Showing 15 of 16 total issues
Cyclomatic complexity for opt_value is too high. [9/6] Open
def opt_value(opt, type = :object, dval = nil)
pos = @args.index(opt)
@args.each_index { |i| pos = i if !pos && opt[0] == @args[i][0] } unless pos
val = @args[pos + 1] if pos
- Read upRead up
- Exclude checks
This cop checks that the cyclomatic complexity of methods is not higher than the configured maximum. The cyclomatic complexity is the number of linearly independent paths through a method. The algorithm counts decision points and adds one.
An if statement (or unless or ?:) increases the complexity by one. An else branch does not, since it doesn't add a decision point. The && operator (or keyword and) can be converted to a nested if statement, and ||/or is shorthand for a sequence of ifs, so they also add one. Loops can be said to have an exit condition, so they add one.
Perceived complexity for normalize_args is too high. [9/7] Open
def normalize_args(args)
@args, @tail, flag = [], [], false
args.each do |opt|
if opt.to_s[0] == '-'
- Read upRead up
- Exclude checks
This cop tries to produce a complexity score that's a measure of the
complexity the reader experiences when looking at a method. For that
reason it considers when
nodes as something that doesn't add as much
complexity as an if
or a &&
. Except if it's one of those special
case
/when
constructs where there's no expression after case
. Then
the cop treats it as an if
/elsif
/elsif
... and lets all the when
nodes count. In contrast to the CyclomaticComplexity cop, this cop
considers else
nodes as adding complexity.
Example:
def my_method # 1
if cond # 1
case var # 2 (0.8 + 4 * 0.2, rounded)
when 1 then func_one
when 2 then func_two
when 3 then func_three
when 4..10 then func_other
end
else # 1
do_something until a && b # 2
end # ===
end # 7 complexity points
Cyclomatic complexity for normalize_args is too high. [8/6] Open
def normalize_args(args)
@args, @tail, flag = [], [], false
args.each do |opt|
if opt.to_s[0] == '-'
- Read upRead up
- Exclude checks
This cop checks that the cyclomatic complexity of methods is not higher than the configured maximum. The cyclomatic complexity is the number of linearly independent paths through a method. The algorithm counts decision points and adds one.
An if statement (or unless or ?:) increases the complexity by one. An else branch does not, since it doesn't add a decision point. The && operator (or keyword and) can be converted to a nested if statement, and ||/or is shorthand for a sequence of ifs, so they also add one. Loops can be said to have an exit condition, so they add one.
Assignment Branch Condition size for normalize_args is too high. [17.58/15] Open
def normalize_args(args)
@args, @tail, flag = [], [], false
args.each do |opt|
if opt.to_s[0] == '-'
- Read upRead up
- Exclude checks
This cop checks that the ABC size of methods is not higher than the configured maximum. The ABC size is based on assignments, branches (method calls), and conditions. See http://c2.com/cgi/wiki?AbcMetric
Method has too many lines. [11/10] Open
def normalize_args(args)
@args, @tail, flag = [], [], false
args.each do |opt|
if opt.to_s[0] == '-'
- Read upRead up
- Exclude checks
This cop checks if the length of a method exceeds some maximum value. Comment lines can optionally be ignored. The maximum allowed length is configurable.
Perceived complexity for opt_value is too high. [8/7] Open
def opt_value(opt, type = :object, dval = nil)
pos = @args.index(opt)
@args.each_index { |i| pos = i if !pos && opt[0] == @args[i][0] } unless pos
val = @args[pos + 1] if pos
- Read upRead up
- Exclude checks
This cop tries to produce a complexity score that's a measure of the
complexity the reader experiences when looking at a method. For that
reason it considers when
nodes as something that doesn't add as much
complexity as an if
or a &&
. Except if it's one of those special
case
/when
constructs where there's no expression after case
. Then
the cop treats it as an if
/elsif
/elsif
... and lets all the when
nodes count. In contrast to the CyclomaticComplexity cop, this cop
considers else
nodes as adding complexity.
Example:
def my_method # 1
if cond # 1
case var # 2 (0.8 + 4 * 0.2, rounded)
when 1 then func_one
when 2 then func_two
when 3 then func_three
when 4..10 then func_other
end
else # 1
do_something until a && b # 2
end # ===
end # 7 complexity points
Assignment Branch Condition size for opt_value is too high. [15.56/15] Open
def opt_value(opt, type = :object, dval = nil)
pos = @args.index(opt)
@args.each_index { |i| pos = i if !pos && opt[0] == @args[i][0] } unless pos
val = @args[pos + 1] if pos
- Read upRead up
- Exclude checks
This cop checks that the ABC size of methods is not higher than the configured maximum. The ABC size is based on assignments, branches (method calls), and conditions. See http://c2.com/cgi/wiki?AbcMetric
Method normalize_args
has a Cognitive Complexity of 14 (exceeds 6 allowed). Consider refactoring. Open
def normalize_args(args)
@args, @tail, flag = [], [], false
args.each do |opt|
if opt.to_s[0] == '-'
- Read upRead up
Cognitive Complexity
Cognitive Complexity is a measure of how difficult a unit of code is to intuitively understand. Unlike Cyclomatic Complexity, which determines how difficult your code will be to test, Cognitive Complexity tells you how difficult your code will be to read and comprehend.
A method's cognitive complexity is based on a few simple rules:
- Code is not considered more complex when it uses shorthand that the language provides for collapsing multiple statements into one
- Code is considered more complex for each "break in the linear flow of the code"
- Code is considered more complex when "flow breaking structures are nested"
Further reading
Method opt_given?
has a Cognitive Complexity of 7 (exceeds 6 allowed). Consider refactoring. Open
def opt_given?(opt)
@args.any? do |arg|
if opt.length == 1 || arg.length == 1
true if arg[0] == opt[0]
else
- Read upRead up
Cognitive Complexity
Cognitive Complexity is a measure of how difficult a unit of code is to intuitively understand. Unlike Cyclomatic Complexity, which determines how difficult your code will be to test, Cognitive Complexity tells you how difficult your code will be to read and comprehend.
A method's cognitive complexity is based on a few simple rules:
- Code is not considered more complex when it uses shorthand that the language provides for collapsing multiple statements into one
- Code is considered more complex for each "break in the linear flow of the code"
- Code is considered more complex when "flow breaking structures are nested"
Further reading
Pass array contents as separate arguments. Open
sh(*%w[rake -f mruby/Rakefile clean]) if Dir.exist? 'mruby'
- Read upRead up
- Exclude checks
This cop checks for unneeded usages of splat expansion
Example:
# bad
a = *[1, 2, 3]
a = *'a'
a = *1
begin
foo
rescue *[StandardError, ApplicationError]
bar
end
case foo
when *[1, 2, 3]
bar
else
baz
end
Example:
# good
c = [1, 2, 3]
a = *c
a, b = *c
a, *b = *c
a = *1..10
a = ['a']
begin
foo
rescue StandardError, ApplicationError
bar
end
case foo
when *[1, 2, 3]
bar
else
baz
end
Pass array contents as separate arguments. Open
sh(*%w[rake -f mruby/Rakefile deep_clean]) if Dir.exist? 'mruby'
- Read upRead up
- Exclude checks
This cop checks for unneeded usages of splat expansion
Example:
# bad
a = *[1, 2, 3]
a = *'a'
a = *1
begin
foo
rescue *[StandardError, ApplicationError]
bar
end
case foo
when *[1, 2, 3]
bar
else
baz
end
Example:
# good
c = [1, 2, 3]
a = *c
a, b = *c
a, *b = *c
a = *1..10
a = ['a']
begin
foo
rescue StandardError, ApplicationError
bar
end
case foo
when *[1, 2, 3]
bar
else
baz
end
Pass array contents as separate arguments. Open
sh(*%w[rake -f mruby/Rakefile test])
- Read upRead up
- Exclude checks
This cop checks for unneeded usages of splat expansion
Example:
# bad
a = *[1, 2, 3]
a = *'a'
a = *1
begin
foo
rescue *[StandardError, ApplicationError]
bar
end
case foo
when *[1, 2, 3]
bar
else
baz
end
Example:
# good
c = [1, 2, 3]
a = *c
a, b = *c
a, *b = *c
a = *1..10
a = ['a']
begin
foo
rescue StandardError, ApplicationError
bar
end
case foo
when *[1, 2, 3]
bar
else
baz
end
Pass array contents as separate arguments. Open
sh(*%w[rake -f mruby/Rakefile all])
- Read upRead up
- Exclude checks
This cop checks for unneeded usages of splat expansion
Example:
# bad
a = *[1, 2, 3]
a = *'a'
a = *1
begin
foo
rescue *[StandardError, ApplicationError]
bar
end
case foo
when *[1, 2, 3]
bar
else
baz
end
Example:
# good
c = [1, 2, 3]
a = *c
a, b = *c
a, *b = *c
a = *1..10
a = ['a']
begin
foo
rescue StandardError, ApplicationError
bar
end
case foo
when *[1, 2, 3]
bar
else
baz
end
Pass array contents as separate arguments. Open
sh(*%w[git clone --depth 1 https://github.com/mruby/mruby.git])
- Read upRead up
- Exclude checks
This cop checks for unneeded usages of splat expansion
Example:
# bad
a = *[1, 2, 3]
a = *'a'
a = *1
begin
foo
rescue *[StandardError, ApplicationError]
bar
end
case foo
when *[1, 2, 3]
bar
else
baz
end
Example:
# good
c = [1, 2, 3]
a = *c
a, b = *c
a, *b = *c
a = *1..10
a = ['a']
begin
foo
rescue StandardError, ApplicationError
bar
end
case foo
when *[1, 2, 3]
bar
else
baz
end
Pass array contents as separate arguments. Open
sh(*%w[git clone --depth 1 https://github.com/mruby/mruby.git -b stable])
- Read upRead up
- Exclude checks
This cop checks for unneeded usages of splat expansion
Example:
# bad
a = *[1, 2, 3]
a = *'a'
a = *1
begin
foo
rescue *[StandardError, ApplicationError]
bar
end
case foo
when *[1, 2, 3]
bar
else
baz
end
Example:
# good
c = [1, 2, 3]
a = *c
a, b = *c
a, *b = *c
a = *1..10
a = ['a']
begin
foo
rescue StandardError, ApplicationError
bar
end
case foo
when *[1, 2, 3]
bar
else
baz
end