Exemplo n.º 1
0
static ast_t* find_embed_constructor_receiver(ast_t* call)
{
  call_tuple_indices_t tuple_indices = {NULL, 0, 4};
  tuple_indices_init(&tuple_indices);

  ast_t* parent = make_tuple_indices(&tuple_indices, call);
  ast_t* fieldref = NULL;

  if((parent != NULL) && (ast_id(parent) == TK_ASSIGN))
  {
    // Traverse the LHS of the assignment looking for what our constructor call
    // is assigned to.
    ast_t* current = ast_child(parent);
    while((ast_id(current) == TK_TUPLE) || (ast_id(current) == TK_SEQ))
    {
      parent = current;
      if(ast_id(current) == TK_TUPLE)
      {
        // If there are no indices left, we're destructuring a tuple.
        // Errors in those cases have already been catched by the expr
        // pass.
        if(tuple_indices.count == 0)
          break;

        size_t index = tuple_indices_pop(&tuple_indices);
        current = ast_childidx(parent, index);
      } else {
        current = ast_childlast(parent);
      }
    }

    if(ast_id(current) == TK_EMBEDREF)
      fieldref = current;
  }

  tuple_indices_destroy(&tuple_indices);
  return fieldref;
}
Exemplo n.º 2
0
LLVMValueRef gen_call(compile_t* c, ast_t* ast)
{
  // Special case calls.
  LLVMValueRef special;

  if(special_case_call(c, ast, &special))
    return special;

  AST_GET_CHILDREN(ast, positional, named, postfix);
  AST_GET_CHILDREN(postfix, receiver, method);
  ast_t* typeargs = NULL;

  // Dig through function qualification.
  switch(ast_id(receiver))
  {
    case TK_NEWREF:
    case TK_NEWBEREF:
    case TK_BEREF:
    case TK_FUNREF:
    case TK_BECHAIN:
    case TK_FUNCHAIN:
      typeargs = method;
      AST_GET_CHILDREN_NO_DECL(receiver, receiver, method);
      break;

    default: {}
  }

  // Get the receiver type.
  const char* method_name = ast_name(method);
  ast_t* type = ast_type(receiver);
  reach_type_t* t = reach_type(c->reach, type);
  pony_assert(t != NULL);

  // Generate the arguments.
  size_t count = ast_childcount(positional) + 1;
  size_t buf_size = count * sizeof(void*);

  LLVMValueRef* args = (LLVMValueRef*)ponyint_pool_alloc_size(buf_size);
  ast_t* arg = ast_child(positional);
  int i = 1;

  while(arg != NULL)
  {
    LLVMValueRef value = gen_expr(c, arg);

    if(value == NULL)
    {
      ponyint_pool_free_size(buf_size, args);
      return NULL;
    }

    args[i] = value;
    arg = ast_sibling(arg);
    i++;
  }

  bool is_new_call = false;

  // Generate the receiver. Must be done after the arguments because the args
  // could change things in the receiver expression that must be accounted for.
  if(call_needs_receiver(postfix, t))
  {
    switch(ast_id(postfix))
    {
      case TK_NEWREF:
      case TK_NEWBEREF:
      {
        call_tuple_indices_t tuple_indices = {NULL, 0, 4};
        tuple_indices.data =
          (size_t*)ponyint_pool_alloc_size(4 * sizeof(size_t));

        ast_t* current = ast;
        ast_t* parent = ast_parent(current);
        while((parent != NULL) && (ast_id(parent) != TK_ASSIGN) &&
          (ast_id(parent) != TK_CALL))
        {
          if(ast_id(parent) == TK_TUPLE)
          {
            size_t index = 0;
            ast_t* child = ast_child(parent);
            while(current != child)
            {
              ++index;
              child = ast_sibling(child);
            }
            tuple_indices_push(&tuple_indices, index);
          }
          current = parent;
          parent = ast_parent(current);
        }

        // If we're constructing an embed field, pass a pointer to the field
        // as the receiver. Otherwise, allocate an object.
        if((parent != NULL) && (ast_id(parent) == TK_ASSIGN))
        {
          size_t index = 1;
          current = ast_childidx(parent, 1);
          while((ast_id(current) == TK_TUPLE) || (ast_id(current) == TK_SEQ))
          {
            parent = current;
            if(ast_id(current) == TK_TUPLE)
            {
              // If there are no indices left, we're destructuring a tuple.
              // Errors in those cases have already been catched by the expr
              // pass.
              if(tuple_indices.count == 0)
                break;
              index = tuple_indices_pop(&tuple_indices);
              current = ast_childidx(parent, index);
            } else {
              current = ast_childlast(parent);
            }
          }
          if(ast_id(current) == TK_EMBEDREF)
          {
            args[0] = gen_fieldptr(c, current);
            set_descriptor(c, t, args[0]);
          } else {
            args[0] = gencall_alloc(c, t);
          }
        } else {
          args[0] = gencall_alloc(c, t);
        }
        is_new_call = true;
        ponyint_pool_free_size(tuple_indices.alloc * sizeof(size_t),
          tuple_indices.data);
        break;
      }

      case TK_BEREF:
      case TK_FUNREF:
      case TK_BECHAIN:
      case TK_FUNCHAIN:
        args[0] = gen_expr(c, receiver);
        break;

      default:
        pony_assert(0);
        return NULL;
    }
  } else {
    // Use a null for the receiver type.
    args[0] = LLVMConstNull(t->use_type);
  }

  // Static or virtual dispatch.
  token_id cap = cap_dispatch(type);
  reach_method_t* m = reach_method(t, cap, method_name, typeargs);
  LLVMValueRef func = dispatch_function(c, t, m, args[0]);

  bool is_message = false;

  if((ast_id(postfix) == TK_NEWBEREF) || (ast_id(postfix) == TK_BEREF) ||
    (ast_id(postfix) == TK_BECHAIN))
  {
    switch(t->underlying)
    {
      case TK_ACTOR:
        is_message = true;
        break;

      case TK_UNIONTYPE:
      case TK_ISECTTYPE:
      case TK_INTERFACE:
      case TK_TRAIT:
        if(m->cap == TK_TAG)
          is_message = can_inline_message_send(t, m, method_name);
        break;

      default: {}
    }
  }

  // Cast the arguments to the parameter types.
  LLVMTypeRef f_type = LLVMGetElementType(LLVMTypeOf(func));
  LLVMTypeRef* params = (LLVMTypeRef*)ponyint_pool_alloc_size(buf_size);
  LLVMGetParamTypes(f_type, params);

  arg = ast_child(positional);
  i = 1;

  LLVMValueRef r = NULL;

  if(is_message)
  {
    // If we're sending a message, trace and send here instead of calling the
    // sender to trace the most specific types possible.
    LLVMValueRef* cast_args = (LLVMValueRef*)ponyint_pool_alloc_size(buf_size);
    cast_args[0] = args[0];
    while(arg != NULL)
    {
      cast_args[i] = gen_assign_cast(c, params[i], args[i], ast_type(arg));
      arg = ast_sibling(arg);
      i++;
    }

    token_id cap = cap_dispatch(type);
    reach_method_t* m = reach_method(t, cap, method_name, typeargs);

    codegen_debugloc(c, ast);
    gen_send_message(c, m, args, cast_args, positional);
    codegen_debugloc(c, NULL);
    switch(ast_id(postfix))
    {
      case TK_NEWREF:
      case TK_NEWBEREF:
        r = args[0];
        break;

      default:
        r = c->none_instance;
        break;
    }
    ponyint_pool_free_size(buf_size, cast_args);
  } else {
    while(arg != NULL)
    {
      args[i] = gen_assign_cast(c, params[i], args[i], ast_type(arg));
      arg = ast_sibling(arg);
      i++;
    }

    if(func != NULL)
    {
      // If we can error out and we have an invoke target, generate an invoke
      // instead of a call.
      codegen_debugloc(c, ast);

      if(ast_canerror(ast) && (c->frame->invoke_target != NULL))
        r = invoke_fun(c, func, args, i, "", true);
      else
        r = codegen_call(c, func, args, i);

      if(is_new_call)
      {
        LLVMValueRef md = LLVMMDNodeInContext(c->context, NULL, 0);
        LLVMSetMetadataStr(r, "pony.newcall", md);
      }

      codegen_debugloc(c, NULL);
    }
  }

  // Class constructors return void, expression result is the receiver.
  if(((ast_id(postfix) == TK_NEWREF) || (ast_id(postfix) == TK_NEWBEREF)) &&
     (t->underlying == TK_CLASS))
    r = args[0];

  // Chained methods forward their receiver.
  if((ast_id(postfix) == TK_BECHAIN) || (ast_id(postfix) == TK_FUNCHAIN))
    r = args[0];

  ponyint_pool_free_size(buf_size, args);
  ponyint_pool_free_size(buf_size, params);
  return r;
}