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Agenda
• Background and Motivation
• qEstimation Analysis
– Test Size Estimation (Test Case Point Analysis)
– Test Effort Estimation
• Conclusion
2
Background
• Software estimation – process of determining the cost, time, staff, and other related
attributes of software projects, often before work is performed
• Estimation is important for the success or failure of software projects
• Methods and Metrics – Source Lines of Code (SLOC)
– Function Points
– Use Case Points
– Story Points
– COCOMO – Expert Judgment
3
Motivation
• Testing accounts for up to 50% of project effort [1]
• Current problems – estimates are done for the whole project rather than testing
specific
– lack of reliable methods designed for estimating size and effort of software testing
– vague definitions of testing productivity • due to the lack of a size measure for software testing
• Our aim – To introduce a method for estimating the size of testing
activities
– To discuss methods to estimate testing effort using this size measure
– To introduce a simple toolkit for this estimation process
4
Agenda
• Background and Motivation
• qEstimation Analysis
– Test Size Estimation (Test Case Point Analysis)
– Test Effort Estimation
• Conclusion
5
qEstimation Analysis’ Principles
• Size reflects the mass and complexity of each test cycle of a testing project
• Test case’s complexity is based on – Number of checkpoints
– Complexity of test setup or precondition
– Complexity of test data
• Test Case Point (TCP) is used as size unit – representing the size of the most simple test case
• Calibration or model refinement is key to estimating effort – calibration based on feedback from different cycles within
project or of similar projects
• Focusing on independent testing (V & V)
6
Test Case
qEstimation Analysis’ Process
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Test Case Count TCPs of all Test
Cases
Estimate Testing Effort
Parameters
Counted Size
Estimated Effort
[Test Cycle i]
Test Cycle Size Actual Effort
Effort by Activity
…. …. …. ….
Test cycle i …. …. ….
…. …. …. ….
Historical Data of this Project
Update Historical
Data
Calibrate Estimation
Model
Estimate size and effort of different test cycles of a same project:
Count Size of Test Cycle
• Size of a test cycle is the total of TCPs of all test cases to be executed in that test cycle
• Steps:
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Test Case
Count Checkpoints
Determine Set Up Complexity
Determine Test Data Complexity
Adjust based on Test Type (optional)
Unadjusted TCPs
TCPs
Count Size of Test Cycle (cont’d)
• Checkpoints
– Checkpoint is the condition in which the tester verifies whether the result produced by the target function matches the expected criterion
– One test case consists of one or many checkpoints
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One checkpoint is counted as one TCP
Count Size of Test Cycle (cont’d)
• Test Setup or Precondition – Test setup specifies the condition to execute the test case
• Include setup steps to prepare environment for testing
• Mainly affect the cost to execute the test case
• May be related to data prepared for the test case
– Four levels of Test Setup complexity • Each is assigned a number of TCPs
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Number of TCP(*)
Complexity Level
Description
0 None • The set up is not applicable or important to execute the test case • Or, the set up is just reused from the previous test case to continue the current test case
1 Low • The condition for executing the test case is available with some simple modifications required • Or, some simple set-up steps are needed
3 Medium • Some explicit preparation is needed to execute the test case • Or, The condition for executing is available with some additional modifications required • Or, some additional set-up steps are needed
5 High • Heavy hardware and/or software configurations are needed to execute the test case
(*) based on our survey of 18 senior QA engineers. You can adjust according to your project’s experience.
Count Size of Test Cycle (cont’d)
• Test Data – Test Data is used to execute the test case
• It can be generated at the test case execution time, sourced from previous tests, or generated by test scripts
• Test data is test case specific, or general to a group of test cases
– Four levels of Test Data complexity • Each is assigned a number of TCPs
Number of TCP (*)
Complexity Level
Description
0 None • No test data preparation is needed
1 Low • Simple test data is needed and can be created during the test case execution time • Or, the test case uses a slightly modified version of existing test data and requires
little or no effort to modify the test data
3 Medium • Test data is deliberately prepared in advance with extra effort to ensure its completeness, comprehensiveness, and consistency
6 High • Test data is prepared in advance with considerable effort to ensure its completeness, comprehensiveness, and consistency
• This could include using support tools to generate data and a database to store and manage test data
• Scripts may be required to generate test data
(*) based on our survey of 18 senior QA engineers. You can adjust according to your project’s experience.
Count Size of Test Cycle (cont’d)
• Adjust TCPs based on Type of Test – This is an OPTIONAL step
– Adjustment is based on types of test cases
• Each type of test case is assigned a weight
• Adjusted TCP of the test case = Counted TCP x Weight(*)
12
(*) based on our survey of 18 senior QA engineers. You can adjust according to your project’s experience.
Estimate Effort of Test Cycle
• Overview
– Two estimation methods • Based on Test Velocity
• Regression analysis of Size and Effort of completed test cycles
– Effort distributed by activity • Test Planning
• Test Analysis and Design
• Test Execution
• Test Tracking and Reporting
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Each of these activities may be performed multiple times
Estimate Effort of Test Cycle (cont’d)
• Estimate Effort based on Test Velocity
Effort(person-hour) = Size(TCP) / Test Velocity (TCP per person-hour)
– Test Velocity is measured as TCP/person-hour
• dependent on project
• calculated based on data from completed test cycles of the same project
14
Estimate Effort of Test Cycle (cont’d)
• Estimate effort using Linear Regression Analysis – Find out the equation of effort and size using similar completed test
cycles of a project
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y = 0.0729x + 1.6408
0
10
20
30
40
50
60
70
80
90
100
0 100 200 300 400 500 600 700 800 900 1000
Eff
ort
(P
M)
Adjusted TCP
Equation of Size and Effort
The data analysis tool like Excel can be used to find out the equation
Calibrate the qEstimation Estimation Model
• Calibration: a process adjusting parameters for a model using historical data or experiences
• With qEstimation, you can calibrate:
(1) TCP assigned to each complexity level of Test Setup
(2) TCP assigned to each complexity level of Test Data
(3) Test Velocity
(4) Effort distribution
(5) Weights of test case types
• Process can be done with the help of tools
16
Tool Demo
Conclusion
• qEstimation Analysis is an agile approach to estimating size and effort of test cycle – Estimate Size in TCP
– Estimate Effort using Test Velocity or Regression
– An Excel toolkit to simplify the approach
• Advantages and experiences learned – Easy to implement
– Reflecting real complexity of test cases
– Independent with the level of details of test cases
– Found useful for estimating testing effort
• Limitations and future improvements – A new approach
– Need more empirical validations
17
Thank You
References
• [1] Y. Yang, Q. Li, M. Li, Q. Wang, “An empirical analysis on distribution patterns of software maintenance effort”, International Conference on Software Maintenance, 2008, pp. 456-459
• [2] N. Patel, M. Govindrajan, S. Maharana, S. Ramdas, “Test Case Point Analysis”, Cognizant Technology Solutions, White Paper, 2001
• [3] QASymphony: www.qasymphony.com
• [4] V. Lam, “Estimable”, Professional Tester, http://www.professionaltester.com/magazine/backissue/PT015/ProfessionalTester-July2012-Lam.pdf
• [5] QASymphony, “Test Case Point Analysis”, White Paper and Tool http://www.qasymphony.com/white-papers.html
