe.ds.StringMap<Arrayish>).getFields(true).sure().filter(function (c) return c.name == 'iterator')[0];
-    
+
     assertSuccess(iterator.type.isSubTypeOf(expected));
     assertSuccess(expected.isSubTypeOf(iterator.type));
   }
-  
+
   function testConvert() {
     assertSuccess((macro : Int).toType());
     assertFailure((macro : Tni).toType());
     function blank()
       return type(MacroApi.pos().makeBlankType());
-    
+
     var bool = type(macro : Bool);
     assertTrue(blank().isSubTypeOf(bool).isSuccess());
     assertTrue(bool.isSubTypeOf(blank()).isSuccess());
@@ -65,7 +64,7 @@ class Types extends Base {
     assertEquals('String', Context.getType('String').toComplex().toString());
     assertEquals('tink.CoreApi.Noise', Context.getType('tink.CoreApi.Noise').toComplex().toString());
   }
-  
+
   function testDeduceCommonType() {
     function ct2t(ct:ComplexType) return ct.toType().sure();
     assertEquals('StdTypes.Float', tink.macro.Types.deduceCommonType([(macro:Float), (macro:Int)].map(ct2t)).sure().toComplex().toString());