microsoft / QuantumLibraries
Conditional Complexity

The distribution of complexity of units (measured with McCabe index).

Intro
  • Conditional complexity (also called cyclomatic complexity) is a term used to measure the complexity of software. The term refers to the number of possible paths through a program function. A higher value ofter means higher maintenance and testing costs (infosecinstitute.com).
  • Conditional complexity is calculated by counting all conditions in the program that can affect the execution path (e.g. if statement, loops, switches, and/or operators, try and catch blocks...).
  • Conditional complexity is measured at the unit level (methods, functions...).
  • Units are classified in four categories based on the measured McCabe index: 1-5 (simple units), 6-10 (medium complex units), 11-25 (complex units), 26+ (very complex units).
Learn more...
Conditional Complexity Overall
  • There are 274 units with 2,955 lines of code in units (48.7% of code).
    • 0 very complex units (0 lines of code)
    • 1 complex units (81 lines of code)
    • 3 medium complex units (254 lines of code)
    • 7 simple units (252 lines of code)
    • 263 very simple units (2,368 lines of code)
0% | 2% | 8% | 8% | 80%
Legend:
51+
26-50
11-25
6-10
1-5
Alternative Visuals
Conditional Complexity per Extension
51+
26-50
11-25
6-10
1-5
cs0% | 2% | 8% | 8% | 80%
py0% | 0% | 0% | 17% | 82%
Conditional Complexity per Logical Component
primary logical decomposition
51+
26-50
11-25
6-10
1-5
Chemistry/src0% | 3% | 6% | 7% | 82%
Standard/src0% | 0% | 19% | 14% | 65%
Build0% | 0% | 0% | 86% | 13%
Python/qsharp-chemistry0% | 0% | 0% | 0% | 100%
Visualization/src0% | 0% | 0% | 0% | 100%
Most Complex Units
Top 20 most complex units
Unit# linesMcCabe index# params
private static IEnumerable ToTwoBodySpinOrbitalTerms()
in Chemistry/src/DataModel/OrbitalIntegral/OrbitalIntegralExtensions.cs
 81 28 3
private long SampleUsingBTPE()
in Standard/src/Emulation/Math.cs
 98 20 0
internal static ElectronicStructureProblem DeserializeSingleProblem()
in Chemistry/src/DataModel/Serialization/LegacyFormats/LiQuiD.cs
 111 13 1
public static UnitaryCCWavefunction CreateAllUCCSDSingletExcitations()
in Chemistry/src/DataModel/Fermion/Wavefunction/WavefunctionExtensions.cs
 45 11 2
public static List ToJordanWignerPauliTerms()
in Chemistry/src/DataModel/Fermion/JordanWignerEncoding.cs
 54 9 3
private static List TwoLevelDecompose()
in Standard/src/Synthesis/UnitaryDecomposition.cs
 50 9 2
public void NormalizeToIndexOrder()
in Chemistry/src/DataModel/LadderOperator/IndexOrderedSequence.cs
 39 8 0
def check_file()
in Build/check_indents.py
 19 7 1
public static bool IsMatrixUnitary()
in Standard/src/Synthesis/MatrixUtils.cs
 22 7 3
internal static TValue GetValueOrDefault()
in Chemistry/src/DataModel/Extensions.cs
 25 6 3
public static LadderSequence ToLadderSequence()
in Chemistry/src/DataModel/LadderOperator/LadderOperatorExtensions.cs
 43 6 2
public static bool IsInAscendingOrder()
in Chemistry/src/DataModel/Extensions.cs
 18 5 2
public bool IsInCanonicalOrder()
in Chemistry/src/DataModel/Fermion/HermitianFermionTerm.cs
 21 5 0
public LadderSequence Multiply()
in Chemistry/src/DataModel/LadderOperator/LadderSequence.cs
 27 5 2
public override object ReadJson()
in Chemistry/src/DataModel/Serialization/JsonConverters/FermionWavefunctionJsonConverter.cs
 24 5 4
public override object ReadJson()
in Chemistry/src/DataModel/Serialization/JsonConverters/HamiltonianTermsJsonConverter.cs
 23 5 4
internal static void Save()
in Chemistry/src/Tools/Convert.cs
 24 5 3
public bool Equals()
in Chemistry/src/DataModel/OrbitalIntegral/OrbitalIntegral.cs
 16 4 1
public static IEnumerable ToHermitianFermionTerms()
in Chemistry/src/DataModel/OrbitalIntegral/OrbitalIntegralExtensions.cs
 23 4 3
private static IEnumerable ToOneBodySpinOrbitalTerms()
in Chemistry/src/DataModel/OrbitalIntegral/OrbitalIntegralExtensions.cs
 21 4 3