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Software Testing Techniques

Software Testing Techniques. Software Testing. Testing is the process of exercising a program with the specific intent of finding errors prior to delivery to the end user. Software Development Process. Tangible Product. Abstract Concept. Testing. Tries hard to demolish the software.

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Software Testing Techniques

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  1. Software Testing Techniques

  2. Software Testing Testing is the process of exercising a program with the specific intent of finding errors priorto delivery to the enduser.

  3. Software Development Process Tangible Product Abstract Concept Testing Tries hard to demolish the software

  4. Developer must discard the preconceived idea that his software is always correct.

  5. Software Testing Objectives • Uncovering different cases of errors • Needing minimum effort and time • Showing that software functions work according to specification It cannot showabsence of errors or defects. It can only show that errors are present

  6. Customer thinks - most serious defect is not meeting his requirements Software Testing Principles All tests can be planned and designed before any coding begins • All tests should be traceable to customer requirements • Tests should be planned long before testing begins • The “pareto” principle applies to software testing • Exhaustive testing is not possible • To be most effective, testing should be conducted by a third party 80 % of errors originate from 20% of programs Too many paths in a normal -size program

  7. Who Tests the Software? developer independent tester Understands the system Must learn about the system, but, will test "gently" but, will attempt to break it and, is driven by quality and, is driven by "delivery"

  8. What is a GOOD Test? Has a high probability of finding an error It must not be redundant. Every test must have a different purpose It should neither be too simple, nor too complex.

  9. What Testing Shows errors requirements conformance performance an indication of quality

  10. Testability • Operability—it operates cleanly • Observability—the results of each test case are readily observed • Controlability—the degree to which testing can be automated and optimized • Decomposability—testing can be targeted • Simplicity—reduce complex architecture and logic to simplify tests • Stability—few changes are requested during testing • Understandability—of the design

  11. Test Case Design • Design of test cases is as challenging asdesigning the software itself • A rich variety of test case design methods have evolved • Methods provide a systematic approach o testing • Methods provide a mechanism for that ensures the completeness of tests and high likelihood of finding an error

  12. Software Testing black-box methods white-box methods Methods Strategies

  13. White Box Testing • Close examination of procedural detail • Logical paths through the software are tested by providing test cases that exercise specific sets of conditions and/or loops • Status of the program is examined at various points to determine if the actual status matches the expected status

  14. Does White Box Testing lead to 100% correct program? The answer is: No It is not possible to exhaustively test every program path because the number paths is simply too large

  15. Exhaustive Testing loop < 20 X 14 There are10 possible paths! If we execute one test per millisecond, it would take 3,170 years to test this program!!

  16. Selective Testing Selected path loop < 20 X

  17. Black Box Testing • Know the specific function that the program is designed to perform • Test that each function is fully operational • Search for more errors in the functions • These tests are conducted at the software interface • Whether input is properly accepted and output is correctly produced • Integrity of external information (database) is maintained • Examines fundamental aspects of the system with little regard to internal logical structure

  18. The attributes of both black-box and white-box testing can be combined to provide an approach that validates the software interface and selectively ensures that the internal workings of the software are correct

  19. White Box Testing • Is also known as “Glass Box Testing” • Uses the control structure of the procedural design to derive test cases If a= b then do c else do v Glass Box

  20. WhiteBox Testing Guarantees that all independent paths within a module have been exercised at least once Exercise all logical decisions on their true and false sides Exercise all loops at their boundaries and within their operational bounds Exercise internal data structures to ensure their validity

  21. Test Case Design "Bugs lurk in corners and congregate at boundaries ..." Boris Beizer OBJECTIVE to uncover errors CRITERIA in a complete manner CONSTRAINT with a minimum of effort and time

  22. Why Cover? logic errors and incorrect assumptions are inversely proportional to a path's execution probability we often believe that a path is not likely to be executed; in fact, reality is often counter intuitive typographicalerrors are random; it's likely that untested paths will contain some

  23. Why need White-box testing? • Logic errors occur more frequently in the less probable paths of execution • Everyday processing tends to be well understood while “special case “ processing tends to fall into cracks • We often believe that a logical path is not likely to be executed when , in fact it may be executed on a regular basis • Typos are random. It is as likely that a type will exist on an obscure logical path as on a mainstream path.

  24. White-Box Testing ... our goal is to ensure that all statements and conditions have been executed at least once ...

  25. Basis Path Testing • It is white-box testing technique • Proposed by Tom Macabe • Derives a logical complexity measure • Test cases derived to exercise the basis set are guaranteed to execute every statement in the program at least once during testing • Uses flow-graph notation • Each structured construct has corresponding flow graph symbol

  26. Structured Constructs if If-then-else else then Sequence Selection While-do Repeat until case Loops

  27. Flow Graph Symbols if while Sequence until case

  28. Flow Graph Symbols • Each circle is called a flow graph node , represents one or more procedural statements • A sequence of process boxes and a decision diamond can map into a single node • An edge (arrow) must terminate at a node • Areas bounded by edged and nodes are called regions • Area outside graph is also a region

  29. Flow Graph for Compound Conditions a • A compound condition occurs when one or more Boolean operators (AND,OR) is present in a conditional statement • Separate node is created for each condition • Each condition node is known as predicate node • Each predicate node has two or more edges leaving it x b x y If a or b then procedure x else procedure y endif

  30. Cyclomatic Complexity • Very useful software metric • Foundation on graph theory • Quantitative measure of the logical complexity of the program • It defines the number of independent paths in the basis set of a program • Provides s with an upper bound for the number of tests to be conducted • Ensures that all statements have been executed at least once

  31. Cyclomatic Complexity A number of industry studies have indicated that the higher V(G), the higher the probability or errors. modules V(G) modules in this range are more error prone

  32. There are three ways: Computation of Cyclomatic Complexity V(G) for flow - graph G V(G) = P+1 where P - no. of predicate nodes in G V(G) = E - N + 2 where W - no. of edges in G N - no. of nodes in G V(G) = R where R- no. of regions in G Given flow-graph has 4 regions V(G) = 11-9 + 2 = 4 V(G) = 3 + 1 = 4

  33. Independent Path • Any path through the program that introduces at least one new set of processing statements or a new condition • Must move along at least one edge that has not been traversed before the path is defined • Each path introduces a new edge • There are Four paths for the given example: • Path 1: 1-11 • Path 2: 1-2-3-4-5-10-1-11 • Path-3: 1-2-3-6-8-9-10-1-11 • Path 4: 1-2-3-6-7-9-10-1-11

  34. 1 2 3 4 5 6 7 8 Basis Path Testing Next, we derive the independent paths: Since V(G) = 4, there are four paths Path 1: 1,2,3,6,7,8 Path 2: 1,2,3,5,7,8 Path 3: 1,2,4,7,8 Path 4: 1,2,4,7,2,4,...7,8 Finally, we derive test cases to exercise these paths.

  35. Deriving Test Cases • Using the code as the foundation , draw a corresponding flow graph • Determine the cyclomatic complexity of the flow graph • Determine a basis set of linearly independent paths • Prepare test cases that will force execution of each path in the basis set • Execute each test case and compared to expected results • Some paths cannot be tested independently and must be tested as part of another path

  36. Condition Testing • It is a design method that exercises the logical conditions (Consisting of arithmetic, relational and Boolean expressions and operators) in a program module • Types of error found in a condition: • Boolean operator error • Boolean variable error • Boolean parenthesis error • Relational operator error • Arithmetic expression error

  37. Condition Testing • Branch Testing • For a compound condition C, the true and false branches of C and every simple condition in C need to be executed at least once • Domain Testing • Requires three or four tests for a relational expression • To detect errors in E1<relational-operator>E2 • three tests are required to detect error in the operator • putting as minimum possible different values in E1 and E2 will help to detect errors in E1and E2

  38. BRO Testing • All relational operators and boolean variables must occur only once • Uses condition constraint for a condition C which is defined as (D1, D2, …Dn) where Dispecifies thea constraint on he outcome of ith condition of C • Boolean variables have constraint value True or False • For relational expression symbols <,>, = are used to specify the conditions

  39. BRO Testing - Examples Example 1: B1 & B2 C1= (D1,D2) = {(t,t),(t,f),(f,t)} Example 2: B1 & (E3=E4) C2= (D1,D2) = {(t,=),(t,>),(t,<),(f,=)} Example 3: (E1 > E2) & (E3=E4) C2= (D1,D2) = {(>,=),(<,=),(>,>),(>,<),(=,=)}

  40. Dataflow Testing • Selects test paths according to the location of definitions and uses of variables in the program (S-statement no.) • DEF(S) = {X| statement S contains a definition of X} USE(S) = (X| statement S contains a use of X} Assume • For if or loop statement DEF set is always empty • The definition of var X at S is said to be live at statement S’ if the path S-S’ contains no other definition of X • A definition-use chain of var Xis of the form [X,S,S’] where X is DEF(S) and USE(S’) and X is live at S’.

  41. DU Testing • Every DU chain should be covered at least once • Useful for programs with nested if and loop statements • Effective for error-detection • Selecting test-paths is quite difficult • Does not guarantee all branches of a program (e.g. if statement with no else statement and no definition in the then part.

  42. DU Testing proc x b1: do while C1 if C2 then if C4 then B4; else B5; endif; else if C3 then B2; else B3; endif; endif; enddo; B6; end proc; Var X is defined in the last statement of blocks B1, B2, B3, B4, B5 and used in the first statements of B2, B3, B4, B5, B6 There are 25 DU chains of var X We need to cover only five paths from each B1, B2, B3, B4, B5 to B6

  43. Loop Testing • Loops are he cornerstone of vast majority of all software • Focuses exclusively on the validity of loop constructs • Four different classes of loops are defined: • Simple loops • Nested loops • concatenated loops • unstructured loops

  44. Loop Testing Simple loop Nested Loops Concatenated Loops Unstructured Loops

  45. Simple Loops Set of Tests • Skip the loop entirely • Only one pass through the loop • Two passes through the loop • M passes through the loop where m < n (n – max no. pf allowable passes) • N-1, n, n+1 passes throughthe loop

  46. Nested Loops Number of possible test is impractically large if simple loop approach is adopted. • Start at the innermost loop. Set allother loops to minimum value • Conduct simple loop test for the innermost loop while outer loops have the minimum loop counter • Work outward, conducting tests for the next loop , keeping outer loops at minimum value and nested loops at typical values • Continue until all loops have been tested

  47. Concatenated Loops • Simple loop approach can be adopted if each of the loops is independent of the others • If loop counter value of one loop is used as the initial loop counter value of another, then the loops are not independent. In such cases nested loop approach should be adopted

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