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require 'test/unit'
require 'fiber'
require 'continuation'
require_relative './envutil'
class TestFiber < Test::Unit::TestCase
def test_normal
f = Fiber.current
assert_equal(:ok2,
Fiber.new{|e|
assert_equal(:ok1, e)
Fiber.yield :ok2
}.resume(:ok1)
)
assert_equal([:a, :b], Fiber.new{|a, b| [a, b]}.resume(:a, :b))
end
def test_argument
assert_equal(4, Fiber.new {|i=4| i}.resume)
end
def test_term
assert_equal(:ok, Fiber.new{:ok}.resume)
assert_equal([:a, :b, :c, :d, :e],
Fiber.new{
Fiber.new{
Fiber.new{
Fiber.new{
[:a]
}.resume + [:b]
}.resume + [:c]
}.resume + [:d]
}.resume + [:e])
end
def test_many_fibers
max = 10000
assert_equal(max, max.times{
Fiber.new{}
})
assert_equal(max,
max.times{|i|
Fiber.new{
}.resume
}
)
end
def test_many_fibers_with_threads
assert_normal_exit %q{
max = 1000
@cnt = 0
(1..100).map{|ti|
Thread.new{
max.times{|i|
Fiber.new{
@cnt += 1
}.resume
}
}
}.each{|t|
t.join
}
}
end
def test_error
assert_raise(ArgumentError){
Fiber.new # Fiber without block
}
assert_raise(FiberError){
f = Fiber.new{}
Thread.new{f.resume}.join # Fiber yielding across thread
}
assert_raise(FiberError){
f = Fiber.new{}
f.resume
f.resume
}
assert_raise(RuntimeError){
f = Fiber.new{
@c = callcc{|c| @c = c}
}.resume
@c.call # cross fiber callcc
}
assert_raise(RuntimeError){
Fiber.new{
raise
}.resume
}
assert_raise(FiberError){
Fiber.yield
}
assert_raise(FiberError){
fib = Fiber.new{
fib.resume
}
fib.resume
}
assert_raise(FiberError){
fib = Fiber.new{
Fiber.new{
fib.resume
}.resume
}
fib.resume
}
end
def test_return
assert_raise(LocalJumpError){
Fiber.new do
return
end.resume
}
end
def test_throw
assert_raise(ArgumentError){
Fiber.new do
throw :a
end.resume
}
end
def test_transfer
ary = []
f2 = nil
f1 = Fiber.new{
ary << f2.transfer(:foo)
:ok
}
f2 = Fiber.new{
ary << f1.transfer(:baz)
:ng
}
assert_equal(:ok, f1.transfer)
assert_equal([:baz], ary)
end
def test_tls
#
def tvar(var, val)
old = Thread.current[var]
begin
Thread.current[var] = val
yield
ensure
Thread.current[var] = old
end
end
fb = Fiber.new {
assert_equal(nil, Thread.current[:v]); tvar(:v, :x) {
assert_equal(:x, Thread.current[:v]); Fiber.yield
assert_equal(:x, Thread.current[:v]); }
assert_equal(nil, Thread.current[:v]); Fiber.yield
raise # unreachable
}
assert_equal(nil, Thread.current[:v]); tvar(:v,1) {
assert_equal(1, Thread.current[:v]); tvar(:v,3) {
assert_equal(3, Thread.current[:v]); fb.resume
assert_equal(3, Thread.current[:v]); }
assert_equal(1, Thread.current[:v]); }
assert_equal(nil, Thread.current[:v]); fb.resume
assert_equal(nil, Thread.current[:v]);
end
def test_alive
fib = Fiber.new{Fiber.yield}
assert_equal(true, fib.alive?)
fib.resume
assert_equal(true, fib.alive?)
fib.resume
assert_equal(false, fib.alive?)
end
def test_resume_self
f = Fiber.new {f.resume}
assert_raise(FiberError, '[ruby-core:23651]') {f.transfer}
end
def test_fiber_transfer_segv
assert_normal_exit %q{
require 'fiber'
f2 = nil
f1 = Fiber.new{ f2.resume }
f2 = Fiber.new{ f1.resume }
f1.transfer
}, '[ruby-dev:40833]'
assert_normal_exit %q{
require 'fiber'
Fiber.new{}.resume
1.times{Fiber.current.transfer}'
}
end
def test_resume_root_fiber
assert_raise(FiberError) do
Thread.new do
Fiber.current.resume
end.join
end
end
def test_gc_root_fiber
bug4612 = '[ruby-core:35891]'
assert_normal_exit %q{
require 'fiber'
GC.stress = true
Thread.start{ Fiber.current; nil }.join
GC.start
}, bug4612
end
def test_no_valid_cfp
bug5083 = '[ruby-dev:44208]'
assert_equal([], Fiber.new(&Module.method(:nesting)).resume)
error = assert_raise(RuntimeError) do
Fiber.new(&Module.method(:undef_method)).resume(:to_s)
end
assert_equal("Can't call on top of Fiber or Thread", error.message, bug5083)
end
def test_prohibit_resume_transfered_fiber
assert_raise(FiberError){
root_fiber = Fiber.current
f = Fiber.new{
root_fiber.transfer
}
f.transfer
f.resume
}
assert_raise(FiberError){
g=nil
f=Fiber.new{
g.resume
g.resume
}
g=Fiber.new{
f.resume
f.resume
}
f.transfer
}
end
def test_fork_from_fiber
begin
Process.fork{}
rescue NotImplementedError
return
end
bug5700 = '[ruby-core:41456]'
pid = nil
assert_nothing_raised(bug5700) do
Fiber.new{ pid = fork {} }.resume
end
pid, status = Process.waitpid2(pid)
assert_equal(0, status.exitstatus, bug5700)
assert_equal(false, status.signaled?, bug5700)
end
end
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