Protocol Buffers - Google's data interchange format (grpc依赖) https://developers.google.com/protocol-buffers/
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#!/usr/bin/ruby
require 'google/protobuf'
require 'json'
require 'test/unit'
# ------------- generated code --------------
module BasicTest
pool = Google::Protobuf::DescriptorPool.new
pool.build do
add_message "Foo" do
optional :bar, :message, 1, "Bar"
repeated :baz, :message, 2, "Baz"
end
add_message "Bar" do
optional :msg, :string, 1
end
add_message "Baz" do
optional :msg, :string, 1
end
add_message "TestMessage" do
optional :optional_int32, :int32, 1
optional :optional_int64, :int64, 2
optional :optional_uint32, :uint32, 3
optional :optional_uint64, :uint64, 4
optional :optional_bool, :bool, 5
optional :optional_float, :float, 6
optional :optional_double, :double, 7
optional :optional_string, :string, 8
optional :optional_bytes, :bytes, 9
optional :optional_msg, :message, 10, "TestMessage2"
optional :optional_enum, :enum, 11, "TestEnum"
repeated :repeated_int32, :int32, 12
repeated :repeated_int64, :int64, 13
repeated :repeated_uint32, :uint32, 14
repeated :repeated_uint64, :uint64, 15
repeated :repeated_bool, :bool, 16
repeated :repeated_float, :float, 17
repeated :repeated_double, :double, 18
repeated :repeated_string, :string, 19
repeated :repeated_bytes, :bytes, 20
repeated :repeated_msg, :message, 21, "TestMessage2"
repeated :repeated_enum, :enum, 22, "TestEnum"
end
add_message "TestMessage2" do
optional :foo, :int32, 1
end
add_message "TestEmbeddedMessageParent" do
optional :child_msg, :message, 1, "TestEmbeddedMessageChild"
optional :number, :int32, 2
repeated :repeated_msg, :message, 3, "TestEmbeddedMessageChild"
repeated :repeated_number, :int32, 4
end
add_message "TestEmbeddedMessageChild" do
optional :sub_child, :message, 1, "TestMessage"
end
add_message "Recursive1" do
optional :foo, :message, 1, "Recursive2"
end
add_message "Recursive2" do
optional :foo, :message, 1, "Recursive1"
end
add_enum "TestEnum" do
value :Default, 0
value :A, 1
value :B, 2
value :C, 3
end
add_message "BadFieldNames" do
optional :dup, :int32, 1
optional :class, :int32, 2
optional :"a.b", :int32, 3
end
add_message "MapMessage" do
map :map_string_int32, :string, :int32, 1
map :map_string_msg, :string, :message, 2, "TestMessage2"
end
add_message "MapMessageWireEquiv" do
repeated :map_string_int32, :message, 1, "MapMessageWireEquiv_entry1"
repeated :map_string_msg, :message, 2, "MapMessageWireEquiv_entry2"
end
add_message "MapMessageWireEquiv_entry1" do
optional :key, :string, 1
optional :value, :int32, 2
end
add_message "MapMessageWireEquiv_entry2" do
optional :key, :string, 1
optional :value, :message, 2, "TestMessage2"
end
add_message "OneofMessage" do
oneof :my_oneof do
optional :a, :string, 1
optional :b, :int32, 2
optional :c, :message, 3, "TestMessage2"
optional :d, :enum, 4, "TestEnum"
end
end
add_message "repro.Outer" do
map :items, :int32, :message, 1, "repro.Inner"
end
add_message "repro.Inner" do
end
end
Outer = pool.lookup("repro.Outer").msgclass
Inner = pool.lookup("repro.Inner").msgclass
Foo = pool.lookup("Foo").msgclass
Bar = pool.lookup("Bar").msgclass
Baz = pool.lookup("Baz").msgclass
TestMessage = pool.lookup("TestMessage").msgclass
TestMessage2 = pool.lookup("TestMessage2").msgclass
TestEmbeddedMessageParent = pool.lookup("TestEmbeddedMessageParent").msgclass
TestEmbeddedMessageChild = pool.lookup("TestEmbeddedMessageChild").msgclass
Recursive1 = pool.lookup("Recursive1").msgclass
Recursive2 = pool.lookup("Recursive2").msgclass
TestEnum = pool.lookup("TestEnum").enummodule
BadFieldNames = pool.lookup("BadFieldNames").msgclass
MapMessage = pool.lookup("MapMessage").msgclass
MapMessageWireEquiv = pool.lookup("MapMessageWireEquiv").msgclass
MapMessageWireEquiv_entry1 =
pool.lookup("MapMessageWireEquiv_entry1").msgclass
MapMessageWireEquiv_entry2 =
pool.lookup("MapMessageWireEquiv_entry2").msgclass
OneofMessage = pool.lookup("OneofMessage").msgclass
# ------------ test cases ---------------
class MessageContainerTest < Test::Unit::TestCase
def test_defaults
m = TestMessage.new
assert m.optional_int32 == 0
assert m.optional_int64 == 0
assert m.optional_uint32 == 0
assert m.optional_uint64 == 0
assert m.optional_bool == false
assert m.optional_float == 0.0
assert m.optional_double == 0.0
assert m.optional_string == ""
assert m.optional_bytes == ""
assert m.optional_msg == nil
assert m.optional_enum == :Default
end
def test_setters
m = TestMessage.new
m.optional_int32 = -42
assert m.optional_int32 == -42
m.optional_int64 = -0x1_0000_0000
assert m.optional_int64 == -0x1_0000_0000
m.optional_uint32 = 0x9000_0000
assert m.optional_uint32 == 0x9000_0000
m.optional_uint64 = 0x9000_0000_0000_0000
assert m.optional_uint64 == 0x9000_0000_0000_0000
m.optional_bool = true
assert m.optional_bool == true
m.optional_float = 0.5
assert m.optional_float == 0.5
m.optional_double = 0.5
m.optional_string = "hello"
assert m.optional_string == "hello"
m.optional_string = :hello
assert m.optional_string == "hello"
m.optional_bytes = "world".encode!('ASCII-8BIT')
assert m.optional_bytes == "world"
m.optional_msg = TestMessage2.new(:foo => 42)
assert m.optional_msg == TestMessage2.new(:foo => 42)
m.optional_msg = nil
assert m.optional_msg == nil
m.optional_enum = :C
assert m.optional_enum == :C
m.optional_enum = 'C'
assert m.optional_enum == :C
end
def test_ctor_args
m = TestMessage.new(:optional_int32 => -42,
:optional_msg => TestMessage2.new,
:optional_enum => :C,
:repeated_string => ["hello", "there", "world"])
assert m.optional_int32 == -42
assert m.optional_msg.class == TestMessage2
assert m.repeated_string.length == 3
assert m.optional_enum == :C
assert m.repeated_string[0] == "hello"
assert m.repeated_string[1] == "there"
assert m.repeated_string[2] == "world"
end
def test_ctor_string_symbol_args
m = TestMessage.new(:optional_enum => 'C', :repeated_enum => ['A', 'B'])
assert_equal :C, m.optional_enum
assert_equal [:A, :B], m.repeated_enum
m = TestMessage.new(:optional_string => :foo, :repeated_string => [:foo, :bar])
assert_equal 'foo', m.optional_string
assert_equal ['foo', 'bar'], m.repeated_string
end
def test_embeddedmsg_hash_init
m = TestEmbeddedMessageParent.new(:child_msg => {sub_child: {optional_int32: 1}},
:number => 2,
:repeated_msg => [{sub_child: {optional_int32: 3}}],
:repeated_number => [10, 20, 30])
assert_equal 2, m.number
assert_equal [10, 20, 30], m.repeated_number
assert_not_nil m.child_msg
assert_not_nil m.child_msg.sub_child
assert_equal m.child_msg.sub_child.optional_int32, 1
assert_not_nil m.repeated_msg
assert_equal 1, m.repeated_msg.length
assert_equal 3, m.repeated_msg.first.sub_child.optional_int32
end
def test_inspect
m = TestMessage.new(:optional_int32 => -42,
:optional_enum => :A,
:optional_msg => TestMessage2.new,
:repeated_string => ["hello", "there", "world"])
expected = '<BasicTest::TestMessage: optional_int32: -42, optional_int64: 0, optional_uint32: 0, optional_uint64: 0, optional_bool: false, optional_float: 0.0, optional_double: 0.0, optional_string: "", optional_bytes: "", optional_msg: <BasicTest::TestMessage2: foo: 0>, optional_enum: :A, repeated_int32: [], repeated_int64: [], repeated_uint32: [], repeated_uint64: [], repeated_bool: [], repeated_float: [], repeated_double: [], repeated_string: ["hello", "there", "world"], repeated_bytes: [], repeated_msg: [], repeated_enum: []>'
assert_equal expected, m.inspect
end
def test_hash
m1 = TestMessage.new(:optional_int32 => 42)
m2 = TestMessage.new(:optional_int32 => 102, repeated_string: ['please', 'work', 'ok?'])
m3 = TestMessage.new(:optional_int32 => 102, repeated_string: ['please', 'work', 'ok?'])
assert m1.hash != 0
assert m2.hash != 0
assert m3.hash != 0
# relying on the randomness here -- if hash function changes and we are
# unlucky enough to get a collision, then change the values above.
assert m1.hash != m2.hash
assert_equal m2.hash, m3.hash
end
def test_unknown_field_errors
e = assert_raise NoMethodError do
TestMessage.new.hello
end
assert_match(/hello/, e.message)
e = assert_raise NoMethodError do
TestMessage.new.hello = "world"
end
assert_match(/hello/, e.message)
end
def test_initialization_map_errors
e = assert_raise ArgumentError do
TestMessage.new(:hello => "world")
end
assert_match(/hello/, e.message)
e = assert_raise ArgumentError do
MapMessage.new(:map_string_int32 => "hello")
end
assert_equal e.message, "Expected Hash object as initializer value for map field 'map_string_int32'."
e = assert_raise ArgumentError do
TestMessage.new(:repeated_uint32 => "hello")
end
assert_equal e.message, "Expected array as initializer value for repeated field 'repeated_uint32'."
end
def test_type_errors
m = TestMessage.new
assert_raise TypeError do
m.optional_int32 = "hello"
end
assert_raise TypeError do
m.optional_string = 42
end
assert_raise TypeError do
m.optional_string = nil
end
assert_raise TypeError do
m.optional_bool = 42
end
assert_raise TypeError do
m.optional_msg = TestMessage.new # expects TestMessage2
end
assert_raise TypeError do
m.repeated_int32 = [] # needs RepeatedField
end
assert_raise TypeError do
m.repeated_int32.push "hello"
end
assert_raise TypeError do
m.repeated_msg.push TestMessage.new
end
end
def test_string_encoding
m = TestMessage.new
# Assigning a normal (ASCII or UTF8) string to a bytes field, or
# ASCII-8BIT to a string field will convert to the proper encoding.
m.optional_bytes = "Test string ASCII".encode!('ASCII')
assert m.optional_bytes.frozen?
assert_equal Encoding::ASCII_8BIT, m.optional_bytes.encoding
assert_equal "Test string ASCII", m.optional_bytes
assert_raise Encoding::UndefinedConversionError do
m.optional_bytes = "Test string UTF-8 \u0100".encode!('UTF-8')
end
assert_raise Encoding::UndefinedConversionError do
m.optional_string = ["FFFF"].pack('H*')
end
# "Ordinary" use case.
m.optional_bytes = ["FFFF"].pack('H*')
m.optional_string = "\u0100"
# strings are immutable so we can't do this, but serialize should catch it.
m.optional_string = "asdf".encode!('UTF-8')
assert_raise RuntimeError do
m.optional_string.encode!('ASCII-8BIT')
end
end
def test_rptfield_int32
l = Google::Protobuf::RepeatedField.new(:int32)
assert l.count == 0
l = Google::Protobuf::RepeatedField.new(:int32, [1, 2, 3])
assert l.count == 3
assert_equal [1, 2, 3], l
assert_equal l, [1, 2, 3]
l.push 4
assert l == [1, 2, 3, 4]
dst_list = []
l.each { |val| dst_list.push val }
assert dst_list == [1, 2, 3, 4]
assert l.to_a == [1, 2, 3, 4]
assert l[0] == 1
assert l[3] == 4
l[0] = 5
assert l == [5, 2, 3, 4]
l2 = l.dup
assert l == l2
assert l.object_id != l2.object_id
l2.push 6
assert l.count == 4
assert l2.count == 5
assert l.inspect == '[5, 2, 3, 4]'
l.concat([7, 8, 9])
assert l == [5, 2, 3, 4, 7, 8, 9]
assert l.pop == 9
assert l == [5, 2, 3, 4, 7, 8]
assert_raise TypeError do
m = TestMessage.new
l.push m
end
m = TestMessage.new
m.repeated_int32 = l
assert m.repeated_int32 == [5, 2, 3, 4, 7, 8]
assert m.repeated_int32.object_id == l.object_id
l.push 42
assert m.repeated_int32.pop == 42
l3 = l + l.dup
assert l3.count == l.count * 2
l.count.times do |i|
assert l3[i] == l[i]
assert l3[l.count + i] == l[i]
end
l.clear
assert l.count == 0
l += [1, 2, 3, 4]
l.replace([5, 6, 7, 8])
assert l == [5, 6, 7, 8]
l4 = Google::Protobuf::RepeatedField.new(:int32)
l4[5] = 42
assert l4 == [0, 0, 0, 0, 0, 42]
l4 << 100
assert l4 == [0, 0, 0, 0, 0, 42, 100]
l4 << 101 << 102
assert l4 == [0, 0, 0, 0, 0, 42, 100, 101, 102]
end
def test_parent_rptfield
#make sure we set the RepeatedField and can add to it
m = TestMessage.new
assert m.repeated_string == []
m.repeated_string << 'ok'
m.repeated_string.push('ok2')
assert m.repeated_string == ['ok', 'ok2']
m.repeated_string += ['ok3']
assert m.repeated_string == ['ok', 'ok2', 'ok3']
end
def test_rptfield_msg
l = Google::Protobuf::RepeatedField.new(:message, TestMessage)
l.push TestMessage.new
assert l.count == 1
assert_raise TypeError do
l.push TestMessage2.new
end
assert_raise TypeError do
l.push 42
end
l2 = l.dup
assert l2[0] == l[0]
assert l2[0].object_id == l[0].object_id
l2 = Google::Protobuf.deep_copy(l)
assert l2[0] == l[0]
assert l2[0].object_id != l[0].object_id
l3 = l + l2
assert l3.count == 2
assert l3[0] == l[0]
assert l3[1] == l2[0]
l3[0].optional_int32 = 1000
assert l[0].optional_int32 == 1000
new_msg = TestMessage.new(:optional_int32 => 200)
l4 = l + [new_msg]
assert l4.count == 2
new_msg.optional_int32 = 1000
assert l4[1].optional_int32 == 1000
end
def test_rptfield_enum
l = Google::Protobuf::RepeatedField.new(:enum, TestEnum)
l.push :A
l.push :B
l.push :C
assert l.count == 3
assert_raise RangeError do
l.push :D
end
assert l[0] == :A
l.push 4
assert l[3] == 4
end
def test_rptfield_initialize
assert_raise ArgumentError do
l = Google::Protobuf::RepeatedField.new
end
assert_raise ArgumentError do
l = Google::Protobuf::RepeatedField.new(:message)
end
assert_raise ArgumentError do
l = Google::Protobuf::RepeatedField.new([1, 2, 3])
end
assert_raise ArgumentError do
l = Google::Protobuf::RepeatedField.new(:message, [TestMessage2.new])
end
end
def test_rptfield_array_ducktyping
l = Google::Protobuf::RepeatedField.new(:int32)
length_methods = %w(count length size)
length_methods.each do |lm|
assert l.send(lm) == 0
end
# out of bounds returns a nil
assert l[0] == nil
assert l[1] == nil
assert l[-1] == nil
l.push 4
length_methods.each do |lm|
assert l.send(lm) == 1
end
assert l[0] == 4
assert l[1] == nil
assert l[-1] == 4
assert l[-2] == nil
l.push 2
length_methods.each do |lm|
assert l.send(lm) == 2
end
assert l[0] == 4
assert l[1] == 2
assert l[2] == nil
assert l[-1] == 2
assert l[-2] == 4
assert l[-3] == nil
#adding out of scope will backfill with empty objects
end
def test_map_basic
# allowed key types:
# :int32, :int64, :uint32, :uint64, :bool, :string, :bytes.
m = Google::Protobuf::Map.new(:string, :int32)
m["asdf"] = 1
assert m["asdf"] == 1
m["jkl;"] = 42
assert m == { "jkl;" => 42, "asdf" => 1 }
assert m.has_key?("asdf")
assert !m.has_key?("qwerty")
assert m.length == 2
m2 = m.dup
assert_equal m, m2
assert m.hash != 0
assert_equal m.hash, m2.hash
collected = {}
m.each { |k,v| collected[v] = k }
assert collected == { 42 => "jkl;", 1 => "asdf" }
assert m.delete("asdf") == 1
assert !m.has_key?("asdf")
assert m["asdf"] == nil
assert !m.has_key?("asdf")
# We only assert on inspect value when there is one map entry because the
# order in which elements appear is unspecified (depends on the internal
# hash function). We don't want a brittle test.
assert m.inspect == "{\"jkl;\"=>42}"
assert m.keys == ["jkl;"]
assert m.values == [42]
m.clear
assert m.length == 0
assert m == {}
assert_raise TypeError do
m[1] = 1
end
assert_raise RangeError do
m["asdf"] = 0x1_0000_0000
end
end
def test_map_ctor
m = Google::Protobuf::Map.new(:string, :int32,
{"a" => 1, "b" => 2, "c" => 3})
assert m == {"a" => 1, "c" => 3, "b" => 2}
end
def test_map_keytypes
m = Google::Protobuf::Map.new(:int32, :int32)
m[1] = 42
m[-1] = 42
assert_raise RangeError do
m[0x8000_0000] = 1
end
assert_raise TypeError do
m["asdf"] = 1
end
m = Google::Protobuf::Map.new(:int64, :int32)
m[0x1000_0000_0000_0000] = 1
assert_raise RangeError do
m[0x1_0000_0000_0000_0000] = 1
end
assert_raise TypeError do
m["asdf"] = 1
end
m = Google::Protobuf::Map.new(:uint32, :int32)
m[0x8000_0000] = 1
assert_raise RangeError do
m[0x1_0000_0000] = 1
end
assert_raise RangeError do
m[-1] = 1
end
m = Google::Protobuf::Map.new(:uint64, :int32)
m[0x8000_0000_0000_0000] = 1
assert_raise RangeError do
m[0x1_0000_0000_0000_0000] = 1
end
assert_raise RangeError do
m[-1] = 1
end
m = Google::Protobuf::Map.new(:bool, :int32)
m[true] = 1
m[false] = 2
assert_raise TypeError do
m[1] = 1
end
assert_raise TypeError do
m["asdf"] = 1
end
m = Google::Protobuf::Map.new(:string, :int32)
m["asdf"] = 1
assert_raise TypeError do
m[1] = 1
end
assert_raise Encoding::UndefinedConversionError do
bytestring = ["FFFF"].pack("H*")
m[bytestring] = 1
end
m = Google::Protobuf::Map.new(:bytes, :int32)
bytestring = ["FFFF"].pack("H*")
m[bytestring] = 1
# Allowed -- we will automatically convert to ASCII-8BIT.
m["asdf"] = 1
assert_raise TypeError do
m[1] = 1
end
end
def test_map_msg_enum_valuetypes
m = Google::Protobuf::Map.new(:string, :message, TestMessage)
m["asdf"] = TestMessage.new
assert_raise TypeError do
m["jkl;"] = TestMessage2.new
end
m = Google::Protobuf::Map.new(
:string, :message, TestMessage,
{ "a" => TestMessage.new(:optional_int32 => 42),
"b" => TestMessage.new(:optional_int32 => 84) })
assert m.length == 2
assert m.values.map{|msg| msg.optional_int32}.sort == [42, 84]
m = Google::Protobuf::Map.new(:string, :enum, TestEnum,
{ "x" => :A, "y" => :B, "z" => :C })
assert m.length == 3
assert m["z"] == :C
m["z"] = 2
assert m["z"] == :B
m["z"] = 4
assert m["z"] == 4
assert_raise RangeError do
m["z"] = :Z
end
assert_raise RangeError do
m["z"] = "z"
end
end
def test_map_dup_deep_copy
m = Google::Protobuf::Map.new(
:string, :message, TestMessage,
{ "a" => TestMessage.new(:optional_int32 => 42),
"b" => TestMessage.new(:optional_int32 => 84) })
m2 = m.dup
assert m == m2
assert m.object_id != m2.object_id
assert m["a"].object_id == m2["a"].object_id
assert m["b"].object_id == m2["b"].object_id
m2 = Google::Protobuf.deep_copy(m)
assert m == m2
assert m.object_id != m2.object_id
assert m["a"].object_id != m2["a"].object_id
assert m["b"].object_id != m2["b"].object_id
end
def test_map_field
m = MapMessage.new
assert m.map_string_int32 == {}
assert m.map_string_msg == {}
m = MapMessage.new(
:map_string_int32 => {"a" => 1, "b" => 2},
:map_string_msg => {"a" => TestMessage2.new(:foo => 1),
"b" => TestMessage2.new(:foo => 2)})
assert m.map_string_int32.keys.sort == ["a", "b"]
assert m.map_string_int32["a"] == 1
assert m.map_string_msg["b"].foo == 2
m.map_string_int32["c"] = 3
assert m.map_string_int32["c"] == 3
m.map_string_msg["c"] = TestMessage2.new(:foo => 3)
assert m.map_string_msg["c"] == TestMessage2.new(:foo => 3)
m.map_string_msg.delete("b")
m.map_string_msg.delete("c")
assert m.map_string_msg == { "a" => TestMessage2.new(:foo => 1) }
assert_raise TypeError do
m.map_string_msg["e"] = TestMessage.new # wrong value type
end
# ensure nothing was added by the above
assert m.map_string_msg == { "a" => TestMessage2.new(:foo => 1) }
m.map_string_int32 = Google::Protobuf::Map.new(:string, :int32)
assert_raise TypeError do
m.map_string_int32 = Google::Protobuf::Map.new(:string, :int64)
end
assert_raise TypeError do
m.map_string_int32 = {}
end
assert_raise TypeError do
m = MapMessage.new(:map_string_int32 => { 1 => "I am not a number" })
end
end
Merge 3.2.x branch into master (#2648) * Down-integrate internal changes to github. * Update conformance test failure list. * Explicitly import used class in nano test to avoid random test fail. * Update _GNUC_VER to use the correct implementation of atomic operation on Mac. * maps_test.js: check whether Symbol is defined before using it (#2524) Symbol is not yet available on older versions of Node.js and so this test fails with them. This change just directly checks whether Symbol is available before we try to use it. * Added well_known_types_embed.cc to CLEANFILES so that it gets cleaned up * Updated Makefile.am to fix out-of-tree builds * Added Bazel genrule for generating well_known_types_embed.cc In pull request #2517 I made this change for the CMake and autotools builds but forgot to do it for the Bazel build. * Update _GNUC_VER to use the correct implementation of atomic operation on Mac. * Add new js file in extra dist. * Bump version number to 3.2.0 * Fixed issue with autoloading - Invalid paths (#2538) * PHP fix int64 decoding (#2516) * fix int64 decoding * fix int64 decoding + tests * Fix int64 decoding on 32-bit machines. * Fix warning in compiler/js/embed.cc embed.cc: In function ‘std::string CEscape(const string&)’: embed.cc:51:32: warning: comparison between signed and unsigned integer expressions [-Wsign-compare] for (int i = 0; i < str.size(); ++i) { ^ * Fix include in auto-generated well_known_types_embed.cc Restore include style fix (e3da722) that has been trampled by auto-generation of well_known_types_embed.cc * Fixed cross compilations with the Autotools build Pull request #2517 caused cross compilations to start failing, because the js_embed binary was being built to run on the target platform instead of on the build machine. This change updates the Autotools build to use the AX_PROG_CXX_FOR_BUILD macro to find a suitable compiler for the build machine and always use that when building js_embed. * Minor fix for autocreated object repeated fields and maps. - If setting/clearing a repeated field/map that was objects, check the class before checking the autocreator. - Just to be paranoid, don’t mutate within copy/mutableCopy for the autocreated classes to ensure there is less chance of issues if someone does something really crazy threading wise. - Some more tests for the internal AutocreatedArray/AutocreatedDictionary classes to ensure things are working as expected. - Add Xcode 8.2 to the full_mac_build.sh supported list. * Fix generation of extending nested messages in JavaScript (#2439) * Fix generation of extending nested messages in JavaScript * Added missing test8.proto to build * Fix generated code when there is no namespace but there is enum definition. * Decoding unknown field should succeed. * Add embed.cc in src/Makefile.am to fix dist check. * Fixed "make distcheck" for the Autotools build To make the test pass I needed to fix out-of-tree builds and update EXTRA_DIST and CLEANFILES. * Remove redundent embed.cc from src/Makefile.am * Update version number to 3.2.0-rc.1 (#2578) * Change protoc-artifacts version to 3.2.0-rc.1 * Update version number to 3.2.0rc2 * Update change logs for 3.2.0 release. * Update php README * Update upb, fixes some bugs (including a hash table problem). (#2611) * Update upb, fixes some bugs (including a hash table problem). * Ruby: added a test for the previous hash table corruption. Verified that this triggers the bug in the currently released version. * Ruby: bugfix for SEGV. * Ruby: removed old code for dup'ing defs. * Reverting deployment target to 7.0 (#2618) The Protobuf library doesn’t require the 7.1 deployment target so reverting it back to 7.0 * Fix typo that breaks builds on big-endian (#2632) * Bump version number to 3.2.0
8 years ago
def test_map_corruption
# This pattern led to a crash in a previous version of upb/protobuf.
m = MapMessage.new(map_string_int32: { "aaa" => 1 })
m.map_string_int32['podid'] = 2
m.map_string_int32['aaa'] = 3
end
def test_concurrent_decoding
o = Outer.new
o.items[0] = Inner.new
raw = Outer.encode(o)
thds = 2.times.map do
Thread.new do
100000.times do
assert_equal o, Outer.decode(raw)
end
end
end
thds.map(&:join)
end
def test_map_encode_decode
m = MapMessage.new(
:map_string_int32 => {"a" => 1, "b" => 2},
:map_string_msg => {"a" => TestMessage2.new(:foo => 1),
"b" => TestMessage2.new(:foo => 2)})
m2 = MapMessage.decode(MapMessage.encode(m))
assert m == m2
m3 = MapMessageWireEquiv.decode(MapMessage.encode(m))
assert m3.map_string_int32.length == 2
kv = {}
m3.map_string_int32.map { |msg| kv[msg.key] = msg.value }
assert kv == {"a" => 1, "b" => 2}
kv = {}
m3.map_string_msg.map { |msg| kv[msg.key] = msg.value }
assert kv == {"a" => TestMessage2.new(:foo => 1),
"b" => TestMessage2.new(:foo => 2)}
end
def test_oneof_descriptors
d = OneofMessage.descriptor
o = d.lookup_oneof("my_oneof")
assert o != nil
assert o.class == Google::Protobuf::OneofDescriptor
assert o.name == "my_oneof"
oneof_count = 0
d.each_oneof{ |oneof|
oneof_count += 1
assert oneof == o
}
assert oneof_count == 1
assert o.count == 4
field_names = o.map{|f| f.name}.sort
assert field_names == ["a", "b", "c", "d"]
end
def test_oneof
d = OneofMessage.new
assert d.a == ""
assert d.b == 0
assert d.c == nil
assert d.d == :Default
assert d.my_oneof == nil
d.a = "hi"
assert d.a == "hi"
assert d.b == 0
assert d.c == nil
assert d.d == :Default
assert d.my_oneof == :a
d.b = 42
assert d.a == ""
assert d.b == 42
assert d.c == nil
assert d.d == :Default
assert d.my_oneof == :b
d.c = TestMessage2.new(:foo => 100)
assert d.a == ""
assert d.b == 0
assert d.c.foo == 100
assert d.d == :Default
assert d.my_oneof == :c
d.d = :C
assert d.a == ""
assert d.b == 0
assert d.c == nil
assert d.d == :C
assert d.my_oneof == :d
d2 = OneofMessage.decode(OneofMessage.encode(d))
assert d2 == d
encoded_field_a = OneofMessage.encode(OneofMessage.new(:a => "string"))
encoded_field_b = OneofMessage.encode(OneofMessage.new(:b => 1000))
encoded_field_c = OneofMessage.encode(
OneofMessage.new(:c => TestMessage2.new(:foo => 1)))
encoded_field_d = OneofMessage.encode(OneofMessage.new(:d => :B))
d3 = OneofMessage.decode(
encoded_field_c + encoded_field_a + encoded_field_d)
assert d3.a == ""
assert d3.b == 0
assert d3.c == nil
assert d3.d == :B
d4 = OneofMessage.decode(
encoded_field_c + encoded_field_a + encoded_field_d +
encoded_field_c)
assert d4.a == ""
assert d4.b == 0
assert d4.c.foo == 1
assert d4.d == :Default
d5 = OneofMessage.new(:a => "hello")
assert d5.a == "hello"
d5.a = nil
assert d5.a == ""
assert OneofMessage.encode(d5) == ''
assert d5.my_oneof == nil
end
def test_enum_field
m = TestMessage.new
assert m.optional_enum == :Default
m.optional_enum = :A
assert m.optional_enum == :A
assert_raise RangeError do
m.optional_enum = :ASDF
end
m.optional_enum = 1
assert m.optional_enum == :A
m.optional_enum = 100
assert m.optional_enum == 100
end
def test_dup
m = TestMessage.new
m.optional_string = "hello"
m.optional_int32 = 42
tm1 = TestMessage2.new(:foo => 100)
tm2 = TestMessage2.new(:foo => 200)
m.repeated_msg.push tm1
assert m.repeated_msg[-1] == tm1
m.repeated_msg.push tm2
assert m.repeated_msg[-1] == tm2
m2 = m.dup
assert m == m2
m.optional_int32 += 1
assert m != m2
assert m.repeated_msg[0] == m2.repeated_msg[0]
assert m.repeated_msg[0].object_id == m2.repeated_msg[0].object_id
end
def test_deep_copy
m = TestMessage.new(:optional_int32 => 42,
:repeated_msg => [TestMessage2.new(:foo => 100)])
m2 = Google::Protobuf.deep_copy(m)
assert m == m2
assert m.repeated_msg == m2.repeated_msg
assert m.repeated_msg.object_id != m2.repeated_msg.object_id
assert m.repeated_msg[0].object_id != m2.repeated_msg[0].object_id
end
def test_eq
m = TestMessage.new(:optional_int32 => 42,
:repeated_int32 => [1, 2, 3])
m2 = TestMessage.new(:optional_int32 => 43,
:repeated_int32 => [1, 2, 3])
assert m != m2
end
def test_enum_lookup
assert TestEnum::A == 1
assert TestEnum::B == 2
assert TestEnum::C == 3
assert TestEnum::lookup(1) == :A
assert TestEnum::lookup(2) == :B
assert TestEnum::lookup(3) == :C
assert TestEnum::resolve(:A) == 1
assert TestEnum::resolve(:B) == 2
assert TestEnum::resolve(:C) == 3
end
def test_parse_serialize
m = TestMessage.new(:optional_int32 => 42,
:optional_string => "hello world",
:optional_enum => :B,
:repeated_string => ["a", "b", "c"],
:repeated_int32 => [42, 43, 44],
:repeated_enum => [:A, :B, :C, 100],
:repeated_msg => [TestMessage2.new(:foo => 1),
TestMessage2.new(:foo => 2)])
data = TestMessage.encode m
m2 = TestMessage.decode data
assert m == m2
data = Google::Protobuf.encode m
m2 = Google::Protobuf.decode(TestMessage, data)
assert m == m2
end
def test_encode_decode_helpers
m = TestMessage.new(:optional_string => 'foo', :repeated_string => ['bar1', 'bar2'])
assert_equal 'foo', m.optional_string
assert_equal ['bar1', 'bar2'], m.repeated_string
json = m.to_json
m2 = TestMessage.decode_json(json)
assert_equal 'foo', m2.optional_string
assert_equal ['bar1', 'bar2'], m2.repeated_string
if RUBY_PLATFORM != "java"
assert m2.optional_string.frozen?
assert m2.repeated_string[0].frozen?
end
proto = m.to_proto
m2 = TestMessage.decode(proto)
assert_equal 'foo', m2.optional_string
assert_equal ['bar1', 'bar2'], m2.repeated_string
end
def test_protobuf_encode_decode_helpers
m = TestMessage.new(:optional_string => 'foo', :repeated_string => ['bar1', 'bar2'])
encoded_msg = Google::Protobuf.encode(m)
assert_equal m.to_proto, encoded_msg
decoded_msg = Google::Protobuf.decode(TestMessage, encoded_msg)
assert_equal TestMessage.decode(m.to_proto), decoded_msg
end
def test_protobuf_encode_decode_json_helpers
m = TestMessage.new(:optional_string => 'foo', :repeated_string => ['bar1', 'bar2'])
encoded_msg = Google::Protobuf.encode_json(m)
assert_equal m.to_json, encoded_msg
decoded_msg = Google::Protobuf.decode_json(TestMessage, encoded_msg)
assert_equal TestMessage.decode_json(m.to_json), decoded_msg
end
def test_to_h
m = TestMessage.new(:optional_bool => true, :optional_double => -10.100001, :optional_string => 'foo', :repeated_string => ['bar1', 'bar2'], :repeated_msg => [TestMessage2.new(:foo => 100)])
expected_result = {
:optional_bool=>true,
:optional_bytes=>"",
:optional_double=>-10.100001,
:optional_enum=>:Default,
:optional_float=>0.0,
:optional_int32=>0,
:optional_int64=>0,
:optional_msg=>nil,
:optional_string=>"foo",
:optional_uint32=>0,
:optional_uint64=>0,
:repeated_bool=>[],
:repeated_bytes=>[],
:repeated_double=>[],
:repeated_enum=>[],
:repeated_float=>[],
:repeated_int32=>[],
:repeated_int64=>[],
:repeated_msg=>[{:foo => 100}],
:repeated_string=>["bar1", "bar2"],
:repeated_uint32=>[],
:repeated_uint64=>[]
}
assert_equal expected_result, m.to_h
m = MapMessage.new(
:map_string_int32 => {"a" => 1, "b" => 2},
:map_string_msg => {"a" => TestMessage2.new(:foo => 1),
"b" => TestMessage2.new(:foo => 2)})
expected_result = {
:map_string_int32 => {"a" => 1, "b" => 2},
:map_string_msg => {"a" => {:foo => 1}, "b" => {:foo => 2}}
}
assert_equal expected_result, m.to_h
end
def test_def_errors
s = Google::Protobuf::DescriptorPool.new
assert_raise TypeError do
s.build do
# enum with no default (integer value 0)
add_enum "MyEnum" do
value :A, 1
end
end
end
assert_raise TypeError do
s.build do
# message with required field (unsupported in proto3)
add_message "MyMessage" do
required :foo, :int32, 1
end
end
end
end
def test_corecursive
# just be sure that we can instantiate types with corecursive field-type
# references.
m = Recursive1.new(:foo => Recursive2.new(:foo => Recursive1.new))
assert Recursive1.descriptor.lookup("foo").subtype ==
Recursive2.descriptor
assert Recursive2.descriptor.lookup("foo").subtype ==
Recursive1.descriptor
serialized = Recursive1.encode(m)
m2 = Recursive1.decode(serialized)
assert m == m2
end
def test_serialize_cycle
m = Recursive1.new(:foo => Recursive2.new)
m.foo.foo = m
assert_raise RuntimeError do
serialized = Recursive1.encode(m)
end
end
def test_bad_field_names
m = BadFieldNames.new(:dup => 1, :class => 2)
m2 = m.dup
assert m == m2
assert m['dup'] == 1
assert m['class'] == 2
m['dup'] = 3
assert m['dup'] == 3
m['a.b'] = 4
assert m['a.b'] == 4
end
def test_int_ranges
m = TestMessage.new
m.optional_int32 = 0
m.optional_int32 = -0x8000_0000
m.optional_int32 = +0x7fff_ffff
m.optional_int32 = 1.0
m.optional_int32 = -1.0
m.optional_int32 = 2e9
assert_raise RangeError do
m.optional_int32 = -0x8000_0001
end
assert_raise RangeError do
m.optional_int32 = +0x8000_0000
end
assert_raise RangeError do
m.optional_int32 = +0x1000_0000_0000_0000_0000_0000 # force Bignum
end
assert_raise RangeError do
m.optional_int32 = 1e12
end
assert_raise RangeError do
m.optional_int32 = 1.5
end
m.optional_uint32 = 0
m.optional_uint32 = +0xffff_ffff
m.optional_uint32 = 1.0
m.optional_uint32 = 4e9
assert_raise RangeError do
m.optional_uint32 = -1
end
assert_raise RangeError do
m.optional_uint32 = -1.5
end
assert_raise RangeError do
m.optional_uint32 = -1.5e12
end
assert_raise RangeError do
m.optional_uint32 = -0x1000_0000_0000_0000
end
assert_raise RangeError do
m.optional_uint32 = +0x1_0000_0000
end
assert_raise RangeError do
m.optional_uint32 = +0x1000_0000_0000_0000_0000_0000 # force Bignum
end
assert_raise RangeError do
m.optional_uint32 = 1e12
end
assert_raise RangeError do
m.optional_uint32 = 1.5
end
m.optional_int64 = 0
m.optional_int64 = -0x8000_0000_0000_0000
m.optional_int64 = +0x7fff_ffff_ffff_ffff
m.optional_int64 = 1.0
m.optional_int64 = -1.0
m.optional_int64 = 8e18
m.optional_int64 = -8e18
assert_raise RangeError do
m.optional_int64 = -0x8000_0000_0000_0001
end
assert_raise RangeError do
m.optional_int64 = +0x8000_0000_0000_0000
end
assert_raise RangeError do
m.optional_int64 = +0x1000_0000_0000_0000_0000_0000 # force Bignum
end
assert_raise RangeError do
m.optional_int64 = 1e50
end
assert_raise RangeError do
m.optional_int64 = 1.5
end
m.optional_uint64 = 0
m.optional_uint64 = +0xffff_ffff_ffff_ffff
m.optional_uint64 = 1.0
m.optional_uint64 = 16e18
assert_raise RangeError do
m.optional_uint64 = -1
end
assert_raise RangeError do
m.optional_uint64 = -1.5
end
assert_raise RangeError do
m.optional_uint64 = -1.5e12
end
assert_raise RangeError do
m.optional_uint64 = -0x1_0000_0000_0000_0000
end
assert_raise RangeError do
m.optional_uint64 = +0x1_0000_0000_0000_0000
end
assert_raise RangeError do
m.optional_uint64 = +0x1000_0000_0000_0000_0000_0000 # force Bignum
end
assert_raise RangeError do
m.optional_uint64 = 1e50
end
assert_raise RangeError do
m.optional_uint64 = 1.5
end
end
def test_stress_test
m = TestMessage.new
m.optional_int32 = 42
m.optional_int64 = 0x100000000
m.optional_string = "hello world"
10.times do m.repeated_msg.push TestMessage2.new(:foo => 42) end
10.times do m.repeated_string.push "hello world" end
data = TestMessage.encode(m)
l = 0
10_000.times do
m = TestMessage.decode(data)
data_new = TestMessage.encode(m)
assert data_new == data
data = data_new
end
end
def test_reflection
m = TestMessage.new(:optional_int32 => 1234)
msgdef = m.class.descriptor
assert msgdef.class == Google::Protobuf::Descriptor
assert msgdef.any? {|field| field.name == "optional_int32"}
optional_int32 = msgdef.lookup "optional_int32"
assert optional_int32.class == Google::Protobuf::FieldDescriptor
assert optional_int32 != nil
assert optional_int32.name == "optional_int32"
assert optional_int32.type == :int32
optional_int32.set(m, 5678)
assert m.optional_int32 == 5678
m.optional_int32 = 1000
assert optional_int32.get(m) == 1000
optional_msg = msgdef.lookup "optional_msg"
assert optional_msg.subtype == TestMessage2.descriptor
optional_msg.set(m, optional_msg.subtype.msgclass.new)
assert msgdef.msgclass == TestMessage
optional_enum = msgdef.lookup "optional_enum"
assert optional_enum.subtype == TestEnum.descriptor
assert optional_enum.subtype.class == Google::Protobuf::EnumDescriptor
optional_enum.subtype.each do |k, v|
# set with integer, check resolution to symbolic name
optional_enum.set(m, v)
assert optional_enum.get(m) == k
end
end
def test_json
# TODO: Fix JSON in JRuby version.
return if RUBY_PLATFORM == "java"
m = TestMessage.new(:optional_int32 => 1234,
:optional_int64 => -0x1_0000_0000,
:optional_uint32 => 0x8000_0000,
:optional_uint64 => 0xffff_ffff_ffff_ffff,
:optional_bool => true,
:optional_float => 1.0,
:optional_double => -1e100,
:optional_string => "Test string",
:optional_bytes => ["FFFFFFFF"].pack('H*'),
:optional_msg => TestMessage2.new(:foo => 42),
:repeated_int32 => [1, 2, 3, 4],
:repeated_string => ["a", "b", "c"],
:repeated_bool => [true, false, true, false],
:repeated_msg => [TestMessage2.new(:foo => 1),
TestMessage2.new(:foo => 2)])
json_text = TestMessage.encode_json(m)
m2 = TestMessage.decode_json(json_text)
puts m.inspect
puts m2.inspect
assert m == m2
# Crash case from GitHub issue 283.
bar = Bar.new(msg: "bar")
baz1 = Baz.new(msg: "baz")
baz2 = Baz.new(msg: "quux")
Foo.encode_json(Foo.new)
Foo.encode_json(Foo.new(bar: bar))
Foo.encode_json(Foo.new(bar: bar, baz: [baz1, baz2]))
end
def test_json_emit_defaults
# TODO: Fix JSON in JRuby version.
return if RUBY_PLATFORM == "java"
m = TestMessage.new
expected = {
optionalInt32: 0,
optionalInt64: 0,
optionalUint32: 0,
optionalUint64: 0,
optionalBool: false,
optionalFloat: 0,
optionalDouble: 0,
optionalString: "",
optionalBytes: "",
optionalEnum: "Default",
repeatedInt32: [],
repeatedInt64: [],
repeatedUint32: [],
repeatedUint64: [],
repeatedBool: [],
repeatedFloat: [],
repeatedDouble: [],
repeatedString: [],
repeatedBytes: [],
repeatedMsg: [],
repeatedEnum: []
}
actual = TestMessage.encode_json(m, :emit_defaults => true)
assert JSON.parse(actual, :symbolize_names => true) == expected
end
def test_json_emit_defaults_submsg
# TODO: Fix JSON in JRuby version.
return if RUBY_PLATFORM == "java"
m = TestMessage.new(optional_msg: TestMessage2.new)
expected = {
optionalInt32: 0,
optionalInt64: 0,
optionalUint32: 0,
optionalUint64: 0,
optionalBool: false,
optionalFloat: 0,
optionalDouble: 0,
optionalString: "",
optionalBytes: "",
optionalMsg: {foo: 0},
optionalEnum: "Default",
repeatedInt32: [],
repeatedInt64: [],
repeatedUint32: [],
repeatedUint64: [],
repeatedBool: [],
repeatedFloat: [],
repeatedDouble: [],
repeatedString: [],
repeatedBytes: [],
repeatedMsg: [],
repeatedEnum: []
}
actual = TestMessage.encode_json(m, :emit_defaults => true)
assert JSON.parse(actual, :symbolize_names => true) == expected
end
def test_json_emit_defaults_repeated_submsg
# TODO: Fix JSON in JRuby version.
return if RUBY_PLATFORM == "java"
m = TestMessage.new(repeated_msg: [TestMessage2.new])
expected = {
optionalInt32: 0,
optionalInt64: 0,
optionalUint32: 0,
optionalUint64: 0,
optionalBool: false,
optionalFloat: 0,
optionalDouble: 0,
optionalString: "",
optionalBytes: "",
optionalEnum: "Default",
repeatedInt32: [],
repeatedInt64: [],
repeatedUint32: [],
repeatedUint64: [],
repeatedBool: [],
repeatedFloat: [],
repeatedDouble: [],
repeatedString: [],
repeatedBytes: [],
repeatedMsg: [{foo: 0}],
repeatedEnum: []
}
actual = TestMessage.encode_json(m, :emit_defaults => true)
assert JSON.parse(actual, :symbolize_names => true) == expected
end
def test_json_maps
# TODO: Fix JSON in JRuby version.
return if RUBY_PLATFORM == "java"
m = MapMessage.new(:map_string_int32 => {"a" => 1})
expected = {mapStringInt32: {a: 1}, mapStringMsg: {}}
expected_preserve = {map_string_int32: {a: 1}, map_string_msg: {}}
assert JSON.parse(MapMessage.encode_json(m), :symbolize_names => true) == expected
json = MapMessage.encode_json(m, :preserve_proto_fieldnames => true)
assert JSON.parse(json, :symbolize_names => true) == expected_preserve
m2 = MapMessage.decode_json(MapMessage.encode_json(m))
assert m == m2
end
def test_json_maps_emit_defaults_submsg
# TODO: Fix JSON in JRuby version.
return if RUBY_PLATFORM == "java"
m = MapMessage.new(:map_string_msg => {"a" => TestMessage2.new})
expected = {mapStringInt32: {}, mapStringMsg: {a: {foo: 0}}}
actual = MapMessage.encode_json(m, :emit_defaults => true)
assert JSON.parse(actual, :symbolize_names => true) == expected
end
def test_comparison_with_arbitrary_object
assert MapMessage.new != nil
end
def test_respond_to
# This test fails with JRuby 1.7.23, likely because of an old JRuby bug.
return if RUBY_PLATFORM == "java"
msg = MapMessage.new
assert msg.respond_to?(:map_string_int32)
assert !msg.respond_to?(:bacon)
end
end
end