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ruby--ruby/test/ruby/test_thread.rb
ko1 0f9b33c793 * thread.c: rename methods:
from Thread.async_interrupt_timing to Thread.handle_interrupt,
  from Thread.async_interrupted? to Thread.pending_interrupt?.
  Also rename option from `defer' to `never'.
  [ruby-core:51074] [ruby-trunk - Feature #6762]
* vm_core.c, thread.c: rename functions and data structure
  `async_errinfo' to `pending_interrupt'.
* thread.c: add global variables sym_immediate, sym_on_blocking and
  sym_never.
* cont.c, process.c, vm.c, signal.c: ditto.
* lib/sync.rb, lib/thread.rb: catch up this renaming.
* test/ruby/test_thread.rb: ditto.



git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@38577 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2012-12-23 10:18:58 +00:00

918 lines
20 KiB
Ruby

# -*- coding: us-ascii -*-
require 'test/unit'
require 'thread'
require_relative 'envutil'
class TestThread < Test::Unit::TestCase
class Thread < ::Thread
Threads = []
def self.new(*)
th = super
Threads << th
th
end
end
def setup
Thread::Threads.clear
end
def teardown
Thread::Threads.each do |t|
t.kill if t.alive?
begin
t.join
rescue Exception
end
end
end
def test_main_thread_variable_in_enumerator
assert_equal Thread.main, Thread.current
Thread.current.thread_variable_set :foo, "bar"
thread, value = Fiber.new {
Fiber.yield [Thread.current, Thread.current.thread_variable_get(:foo)]
}.resume
assert_equal Thread.current, thread
assert_equal Thread.current.thread_variable_get(:foo), value
end
def test_thread_variable_in_enumerator
Thread.new {
Thread.current.thread_variable_set :foo, "bar"
thread, value = Fiber.new {
Fiber.yield [Thread.current, Thread.current.thread_variable_get(:foo)]
}.resume
assert_equal Thread.current, thread
assert_equal Thread.current.thread_variable_get(:foo), value
}.join
end
def test_thread_variables
assert_equal [], Thread.new { Thread.current.thread_variables }.join.value
t = Thread.new {
Thread.current.thread_variable_set(:foo, "bar")
Thread.current.thread_variables
}
assert_equal [:foo], t.join.value
end
def test_thread_variable?
refute Thread.new { Thread.current.thread_variable?("foo") }.join.value
t = Thread.new {
Thread.current.thread_variable_set("foo", "bar")
}.join
assert t.thread_variable?("foo")
assert t.thread_variable?(:foo)
refute t.thread_variable?(:bar)
end
def test_thread_variable_strings_and_symbols_are_the_same_key
t = Thread.new {}.join
t.thread_variable_set("foo", "bar")
assert_equal "bar", t.thread_variable_get(:foo)
end
def test_thread_variable_frozen
t = Thread.new { }.join
t.freeze
assert_raises(RuntimeError) do
t.thread_variable_set(:foo, "bar")
end
end
def test_thread_variable_security
t = Thread.new { sleep }
assert_raises(SecurityError) do
Thread.new { $SAFE = 4; t.thread_variable_get(:foo) }.join
end
assert_raises(SecurityError) do
Thread.new { $SAFE = 4; t.thread_variable_set(:foo, :baz) }.join
end
end
def test_mutex_synchronize
m = Mutex.new
r = 0
max = 10
(1..max).map{
Thread.new{
i=0
while i<max*max
i+=1
m.synchronize{
r += 1
}
end
}
}.each{|e|
e.join
}
assert_equal(max * max * max, r)
end
def test_local_barrier
dir = File.dirname(__FILE__)
lbtest = File.join(dir, "lbtest.rb")
$:.unshift File.join(File.dirname(dir), 'ruby')
require 'envutil'
$:.shift
3.times {
`#{EnvUtil.rubybin} #{lbtest}`
assert_not_predicate($?, :coredump?, '[ruby-dev:30653]')
}
end
def test_priority
c1 = c2 = 0
t1 = Thread.new { loop { c1 += 1 } }
t1.priority = 3
t2 = Thread.new { loop { c2 += 1 } }
t2.priority = -3
assert_equal(3, t1.priority)
assert_equal(-3, t2.priority)
sleep 0.5
5.times do
break if c1 > c2
sleep 0.1
end
t1.kill
t2.kill
assert_operator(c1, :>, c2, "[ruby-dev:33124]") # not guaranteed
end
def test_new
assert_raise(ThreadError) do
Thread.new
end
t1 = Thread.new { sleep }
assert_raise(ThreadError) do
t1.instance_eval { initialize { } }
end
t2 = Thread.new(&method(:sleep).to_proc)
assert_raise(ThreadError) do
t2.instance_eval { initialize { } }
end
ensure
t1.kill if t1
t2.kill if t2
end
def test_join
t = Thread.new { sleep }
assert_nil(t.join(0.5))
ensure
t.kill if t
end
def test_join2
t1 = Thread.new { sleep(1.5) }
t2 = Thread.new do
t1.join(1)
end
t3 = Thread.new do
sleep 0.5
t1.join
end
assert_nil(t2.value)
assert_equal(t1, t3.value)
ensure
t1.kill if t1
t2.kill if t2
t3.kill if t3
end
def test_kill_main_thread
assert_in_out_err([], <<-INPUT, %w(1), [])
p 1
Thread.kill Thread.current
p 2
INPUT
end
def test_kill_wrong_argument
bug4367 = '[ruby-core:35086]'
assert_raise(TypeError, bug4367) {
Thread.kill(nil)
}
o = Object.new
assert_raise(TypeError, bug4367) {
Thread.kill(o)
}
end
def test_kill_thread_subclass
c = Class.new(Thread)
t = c.new { sleep 10 }
assert_nothing_raised { Thread.kill(t) }
assert_equal(nil, t.value)
end
def test_exit
s = 0
Thread.new do
s += 1
Thread.exit
s += 2
end.join
assert_equal(1, s)
end
def test_wakeup
s = 0
t = Thread.new do
s += 1
Thread.stop
s += 1
end
sleep 0.5
assert_equal(1, s)
t.wakeup
sleep 0.5
assert_equal(2, s)
assert_raise(ThreadError) { t.wakeup }
ensure
t.kill if t
end
def test_stop
assert_in_out_err([], <<-INPUT, %w(2), [])
begin
Thread.stop
p 1
rescue ThreadError
p 2
end
INPUT
end
def test_list
assert_in_out_err([], <<-INPUT) do |r, e|
t1 = Thread.new { sleep }
Thread.pass
t2 = Thread.new { loop { } }
Thread.new { }.join
p [Thread.current, t1, t2].map{|t| t.object_id }.sort
p Thread.list.map{|t| t.object_id }.sort
INPUT
assert_equal(r.first, r.last)
assert_equal([], e)
end
end
def test_main
assert_in_out_err([], <<-INPUT, %w(true false), [])
p Thread.main == Thread.current
Thread.new { p Thread.main == Thread.current }.join
INPUT
end
def test_abort_on_exception
assert_in_out_err([], <<-INPUT, %w(false 1), [])
p Thread.abort_on_exception
begin
Thread.new { raise }
sleep 0.5
p 1
rescue
p 2
end
INPUT
assert_in_out_err([], <<-INPUT, %w(true 2), [])
Thread.abort_on_exception = true
p Thread.abort_on_exception
begin
Thread.new { raise }
sleep 0.5
p 1
rescue
p 2
end
INPUT
assert_in_out_err(%w(--disable-gems -d), <<-INPUT, %w(false 2), %r".+")
p Thread.abort_on_exception
begin
Thread.new { raise }
sleep 0.5
p 1
rescue
p 2
end
INPUT
assert_in_out_err([], <<-INPUT, %w(false true 2), [])
p Thread.abort_on_exception
begin
t = Thread.new { sleep 0.5; raise }
t.abort_on_exception = true
p t.abort_on_exception
sleep 1
p 1
rescue
p 2
end
INPUT
end
def test_status_and_stop_p
a = ::Thread.new { raise("die now") }
b = Thread.new { Thread.stop }
c = Thread.new { Thread.exit }
e = Thread.current
sleep 0.5
assert_equal(nil, a.status)
assert_predicate(a, :stop?)
assert_equal("sleep", b.status)
assert_predicate(b, :stop?)
assert_equal(false, c.status)
assert_match(/^#<TestThread::Thread:.* dead>$/, c.inspect)
assert_predicate(c, :stop?)
es1 = e.status
es2 = e.stop?
assert_equal(["run", false], [es1, es2])
ensure
a.kill if a
b.kill if b
c.kill if c
end
def test_safe_level
t = Thread.new { $SAFE = 3; sleep }
sleep 0.5
assert_equal(0, Thread.current.safe_level)
assert_equal(3, t.safe_level)
ensure
t.kill if t
end
def test_thread_local
t = Thread.new { sleep }
assert_equal(false, t.key?(:foo))
t["foo"] = "foo"
t["bar"] = "bar"
t["baz"] = "baz"
assert_equal(true, t.key?(:foo))
assert_equal(true, t.key?("foo"))
assert_equal(false, t.key?(:qux))
assert_equal(false, t.key?("qux"))
assert_equal([:foo, :bar, :baz], t.keys)
ensure
t.kill if t
end
def test_thread_local_security
t = Thread.new { sleep }
assert_raise(SecurityError) do
Thread.new { $SAFE = 4; t[:foo] }.join
end
assert_raise(SecurityError) do
Thread.new { $SAFE = 4; t[:foo] = :baz }.join
end
assert_raise(RuntimeError) do
Thread.new do
Thread.current[:foo] = :bar
Thread.current.freeze
Thread.current[:foo] = :baz
end.join
end
end
def test_select_wait
assert_nil(IO.select(nil, nil, nil, 1))
t = Thread.new do
IO.select(nil, nil, nil, nil)
end
sleep 0.5
t.kill
end
def test_mutex_deadlock
m = Mutex.new
m.synchronize do
assert_raise(ThreadError) do
m.synchronize do
assert(false)
end
end
end
end
def test_mutex_interrupt
m = Mutex.new
m.lock
t = Thread.new do
m.lock
:foo
end
sleep 0.5
t.kill
assert_nil(t.value)
end
def test_mutex_illegal_unlock
m = Mutex.new
m.lock
assert_raise(ThreadError) do
Thread.new do
m.unlock
end.join
end
end
def test_mutex_fifo_like_lock
m1 = Mutex.new
m2 = Mutex.new
m1.lock
m2.lock
m1.unlock
m2.unlock
assert_equal(false, m1.locked?)
assert_equal(false, m2.locked?)
m3 = Mutex.new
m1.lock
m2.lock
m3.lock
m1.unlock
m2.unlock
m3.unlock
assert_equal(false, m1.locked?)
assert_equal(false, m2.locked?)
assert_equal(false, m3.locked?)
end
def test_mutex_trylock
m = Mutex.new
assert_equal(true, m.try_lock)
assert_equal(false, m.try_lock, '[ruby-core:20943]')
Thread.new{
assert_equal(false, m.try_lock)
}.join
m.unlock
end
def test_recursive_outer
arr = []
obj = Struct.new(:foo, :visited).new(arr, false)
arr << obj
def obj.hash
self[:visited] = true
super
raise "recursive_outer should short circuit intermediate calls"
end
assert_nothing_raised {arr.hash}
assert(obj[:visited], "obj.hash was not called")
end
def test_thread_instance_variable
bug4389 = '[ruby-core:35192]'
assert_in_out_err([], <<-INPUT, %w(), [], bug4389)
class << Thread.current
@data = :data
end
INPUT
end
def test_no_valid_cfp
skip 'with win32ole, cannot run this testcase because win32ole redefines Thread#intialize' if defined?(WIN32OLE)
bug5083 = '[ruby-dev:44208]'
assert_equal([], Thread.new(&Module.method(:nesting)).value)
error = assert_raise(RuntimeError) do
Thread.new(:to_s, &Module.method(:undef_method)).join
end
assert_equal("Can't call on top of Fiber or Thread", error.message, bug5083)
end
def make_handle_interrupt_test_thread1 flag
r = []
ready_p = false
th = Thread.new{
begin
Thread.handle_interrupt(RuntimeError => flag){
begin
ready_p = true
sleep 0.5
rescue
r << :c1
end
}
rescue
r << :c2
end
}
Thread.pass until ready_p
th.raise
begin
th.join
rescue
r << :c3
end
r
end
def test_handle_interrupt
[[:never, :c2],
[:immediate, :c1],
[:on_blocking, :c1]].each{|(flag, c)|
assert_equal([flag, c], [flag] + make_handle_interrupt_test_thread1(flag))
}
# TODO: complex cases are needed.
end
def test_handle_interrupt_invalid_argument
assert_raise(ArgumentError) {
Thread.handle_interrupt(RuntimeError => :immediate) # no block
}
assert_raise(ArgumentError) {
Thread.handle_interrupt(RuntimeError => :xyzzy) {}
}
assert_raise(TypeError) {
Thread.handle_interrupt([]) {} # array
}
end
def for_test_handle_interrupt_with_return
Thread.handle_interrupt(Object => :never){
Thread.current.raise RuntimeError.new("have to be rescured")
return
}
rescue
end
def test_handle_interrupt_with_return
assert_nothing_raised do
for_test_handle_interrupt_with_return
_dummy_for_check_ints=nil
end
end
def test_handle_interrupt_with_break
assert_nothing_raised do
begin
Thread.handle_interrupt(Object => :never){
Thread.current.raise RuntimeError.new("have to be rescured")
break
}
rescue
end
_dummy_for_check_ints=nil
end
end
def test_handle_interrupt_blocking
r=:ng
e=Class.new(Exception)
th_s = Thread.current
begin
th = Thread.start{
Thread.handle_interrupt(Object => :on_blocking){
begin
Thread.current.raise RuntimeError
r=:ok
sleep
ensure
th_s.raise e
end
}
}
sleep 1
r=:ng
th.raise RuntimeError
th.join
rescue e
end
assert_equal(:ok,r)
end
def test_handle_interrupt_and_io
assert_in_out_err([], <<-INPUT, %w(ok), [])
th_waiting = true
t = Thread.new {
Thread.handle_interrupt(RuntimeError => :on_blocking) {
nil while th_waiting
# async interrupt should be raised _before_ writing puts arguments
puts "ng"
}
}
sleep 0.1
t.raise RuntimeError
th_waiting = false
t.join rescue nil
puts "ok"
INPUT
end
def test_handle_interrupt_and_p
assert_in_out_err([], <<-INPUT, %w(:ok :ok), [])
th_waiting = true
t = Thread.new {
Thread.handle_interrupt(RuntimeError => :on_blocking) {
nil while th_waiting
# p shouldn't provide interruptible point
p :ok
p :ok
}
}
sleep 0.1
t.raise RuntimeError
th_waiting = false
t.join rescue nil
INPUT
end
def test_handle_interrupted?
q = Queue.new
Thread.handle_interrupt(RuntimeError => :never){
th = Thread.new{
q.push :e
begin
begin
sleep 0.5
rescue => e
q.push :ng1
end
begin
Thread.handle_interrupthandle_interrupt(Object => :immediate){} if Thread.pending_interrupt?
rescue => e
q.push :ok
end
rescue => e
q.push :ng2
ensure
q.push :ng3
end
}
q.pop
th.raise
th.join
assert_equal(:ok, q.pop)
}
end
def test_thread_timer_and_ensure
assert_normal_exit(<<_eom, 'r36492', timeout: 3)
flag = false
t = Thread.new do
begin
sleep
ensure
1 until flag
end
end
Thread.pass until t.status == "sleep"
t.kill
t.alive? == true
flag = true
t.join
_eom
end
def test_uninitialized
c = Class.new(Thread)
c.class_eval { def initialize; end }
assert_raise(ThreadError) { c.new.start }
end
def test_backtrace
Thread.new{
assert_equal(Array, Thread.main.backtrace.class)
}.join
t = Thread.new{}
t.join
assert_equal(nil, t.backtrace)
end
def test_thread_timer_and_interrupt
bug5757 = '[ruby-dev:44985]'
t0 = Time.now.to_f
pid = nil
cmd = 'r,=IO.pipe; Thread.start {Thread.pass until Thread.main.stop?; puts; STDOUT.flush}; r.read'
opt = {}
opt[:new_pgroup] = true if /mswin|mingw/ =~ RUBY_PLATFORM
s, _err = EnvUtil.invoke_ruby(['-e', cmd], "", true, true, opt) do |in_p, out_p, err_p, cpid|
out_p.gets
pid = cpid
Process.kill(:SIGINT, pid)
Process.wait(pid)
[$?, err_p.read]
end
t1 = Time.now.to_f
assert_equal(pid, s.pid, bug5757)
unless /mswin|mingw/ =~ RUBY_PLATFORM
# status of signal is not supported on Windows
assert_equal([false, true, false, Signal.list["INT"]],
[s.exited?, s.signaled?, s.stopped?, s.termsig],
"[s.exited?, s.signaled?, s.stopped?, s.termsig]")
end
assert_in_delta(t1 - t0, 1, 1, bug5757)
end
def test_thread_join_in_trap
assert_nothing_raised{
t = Thread.new{ sleep 0.2; Process.kill(:INT, $$) }
Signal.trap :INT do
t.join
end
t.join
}
assert_equal(:normal_end,
begin
t = Thread.new{ sleep 0.2; Process.kill(:INT, $$); :normal_end }
Signal.trap :INT do
t.value
end
t.value
end
)
end
def test_thread_join_current
assert_raises(ThreadError) do
Thread.current.join
end
end
def test_thread_join_main_thread
assert_raises(ThreadError) do
Thread.new(Thread.current) {|t|
t.join
}.join
end
end
def test_main_thread_status_at_exit
assert_in_out_err([], <<-INPUT, %w(false), [])
Thread.new(Thread.current) {|mth|
begin
sleep 0.1
ensure
p mth.alive?
end
}
INPUT
end
def test_thread_status_in_trap
# when running trap handler, Thread#status must show "run"
# Even though interrupted from sleeping function
assert_in_out_err([], <<-INPUT, %w(sleep run), [])
Signal.trap(:INT) {
puts Thread.current.status
}
Thread.new(Thread.current) {|mth|
sleep 0.01
puts mth.status
Process.kill(:INT, $$)
}
sleep 0.1
INPUT
end
# Bug #7450
def test_thread_status_raise_after_kill
ary = []
t = Thread.new {
begin
ary << Thread.current.status
sleep #1
ensure
begin
ary << Thread.current.status
sleep #2
ensure
ary << Thread.current.status
end
end
}
begin
sleep 0.01
t.kill # wake up sleep #1
sleep 0.01
t.raise "wakeup" # wake up sleep #2
sleep 0.01
assert_equal(ary, ["run", "aborting", "aborting"])
ensure
t.join rescue nil
end
end
def test_mutex_owned
mutex = Mutex.new
assert_equal(mutex.owned?, false)
mutex.synchronize {
# Now, I have the mutex
assert_equal(mutex.owned?, true)
}
assert_equal(mutex.owned?, false)
end
def test_mutex_owned2
begin
mutex = Mutex.new
th = Thread.new {
# lock forever
mutex.lock
sleep
}
sleep 0.01 until th.status == "sleep"
# acquired another thread.
assert_equal(mutex.locked?, true)
assert_equal(mutex.owned?, false)
ensure
th.kill if th
end
end
def invoke_rec script, vm_stack_size, machine_stack_size, use_length = true
env = {}
env['RUBY_THREAD_VM_STACK_SIZE'] = vm_stack_size.to_s if vm_stack_size
env['RUBY_THREAD_MACHINE_STACK_SIZE'] = machine_stack_size.to_s if machine_stack_size
out, = EnvUtil.invoke_ruby([env, '-e', script], '', true, true)
use_length ? out.length : out
end
def test_stack_size
h_default = eval(invoke_rec('p RubyVM::DEFAULT_PARAMS', nil, nil, false))
h_0 = eval(invoke_rec('p RubyVM::DEFAULT_PARAMS', 0, 0, false))
h_large = eval(invoke_rec('p RubyVM::DEFAULT_PARAMS', 1024 * 1024 * 10, 1024 * 1024 * 10, false))
assert_operator(h_default[:thread_vm_stack_size], :>, h_0[:thread_vm_stack_size],
"0 thread_vm_stack_size")
assert_operator(h_default[:thread_vm_stack_size], :<, h_large[:thread_vm_stack_size],
"large thread_vm_stack_size")
assert_operator(h_default[:thread_machine_stack_size], :>=, h_0[:thread_machine_stack_size],
"0 thread_machine_stack_size")
assert_operator(h_default[:thread_machine_stack_size], :<=, h_large[:thread_machine_stack_size],
"large thread_machine_stack_size")
# check VM machine stack size
script = 'def rec; print "."; STDOUT.flush; rec; end; rec'
size_default = invoke_rec script, nil, nil
assert_operator(size_default, :>, 0, "default size")
size_0 = invoke_rec script, 0, nil
assert_operator(size_default, :>, size_0, "0 size")
size_large = invoke_rec script, 1024 * 1024 * 10, nil
assert_operator(size_default, :<, size_large, "large size")
return if /mswin|mingw/ =~ RUBY_PLATFORM
# check machine stack size
# Note that machine stack size may not change size (depend on OSs)
script = 'def rec; print "."; STDOUT.flush; 1.times{1.times{1.times{rec}}}; end; Thread.new{rec}.join'
vm_stack_size = 1024 * 1024
size_default = invoke_rec script, vm_stack_size, nil
size_0 = invoke_rec script, vm_stack_size, 0
assert_operator(size_default, :>=, size_0, "0 size")
size_large = invoke_rec script, vm_stack_size, 1024 * 1024 * 10
assert_operator(size_default, :<=, size_large, "large size")
end
end