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CS2113/T Aug '19
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  • Project: DeliverablesProject: Supervision


    Project: Assessment

    Marks for the project component are divided according to the two phases.

    Total: 50 marks

    Split as follows: 10 marks for phase 1 + 40 marks for phase 2


    Phase 1

    Total: 10 marks ( 5 individual marks + 5 team marks)

    To score five individual marks, demonstrate achieving 80% of the mandatory tasks, with some contribution each week.

    • The key thing to note is that you need to have some contribution each week, you are free to decide how big your contribution will be.

    To score five team marks, as a team, demonstrate achieving all mandatory extensions to your tutor.

    • Do note that, this does not mean each of you do all the mandatory extensions, you need to divide the work among the team members.

    Phase 2

    Total: 40 marks ( 30 individual marks + 10 team marks)

    Evaluates: How well do your features fit together to form a cohesive product (not how many features or how big the features are)?

    Based on: user guide and the product demo. The quality of the demo will be factored in as well.

    💡 Feature that fit well with the other features will earn more marks.

    Evaluates:

    A. Code quality/quantity:

    How good your implementation is, in terms of the quality and the quantity of the code you have written yourself.

    Based on: an inspection of the parts of the code you claim as written by you.

    • Ensure your code has at least some evidence of these (see here for more info)

      • logging
      • exceptions
      • assertions
      • defensive coding
    • Ensure there are no coding standard violations  e.g. all boolean variables/methods sounds like booleans. Checkstyle can prevent only some coding standard violations; others need to be checked manually.

    • Ensure SLAP is applied at a reasonable level. Long methods or deeply-nested code are symptoms of low-SLAP may be counted against your code quality.

    • Reduce code duplications  i.e. if there multiple blocks of code that vary only in minor ways, try to extract out similarities into one place, especially in test code.

    • In addition, try to apply as many of the code quality guidelines covered in the module as much as you can.

     

    Code Quality

    Introduction

    What

    Can explain the importance of code quality

    Always code as if the person who ends up maintaining your code will be a violent psychopath who knows where you live. -- Martin Golding

    Production code needs to be of high quality . Given how the world is becoming increasingly dependent of software, poor quality code is something we cannot afford to tolerate.

    Code being used in an actual product with actual users

    Guideline: Maximise Readability

    Introduction

    Can explain the importance of readability

    Programs should be written and polished until they acquire publication quality. --Niklaus Wirth

    Among various dimensions of code quality, such as run-time efficiency, security, and robustness, one of the most important is understandability. This is because in any non-trivial software project, code needs to be read, understood, and modified by other developers later on. Even if we do not intend to pass the code to someone else, code quality is still important because we all become 'strangers' to our own code someday.

    The two code samples given below achieve the same functionality, but one is easier to read.

    Bad

    int subsidy() {
        int subsidy;
        if (!age) {
            if (!sub) {
                if (!notFullTime) {
                    subsidy = 500;
                } else {
                    subsidy = 250;
                }
            } else {
                subsidy = 250;
            }
        } else {
            subsidy = -1;
        }
        return subsidy;
    }
    
      

    Good

    int calculateSubsidy() {
        int subsidy;
        if (isSenior) {
            subsidy = REJECT_SENIOR;
        } else if (isAlreadySubsidised) {
            subsidy = SUBSIDISED_SUBSIDY;
        } else if (isPartTime) {
            subsidy = FULLTIME_SUBSIDY * RATIO;
        } else {
            subsidy = FULLTIME_SUBSIDY;
        }
        return subsidy;
    }
    

    Bad

    def calculate_subs():
        if not age:
            if not sub:
                if not not_fulltime:
                    subsidy = 500
                else:
                    subsidy = 250
            else:
                subsidy = 250
        else:
            subsidy = -1
        return subsidy
    
      

    Good

    def calculate_subsidy():
        if is_senior:
            return REJECT_SENIOR
        elif is_already_subsidised:
            return SUBSIDISED_SUBSIDY
        elif is_parttime:
            return FULLTIME_SUBSIDY * RATIO
        else:
            return FULLTIME_SUBSIDY
    

    Basic

    Avoid Long Methods

    Can improve code quality using technique: avoid long methods

    Be wary when a method is longer than the computer screen, and take corrective action when it goes beyond 30 LOC (lines of code). The bigger the haystack, the harder it is to find a needle.

    Avoid Deep Nesting

    Can improve code quality using technique: avoid deep nesting

    If you need more than 3 levels of indentation, you're screwed anyway, and should fix your program. --Linux 1.3.53 CodingStyle

    In particular, avoid arrowhead style code.

    A real code example:

    Bad

    int subsidy() {
        int subsidy;
        if (!age) {
            if (!sub) {
                if (!notFullTime) {
                    subsidy = 500;
                } else {
                    subsidy = 250;
                }
            } else {
                subsidy = 250;
            }
        } else {
            subsidy = -1;
        }
        return subsidy;
    }
    
      

    Good

    int calculateSubsidy() {
        int subsidy;
        if (isSenior) {
            subsidy = REJECT_SENIOR;
        } else if (isAlreadySubsidised) {
            subsidy = SUBSIDISED_SUBSIDY;
        } else if (isPartTime) {
            subsidy = FULLTIME_SUBSIDY * RATIO;
        } else {
            subsidy = FULLTIME_SUBSIDY;
        }
        return subsidy;
    }
    

    Bad

    def calculate_subs():
        if not age:
            if not sub:
                if not not_fulltime:
                    subsidy = 500
                else:
                    subsidy = 250
            else:
                subsidy = 250
        else:
            subsidy = -1
        return subsidy
    
      

    Good

    def calculate_subsidy():
        if is_senior:
            return REJECT_SENIOR
        elif is_already_subsidised:
            return SUBSIDISED_SUBSIDY
        elif is_parttime:
            return FULLTIME_SUBSIDY * RATIO
        else:
            return FULLTIME_SUBSIDY
    

    Avoid Complicated Expressions

    Can improve code quality using technique: avoid complicated expressions

    Avoid complicated expressions, especially those having many negations and nested parentheses. If you must evaluate complicated expressions, have it done in steps (i.e. calculate some intermediate values first and use them to calculate the final value).

    Example:

    Bad

    return ((length < MAX_LENGTH) || (previousSize != length)) && (typeCode == URGENT);
    

    Good

    
    boolean isWithinSizeLimit = length < MAX_LENGTH;
    boolean isSameSize = previousSize != length;
    boolean isValidCode = isWithinSizeLimit || isSameSize;
    
    boolean isUrgent = typeCode == URGENT;
    
    return isValidCode && isUrgent;
    

    Example:

    Bad

    return ((length < MAX_LENGTH) or (previous_size != length)) and (type_code == URGENT)
    

    Good

    is_within_size_limit = length < MAX_LENGTH
    is_same_size = previous_size != length
    is_valid_code = is_within_size_limit or is_same_size
    
    is_urgent = type_code == URGENT
    
    return is_valid_code and is_urgent
    

    The competent programmer is fully aware of the strictly limited size of his own skull; therefore he approaches the programming task in full humility, and among other things he avoids clever tricks like the plague. -- Edsger Dijkstra

    Avoid Magic Numbers

    Can improve code quality using technique: avoid magic numbers

    When the code has a number that does not explain the meaning of the number, we call that a "magic number" (as in "the number appears as if by magic"). Using a named constant makes the code easier to understand because the name tells us more about the meaning of the number.

    Example:

    Bad

    return 3.14236;
    ...
    return 9;
    
      

    Good

    static final double PI = 3.14236;
    static final int MAX_SIZE = 10;
    ...
    return PI;
    ...
    return MAX_SIZE-1;
    

    Note: Python does not have a way to make a variable a constant. However, you can use a normal variable with an ALL_CAPS name to simulate a constant.

    Bad

    return 3.14236
    ...
    return 9
    
      

    Good

    PI = 3.14236
    MAX_SIZE = 10
    ...
    return PI
    ...
    return MAX_SIZE-1
    

    Similarly, we can have ‘magic’ values of other data types.

    Bad

    "Error 1432"  // A magic string!
    

    In general, try to avoid any magic literals.

    Make the Code Obvious

    Can improve code quality using technique: make the code obvious

    Make the code as explicit as possible, even if the language syntax allows them to be implicit. Here are some examples:

    • [Java] Use explicit type conversion instead of implicit type conversion.
    • [Java, Python] Use parentheses/braces to show grouping even when they can be skipped.
    • [Java, Python] Use enumerations when a certain variable can take only a small number of finite values. For example, instead of declaring the variable 'state' as an integer and using values 0,1,2 to denote the states 'starting', 'enabled', and 'disabled' respectively, declare 'state' as type SystemState and define an enumeration SystemState that has values 'STARTING', 'ENABLED', and 'DISABLED'.

    Intermediate

    Structure Code Logically

    Can improve code quality using technique: structure code logically

    Lay out the code so that it adheres to the logical structure. The code should read like a story. Just like we use section breaks, chapters and paragraphs to organize a story, use classes, methods, indentation and line spacing in your code to group related segments of the code. For example, you can use blank lines to group related statements together. Sometimes, the correctness of your code does not depend on the order in which you perform certain intermediary steps. Nevertheless, this order may affect the clarity of the story you are trying to tell. Choose the order that makes the story most readable.

    Do Not 'Trip Up' Reader

    Can improve code quality using technique: do not 'trip up' reader

    Avoid things that would make the reader go ‘huh?’, such as,

    • unused parameters in the method signature
    • similar things look different
    • different things that look similar
    • multiple statements in the same line
    • data flow anomalies such as, pre-assigning values to variables and modifying it without any use of the pre-assigned value

    Practice KISSing

    Can improve code quality using technique: practice kissing

    As the old adage goes, "keep it simple, stupid” (KISS). Do not try to write ‘clever’ code. For example, do not dismiss the brute-force yet simple solution in favor of a complicated one because of some ‘supposed benefits’ such as 'better reusability' unless you have a strong justification.

    Debugging is twice as hard as writing the code in the first place. Therefore, if you write the code as cleverly as possible, you are, by definition, not smart enough to debug it. --Brian W. Kernighan

    Programs must be written for people to read, and only incidentally for machines to execute. --Abelson and Sussman

    Avoid Premature Optimizations

    Can improve code quality using technique: avoid premature optimizations

    Optimizing code prematurely has several drawbacks:

    • We may not know which parts are the real performance bottlenecks. This is especially the case when the code undergoes transformations (e.g. compiling, minifying, transpiling, etc.) before it becomes an executable. Ideally, you should use a profiler tool to identify the actual bottlenecks of the code first, and optimize only those parts.
    • Optimizing can complicate the code, affecting correctness and understandability
    • Hand-optimized code can be harder for the compiler to optimize (the simpler the code, the easier for the compiler to optimize it). In many cases a compiler can do a better job of optimizing the runtime code if you don't get in the way by trying to hand-optimize the source code.

    A popular saying in the industry is make it work, make it right, make it fast which means in most cases getting the code to perform correctly should take priority over optimizing it. If the code doesn't work correctly, it has no value on matter how fast/efficient it it.

    Premature optimization is the root of all evil in programming. --Donald Knuth

    Note that there are cases where optimizing takes priority over other things e.g. when writing code for resource-constrained environments. This guideline simply a caution that you should optimize only when it is really needed.

    SLAP Hard

    Can improve code quality using technique: SLAP hard

    Avoid varying the level of abstraction within a code fragment. Note: The Productive Programmer (by Neal Ford) calls this the SLAP principle i.e. Single Level of Abstraction Per method.

    Example:

    Bad (readData(); and salary = basic*rise+1000; are at different levels of abstraction)

    readData();
    salary = basic*rise+1000;
    tax = (taxable?salary*0.07:0);
    displayResult();
    

    Good (all statements are at the same level of abstraction)

    readData();
    processData();
    displayResult();
    

    Design → Design Fundamentals → Abstraction →

    What

    Abstraction is a technique for dealing with complexity. It works by establishing a level of complexity we are interested in, and suppressing the more complex details below that level.

    The guiding principle of abstraction is that only details that are relevant to the current perspective or the task at hand needs to be considered. As most programs are written to solve complex problems involving large amounts of intricate details, it is impossible to deal with all these details at the same time. That is where abstraction can help.

    Data abstraction: abstracting away the lower level data items and thinking in terms of bigger entities

    Within a certain software component, we might deal with a user data type, while ignoring the details contained in the user data item such as name, and date of birth. These details have been ‘abstracted away’ as they do not affect the task of that software component.

    Control abstraction: abstracting away details of the actual control flow to focus on tasks at a higher level

    print(“Hello”) is an abstraction of the actual output mechanism within the computer.

    Abstraction can be applied repeatedly to obtain progressively higher levels of abstractions.

    An example of different levels of data abstraction: a File is a data item that is at a higher level than an array and an array is at a higher level than a bit.

    An example of different levels of control abstraction: execute(Game) is at a higher level than print(Char) which is at a higher than an Assembly language instruction MOV.

    Abstraction is a general concept that is not limited to just data or control abstractions.

    Some more general examples of abstraction:

    • An OOP class is an abstraction over related data and behaviors.
    • An architecture is a higher-level abstraction of the design of a software.
    • Models (e.g., UML models) are abstractions of some aspect of reality.

    Advanced

    Make the Happy Path Prominent

    Can improve code quality using technique: make the happy path prominent

    The happy path (i.e. the execution path taken when everything goes well) should be clear and prominent in your code. Restructure the code to make the happy path unindented as much as possible. It is the ‘unusual’ cases that should be indented. Someone reading the code should not get distracted by alternative paths taken when error conditions happen. One technique that could help in this regard is the use of guard clauses.

    Example:

    Bad

    if (!isUnusualCase) {  //detecting an unusual condition
        if (!isErrorCase) {
            start();    //main path
            process();
            cleanup();
            exit();
        } else {
            handleError();
        }
    } else {
        handleUnusualCase(); //handling that unusual condition
    }
    

    In the code above,

    • Unusual condition detection is separated from their handling.
    • Main path is nested deeply.

    Good

    if (isUnusualCase) { //Guard Clause
        handleUnusualCase();
        return;
    }
    
    if (isErrorCase) { //Guard Clause
        handleError();
        return;
    }
    
    start();
    process();
    cleanup();
    exit();
    

    In contrast, the above code

    • deals with unusual conditions as soon as they are detected so that the reader doesn't have to remember them for long.
    • keeps the main path un-indented.

    Guideline: Follow a Standard

    Introduction

    Can explain the need for following a standard

    One essential way to improve code quality is to follow a consistent style. That is why software engineers follow a strict coding standard (aka style guide).

    The aim of a coding standard is to make the entire code base look like it was written by one person. A coding standard is usually specific to a programming language and specifies guidelines such as the location of opening and closing braces, indentation styles and naming styles (e.g. whether to use Hungarian style, Pascal casing, Camel casing, etc.). It is important that the whole team/company use the same coding standard and that standard is not generally inconsistent with typical industry practices. If a company's coding standards is very different from what is used typically in the industry, new recruits will take longer to get used to the company's coding style.

    IDEs can help to enforce some parts of a coding standard e.g. indentation rules.

    What is the recommended approach regarding coding standards?

    c

    What is the aim of using a coding standard? How does it help?

    What

    Can follow simple mechanical style rules

    Learn basic guidelines of the Java coding standard (by OSS-Generic)

    Consider the code given below:

    import java.util.*;
    
    public class Task {
        public static final String descriptionPrefix = "description: ";
        private String description;
        private boolean important;
        List<String> pastDescription = new ArrayList<>(); // a list of past descriptions
    
        public Task(String d) {
          this.description = d;
          if (!d.isEmpty())
              this.important = true;
        }
    
        public String getAsXML() { return "<task>"+description+"</task>"; }
    
        /**
         * Print the description as a string.
         */
        public void printingDescription(){ System.out.println(this); }
    
        @Override
        public String toString() { return descriptionPrefix + description; }
    }
    

    In what ways the code violate the basic guidelines (i.e., those marked with one ⭐️) of the OSS-Generic Java Coding Standard given here?

    Here are three:

    • descriptionPrefix is a constant and should be named DESCRIPTION_PREFIX
    • method name printingDescription() should be named as printDescription()
    • boolean variable important should be named to sound boolean e.g., isImportant

    There are many more.

    Intermediate

    Can follow intermediate style rules

    Go through the provided Java coding standard and learn the intermediate style rules.

    According to the given Java coding standard, which one of these is not a good name?

    b

    Explanation: checkWeight is an action. Naming variables as actions makes the code harder to follow. isWeightValid may be a better name.

    Repeat the exercise in the panel below but also find violations of intermediate level guidelines.

    Consider the code given below:

    import java.util.*;
    
    public class Task {
        public static final String descriptionPrefix = "description: ";
        private String description;
        private boolean important;
        List<String> pastDescription = new ArrayList<>(); // a list of past descriptions
    
        public Task(String d) {
          this.description = d;
          if (!d.isEmpty())
              this.important = true;
        }
    
        public String getAsXML() { return "<task>"+description+"</task>"; }
    
        /**
         * Print the description as a string.
         */
        public void printingDescription(){ System.out.println(this); }
    
        @Override
        public String toString() { return descriptionPrefix + description; }
    }
    

    In what ways the code violate the basic guidelines (i.e., those marked with one ⭐️) of the OSS-Generic Java Coding Standard given here?

    Here are three:

    • descriptionPrefix is a constant and should be named DESCRIPTION_PREFIX
    • method name printingDescription() should be named as printDescription()
    • boolean variable important should be named to sound boolean e.g., isImportant

    There are many more.

    Here's one you are more likely to miss:

    • * Print the description as a string.* Prints the description as a string.

    There are more.

    Guideline: Name Well

    Introduction

    Can explain the need for good names in code

    Proper naming improves the readability. It also reduces bugs caused by ambiguities regarding the intent of a variable or a method.

    There are only two hard things in Computer Science: cache invalidation and naming things. -- Phil Karlton

    Basic

    Use Nouns for Things and Verbs for Actions

    Can improve code quality using technique: use nouns for things and verbs for actions

    Every system is built from a domain-specific language designed by the programmers to describe that system. Functions are the verbs of that language, and classes are the nouns. ― Robert C. Martin, Clean Code: A Handbook of Agile Software Craftsmanship

    Use nouns for classes/variables and verbs for methods/functions.

    Examples:

    Name for a Bad Good
    Class CheckLimit LimitChecker
    method result() calculate()

    Distinguish clearly between single-valued and multivalued variables.

    Examples:

    Good

    Person student;
    ArrayList<Person> students;
    

    Good

    name = 'Jim'
    names = ['Jim', 'Alice']
    

    Use Standard Words

    Can improve code quality using technique: use standard words

    Use correct spelling in names. Avoid 'texting-style' spelling. Avoid foreign language words, slang, and names that are only meaningful within specific contexts/times e.g. terms from private jokes, a TV show currently popular in your country

    Intermediate

    Use Name to Explain

    Can improve code quality using technique: use name to explain

    A name is not just for differentiation; it should explain the named entity to the reader accurately and at a sufficient level of detail.

    Examples:

    Bad Good
    processInput() (what 'process'?) removeWhiteSpaceFromInput()
    flag isValidInput
    temp

    If the name has multiple words, they should be in a sensible order.

    Examples:

    Bad Good
    bySizeOrder() orderBySize()

    Imagine going to the doctor's and saying "My eye1 is swollen"! Don’t use numbers or case to distinguish names.

    Examples:

    Bad Bad Good
    value1, value2 value, Value originalValue, finalValue

    Not Too Long, Not Too Short

    Can improve code quality using technique: not too long, not too short

    While it is preferable not to have lengthy names, names that are 'too short' are even worse. If you must abbreviate or use acronyms, do it consistently. Explain their full meaning at an obvious location.

    Avoid Misleading Names

    Can improve code quality using technique: avoid misleading names

    Related things should be named similarly, while unrelated things should NOT.

    Example: Consider these variables

    • colorBlack: hex value for color black
    • colorWhite: hex value for color white
    • colorBlue: number of times blue is used
    • hexForRed: hex value for color red

    This is misleading because colorBlue is named similar to colorWhite and colorBlack but has a different purpose while hexForRed is named differently but has very similar purpose to the first two variables. The following is better:

    • hexForBlack hexForWhite hexForRed
    • blueColorCount

    Avoid misleading or ambiguous names (e.g. those with multiple meanings), similar sounding names, hard-to-pronounce ones (e.g. avoid ambiguities like "is that a lowercase L, capital I or number 1?", or "is that number 0 or letter O?"), almost similar names.

    Examples:

    Bad Good Reason
    phase0 phaseZero Is that zero or letter O?
    rwrLgtDirn rowerLegitDirection Hard to pronounce
    right left wrong rightDirection leftDirection wrongResponse right is for 'correct' or 'opposite of 'left'?
    redBooks readBooks redColorBooks booksRead red and read (past tense) sounds the same
    FiletMignon egg If the requirement is just a name of a food, egg is a much easier to type/say choice than FiletMignon

    Guideline: Avoid Unsafe Shortcuts

    Introduction

    Can explain the need for avoiding error-prone shortcuts

    It is safer to use language constructs in the way they are meant to be used, even if the language allows shortcuts. Some such coding practices are common sources of bugs. Know them and avoid them.

    Basic

    Use the Default Branch

    Can improve code quality using technique: use the default branch

    Always include a default branch in case statements.

    Furthermore, use it for the intended default action and not just to execute the last option. If there is no default action, you can use the 'default' branch to detect errors (i.e. if execution reached the default branch, throw an exception). This also applies to the final else of an if-else construct. That is, the final else should mean 'everything else', and not the final option. Do not use else when an if condition can be explicitly specified, unless there is absolutely no other possibility.

    Bad

    if (red) print "red";
    else print "blue";
    

    Good

    if (red) print "red";
    else if (blue) print "blue";
    else error("incorrect input");
    

    Don't Recycle Variables or Parameters

    Can improve code quality using technique: don't recycle variables or parameters

    • Use one variable for one purpose. Do not reuse a variable for a different purpose other than its intended one, just because the data type is the same.
    • Do not reuse formal parameters as local variables inside the method.

    Bad

    double computeRectangleArea(double length, double width) {
        length = length * width;
        return length;
    }
    
    

    Good

    double computeRectangleArea(double length, double width) {
        double area;
        area = length * width;
        return area;
    }
    

    Avoid Empty Catch Blocks

    Can improve code quality using technique: avoid empty catch blocks

    Never write an empty catch statement. At least give a comment to explain why the catch block is left empty.

    Delete Dead Code

    Can improve code quality using technique: delete dead code

    We all feel reluctant to delete code we have painstakingly written, even if we have no use for that code any more ("I spent a lot of time writing that code; what if we need it again?"). Consider all code as baggage you have to carry; get rid of unused code the moment it becomes redundant. If you need that code again, simply recover it from the revision control tool you are using. Deleting code you wrote previously is a sign that you are improving.

    Intermediate

    Minimize Scope of Variables

    Can improve code quality using technique: minimise scope of variables

    Minimize global variables. Global variables may be the most convenient way to pass information around, but they do create implicit links between code segments that use the global variable. Avoid them as much as possible.

    Define variables in the least possible scope. For example, if the variable is used only within the if block of the conditional statement, it should be declared inside that if block.

    The most powerful technique for minimizing the scope of a local variable is to declare it where it is first used. -- Effective Java, by Joshua Bloch

    Resources:

    Minimize Code Duplication

    Can improve code quality using technique: minimize code duplication

    Code duplication, especially when you copy-paste-modify code, often indicates a poor quality implementation. While it may not be possible to have zero duplication, always think twice before duplicating code; most often there is a better alternative.

    This guideline is closely related to the DRY Principle.

    Principles →

    DRY Principle

    DRY (Don't Repeat Yourself) Principle: Every piece of knowledge must have a single, unambiguous, authoritative representation within a system The Pragmatic Programmer, by Andy Hunt and Dave Thomas

    This principle guards against duplication of information.

    The functionality implemented twice is a violation of the DRY principle even if the two implementations are different.

    The value a system-wide timeout being defined in multiple places is a violation of DRY.

    Guideline: Comment Minimally, but Sufficiently

    Introduction

    Can explain the need for commenting minimally but sufficiently

    Good code is its own best documentation. As you’re about to add a comment, ask yourself, ‘How can I improve the code so that this comment isn’t needed?’ Improve the code and then document it to make it even clearer. --Steve McConnell, Author of Clean Code

    Some think commenting heavily increases the 'code quality'. This is not so. Avoid writing comments to explain bad code. Improve the code to make it self-explanatory.

    Basic

    Do Not Repeat the Obvious

    Can improve code quality using technique: do not repeat the obvious

    If the code is self-explanatory, refrain from repeating the description in a comment just for the sake of 'good documentation'.

    Bad

    // increment x
    x++;
    
    //trim the input
    trimInput();
    

    Bad

    // increment x
    x = x + 1
    
    //trim the input
    trim_input()
    

    Write to the Reader

    Can improve code quality using technique: write to the reader

    Do not write comments as if they are private notes to yourself. Instead, write them well enough to be understood by another programmer. One type of comments that is almost always useful is the header comment that you write for a class or an operation to explain its purpose.

    Examples:

    Bad Reason: this comment will only make sense to the person who wrote it

    // a quick trim function used to fix bug I detected overnight
    void trimInput(){
        ....
    }
    

    Good

    /** Trims the input of leading and trailing spaces */
    void trimInput(){
        ....
    }
    

    Bad Reason: this comment will only make sense to the person who wrote it

    # a quick trim function used to fix bug I detected overnight
    def trim_input():
        ...
    

    Good

    def trim_input():
    """Trim the input of leading and trailing spaces"""
        ...
    

    Intermediate

    Explain WHAT and WHY, not HOW

    Can improve code quality using technique: explain what and why, not how

    Comments should explain what and why aspect of the code, rather than the how aspect.

    What : The specification of what the code supposed to do. The reader can compare such comments to the implementation to verify if the implementation is correct

    Example: This method is possibly buggy because the implementation does not seem to match the comment. In this case the comment could help the reader to detect the bug.

    /** Removes all spaces from the {@code input} */
    void compact(String input){
        input.trim();
    }
    

    Why : The rationale for the current implementation.

    Example: Without this comment, the reader will not know the reason for calling this method.

    // Remove spaces to comply with IE23.5 formatting rules
    compact(input);
    

    How : The explanation for how the code works. This should already be apparent from the code, if the code is self-explanatory. Adding comments to explain the same thing is redundant.

    Example:

    Bad Reason: Comment explains how the code works.

    // return true if both left end and right end are correct or the size has not incremented
    return (left && right) || (input.size() == size);
    

    Good Reason: Code refactored to be self-explanatory. Comment no longer needed.

    
    boolean isSameSize = (input.size() == size) ;
    return (isLeftEndCorrect && isRightEndCorrect) || isSameSize;
    

    B. Quality of your feature(s)

    Evaluates: How good is your Quality Assurance?

    Based on:

    1. bugs you found in the v1.4 Practical Exam
    2. bugs in your work found by others during the PE
    3. testability of your feature (you will lose marks if testers feel that your feature is hard to test manually)
    4. your test code (you will lose marks if you don't meet our expectations for automated testing)
    5. our own manual testing (when necessary)
     
    • There is no requirement for a minimum coverage level. Note that in a production environment you are often required to have at least 90% of the code covered by tests. In this project, it can be less. The less coverage you have, the higher the risk of regression bugs, which will cost marks if not fixed before the final submission.
    • You must write some tests so that we can evaluate your ability to write tests. (Please refer to Expectations on Lines of Code for LoC requirement).
    • How much of each type of testing should you do? We expect you to decide. You learned different types of testing and what they try to achieve. Based on that, you should decide how much of each type is required. Similarly, you can decide to what extent you want to automate tests, depending on the benefits and the effort required.

    Evaluates: How good are the sections you wrote for the user guide and the developer guide?

    Based on: the relevant sections of your project portfolio. Criteria considered:

    • Explanation should be clear and written to match the audience.
    • Good use of visuals to complement text.
    • Use of correct UML notations (where applicable)

    A. Process:

    Evaluates: How well you did in project management related aspects of the project, as an individual and as a team

    Based on: Supervisor observations of project milestones and GitHub data.

    Milestones need to be reached the midnight before of the tutorial for it to be counted as achieved. To get a good grade for this aspect, achieve at least 60% of the recommended milestone progress.

    Other criteria:

    • Good use of GitHub milestones
    • Good use of GitHub release mechanism
    • Good version control, based on the repo
    • Reasonable attempt to use the forking workflow
    • Good task definition, assignment and tracking, based on the issue tracker
    • Good use of buffers (opposite: everything at the last minute)
    • Project done iteratively and incrementally (opposite: doing most of the work in one big burst)

    B. Team-tasks:

    Evaluates: How much did you contribute to team-tasks?

    Based on: peer evaluations and tutor observations

    Relevant: [Admin Project Scope → Examples of team-tasks ]

     

    Here is a non-exhaustive list of team-tasks:

    1. Necessary general code enhancements e.g.,
      1. Work related to renaming the product
      2. Work related to changing the product icon
      3. Morphing the product into a different product
    2. Setting up the GitHub, Travis, AppVeyor, etc.
    3. Maintaining the issue tracker
    4. Release management
    5. Updating user/developer docs that are not specific to a feature e.g. documenting the target user profile
    6. Incorporating more useful tools/libraries/frameworks into the product or the project workflow (e.g. automate more aspects of the project workflow using a GitHub plugin)


    Project: DeliverablesProject: Supervision