Abstract: A data processing system having a flexible internal structure, protected from and effectively invisible to users, with multilevel control and stack mechanisms and capability of performing multiple, concurrent operations, and providing a flexible, simplified interface to users. The system is internally comprised of a plurality of separate, independent processors, each having a separate microinstruction control and at least one separate, independent port to a central communications and memory node. The communications and memory node is an independent processor having separate, independent microinstruction control and comprised of a plurality of independently operating, microinstruction controlled processors capable of performing multiple, concurrent memory and communications operations. Addressing mechanisms allow permanent, unique identification of information and an extremely large address space accessible and common to all such systems. Addresses are independent of system physical configuration.

Abstract: A method for executing call and return instructions in a digital computer system operating under control of microcode. The microcode may specify calls to and returns from sequences of microinstructions. A call microinstruction sequence corresponds to the call instruction. The call microcode in turn calls other microinstruction sequences for deriving pointers representing the location of the called procedure and of arguments from operands in the call instruction. As the call microcode obtains each argument pointer, it places the pointer on the stack. After it has obtained all of the argument pointers, it passes the pointer to the called procedure and a pointer to the argument pointers to a general call microinstruction sequence. That microinstruction sequence locates the called procedure, makes a new frame including the argument pointers, and saves the state necessary to resume execution of the call microinstruction sequence itself.

Abstract: A data processing system having a flexible internal structure, protected from and effectively invisible to users, with multilevel control and stack mechanisms and capability of performing multiple, concurrent operations, and providing a flexible, simplified interface to users. The system is internally comprised of a plurality of separate, independent processors, each having a separate microinstruction control and at least one separate, independent port to a central communications and memory node. The communications and memory node is an independent processor having separate, independent microinstruction control and comprised of a plurality of independently operating, microinstruction controlled processors capable of performing multiple, concurrent memory and communications operations. Addressing mechanisms allow permanent, unique identification of information as objects and an extremely large address space accessible and common to all such systems.

Abstract: Systems and method for resolving unresolved pointers in digital computer systems. In unresolved pointers, addresses are represented by means of data items from which the addresses may be derived. The unresolved pointer is resolved when the represented address is derived from the data items. One such system includes the unresolved pointers and procedures for resolving the unresolved pointers in the digital computer system's memory and apparatus in the digital computer system's process which operates under control of pointer translation microcode to translate pointers into represented addreses and under control of call-return microcode for invoking procedures from microcode. The pointer translation microcode responds to an unresolved pointer by causing the call-return microcode to invoke the procedures for resolving the unresolved pointer. Using the data items in the unresolved pointer, the procedures derive the represented address and return it to the pointer translation microcode.

Abstract: The processor of the present invention executes procedures, which comprise S-language instructions and names. S-languages are of higher order than typical machine languages and can be tailored to user high-order languages. Each procedure includes a dialect code which the processor interprets, enabling it to execute any of a plurality of dialects of S-languages. The processor includes means for resolving names into operand logical addresses. The processor possosses multiple levels of microcode control means, each with its own set of stacks.

Abstract: A data processing system having a flexible internal structure, protected from and effectively invisible to users, with multilevel control and stack mechanisms and capability of performing multiple, concurrent operations, and providing a flexible, simplified interface to users. The system is internally comprised of a plurality of separate, independent processors, each having a separate microinstruction control and at least one separate, independent port to a central communications and memory node. The communications and memory node is an independent processor having separate, independent microinstruction control and comprised of a plurality of independently operating, microinstruction controlled processors capable of performing multiple, concurrent memory and communications operations. Addressing mechanisms allow permanent, unique indentification of information as objects and an extremely large address space accessible and common to all such systems.