Reenable unboxed ints

- Change INT to a type that remembers whether it was boxed or not.
- We still need a way of specifying a plain unboxed int, so add a
"phony" UNBOXED_INT.  UNBOXED_INT is not usable as a variable type,
but can be used to specify argument and return types.  It's up to
the receiver (irgen or type analysis) to convert UNBOXED_INT to
a usable INT.  Right now that's only guarded with a number of
asserts (and not through, say, the C++ type system).

src/analysis/type_analysis.cpp

@@ -57,12 +57,12 @@ ConcreteCompilerType* NullTypeAnalysis::getTypeAtBlockEnd(InternedString name, C
 
 
 // Note: the behavior of this function must match irgenerator.cpp::unboxVar()
-static ConcreteCompilerType* unboxedType(ConcreteCompilerType* t) {
+static CompilerType* unboxedType(ConcreteCompilerType* t) {
     if (t == BOXED_BOOL)
         return BOOL;
-#if ENABLE_UNBOXED_VALUES
     if (t == BOXED_INT)
         return INT;
+#if ENABLE_UNBOXED_VALUES
     if (t == BOXED_FLOAT)
         return FLOAT;
 #endif
@@ -117,17 +117,17 @@ private:
         assert(speculation != TypeAnalysis::NONE);
 
         if (speculated_cls != NULL && speculated_cls->is_constant) {
-            ConcreteCompilerType* speculated_type = unboxedType(typeFromClass(speculated_cls));
-            if (VERBOSITY() >= 2) {
-                printf("in propagator, speculating that %s would actually be %s, at ", old_type->debugName().c_str(),
-                       speculated_type->debugName().c_str());
-                fflush(stdout);
-                print_ast(node);
-                llvm::outs().flush();
-                printf("\n");
-            }
-
+            CompilerType* speculated_type = unboxedType(typeFromClass(speculated_cls));
             if (!old_type->canConvertTo(speculated_type)) {
+                if (VERBOSITY() >= 2) {
+                    printf("in propagator, speculating that %s would actually be %s, at ",
+                           old_type->debugName().c_str(), speculated_type->debugName().c_str());
+                    fflush(stdout);
+                    print_ast(node);
+                    llvm::outs().flush();
+                    printf("\n");
+                }
+
                 type_speculations[node] = speculated_cls;
                 return speculated_type;
             }
@@ -147,6 +147,7 @@ private:
         }
 
         expr_types[node] = rtn;
+        assert(rtn->isUsable());
         return rtn;
     }
 
@@ -163,10 +164,12 @@ private:
         }
 
         expr_types[node] = rtn;
+        assert(rtn->isUsable());
         return rtn;
     }
 
     void _doSet(InternedString target, CompilerType* t) {
+        assert(t->isUsable());
         if (t)
             sym_table[target] = t;
     }

src/codegen/compvars.h

@@ -47,7 +47,7 @@ public:
     virtual std::string debugName() = 0;
     virtual ConcreteCompilerType* getConcreteType() = 0;
     virtual ConcreteCompilerType* getBoxType() = 0;
-    virtual bool canConvertTo(ConcreteCompilerType* other_type) = 0;
+    virtual bool canConvertTo(CompilerType* other_type) = 0;
     virtual CompilerType* getattrType(BoxedString* attr, bool cls_only) = 0;
     virtual CompilerType* getPystonIterType();
     virtual Result hasattr(BoxedString* attr);
@@ -58,6 +58,13 @@ public:
     virtual Box* deserializeFromFrame(const FrameVals& vals) = 0;
     virtual int numFrameArgs() = 0;
     virtual std::vector<CompilerType*> unpackTypes(int num_into);
+
+    // Some types are not "usable" even if they are "concrete".  Concrete means that it's possible to
+    // represent the value as an llvm::Value*; usable means that we are allowed to use it as a variable's
+    // type.  Some concrete types are not usable; for example unboxed ints are concrete (can be represented
+    // as an i64) but are not usable, since we need to use the form that remembers what it gets boxed to.
+    virtual CompilerType* getUsableType() { return this; }
+    bool isUsable() { return this == getUsableType(); }
 };
 
 typedef std::unordered_map<CompilerVariable*, CompilerVariable*> DupCache;
@@ -94,7 +101,7 @@ public:
         printf("grab not defined for %s\n", debugName().c_str());
         abort();
     }
-    bool canConvertTo(ConcreteCompilerType* other_type) override {
+    bool canConvertTo(CompilerType* other_type) override {
         printf("canConvertTo not defined for %s\n", debugName().c_str());
         abort();
     }
@@ -102,13 +109,12 @@ public:
         printf("makeConverted not defined for %s\n", debugName().c_str());
         abort();
     }
-    virtual ConcreteCompilerVariable* nonzero(IREmitter& emitter, const OpInfo& info, VAR* var) {
+    virtual CompilerVariable* nonzero(IREmitter& emitter, const OpInfo& info, VAR* var) {
         printf("nonzero not defined for %s\n", debugName().c_str());
         abort();
     }
-    virtual ConcreteCompilerVariable* unaryop(IREmitter& emitter, const OpInfo& info, VAR* var,
-                                              AST_TYPE::AST_TYPE op_type);
-    virtual ConcreteCompilerVariable* hasnext(IREmitter& emitter, const OpInfo& info, VAR* var) {
+    virtual CompilerVariable* unaryop(IREmitter& emitter, const OpInfo& info, VAR* var, AST_TYPE::AST_TYPE op_type);
+    virtual CompilerVariable* hasnext(IREmitter& emitter, const OpInfo& info, VAR* var) {
         printf("hasnext not defined for %s\n", debugName().c_str());
         abort();
     }
@@ -139,7 +145,7 @@ public:
         printf("call not defined for %s\n", debugName().c_str());
         abort();
     }
-    virtual ConcreteCompilerVariable* len(IREmitter& emitter, const OpInfo& info, VAR* var) {
+    virtual CompilerVariable* len(IREmitter& emitter, const OpInfo& info, VAR* var) {
         printf("len not defined for %s\n", debugName().c_str());
         abort();
     }
@@ -202,7 +208,7 @@ public:
 
     CompilerVariable* dup(ConcreteCompilerVariable* v, DupCache& cache) override;
     ConcreteCompilerType* getConcreteType() override { return this; }
-    bool canConvertTo(ConcreteCompilerType* other_type) override { return other_type == this || other_type == UNKNOWN; }
+    bool canConvertTo(CompilerType* other_type) override { return other_type == this || other_type == UNKNOWN; }
     ConcreteCompilerVariable* makeConverted(IREmitter& emitter, ConcreteCompilerVariable* var,
                                             ConcreteCompilerType* other_type) override;
     void serializeToFrame(VAR* var, std::vector<llvm::Value*>& stackmap_args) override;
@@ -261,14 +267,14 @@ public:
     virtual CompilerType* getType() = 0;
     virtual ConcreteCompilerType* getConcreteType() = 0;
     virtual ConcreteCompilerType* getBoxType() = 0;
-    virtual bool canConvertTo(ConcreteCompilerType* other_type) = 0;
+    virtual bool canConvertTo(CompilerType* other_type) = 0;
     virtual ConcreteCompilerVariable* makeConverted(IREmitter& emitter, ConcreteCompilerType* other_type) = 0;
     virtual llvm::Value* makeClassCheck(IREmitter& emitter, BoxedClass* cls) = 0;
     virtual BoxedClass* guaranteedClass() = 0;
 
-    virtual ConcreteCompilerVariable* nonzero(IREmitter& emitter, const OpInfo& info) = 0;
-    virtual ConcreteCompilerVariable* unaryop(IREmitter& emitter, const OpInfo& info, AST_TYPE::AST_TYPE op_type) = 0;
-    virtual ConcreteCompilerVariable* hasnext(IREmitter& emitter, const OpInfo& info) = 0;
+    virtual CompilerVariable* nonzero(IREmitter& emitter, const OpInfo& info) = 0;
+    virtual CompilerVariable* unaryop(IREmitter& emitter, const OpInfo& info, AST_TYPE::AST_TYPE op_type) = 0;
+    virtual CompilerVariable* hasnext(IREmitter& emitter, const OpInfo& info) = 0;
     virtual CompilerVariable* getattr(IREmitter& emitter, const OpInfo& info, BoxedString* attr, bool cls_only) = 0;
     virtual void setattr(IREmitter& emitter, const OpInfo& info, BoxedString* attr, CompilerVariable* v) = 0;
     virtual void delattr(IREmitter& emitter, const OpInfo& info, BoxedString* attr) = 0;
@@ -278,7 +284,7 @@ public:
     virtual CompilerVariable* call(IREmitter& emitter, const OpInfo& info, struct ArgPassSpec argspec,
                                    const std::vector<CompilerVariable*>& args,
                                    const std::vector<BoxedString*>* keyword_names) = 0;
-    virtual ConcreteCompilerVariable* len(IREmitter& emitter, const OpInfo& info) = 0;
+    virtual CompilerVariable* len(IREmitter& emitter, const OpInfo& info) = 0;
     virtual CompilerVariable* getitem(IREmitter& emitter, const OpInfo& info, CompilerVariable*) = 0;
     virtual CompilerVariable* getPystonIter(IREmitter& emitter, const OpInfo& info) = 0;
     virtual CompilerVariable* binexp(IREmitter& emitter, const OpInfo& info, CompilerVariable* rhs,
@@ -330,19 +336,19 @@ public:
         return rtn;
     }
 
-    bool canConvertTo(ConcreteCompilerType* other_type) override { return type->canConvertTo(other_type); }
+    bool canConvertTo(CompilerType* other_type) override { return type->canConvertTo(other_type); }
     ConcreteCompilerVariable* makeConverted(IREmitter& emitter, ConcreteCompilerType* other_type) override {
         ConcreteCompilerVariable* rtn = type->makeConverted(emitter, this, other_type);
         ASSERT(rtn->getType() == other_type, "%s", type->debugName().c_str());
         return rtn;
     }
-    ConcreteCompilerVariable* nonzero(IREmitter& emitter, const OpInfo& info) override {
+    CompilerVariable* nonzero(IREmitter& emitter, const OpInfo& info) override {
         return type->nonzero(emitter, info, this);
     }
-    ConcreteCompilerVariable* unaryop(IREmitter& emitter, const OpInfo& info, AST_TYPE::AST_TYPE op_type) override {
+    CompilerVariable* unaryop(IREmitter& emitter, const OpInfo& info, AST_TYPE::AST_TYPE op_type) override {
         return type->unaryop(emitter, info, this, op_type);
     }
-    ConcreteCompilerVariable* hasnext(IREmitter& emitter, const OpInfo& info) override {
+    CompilerVariable* hasnext(IREmitter& emitter, const OpInfo& info) override {
         return type->hasnext(emitter, info, this);
     }
     CompilerVariable* getattr(IREmitter& emitter, const OpInfo& info, BoxedString* attr, bool cls_only) override {
@@ -366,9 +372,7 @@ public:
                            const std::vector<BoxedString*>* keyword_names) override {
         return type->call(emitter, info, this, argspec, args, keyword_names);
     }
-    ConcreteCompilerVariable* len(IREmitter& emitter, const OpInfo& info) override {
-        return type->len(emitter, info, this);
-    }
+    CompilerVariable* len(IREmitter& emitter, const OpInfo& info) override { return type->len(emitter, info, this); }
     CompilerVariable* getitem(IREmitter& emitter, const OpInfo& info, CompilerVariable* slice) override {
         return type->getitem(emitter, info, this, slice);
     }
@@ -407,8 +411,14 @@ public:
 // Emit the test for whether one variable 'is' another one.
 ConcreteCompilerVariable* doIs(IREmitter& emitter, CompilerVariable* lhs, CompilerVariable* rhs, bool negate);
 
+// These functions all return an INT variable, from either an unboxed representation (makeInt) or
+// a boxed representation (makeUnboxedInt)
+CompilerVariable* makeInt(int64_t);
+CompilerVariable* makeInt(llvm::Value*);
+CompilerVariable* makeUnboxedInt(IREmitter&, ConcreteCompilerVariable*);
+CompilerVariable* makeUnboxedInt(IREmitter&, llvm::Value*);
+
 ConcreteCompilerVariable* makeBool(bool);
-ConcreteCompilerVariable* makeInt(int64_t);
 ConcreteCompilerVariable* makeFloat(double);
 ConcreteCompilerVariable* makeLong(Box*);
 ConcreteCompilerVariable* makePureImaginary(Box*);
@@ -447,8 +457,8 @@ CompilerVariable* _ValuedCompilerType<V>::contains(IREmitter& emitter, const OpI
 }
 
 template <typename V>
-ConcreteCompilerVariable* _ValuedCompilerType<V>::unaryop(IREmitter& emitter, const OpInfo& info, VAR* var,
-                                                          AST_TYPE::AST_TYPE op_type) {
+CompilerVariable* _ValuedCompilerType<V>::unaryop(IREmitter& emitter, const OpInfo& info, VAR* var,
+                                                  AST_TYPE::AST_TYPE op_type) {
     ConcreteCompilerVariable* converted = makeConverted(emitter, var, getBoxType());
     auto r = UNKNOWN->unaryop(emitter, info, converted, op_type);
     converted->decvref(emitter);

src/codegen/irgen/irgenerator.cpp

@@ -799,7 +799,7 @@ private:
                 assert(node->args.size() == 1);
                 CompilerVariable* obj = evalExpr(node->args[0], unw_info);
 
-                ConcreteCompilerVariable* rtn = obj->nonzero(emitter, getOpInfoForNode(node, unw_info));
+                CompilerVariable* rtn = obj->nonzero(emitter, getOpInfoForNode(node, unw_info));
                 obj->decvref(emitter);
                 return rtn;
             }
@@ -807,7 +807,7 @@ private:
                 assert(node->args.size() == 1);
                 CompilerVariable* obj = evalExpr(node->args[0], unw_info);
 
-                ConcreteCompilerVariable* rtn = obj->hasnext(emitter, getOpInfoForNode(node, unw_info));
+                CompilerVariable* rtn = obj->hasnext(emitter, getOpInfoForNode(node, unw_info));
                 obj->decvref(emitter);
                 return rtn;
             }
@@ -1348,18 +1348,18 @@ private:
         CompilerVariable* operand = evalExpr(node->operand, unw_info);
 
         if (node->op_type == AST_TYPE::Not) {
-            ConcreteCompilerVariable* rtn = operand->nonzero(emitter, getOpInfoForNode(node, unw_info));
+            CompilerVariable* rtn = operand->nonzero(emitter, getOpInfoForNode(node, unw_info));
             operand->decvref(emitter);
 
             assert(rtn->getType() == BOOL);
-            llvm::Value* v = i1FromBool(emitter, rtn);
+            llvm::Value* v = i1FromBool(emitter, static_cast<ConcreteCompilerVariable*>(rtn));
             assert(v->getType() == g.i1);
 
             llvm::Value* negated = emitter.getBuilder()->CreateNot(v);
             rtn->decvref(emitter);
             return boolFromI1(emitter, negated);
         } else {
-            ConcreteCompilerVariable* rtn = operand->unaryop(emitter, getOpInfoForNode(node, unw_info), node->op_type);
+            CompilerVariable* rtn = operand->unaryop(emitter, getOpInfoForNode(node, unw_info), node->op_type);
             operand->decvref(emitter);
             return rtn;
         }
@@ -1517,13 +1517,11 @@ private:
     }
 
     // Note: the behavior of this function must match type_analysis.cpp:unboxedType()
-    ConcreteCompilerVariable* unboxVar(ConcreteCompilerType* t, llvm::Value* v, bool grabbed) {
-#if ENABLE_UNBOXED_VALUES
+    CompilerVariable* unboxVar(ConcreteCompilerType* t, llvm::Value* v, bool grabbed) {
         if (t == BOXED_INT) {
-            llvm::Value* unboxed = emitter.getBuilder()->CreateCall(g.funcs.unboxInt, v);
-            ConcreteCompilerVariable* rtn = new ConcreteCompilerVariable(INT, unboxed, true);
-            return rtn;
+            return makeUnboxedInt(emitter, v);
         }
+#if ENABLE_UNBOXED_VALUES
         if (t == BOXED_FLOAT) {
             llvm::Value* unboxed = emitter.getBuilder()->CreateCall(g.funcs.unboxFloat, v);
             ConcreteCompilerVariable* rtn = new ConcreteCompilerVariable(FLOAT, unboxed, true);
@@ -1548,7 +1546,7 @@ private:
 
             ConcreteCompilerType* speculated_type = typeFromClass(speculated_class);
             if (VERBOSITY("irgen") >= 2) {
-                printf("Speculating that %s is actually %s, at ", rtn->getConcreteType()->debugName().c_str(),
+                printf("Speculating that %s is actually %s, at ", rtn->getType()->debugName().c_str(),
                        speculated_type->debugName().c_str());
                 fflush(stdout);
                 print_ast(node);
@@ -1580,6 +1578,7 @@ private:
         }
 
         assert(rtn);
+        assert(rtn->getType()->isUsable());
 
         return rtn;
     }
@@ -1728,6 +1727,7 @@ private:
     void _doSet(InternedString name, CompilerVariable* val, const UnwindInfo& unw_info) {
         assert(name.s() != "None");
         assert(name.s() != FRAME_INFO_PTR_NAME);
+        assert(val->getType()->isUsable());
 
         auto scope_info = irstate->getScopeInfo();
         ScopeInfo::VarScopeType vst = scope_info->getScopeTypeOfName(name);
@@ -2210,8 +2210,8 @@ private:
             ConcreteCompilerVariable* var = p.second->makeConverted(emitter, p.second->getConcreteType());
             converted_args.push_back(var);
 
+            assert(var->getType() != BOXED_INT);
 #if ENABLE_UNBOXED_VALUES
-            assert(var->getType() != BOXED_INT && "should probably unbox it, but why is it boxed in the first place?");
             assert(var->getType() != BOXED_FLOAT
                    && "should probably unbox it, but why is it boxed in the first place?");
 #endif
@@ -2438,13 +2438,13 @@ private:
 
     void loadArgument(InternedString name, ConcreteCompilerType* t, llvm::Value* v, const UnwindInfo& unw_info) {
         assert(name.s() != FRAME_INFO_PTR_NAME);
-        ConcreteCompilerVariable* var = unboxVar(t, v, false);
+        CompilerVariable* var = unboxVar(t, v, false);
         _doSet(name, var, unw_info);
         var->decvref(emitter);
     }
 
     void loadArgument(AST_expr* name, ConcreteCompilerType* t, llvm::Value* v, const UnwindInfo& unw_info) {
-        ConcreteCompilerVariable* var = unboxVar(t, v, false);
+        CompilerVariable* var = unboxVar(t, v, false);
         _doSet(name, var, unw_info);
         var->decvref(emitter);
     }
@@ -2467,6 +2467,7 @@ private:
         std::map<InternedString, CompilerVariable*> sorted_symbol_table(symbol_table.begin(), symbol_table.end());
         for (const auto& p : sorted_symbol_table) {
             assert(p.first.s() != FRAME_INFO_PTR_NAME);
+            assert(p.second->getType()->isUsable());
             if (allowableFakeEndingSymbol(p.first))
                 continue;
 
@@ -2483,6 +2484,7 @@ private:
             } else if (irstate->getPhis()->isRequiredAfter(p.first, myblock)) {
                 assert(scope_info->getScopeTypeOfName(p.first) != ScopeInfo::VarScopeType::GLOBAL);
                 ConcreteCompilerType* phi_type = types->getTypeAtBlockEnd(p.first, myblock);
+                assert(phi_type->isUsable());
                 // printf("Converting %s from %s to %s\n", p.first.c_str(),
                 // p.second->getType()->debugName().c_str(), phi_type->debugName().c_str());
                 // printf("have to convert %s from %s to %s\n", p.first.c_str(),
@@ -2533,6 +2535,7 @@ private:
             } else {
                 // printf("no st entry, setting undefined\n");
                 ConcreteCompilerType* phi_type = types->getTypeAtBlockEnd(*it, myblock);
+                assert(phi_type->isUsable());
                 cur = new ConcreteCompilerVariable(phi_type, llvm::UndefValue::get(phi_type->llvmType()), true);
                 _setFake(defined_name, makeBool(0));
             }
@@ -2553,7 +2556,7 @@ public:
             pp->addFrameVar(PASSED_GLOBALS_NAME, UNKNOWN);
         }
 
-        assert(INT->llvmType() == g.i64);
+        assert(UNBOXED_INT->llvmType() == g.i64);
         if (ENABLE_JIT_OBJECT_CACHE) {
             llvm::Value* v;
             if (current_stmt)
@@ -2565,7 +2568,7 @@ public:
             stackmap_args.push_back(getConstantInt((uint64_t)current_stmt, g.i64));
         }
 
-        pp->addFrameVar("!current_stmt", INT);
+        pp->addFrameVar("!current_stmt", UNBOXED_INT);
 
         if (ENABLE_FRAME_INTROSPECTION) {
             // TODO: don't need to use a sorted symbol table if we're explicitly recording the names!
@@ -2600,6 +2603,10 @@ public:
         // This should have been consumed:
         assert(incoming_exc_state.empty());
 
+        for (auto&& p : symbol_table) {
+            ASSERT(p.second->getType()->isUsable(), "%s", p.first.c_str());
+        }
+
         if (myblock->successors.size() == 0) {
             for (auto& p : *st) {
                 p.second->decvref(emitter);
@@ -2645,6 +2652,7 @@ public:
                 } else {
                     ending_type = types->getTypeAtBlockEnd(it->first, myblock);
                 }
+                assert(ending_type->isUsable());
                 //(*phi_st)[it->first] = it->second->makeConverted(emitter, it->second->getConcreteType());
                 // printf("%s %p %d\n", it->first.c_str(), it->second, it->second->getVrefs());
                 (*phi_st)[it->first] = it->second->split(emitter)->makeConverted(emitter, ending_type);
@@ -2661,8 +2669,10 @@ public:
         assert(name.s() != FRAME_INFO_PTR_NAME);
         ASSERT(irstate->getScopeInfo()->getScopeTypeOfName(name) != ScopeInfo::VarScopeType::GLOBAL, "%s",
                name.c_str());
+
+        ASSERT(var->getType()->isUsable(), "%s", name.c_str());
+
 #if ENABLE_UNBOXED_VALUES
-        assert(var->getType() != BOXED_INT);
         assert(var->getType() != BOXED_FLOAT);
 #endif
         CompilerVariable*& cur = symbol_table[name];
@@ -2675,7 +2685,9 @@ public:
         DupCache cache;
         for (SymbolTable::iterator it = st->begin(); it != st->end(); ++it) {
             // printf("Copying in %s: %p, %d\n", it->first.c_str(), it->second, it->second->getVrefs());
+            // printf("Copying in %s, a %s\n", it->first.c_str(), it->second->getType()->debugName().c_str());
             symbol_table[it->first] = it->second->dup(cache);
+            assert(symbol_table[it->first]->getType()->isUsable());
             // printf("got: %p, %d\n", symbol_table[it->first], symbol_table[it->first]->getVrefs());
         }
     }

src/core/types.h

@@ -93,10 +93,10 @@ template <class V> class ValuedCompilerType;
 typedef ValuedCompilerType<llvm::Value*> ConcreteCompilerType;
 ConcreteCompilerType* typeFromClass(BoxedClass*);
 
-extern ConcreteCompilerType* INT, *BOXED_INT, *LONG, *FLOAT, *BOXED_FLOAT, *UNKNOWN, *BOOL, *STR, *NONE, *LIST, *SLICE,*ELLIPSIS,
-    *MODULE, *DICT, *BOOL, *BOXED_BOOL, *BOXED_TUPLE, *SET, *FROZENSET, *CLOSURE, *GENERATOR, *BOXED_COMPLEX,
-    *FRAME_INFO;
-extern CompilerType* UNDEF;
+extern ConcreteCompilerType* UNBOXED_INT, *BOXED_INT, *LONG, *FLOAT, *BOXED_FLOAT, *UNKNOWN, *BOOL, *STR, *NONE, *LIST,
+    *SLICE, *ELLIPSIS, *MODULE, *DICT, *BOOL, *BOXED_BOOL, *BOXED_TUPLE, *SET, *FROZENSET, *CLOSURE, *GENERATOR,
+    *BOXED_COMPLEX, *FRAME_INFO;
+extern CompilerType* UNDEF, *INT;
 
 class CompilerVariable;
 template <class V> class ValuedCompilerVariable;

src/runtime/inline/xrange.cpp

@@ -270,7 +270,7 @@ void setupXrange() {
         "__iter__", new BoxedFunction(boxRTFunction((void*)xrangeIterIter, typeFromClass(xrange_iterator_cls), 1)));
     xrange_iterator_cls->giveAttr("__hasnext__", new BoxedFunction(hasnext));
 
-    CLFunction* next = boxRTFunction((void*)BoxedXrangeIterator::xrangeIteratorNextUnboxed, INT, 1);
+    CLFunction* next = boxRTFunction((void*)BoxedXrangeIterator::xrangeIteratorNextUnboxed, UNBOXED_INT, 1);
     addRTFunction(next, (void*)BoxedXrangeIterator::xrangeIteratorNext, BOXED_INT);
     xrange_iterator_cls->giveAttr("next", new BoxedFunction(next));