Stack machine

In computer science, computer engineering and programming language implementations, a stack machine is a computer processor or a virtual machine in which the primary interaction is moving short-lived temporary values to and from a push down stack. In the case of a hardware processor, a hardware stack is used. The use of a stack significantly reduces the required number of processor registers. Stack machines extend push-down automata with additional load/store operations or multiple stacks and hence are Turing-complete. Most or all stack machine instructions assume that operands will be from the stack, and results placed in the stack. The stack easily holds more than two inputs or more than one result, so a rich set of operations can be computed. In stack machine code (sometimes called p-code), instructions will frequently have only an opcode commanding an operation, with no additional fields identifying a constant, register or memory cell, known as a zero address format. This greatly simplifies instruction decoding. Branches, load immediates, and load/store instructions require an argument field, but stack machines often arrange that the frequent cases of these still fit together with the opcode into a compact group of bits. The selection of operands from prior results is done implicitly by ordering the instructions. Some stack machine instruction sets are intended for interpretive execution of a virtual machine, rather than driving hardware directly. Integer constant operands are pushed by or instructions. Memory is often accessed by separate or instructions containing a memory address or calculating the address from values in the stack. All practical stack machines have variants of the load–store opcodes for accessing local variables and formal parameters without explicit address calculations. This can be by offsets from the current top-of-stack address, or by offsets from a stable frame-base register. The instruction set carries out most ALU actions with postfix (reverse Polish notation) operations that work only on the expression stack, not on data registers or main memory cells.

Rising from rubble - Leveraging existing construction tools for upcycling concrete waste into slender walls

WarpAttack: Bypassing CFI through Compiler-Introduced Double-Fetches

Local electrochemical and thermal investigation of a segmented reversible solid oxide fuel cell and electrolyzer

Local electrochemical and thermal investigation of a segmented reversible solid oxide fuel cell and electrolyzer

WarpAttack: Bypassing CFI through Compiler-Introduced Double-Fetches

Rising from rubble - Leveraging existing construction tools for upcycling concrete waste into slender walls