Quil (instruction set architecture)


Quil is a quantum instruction set architecture that first introduced a shared quantum/classical memory model. It was introduced by Robert Smith, Michael Curtis, and William Zeng in A Practical Quantum Instruction Set Architecture. Many quantum algorithms require a shared memory architecture. Quil is being developed for the superconducting quantum processors developed by Rigetti Computing through the Forest quantum programming API. A Python library called pyQuil was introduced to develop Quil programs with higher level constructs. A Quil backend is also supported by other quantum programming environments.

Underlying quantum abstract machine

In the paper presented by Smith, Curtis and Zeng, Quil specifies the instruction set for a Quantum Abstract Machine akin to a Turing machine, yet more practical for accomplishing "real-world" tasks. The state of the QAM can be represented as a 6-tuple where:
The semantics of the QAM are defined using tensor products of Hilbert spaces and the linear maps between them.

Features

Quil has support for defining possibly parametrized gates in matrix form and their application on qubits. The language also supports macro-like definitions of possibly parametrized quantum circuits and their expansion, qubit measurement and recording of the outcome in classical memory, synchronization with classical computers with the WAIT instruction which pauses the execution of a Quil program until a classical program has ended its execution, conditional and unconditional branching, pragma support, as well as inclusion of files for use as libraries

Rigetti QVM

Rigetti Computing developed a Quantum Virtual Machine in Common Lisp that simulates the defined Quantum Abstract Machine on a classical computer and is capable of the parsing and execution of Quil programs with possibly remote execution via HTTP.

Example

The following example demonstrates the classical control flow needed to do quantum teleportation of the qubit in register 2 to register 1:

  1. Declare classical memory
DECLARE ro BIT
  1. Create Bell Pair
H 0
CNOT 0 1
  1. Teleport
CNOT 2 0
H 2
MEASURE 2 ro
MEASURE 0 ro
  1. Classically communicate measurements
JUMP-UNLESS @SKIP ro
X 1
LABEL @SKIP
JUMP-UNLESS @END ro
Z 1
LABEL @END
Examples of the implementations of the quantum fourier transform and the variational quantum Eigensolver are given in the paper.