qirrunner 0.8.3

JIT compiles and executes programs written in QIR (Quantum Intermediate Representation).

QIR Runner

This project implements a basic QIR runtime and execution tool. Once installed, qir-runner will be available via the command line in your python environment as well as the qirrunner module which can be imported into a Python program.

Usage

Command line

Usage: qir-runner [OPTIONS] --file <PATH>

Options:
  -f, --file <PATH>        (Required) Path to the QIR file to run
  -e, --entrypoint <NAME>  Name of the entry point function to execute
  -s, --shots <NUM>        The number of times to repeat the execution of the chosen entry point in the program [default: 1]
  -r, --rngseed <NUM>      The value to use when seeding the random number generator used for quantum simulation
  -h, --help               Print help
  -V, --version            Print version

Python module

From a Python program, qirrunner provides a run function and two output helpers Output and OutputHandler. If the output_fn parameter of run is not specified, output will be written to stdout. Supplying the parameter allows the output of the execution to be captured.

from qirrunner import run, OutputHandler

path = "./runner/tests/resources/bv.bc"

handler = OutputHandler()
run(path, shots=2, output_fn=handler.handle)

print(handler.get_output())

Installation

pip install qirrunner

Installing from sdist

Platforms for which qirrunner doesn't have pre-built wheels (such as aarch64 macos), installation is available via sdist. Before installing qirrunner via pip:

• Install a usable LLVM distribution which has llvm-config available.
• Set the LLVM_SYS_140_PREFIX environment variable to the LLVM installation directory
  • example: export LLVM_SYS_140_PREFIX=/Users/sample/llvm
• Install: python -m pip install qirrunner
  • This will build qirrunner from source. You will need a working Rust installation in order for this to compile.

Implemented APIs

double @__quantum__qis__arccos__body(double)
double @__quantum__qis__arcsin__body(double)
double @__quantum__qis__arctan__body(double)
double @__quantum__qis__arctan2__body(double)
void @__quantum__qis__assertmeasurementprobability__body(%Array*, %Array*, %Result*, double, %String*, double)
void @__quantum__qis__assertmeasurementprobability__ctl(%Array*, %Tuple*)
void @__quantum__qis__barrier__body()
void @__quantum__qis__ccx__body(%Qubit*, %Qubit*)
void @__quantum__qis__cnot__body(%Qubit*, %Qubit*)
double @__quantum__qis__cos__body(double)
double @__quantum__qis__cosh__body(double)
void @__quantum__qis__cx__body(%Qubit*, %Qubit*)
void @__quantum__qis__cy__body(%Qubit*, %Qubit*)
void @__quantum__qis__cz__body(%Qubit*, %Qubit*)
double @__quantum__qis__drawrandomdouble__body()
i64 @__quantum__qis__drawrandomint__body()
void @__quantum__qis__dumpmachine__body()
void @__quantum__qis__exp__adj(%Array*, double, %Array*)
void @__quantum__qis__exp__body(%Array*, double, %Array*)
void @__quantum__qis__exp__ctl(%Array*, %Tuple*)
void @__quantum__qis__exp__ctladj(%Array*, %Tuple*)
void @__quantum__qis__exp__ctl(%Array*, %Tuple*)
void @__quantum__qis__h__body(%Qubit*)
void @__quantum__qis__h__ctl(%Array*, %Qubit*)
double @__quantum__qis__ieeeremainder__body(double, double)
double @__quantum__qis__infinity__body()
i1 @__quantum__qis__isinf__body()
i1 @__quantum__qis__isnan__body()
i1 @__quantum__qis__isnegativeinfinity__body()
double @__quantum__qis__log__body(double)
%Result* @__quantum__qis__m__body(%Qubit*)
%Result* @__quantum__qis__measure__body(%Array*, %Array*)
%Result* @__quantum__qis__mresetz__body(%Qubit*)
void @__quantum__qis__mz__body(%Qubit*, %Result*)
double @__quantum__qis__nan__body()
void @__quantum__qis__r__adj(i2, double, %Qubit*)
void @__quantum__qis__r__body(i2, double, %Qubit*)
void @__quantum__qis__r__ctl(%Array*, %Tuple*)
void @__quantum__qis__r__ctladj(%Array*, %Tuple*)
bool @__quantum__qis__read_result__body(%Result*)
void @__quantum__qis__reset__body(%Qubit*)
void @__quantum__qis__rx__body(double, %Qubit*)
void @__quantum__qis__rx__ctl(%Array*, %Tuple*)
void @__quantum__qis__rxx__body(double, %Qubit*, %Qubit*)
void @__quantum__qis__ry__body(double, %Qubit*)
void @__quantum__qis__ry__ctl(%Array*, %Tuple*)
void @__quantum__qis__ryy__body(double, %Qubit*, %Qubit*)
void @__quantum__qis__rz__body(double, %Qubit*)
void @__quantum__qis__rz__ctl(%Array*, %Tuple*)
void @__quantum__qis__rzz__body(double, %Qubit*, %Qubit*)
void @__quantum__qis__s__adj(%Qubit*)
void @__quantum__qis__s__body(%Qubit*)
void @__quantum__qis__s__ctl(%Array*, %Qubit*)
void @__quantum__qis__s__ctladj(%Array*, %Qubit*)
void @__quantum__qis__sx__body(%Qubit*)
double @__quantum__qis__sin__body(double)
double @__quantum__qis__sinh__body(double)
double @__quantum__qis__sqrt__body(double)
void @__quantum__qis__swap__body(%Qubit*, %Qubit*)
void @__quantum__qis__t__adj(%Qubit*)
void @__quantum__qis__t__body(%Qubit*)
void @__quantum__qis__t__ctl(%Array*, %Qubit*)
void @__quantum__qis__t__ctladj(%Array*, %Qubit*)
double @__quantum__qis__tan__body(double)
double @__quantum__qis__tanh__body(double)
void @__quantum__qis__x__body(%Qubit*)
void @__quantum__qis__x__ctl(%Array*, %Qubit*)
void @__quantum__qis__y__body(%Qubit*)
void @__quantum__qis__y__ctl(%Array*, %Qubit*)
void @__quantum__qis__z__body(%Qubit*)
void @__quantum__qis__z__ctl(%Array*, %Qubit*)
%Array* @__quantum__rt__array_concatenate(%Array*, %Array*)
%Array* @__quantum__rt__array_copy(%Array*, bool)
%Array* @__quantum__rt__array_create_1d(i32, i64)
i8* @__quantum__rt__array_get_element_ptr_1d(%Array*, i64)
i64 @__quantum__rt__array_get_size_1d(%Array*)
void @__quantum__rt__array_record_output(i64, i8*)
void @__quantum__rt__array_update_alias_count(%Array*, i32)
void @__quantum__rt__array_update_reference_count(%Array*, i32)
%BigInt* @__quantum__rt__bigint_add(%BigInt*, %BigInt*)
%BigInt* @__quantum__rt__bigint_bitand(%BigInt*, %BigInt*)
%BigInt* @__quantum__rt__bigint_bitnot(%BigInt*)
%BigInt* @__quantum__rt__bigint_bitor(%BigInt*, %BigInt*)
%BigInt* @__quantum__rt__bigint_bitxor(%BigInt*, %BigInt*)
%BigInt* @__quantum__rt__bigint_create_array(i32, i8*)
%BigInt* @__quantum__rt__bigint_create_i64(i64)
%BigInt* @__quantum__rt__bigint_divide(%BigInt*, %BigInt*)
bool @__quantum__rt__bigint_equal(%BigInt*, %BigInt*)
i8* @__quantum__rt__bigint_get_data(%BigInt*)
i32 @__quantum__rt__bigint_get_length(%BigInt*)
bool @__quantum__rt__bigint_greater(%BigInt*, %BigInt*)
bool @__quantum__rt__bigint_greater_eq(%BigInt*, %BigInt*)
%BigInt* @__quantum__rt__bigint_modulus(%BigInt*, %BigInt*)
%BigInt* @__quantum__rt__bigint_multiply(%BigInt*, %BigInt*)
%BigInt* @__quantum__rt__bigint_negate(%BigInt*)
%BigInt* @__quantum__rt__bigint_power(%BigInt*, i32)
%BigInt* @__quantum__rt__bigint_shiftleft(%BigInt*, i64)
%BigInt*@__quantum__rt__bigint_shiftright(%BigInt*, i64)
void @__quantum__rt__bigint_subtract(%BigInt*, %BigInt*)
%String* @__quantum__rt__bigint_to_string(%BigInt*)
void @__quantum__rt__bigint_update_reference_count(%BigInt*, i32)
void @__quantum__rt__bool_record_output(i1, i8*)
%String* @__quantum__rt__bool_to_string(i1)
%Callable* @__quantum__rt__callable_copy(%Callable*, bool)
%Callable* @__quantum__rt__callable_create([4 x void(%Tuple*, %Tuple*, %Tuple*)*]*, [2 x void (%Tuple*, i32)]*, %Tuple*)
void @__quantum__rt__callable_invoke(%Callable*, %Tuple*, %Tuple*)
void @__quantum__rt__callable_make_adjoint(%Callable*)
void @__quantum__rt__callable_make_controlled(%Callable*)
void @__quantum__rt__callable_update_alias_count(%Callable*, i32)
void @__quantum__rt__callable_update_reference_count(%Callable*, i32)
void @__quantum__rt__capture_update_alias_count(%Callable*, i32)
void @__quantum__rt__capture_update_reference_count(%Callable*, i32)
void @__quantum__rt__double_record_output(double, i8*)
%String* @__quantum__rt__double_to_string(double)
void @__quantum__rt__fail(%String*)
void @__quantum__rt__int_record_output(i64, i8*)
%String* @__quantum__rt__int_to_string(i64)
i8* @__quantum__rt__memory_allocate(i64)
void @__quantum__rt__message(%String*)
void @__quantum__rt__message_record_output(%String*)
%String* @__quantum__rt__pauli_to_string(i2)
%Qubit* @__quantum__rt__qubit_allocate()
%Array* @__quantum__rt__qubit_allocate_array(i64)
void @__quantum__rt__qubit_release(%Qubit*)
void @__quantum__rt__qubit_release_array(%Array*)
%String* @__quantum__rt__qubit_to_string(%Qubit*)
bool @__quantum__rt__read_result(%Result*)
bool @__quantum__rt__result_equal(%Result*, %Result*)
%Result* @__quantum__rt__result_get_one()
%Result* @__quantum__rt__result_get_zero()
void @__quantum__rt__result_record_output(%Result*, i8*)
%String* @__quantum__rt__result_to_string(%Result*)
void @__quantum__rt__result_update_reference_count(%Result*, i32)
%String* @__quantum__rt__string_concatenate(%String*, %String*)
%String* @__quantum__rt__string_create(i8*)
bool @__quantum__rt__string_equal(%String*, %String*)
i8* @__quantum__rt__string_get_data(%String*)
i32 @__quantum__rt__string_get_length(%String*)
void @__quantum__rt__string_update_reference_count(%String*, i32)
%Tuple* @__quantum__rt__tuple_copy(%Tuple*, i1)
%Tuple* @__quantum__rt__tuple_create(i64)
void @__quantum__rt__tuple_record_output(i64, i8*)
void @__quantum__rt__tuple_update_alias_count(%Tuple*, i32)
void @__quantum__rt__tuple_update_reference_count(%Tuple*, i32)