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Andrew Ryan Davis
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@ -3,6 +3,7 @@ language: Q#
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contributors:
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- ["Vincent van Wingerden", "https://github.com/vivanwin"]
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- ["Mariia Mykhailova", "https://github.com/tcNickolas"]
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- ["Andrew Ryan Davis", "https://github.com/AndrewDavis1191"]
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filename: LearnQSharp.qs
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---
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@ -13,6 +14,11 @@ This is the new outline
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```C#
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// Single-line comments start with //
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/
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Multi-line comments
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like so
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\
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/////////////////////////////////////
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// 1. Quantum data types and operators
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@ -22,27 +28,33 @@ This is the new outline
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using (qs = Qubit[2]) {
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// The qubits have internal state that you cannot access to read or modify directly.
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// You can inspect the current state of your quantum program if you're running it on a classical simulator.
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// You can inspect the current state of your quantum program
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// if you're running it on a classical simulator.
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// Note that this will not work on actual quantum hardware!
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DumpMachine();
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// If you want to change the state of a qubit, you have to do this by applying quantum gates to the qubit.
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H(q[0]); // This changes the state of the first qubit from |0⟩ (the initial state of allocated qubits) to (|0⟩ + |1⟩) / sqrt(2).
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// If you want to change the state of a qubit
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// you have to do this by applying quantum gates to the qubit.
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H(q[0]); // This changes the state of the first qubit
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// from |0⟩ (the initial state of allocated qubits) to (|0⟩ + |1⟩) / sqrt(2).
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// q[1] = |1⟩; - this does NOT work, you have to manipulate a qubit by using gates.
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// You can apply multi-qubit gates to several qubits.
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CNOT(qs[0], qs[1]);
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// You can also apply a controlled version of a gate: a gate that is applied if all control qubits are in |1⟩ state.
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// The first argument is an array of control qubits, the second argument is the target qubit.
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/ You can also apply a controlled version of a gate:
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a gate that is applied if all control qubits are in |1⟩ state.
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\ The first argument is an array of control qubits, the second argument is the target qubit.
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Controlled Y([qs[0]], qs[1]);
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// If you want to apply an anti-controlled gate (a gate that is applied if all control qubits are in |0⟩ state), you can use a library function.
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/ If you want to apply an anti-controlled gate
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(a gate that is applied if all control qubits are in |0⟩ state),
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\ you can use a library function.
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ApplyControlledOnInt(0, X, [qs[0]], qs[1]);
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// To read the information from the quantum system, you use measurements.
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// Measurements return a value of Result data type: Zero or One.
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// You can print measurement results as a classical value.
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/ To read the information from the quantum system, you use measurements.
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Measurements return a value of Result data type: Zero or One.
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\ You can print measurement results as a classical value.
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Message($"Measured {M(qs[0])}, {M(qs[1])}");
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}
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@ -57,7 +69,8 @@ let d = 1.0; // This defines a Double variable d equal to 1
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// Arithmetic is done as expected, as long as the types are the same
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let n = 2 * 10; // = 20
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// Q# does not have implicit type cast, so to perform arithmetic on values of different types, you need to cast type explicitly
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// Q# does not have implicit type cast,
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// so to perform arithmetic on values of different types, you need to cast type explicitly
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let nd = IntAsDouble(2) * 1.0; // = 20.0
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// Boolean type is called Bool
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@ -78,9 +91,9 @@ let x = 10 == 15; // is false
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// Range is a sequence of integers and can be defined like: start..step..stop
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let xi = 1..2..7; // Gives the sequence 1,3,5,7
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// Assigning new value to a variable:
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// by default all Q# variables are immutable;
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// if the variable was defined using let, you cannot reassign its value.
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/ Assigning new value to a variable:
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by default all Q# variables are immutable;
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\ if the variable was defined using let, you cannot reassign its value.
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// When you want to make a variable mutable, you have to declare it as such,
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// and use the set word to update value
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@ -126,9 +139,10 @@ while (index < 10) {
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set index += 1;
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}
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// Quantum equivalent of a while loop is a repeat-until-success loop.
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// Because of the probabilistic nature of quantum computing sometimes
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// you want to repeat a certain sequence of operations until a specific condition is achieved; you can use this loop to express this.
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/ Quantum equivalent of a while loop is a repeat-until-success loop.
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Because of the probabilistic nature of quantum computing sometimes
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you want to repeat a certain sequence of operations
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\ until a specific condition is achieved; you can use this loop to express this.
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repeat {
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// Your operation here
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}
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@ -146,10 +160,10 @@ operation ApplyXGate(source : Qubit) : Unit {
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X(source);
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}
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// If the operation implements a unitary transformation, you can define
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// adjoint and controlled variants of it.
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// The easiest way to do that is to add "is Adj + Ctl" after Unit.
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// This will tell the compiler to generate the variants automatically.
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/ If the operation implements a unitary transformation, you can define
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adjoint and controlled variants of it.
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The easiest way to do that is to add "is Adj + Ctl" after Unit.
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\ This will tell the compiler to generate the variants automatically.
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operation ApplyXGateCA (source : Qubit) : Unit is Adj + Ctl {
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X(source);
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}
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@ -169,16 +183,16 @@ operation XGateDemo() : Unit {
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// We will generate a classical array of random bits using quantum code.
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@EntryPoint()
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operation QRNGDemo() : Unit {
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mutable bits = new Int[5]; // Array we'll use to store bits
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using (q = Qubit()) { // Allocate a qubit
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for (i in 0 .. 4) { // Generate each bit independently
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H(q); // Apply Hadamard gate to prepare equal superposition
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let result = M(q); // Measure the qubit to get Zero or One with 50/50 probability
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let bit = result == Zero ? 0 | 1; // Convert measurement result to an integer
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set bits w/= i <- bit; // Write generated bit to an array
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mutable bits = new Int[5]; / Array we'll use to store bits
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using (q = Qubit()) { / Allocate a qubit
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for (i in 0 .. 4) { / Generate each bit independently
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H(q); / Apply Hadamard gate prepares equal superposition
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let result = M(q); / Measure the qubit to get 0 or 1 with 50/50 prob
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let bit = result == Zero ? 0 | 1; / Convert measurement result to an integer
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set bits w/= i <- bit; / Write generated bit to an array
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}
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}
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Message($"{bits}"); // Print the result
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Message($"{bits}"); / Print the result
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}
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```
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