static ArgDeclType BuildArgument(string name, ResolvedType t) { var validName = QsLocalSymbol.NewValidName(NonNullable <string> .New(name)); var info = new InferredExpressionInformation(false, false); return(new ArgDeclType(validName, t, info, QsNullable <Tuple <int, int> > .Null, EmptyRange)); }
static ArgDeclType BuildArgument(string name, ResolvedType t) { var validName = QsLocalSymbol.NewValidName(name); var info = new InferredExpressionInformation(false, false); return(new ArgDeclType(validName, t, info, QsNullable <Position> .Null, Range.Zero)); }
public void ParseOp() { ArgDeclType BuildArgument(string name, ResolvedType t) { var validName = QsLocalSymbol.NewValidName(NonNullable <string> .New(name)); var info = new InferredExpressionInformation(false, false); return(new ArgDeclType(validName, t, info, QsNullable <Tuple <int, int> > .Null, EmptyRange)); } string[] comments = { "# Summary", "Convenience function that performs state preparation by applying a ", "`statePrepUnitary` on the input state, followed by adiabatic state ", "preparation using a `adiabaticUnitary`, and finally phase estimation ", "with respect to `qpeUnitary`on the resulting state using a ", "`phaseEstAlgorithm`.", "", "# Input", "## statePrepUnitary", "An oracle representing state preparation for the initial dynamical", "generator.", "## adiabaticUnitary", "An oracle representing the adiabatic evolution algorithm to be used", "to implement the sweeps to the final state of the algorithm.", "## qpeUnitary", "An oracle representing a unitary operator $U$ representing evolution", "for time $\\delta t$ under a dynamical generator with ground state", "$\\ket{\\phi}$ and ground state energy $E = \\phi\\\\,\\delta t$.", "## phaseEstAlgorithm", "An operation that performs phase estimation on a given unitary operation.", "See [iterative phase estimation](/quantum/libraries/characterization#iterative-phase-estimation)", "for more details.", "## qubits", "A register of qubits to be used to perform the simulation.", "", "# Output", "An estimate $\\hat{\\phi}$ of the ground state energy $\\phi$", "of the generator represented by $U$." }; string expected = @"### YamlMime:QSharpType uid: microsoft.quantum.canon.adiabaticstateenergyunitary name: AdiabaticStateEnergyUnitary type: operation namespace: Microsoft.Quantum.Canon summary: |- Convenience function that performs state preparation by applying a `statePrepUnitary` on the input state, followed by adiabatic state preparation using a `adiabaticUnitary`, and finally phase estimation with respect to `qpeUnitary`on the resulting state using a `phaseEstAlgorithm`. syntax: 'operation AdiabaticStateEnergyUnitary (statePrepUnitary : (Qubit[] => Unit), adiabaticUnitary : (Qubit[] => Unit), qpeUnitary : (Qubit[] => Unit is Adj + Ctl), phaseEstAlgorithm : ((Microsoft.Quantum.Canon.DiscreteOracle, Qubit[]) => Double), qubits : Qubit[]) : Double' input: content: '(statePrepUnitary : (Qubit[] => Unit), adiabaticUnitary : (Qubit[] => Unit), qpeUnitary : (Qubit[] => Unit is Adj + Ctl), phaseEstAlgorithm : ((Microsoft.Quantum.Canon.DiscreteOracle, Qubit[]) => Double), qubits : Qubit[])' types: - name: statePrepUnitary summary: |- An oracle representing state preparation for the initial dynamical generator. isOperation: true input: types: - isArray: true isPrimitive: true uid: Qubit output: types: - isPrimitive: true uid: Unit - name: adiabaticUnitary summary: |- An oracle representing the adiabatic evolution algorithm to be used to implement the sweeps to the final state of the algorithm. isOperation: true input: types: - isArray: true isPrimitive: true uid: Qubit output: types: - isPrimitive: true uid: Unit - name: qpeUnitary summary: |- An oracle representing a unitary operator $U$ representing evolution for time $\delta t$ under a dynamical generator with ground state $\ket{\phi}$ and ground state energy $E = \phi\\,\delta t$. isOperation: true input: types: - isArray: true isPrimitive: true uid: Qubit output: types: - isPrimitive: true uid: Unit functors: - Adjoint - Controlled - name: phaseEstAlgorithm summary: |- An operation that performs phase estimation on a given unitary operation. See [iterative phase estimation](/quantum/libraries/characterization#iterative-phase-estimation) for more details. isOperation: true input: types: - uid: microsoft.quantum.canon.discreteoracle - isArray: true isPrimitive: true uid: Qubit output: types: - isPrimitive: true uid: Double - name: qubits summary: A register of qubits to be used to perform the simulation. isArray: true isPrimitive: true uid: Qubit output: content: Double types: - summary: |- An estimate $\hat{\phi}$ of the ground state energy $\phi$ of the generator represented by $U$. isPrimitive: true uid: Double ... "; var qubitArrayType = ResolvedType.New(QsType.NewArrayType(ResolvedType.New(QsType.Qubit))); var unitType = ResolvedType.New(QsType.UnitType); var doubleType = ResolvedType.New(QsType.Double); var oracleType = ResolvedType.New(QsType.NewUserDefinedType(new UserDefinedType(CanonName, NonNullable <string> .New("DiscreteOracle"), QsNullable <Tuple <QsPositionInfo, QsPositionInfo> > .Null))); var noInfo = CallableInformation.NoInformation; var acFunctors = ResolvedCharacteristics.FromProperties(new[] { OpProperty.Adjointable, OpProperty.Controllable }); var acInfo = new CallableInformation(acFunctors, InferredCallableInformation.NoInformation); var qubitToUnitOp = ResolvedType.New(QsType.NewOperation(new SigTypeTuple(qubitArrayType, unitType), noInfo)); var qubitToUnitOpAC = ResolvedType.New(QsType.NewOperation(new SigTypeTuple(qubitArrayType, unitType), acInfo)); var phaseEstArgs = new ResolvedType[] { oracleType, qubitArrayType }.ToImmutableArray(); var phaseEstArgTuple = ResolvedType.New(QsType.NewTupleType(phaseEstArgs)); var phaseEstOp = ResolvedType.New(QsType.NewOperation(new SigTypeTuple(phaseEstArgTuple, doubleType), noInfo)); var typeParams = new QsLocalSymbol[] { }.ToImmutableArray(); var argTypes = new ResolvedType[] { qubitToUnitOp, qubitToUnitOp, qubitToUnitOpAC, phaseEstOp, qubitArrayType }.ToImmutableArray(); var argTupleType = ResolvedType.New(QsType.NewTupleType(argTypes)); var signature = new ResolvedSignature(typeParams, argTupleType, doubleType, noInfo); var args = new List <ArgDeclType> { BuildArgument("statePrepUnitary", qubitToUnitOp), BuildArgument("adiabaticUnitary", qubitToUnitOp), BuildArgument("qpeUnitary", qubitToUnitOpAC), BuildArgument("phaseEstAlgorithm", phaseEstOp), BuildArgument("qubits", qubitArrayType) } .ConvertAll(arg => QsTuple <ArgDeclType> .NewQsTupleItem(arg)) .ToImmutableArray(); var argTuple = QsTuple <ArgDeclType> .NewQsTuple(args); var specs = new QsSpecialization[] { }.ToImmutableArray(); var qsCallable = new QsCallable(QsCallableKind.Operation, MakeFullName("AdiabaticStateEnergyUnitary"), ImmutableArray <QsDeclarationAttribute> .Empty, NonNullable <string> .New("Techniques.qs"), ZeroLocation, signature, argTuple, specs, comments.ToImmutableArray(), QsComments.Empty); var callable = new DocCallable("Microsoft.Quantum.Canon", qsCallable); var stream = new StringWriter(); callable.WriteToFile(stream); var s = stream.ToString(); Assert.Equal(expected, s); }