import static com.google.flatbuffers.Constants.*;
import MyGame.Example.*;
import optional_scalars.ScalarStuff;
import optional_scalars.OptionalByte;
import MyGame.MonsterExtra;
import NamespaceA.*;
import NamespaceA.NamespaceB.*;
import com.google.flatbuffers.ByteBufferUtil;
import com.google.flatbuffers.ByteVector;
import com.google.flatbuffers.FlatBufferBuilder;
import com.google.flatbuffers.FlexBuffers;
import com.google.flatbuffers.FlexBuffersBuilder;
import com.google.flatbuffers.StringVector;
import com.google.flatbuffers.UnionVector;
import com.google.flatbuffers.FlexBuffers.FlexBufferException;
import com.google.flatbuffers.FlexBuffers.Reference;
import com.google.flatbuffers.FlexBuffers.Vector;
import com.google.flatbuffers.ArrayReadWriteBuf;
import com.google.flatbuffers.FlexBuffers.KeyVector;
import java.io.*;
import java.math.BigInteger;
import java.nio.ByteBuffer;
import java.nio.ByteOrder;
import java.nio.CharBuffer;
import java.nio.channels.FileChannel;
import java.nio.charset.StandardCharsets;
import java.util.Arrays;
import java.util.HashMap;
import java.util.Map;
/*
* Copyright 2014 Google Inc. All rights reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
class JavaTest {
public static void main(String[] args) {
// First, let's test reading a FlatBuffer generated by C++ code:
// This file was generated from monsterdata_test.json
byte[] data = null;
File file = new File("monsterdata_test.mon");
RandomAccessFile f = null;
try {
f = new RandomAccessFile(file, "r");
data = new byte[(int)f.length()];
f.readFully(data);
f.close();
} catch(java.io.IOException e) {
System.out.println("FlatBuffers test: couldn't read file");
return;
}
// Now test it:
ByteBuffer bb = ByteBuffer.wrap(data);
TestBuffer(bb);
// Second, let's create a FlatBuffer from scratch in Java, and test it also.
// We use an initial size of 1 to exercise the reallocation algorithm,
// normally a size larger than the typical FlatBuffer you generate would be
// better for performance.
FlatBufferBuilder fbb = new FlatBufferBuilder(1);
TestBuilderBasics(fbb, true);
TestBuilderBasics(fbb, false);
TestExtendedBuffer(fbb.dataBuffer().asReadOnlyBuffer());
TestNamespaceNesting();
TestNestedFlatBuffer();
TestCreateByteVector();
TestCreateUninitializedVector();
TestByteBufferFactory();
TestSizedInputStream();
TestVectorOfUnions();
TestFixedLengthArrays();
TestFlexBuffers();
TestVectorOfBytes();
TestSharedStringPool();
TestScalarOptional();
System.out.println("FlatBuffers test: completed successfully");
}
static void TestEnums() {
TestEq(Color.name(Color.Red), "Red");
TestEq(Color.name(Color.Blue), "Blue");
TestEq(Any.name(Any.NONE), "NONE");
TestEq(Any.name(Any.Monster), "Monster");
}
static void TestBuffer(ByteBuffer bb) {
TestEq(Monster.MonsterBufferHasIdentifier(bb), true);
Monster monster = Monster.getRootAsMonster(bb);
TestEq(monster.hp(), (short)80);
TestEq(monster.mana(), (short)150); // default
TestEq(monster.name(), "MyMonster");
// monster.friendly() // can't access, deprecated
Vec3 pos = monster.pos();
TestEq(pos.x(), 1.0f);
TestEq(pos.y(), 2.0f);
TestEq(pos.z(), 3.0f);
TestEq(pos.test1(), 3.0);
// issue: int != byte
TestEq(pos.test2(), (int) Color.Green);
Test t = pos.test3();
TestEq(t.a(), (short)5);
TestEq(t.b(), (byte)6);
TestEq(monster.testType(), (byte)Any.Monster);
Monster monster2 = new Monster();
TestEq(monster.test(monster2) != null, true);
TestEq(monster2.name(), "Fred");
TestEq(monster.inventoryLength(), 5);
int invsum = 0;
for (int i = 0; i < monster.inventoryLength(); i++)
invsum += monster.inventory(i);
TestEq(invsum, 10);
// Method using a vector access object:
ByteVector inventoryVector = monster.inventoryVector();
TestEq(inventoryVector.length(), 5);
invsum = 0;
for (int i = 0; i < inventoryVector.length(); i++)
invsum += inventoryVector.getAsUnsigned(i);
TestEq(invsum, 10);
// Alternative way of accessing a vector:
ByteBuffer ibb = monster.inventoryAsByteBuffer();
invsum = 0;
while (ibb.position() < ibb.limit())
invsum += ibb.get();
TestEq(invsum, 10);
Test test_0 = monster.test4(0);
Test test_1 = monster.test4(1);
TestEq(monster.test4Length(), 2);
TestEq(test_0.a() + test_0.b() + test_1.a() + test_1.b(), 100);
Test.Vector test4Vector = monster.test4Vector();
test_0 = test4Vector.get(0);
test_1 = test4Vector.get(1);
TestEq(test4Vector.length(), 2);
TestEq(test_0.a() + test_0.b() + test_1.a() + test_1.b(), 100);
TestEq(monster.testarrayofstringLength(), 2);
TestEq(monster.testarrayofstring(0),"test1");
TestEq(monster.testarrayofstring(1),"test2");
// Method using a vector access object:
StringVector testarrayofstringVector = monster.testarrayofstringVector();
TestEq(testarrayofstringVector.length(), 2);
TestEq(testarrayofstringVector.get(0),"test1");
TestEq(testarrayofstringVector.get(1),"test2");
TestEq(monster.testbool(), true);
}
// this method checks additional fields not present in the binary buffer read from file
// these new tests are performed on top of the regular tests
static void TestExtendedBuffer(ByteBuffer bb) {
TestBuffer(bb);
Monster monster = Monster.getRootAsMonster(bb);
TestEq(monster.testhashu32Fnv1(), Integer.MAX_VALUE + 1L);
}
static void TestNamespaceNesting() {
// reference / manipulate these to verify compilation
FlatBufferBuilder fbb = new FlatBufferBuilder(1);
TableInNestedNS.startTableInNestedNS(fbb);
TableInNestedNS.addFoo(fbb, 1234);
int nestedTableOff = TableInNestedNS.endTableInNestedNS(fbb);
TableInFirstNS.startTableInFirstNS(fbb);
TableInFirstNS.addFooTable(fbb, nestedTableOff);
int off = TableInFirstNS.endTableInFirstNS(fbb);
}
static void TestNestedFlatBuffer() {
final String nestedMonsterName = "NestedMonsterName";
final short nestedMonsterHp = 600;
final short nestedMonsterMana = 1024;
FlatBufferBuilder fbb1 = new FlatBufferBuilder(16);
int str1 = fbb1.createString(nestedMonsterName);
Monster.startMonster(fbb1);
Monster.addName(fbb1, str1);
Monster.addHp(fbb1, nestedMonsterHp);
Monster.addMana(fbb1, nestedMonsterMana);
int monster1 = Monster.endMonster(fbb1);
Monster.finishMonsterBuffer(fbb1, monster1);
byte[] fbb1Bytes = fbb1.sizedByteArray();
fbb1 = null;
FlatBufferBuilder fbb2 = new FlatBufferBuilder(16);
int str2 = fbb2.createString("My Monster");
int nestedBuffer = Monster.createTestnestedflatbufferVector(fbb2, fbb1Bytes);
Monster.startMonster(fbb2);
Monster.addName(fbb2, str2);
Monster.addHp(fbb2, (short)50);
Monster.addMana(fbb2, (short)32);
Monster.addTestnestedflatbuffer(fbb2, nestedBuffer);
int monster = Monster.endMonster(fbb2);
Monster.finishMonsterBuffer(fbb2, monster);
// Now test the data extracted from the nested buffer
Monster mons = Monster.getRootAsMonster(fbb2.dataBuffer());
Monster nestedMonster = mons.testnestedflatbufferAsMonster();
TestEq(nestedMonsterMana, nestedMonster.mana());
TestEq(nestedMonsterHp, nestedMonster.hp());
TestEq(nestedMonsterName, nestedMonster.name());
}
static void TestCreateByteVector() {
FlatBufferBuilder fbb = new FlatBufferBuilder(16);
int str = fbb.createString("MyMonster");
byte[] inventory = new byte[] { 0, 1, 2, 3, 4 };
int vec = fbb.createByteVector(inventory);
Monster.startMonster(fbb);
Monster.addInventory(fbb, vec);
Monster.addName(fbb, str);
int monster1 = Monster.endMonster(fbb);
Monster.finishMonsterBuffer(fbb, monster1);
Monster monsterObject = Monster.getRootAsMonster(fbb.dataBuffer());
TestEq(monsterObject.inventory(1), (int)inventory[1]);
TestEq(monsterObject.inventoryLength(), inventory.length);
ByteVector inventoryVector = monsterObject.inventoryVector();
TestEq(inventoryVector.getAsUnsigned(1), (int)inventory[1]);
TestEq(inventoryVector.length(), inventory.length);
TestEq(ByteBuffer.wrap(inventory), monsterObject.inventoryAsByteBuffer());
}
static void TestCreateUninitializedVector() {
FlatBufferBuilder fbb = new FlatBufferBuilder(16);
int str = fbb.createString("MyMonster");
byte[] inventory = new byte[] { 0, 1, 2, 3, 4 };
ByteBuffer bb = fbb.createUnintializedVector(1, inventory.length, 1);
for (byte i:inventory) {
bb.put(i);
}
int vec = fbb.endVector();
Monster.startMonster(fbb);
Monster.addInventory(fbb, vec);
Monster.addName(fbb, str);
int monster1 = Monster.endMonster(fbb);
Monster.finishMonsterBuffer(fbb, monster1);
Monster monsterObject = Monster.getRootAsMonster(fbb.dataBuffer());
TestEq(monsterObject.inventory(1), (int)inventory[1]);
TestEq(monsterObject.inventoryLength(), inventory.length);
ByteVector inventoryVector = monsterObject.inventoryVector();
TestEq(inventoryVector.getAsUnsigned(1), (int)inventory[1]);
TestEq(inventoryVector.length(), inventory.length);
TestEq(ByteBuffer.wrap(inventory), monsterObject.inventoryAsByteBuffer());
}
static void TestByteBufferFactory() {
final class MappedByteBufferFactory extends FlatBufferBuilder.ByteBufferFactory {
@Override
public ByteBuffer newByteBuffer(int capacity) {
ByteBuffer bb;
try {
RandomAccessFile f = new RandomAccessFile("javatest.bin", "rw");
bb = f.getChannel().map(FileChannel.MapMode.READ_WRITE, 0, capacity).order(ByteOrder.LITTLE_ENDIAN);
f.close();
} catch(Throwable e) {
System.out.println("FlatBuffers test: couldn't map ByteBuffer to a file");
bb = null;
}
return bb;
}
}
FlatBufferBuilder fbb = new FlatBufferBuilder(1, new MappedByteBufferFactory());
TestBuilderBasics(fbb, false);
}
static void TestSizedInputStream() {
// Test on default FlatBufferBuilder that uses HeapByteBuffer
FlatBufferBuilder fbb = new FlatBufferBuilder(1);
TestBuilderBasics(fbb, false);
InputStream in = fbb.sizedInputStream();
byte[] array = fbb.sizedByteArray();
int count = 0;
int currentVal = 0;
while (currentVal != -1 && count < array.length) {
try {
currentVal = in.read();
} catch(java.io.IOException e) {
System.out.println("FlatBuffers test: couldn't read from InputStream");
return;
}
TestEq((byte)currentVal, array[count]);
count++;
}
TestEq(count, array.length);
}
static void TestBuilderBasics(FlatBufferBuilder fbb, boolean sizePrefix) {
int[] names = {fbb.createString("Frodo"), fbb.createString("Barney"), fbb.createString("Wilma")};
int[] off = new int[3];
Monster.startMonster(fbb);
Monster.addName(fbb, names[0]);
off[0] = Monster.endMonster(fbb);
Monster.startMonster(fbb);
Monster.addName(fbb, names[1]);
off[1] = Monster.endMonster(fbb);
Monster.startMonster(fbb);
Monster.addName(fbb, names[2]);
off[2] = Monster.endMonster(fbb);
int sortMons = fbb.createSortedVectorOfTables(new Monster(), off);
// We set up the same values as monsterdata.json:
int str = fbb.createString("MyMonster");
int inv = Monster.createInventoryVector(fbb, new byte[] { 0, 1, 2, 3, 4 });
int fred = fbb.createString("Fred");
Monster.startMonster(fbb);
Monster.addName(fbb, fred);
int mon2 = Monster.endMonster(fbb);
Monster.startTest4Vector(fbb, 2);
Test.createTest(fbb, (short)10, (byte)20);
Test.createTest(fbb, (short)30, (byte)40);
int test4 = fbb.endVector();
int testArrayOfString = Monster.createTestarrayofstringVector(fbb, new int[] {
fbb.createString("test1"),
fbb.createString("test2")
});
Monster.startMonster(fbb);
Monster.addPos(fbb, Vec3.createVec3(fbb, 1.0f, 2.0f, 3.0f, 3.0,
Color.Green, (short)5, (byte)6));
Monster.addHp(fbb, (short)80);
Monster.addName(fbb, str);
Monster.addInventory(fbb, inv);
Monster.addTestType(fbb, (byte)Any.Monster);
Monster.addTest(fbb, mon2);
Monster.addTest4(fbb, test4);
Monster.addTestarrayofstring(fbb, testArrayOfString);
Monster.addTestbool(fbb, true);
Monster.addTesthashu32Fnv1(fbb, Integer.MAX_VALUE + 1L);
Monster.addTestarrayoftables(fbb, sortMons);
int mon = Monster.endMonster(fbb);
if (sizePrefix) {
Monster.finishSizePrefixedMonsterBuffer(fbb, mon);
} else {
Monster.finishMonsterBuffer(fbb, mon);
}
// Write the result to a file for debugging purposes:
// Note that the binaries are not necessarily identical, since the JSON
// parser may serialize in a slightly different order than the above
// Java code. They are functionally equivalent though.
try {
String filename = "monsterdata_java_wire" + (sizePrefix ? "_sp" : "") + ".mon";
FileChannel fc = new FileOutputStream(filename).getChannel();
fc.write(fbb.dataBuffer().duplicate());
fc.close();
} catch(java.io.IOException e) {
System.out.println("FlatBuffers test: couldn't write file");
return;
}
// Test it:
ByteBuffer dataBuffer = fbb.dataBuffer();
if (sizePrefix) {
TestEq(ByteBufferUtil.getSizePrefix(dataBuffer) + SIZE_PREFIX_LENGTH,
dataBuffer.remaining());
dataBuffer = ByteBufferUtil.removeSizePrefix(dataBuffer);
}
TestExtendedBuffer(dataBuffer);
// Make sure it also works with read only ByteBuffers. This is slower,
// since creating strings incurs an additional copy
// (see Table.__string).
TestExtendedBuffer(dataBuffer.asReadOnlyBuffer());
TestEnums();
//Attempt to mutate Monster fields and check whether the buffer has been mutated properly
// revert to original values after testing
Monster monster = Monster.getRootAsMonster(dataBuffer);
// mana is optional and does not exist in the buffer so the mutation should fail
// the mana field should retain its default value
TestEq(monster.mutateMana((short)10), false);
TestEq(monster.mana(), (short)150);
// Accessing a vector of sorted by the key tables
TestEq(monster.testarrayoftables(0).name(), "Barney");
TestEq(monster.testarrayoftables(1).name(), "Frodo");
TestEq(monster.testarrayoftables(2).name(), "Wilma");
Monster.Vector testarrayoftablesVector = monster.testarrayoftablesVector();
TestEq(testarrayoftablesVector.get(0).name(), "Barney");
TestEq(testarrayoftablesVector.get(1).name(), "Frodo");
TestEq(testarrayoftablesVector.get(2).name(), "Wilma");
// Example of searching for a table by the key
TestEq(monster.testarrayoftablesByKey("Frodo").name(), "Frodo");
TestEq(monster.testarrayoftablesByKey("Barney").name(), "Barney");
TestEq(monster.testarrayoftablesByKey("Wilma").name(), "Wilma");
TestEq(testarrayoftablesVector.getByKey("Frodo").name(), "Frodo");
TestEq(testarrayoftablesVector.getByKey("Barney").name(), "Barney");
TestEq(testarrayoftablesVector.getByKey("Wilma").name(), "Wilma");
// testType is an existing field and mutating it should succeed
TestEq(monster.testType(), (byte)Any.Monster);
//mutate the inventory vector
TestEq(monster.mutateInventory(0, 1), true);
TestEq(monster.mutateInventory(1, 2), true);
TestEq(monster.mutateInventory(2, 3), true);
TestEq(monster.mutateInventory(3, 4), true);
TestEq(monster.mutateInventory(4, 5), true);
for (int i = 0; i < monster.inventoryLength(); i++) {
TestEq(monster.inventory(i), i + 1);
}
ByteVector inventoryVector = monster.inventoryVector();
for (int i = 0; i < inventoryVector.length(); i++) {
TestEq((int)inventoryVector.get(i), i + 1);
}
//reverse mutation
TestEq(monster.mutateInventory(0, 0), true);
TestEq(monster.mutateInventory(1, 1), true);
TestEq(monster.mutateInventory(2, 2), true);
TestEq(monster.mutateInventory(3, 3), true);
TestEq(monster.mutateInventory(4, 4), true);
// get a struct field and edit one of its fields
Vec3 pos = monster.pos();
TestEq(pos.x(), 1.0f);
pos.mutateX(55.0f);
TestEq(pos.x(), 55.0f);
pos.mutateX(1.0f);
TestEq(pos.x(), 1.0f);
}
static void TestVectorOfUnions() {
final FlatBufferBuilder fbb = new FlatBufferBuilder();
final int swordAttackDamage = 1;
final int[] characterVector = new int[] {
Attacker.createAttacker(fbb, swordAttackDamage),
};
final byte[] characterTypeVector = new byte[]{
Character.MuLan,
};
Movie.finishMovieBuffer(
fbb,
Movie.createMovie(
fbb,
(byte)0,
(byte)0,
Movie.createCharactersTypeVector(fbb, characterTypeVector),
Movie.createCharactersVector(fbb, characterVector)
)
);
final Movie movie = Movie.getRootAsMovie(fbb.dataBuffer());
ByteVector charactersTypeByteVector = movie.charactersTypeVector();
UnionVector charactersVector = movie.charactersVector();
TestEq(movie.charactersTypeLength(), characterTypeVector.length);
TestEq(charactersTypeByteVector.length(), characterTypeVector.length);
TestEq(movie.charactersLength(), characterVector.length);
TestEq(charactersVector.length(), characterVector.length);
TestEq(movie.charactersType(0), characterTypeVector[0]);
TestEq(charactersTypeByteVector.get(0), characterTypeVector[0]);
TestEq(((Attacker)movie.characters(new Attacker(), 0)).swordAttackDamage(), swordAttackDamage);
}
static void TestFixedLengthArrays() {
FlatBufferBuilder builder = new FlatBufferBuilder(0);
float a;
int[] b = new int[15];
byte c;
int[][] d_a = new int[2][2];
byte[] d_b = new byte[2];
byte[][] d_c = new byte[2][2];
long[][] d_d = new long[2][2];
int e;
long[] f = new long[2];
a = 0.5f;
for (int i = 0; i < 15; i++) b[i] = i;
c = 1;
d_a[0][0] = 1;
d_a[0][1] = 2;
d_a[1][0] = 3;
d_a[1][1] = 4;
d_b[0] = TestEnum.B;
d_b[1] = TestEnum.C;
d_c[0][0] = TestEnum.A;
d_c[0][1] = TestEnum.B;
d_c[1][0] = TestEnum.C;
d_c[1][1] = TestEnum.B;
d_d[0][0] = -1;
d_d[0][1] = 1;
d_d[1][0] = -2;
d_d[1][1] = 2;
e = 2;
f[0] = -1;
f[1] = 1;
int arrayOffset = ArrayStruct.createArrayStruct(builder,
a, b, c, d_a, d_b, d_c, d_d, e, f);
// Create a table with the ArrayStruct.
ArrayTable.startArrayTable(builder);
ArrayTable.addA(builder, arrayOffset);
int tableOffset = ArrayTable.endArrayTable(builder);
ArrayTable.finishArrayTableBuffer(builder, tableOffset);
ArrayTable table = ArrayTable.getRootAsArrayTable(builder.dataBuffer());
NestedStruct nested = new NestedStruct();
TestEq(table.a().a(), 0.5f);
for (int i = 0; i < 15; i++) TestEq(table.a().b(i), i);
TestEq(table.a().c(), (byte)1);
TestEq(table.a().d(nested, 0).a(0), 1);
TestEq(table.a().d(nested, 0).a(1), 2);
TestEq(table.a().d(nested, 1).a(0), 3);
TestEq(table.a().d(nested, 1).a(1), 4);
TestEq(table.a().d(nested, 0).b(), TestEnum.B);
TestEq(table.a().d(nested, 1).b(), TestEnum.C);
TestEq(table.a().d(nested, 0).c(0), TestEnum.A);
TestEq(table.a().d(nested, 0).c(1), TestEnum.B);
TestEq(table.a().d(nested, 1).c(0), TestEnum.C);
TestEq(table.a().d(nested, 1).c(1), TestEnum.B);
TestEq(table.a().d(nested, 0).d(0), (long)-1);
TestEq(table.a().d(nested, 0).d(1), (long)1);
TestEq(table.a().d(nested, 1).d(0), (long)-2);
TestEq(table.a().d(nested, 1).d(1), (long)2);
TestEq(table.a().e(), 2);
TestEq(table.a().f(0), (long)-1);
TestEq(table.a().f(1), (long)1);
}
public static void testFlexBuffersTest() {
FlexBuffersBuilder builder = new FlexBuffersBuilder(ByteBuffer.allocate(512),
FlexBuffersBuilder.BUILDER_FLAG_SHARE_KEYS_AND_STRINGS);
testFlexBuffersTest(builder);
int bufferLimit1 = ((ArrayReadWriteBuf) builder.getBuffer()).limit();
// Repeat after clearing the builder to ensure the builder is reusable
builder.clear();
testFlexBuffersTest(builder);
int bufferLimit2 = ((ArrayReadWriteBuf) builder.getBuffer()).limit();
TestEq(bufferLimit1, bufferLimit2);
}
public static void testFlexBuffersTest(FlexBuffersBuilder builder) {
// Write the equivalent of:
// { vec: [ -100, "Fred", 4.0, false ], bar: [ 1, 2, 3 ], bar3: [ 1, 2, 3 ],
// foo: 100, bool: true, mymap: { foo: "Fred" } }
// It's possible to do this without std::function support as well.
int map1 = builder.startMap();
int vec1 = builder.startVector();
builder.putInt(-100);
builder.putString("Fred");
builder.putBlob(new byte[]{(byte) 77});
builder.putBoolean(false);
builder.putInt(Long.MAX_VALUE);
int map2 = builder.startMap();
builder.putInt("test", 200);
builder.endMap(null, map2);
builder.putFloat(150.9);
builder.putFloat(150.9999998);
builder.endVector("vec", vec1, false, false);
vec1 = builder.startVector();
builder.putInt(1);
builder.putInt(2);
builder.putInt(3);
builder.endVector("bar", vec1, true, false);
vec1 = builder.startVector();
builder.putBoolean(true);
builder.putBoolean(false);
builder.putBoolean(true);
builder.putBoolean(false);
builder.endVector("bools", vec1, true, false);
builder.putBoolean("bool", true);
builder.putFloat("foo", 100);
map2 = builder.startMap();
builder.putString("bar", "Fred"); // Testing key and string reuse.
builder.putInt("int", -120);
builder.putFloat("float", -123.0f);
builder.putBlob("blob", new byte[]{ 65, 67 });
builder.endMap("mymap", map2);
builder.endMap(null, map1);
builder.finish();
FlexBuffers.Map m = FlexBuffers.getRoot(builder.getBuffer()).asMap();
TestEq(m.size(), 6);
// test empty (an null)
TestEq(m.get("no_key").asString(), ""); // empty if fail
TestEq(m.get("no_key").asMap(), FlexBuffers.Map.empty()); // empty if fail
TestEq(m.get("no_key").asKey(), FlexBuffers.Key.empty()); // empty if fail
TestEq(m.get("no_key").asVector(), FlexBuffers.Vector.empty()); // empty if fail
TestEq(m.get("no_key").asBlob(), FlexBuffers.Blob.empty()); // empty if fail
assert(m.get("no_key").asVector().isEmpty()); // empty if fail
// testing "vec" field
FlexBuffers.Vector vec = m.get("vec").asVector();
TestEq(vec.size(), 8);
TestEq(vec.get(0).asLong(), (long) -100);
TestEq(vec.get(1).asString(), "Fred");
TestEq(vec.get(2).isBlob(), true);
TestEq(vec.get(2).asBlob().size(), 1);
TestEq(vec.get(2).asBlob().data().get(0), (byte) 77);
TestEq(vec.get(3).isBoolean(), true); // Check if type is a bool
TestEq(vec.get(3).asBoolean(), false); // Check if value is false
TestEq(vec.get(4).asLong(), Long.MAX_VALUE);
TestEq(vec.get(5).isMap(), true);
TestEq(vec.get(5).asMap().get("test").asInt(), 200);
TestEq(Float.compare((float)vec.get(6).asFloat(), 150.9f), 0);
TestEq(Double.compare(vec.get(7).asFloat(), 150.9999998), 0);
TestEq((long)0, (long)vec.get(1).asLong()); //conversion fail returns 0 as C++
// bar vector
FlexBuffers.Vector tvec = m.get("bar").asVector();
TestEq(tvec.size(), 3);
TestEq(tvec.get(0).asInt(), 1);
TestEq(tvec.get(1).asInt(), 2);
TestEq(tvec.get(2).asInt(), 3);
TestEq(((FlexBuffers.TypedVector) tvec).getElemType(), FlexBuffers.FBT_INT);
// bools vector
FlexBuffers.Vector bvec = m.get("bools").asVector();
TestEq(bvec.size(), 4);
TestEq(bvec.get(0).asBoolean(), true);
TestEq(bvec.get(1).asBoolean(), false);
TestEq(bvec.get(2).asBoolean(), true);
TestEq(bvec.get(3).asBoolean(), false);
TestEq(((FlexBuffers.TypedVector) bvec).getElemType(), FlexBuffers.FBT_BOOL);
TestEq((float)m.get("foo").asFloat(), (float) 100);
TestEq(m.get("unknown").isNull(), true);
// mymap vector
FlexBuffers.Map mymap = m.get("mymap").asMap();
TestEq(mymap.keys().get(0), m.keys().get(0)); // These should be equal by pointer equality, since key and value are shared.
TestEq(mymap.keys().get(0).toString(), "bar");
TestEq(mymap.values().get(0).asString(), vec.get(1).asString());
TestEq(mymap.get("int").asInt(), -120);
TestEq((float)mymap.get("float").asFloat(), -123.0f);
TestEq(Arrays.equals(mymap.get("blob").asBlob().getBytes(), new byte[]{ 65, 67 }), true);
TestEq(mymap.get("blob").asBlob().toString(), "AC");
TestEq(mymap.get("blob").toString(), "\"AC\"");
}
public static void testFlexBufferVectorStrings() {
FlexBuffersBuilder builder = new FlexBuffersBuilder(ByteBuffer.allocate(10000000));
int size = 3000;
StringBuilder sb = new StringBuilder();
for (int i=0; i< size; i++) {
sb.append("a");
}
String text = sb.toString();
TestEq(text.length(), size);
int pos = builder.startVector();
for (int i=0; i<size; i++) {
builder.putString(text);
}
try {
builder.endVector(null, pos, true, false);
// this should raise an exception as
// typed vector of string was deprecated
assert false;
} catch(FlexBufferException fb) {
// no op
}
// we finish the vector again as non-typed
builder.endVector(null, pos, false, false);
ByteBuffer b = builder.finish();
Vector v = FlexBuffers.getRoot(b).asVector();
TestEq(v.size(), size);
for (int i=0; i<size; i++) {
TestEq(v.get(i).asString().length(), size);
TestEq(v.get(i).asString(), text);
}
}
public static void testDeprecatedTypedVectorString() {
// tests whether we are able to support reading deprecated typed vector string
// data is equivalent to [ "abc", "abc", "abc", "abc"]
byte[] data = new byte[] {0x03, 0x61, 0x62, 0x63, 0x00, 0x03, 0x61, 0x62, 0x63, 0x00,
0x03, 0x61, 0x62, 0x63, 0x00, 0x03, 0x61, 0x62, 0x63, 0x00, 0x04, 0x14, 0x10,
0x0c, 0x08, 0x04, 0x3c, 0x01};
Reference ref = FlexBuffers.getRoot(ByteBuffer.wrap(data));
TestEq(ref.getType(), FlexBuffers.FBT_VECTOR_STRING_DEPRECATED);
TestEq(ref.isTypedVector(), true);
Vector vec = ref.asVector();
for (int i=0; i< vec.size(); i++) {
TestEq("abc", vec.get(i).asString());
}
}
public static void testSingleElementBoolean() {
FlexBuffersBuilder builder = new FlexBuffersBuilder(ByteBuffer.allocate(100));
builder.putBoolean(true);
ByteBuffer b = builder.finish();
assert(FlexBuffers.getRoot(b).asBoolean());
}
public static void testSingleElementByte() {
FlexBuffersBuilder builder = new FlexBuffersBuilder();
builder.putInt(10);
ByteBuffer b = builder.finish();
TestEq(10, FlexBuffers.getRoot(b).asInt());
}
public static void testSingleElementShort() {
FlexBuffersBuilder builder = new FlexBuffersBuilder();
builder.putInt(Short.MAX_VALUE);
ByteBuffer b = builder.finish();
TestEq(Short.MAX_VALUE, (short)FlexBuffers.getRoot(b).asInt());
}
public static void testSingleElementInt() {
FlexBuffersBuilder builder = new FlexBuffersBuilder();
builder.putInt(Integer.MIN_VALUE);
ByteBuffer b = builder.finish();
TestEq(Integer.MIN_VALUE, FlexBuffers.getRoot(b).asInt());
}
public static void testSingleElementLong() {
FlexBuffersBuilder builder = new FlexBuffersBuilder();
builder.putInt(Long.MAX_VALUE);
ByteBuffer b = builder.finish();
TestEq(Long.MAX_VALUE, FlexBuffers.getRoot(b).asLong());
}
public static void testSingleElementFloat() {
FlexBuffersBuilder builder = new FlexBuffersBuilder();
builder.putFloat(Float.MAX_VALUE);
ByteBuffer b = builder.finish();
TestEq(Float.compare(Float.MAX_VALUE, (float) FlexBuffers.getRoot(b).asFloat()), 0);
}
public static void testSingleElementDouble() {
FlexBuffersBuilder builder = new FlexBuffersBuilder();
builder.putFloat(Double.MAX_VALUE);
ByteBuffer b = builder.finish();
TestEq(Double.compare(Double.MAX_VALUE, FlexBuffers.getRoot(b).asFloat()), 0);
}
public static void testSingleElementBigString() {
FlexBuffersBuilder builder = new FlexBuffersBuilder(ByteBuffer.allocate(10000));
StringBuilder sb = new StringBuilder();
for (int i=0; i< 3000; i++) {
sb.append("a");
}
builder.putString(sb.toString());
ByteBuffer b = builder.finish();
FlexBuffers.Reference r = FlexBuffers.getRoot(b);
TestEq(FlexBuffers.FBT_STRING, r.getType());
TestEq(sb.toString(), r.asString());
}
public static void testSingleElementSmallString() {
FlexBuffersBuilder builder = new FlexBuffersBuilder(ByteBuffer.allocate(10000));
builder.putString("aa");
ByteBuffer b = builder.finish();
FlexBuffers.Reference r = FlexBuffers.getRoot(b);
TestEq(FlexBuffers.FBT_STRING, r.getType());
TestEq("aa", r.asString());
}
public static void testSingleElementBlob() {
FlexBuffersBuilder builder = new FlexBuffersBuilder();
builder.putBlob(new byte[]{5, 124, 118, -1});
ByteBuffer b = builder.finish();
FlexBuffers.Reference r = FlexBuffers.getRoot(b);
byte[] result = r.asBlob().getBytes();
TestEq((byte)5, result[0]);
TestEq((byte)124, result[1]);
TestEq((byte)118, result[2]);
TestEq((byte)-1, result[3]);
}
public static void testSingleElementUByte() {
FlexBuffersBuilder builder = new FlexBuffersBuilder();
builder.putUInt(0xFF);
ByteBuffer b = builder.finish();
FlexBuffers.Reference r = FlexBuffers.getRoot(b);
TestEq(255, (int)r.asUInt());
}
public static void testSingleElementUShort() {
FlexBuffersBuilder builder = new FlexBuffersBuilder();
builder.putUInt(0xFFFF);
ByteBuffer b = builder.finish();
FlexBuffers.Reference r = FlexBuffers.getRoot(b);
TestEq(65535, (int)r.asUInt());
}
public static void testSingleElementUInt() {
FlexBuffersBuilder builder = new FlexBuffersBuilder();
builder.putUInt(0xFFFF_FFFFL);
ByteBuffer b = builder.finish();
FlexBuffers.Reference r = FlexBuffers.getRoot(b);
TestEq(4294967295L, r.asUInt());
}
public static void testSingleFixedTypeVector() {
int[] ints = new int[]{5, 124, 118, -1};
float[] floats = new float[]{5.5f, 124.124f, 118.118f, -1.1f};
String[] strings = new String[]{"This", "is", "a", "typed", "array"};
boolean[] booleans = new boolean[]{false, true, true, false};
FlexBuffersBuilder builder = new FlexBuffersBuilder(ByteBuffer.allocate(512),
FlexBuffersBuilder.BUILDER_FLAG_NONE);
int mapPos = builder.startMap();
int vecPos = builder.startVector();
for (final int i : ints) {
builder.putInt(i);
}
builder.endVector("ints", vecPos, true, false);
vecPos = builder.startVector();
for (final float i : floats) {
builder.putFloat(i);
}
builder.endVector("floats", vecPos, true, false);
vecPos = builder.startVector();
for (final boolean i : booleans) {
builder.putBoolean(i);
}
builder.endVector("booleans", vecPos, true, false);
builder.endMap(null, mapPos);
ByteBuffer b = builder.finish();
FlexBuffers.Reference r = FlexBuffers.getRoot(b);
assert(r.asMap().get("ints").isTypedVector());
assert(r.asMap().get("floats").isTypedVector());
assert(r.asMap().get("booleans").isTypedVector());
}
public static void testSingleElementVector() {
FlexBuffersBuilder b = new FlexBuffersBuilder();
int vecPos = b.startVector();
b.putInt(99);
b.putString("wow");
int vecpos2 = b.startVector();
b.putInt(99);
b.putString("wow");
b.endVector(null, vecpos2, false, false);
b.endVector(null, vecPos, false, false);
b.finish();
FlexBuffers.Reference r = FlexBuffers.getRoot(b.getBuffer());
TestEq(FlexBuffers.FBT_VECTOR, r.getType());
FlexBuffers.Vector vec = FlexBuffers.getRoot(b.getBuffer()).asVector();
TestEq(3, vec.size());
TestEq(99, vec.get(0).asInt());
TestEq("wow", vec.get(1).asString());
TestEq("[ 99, \"wow\" ]", vec.get(2).toString());
TestEq("[ 99, \"wow\", [ 99, \"wow\" ] ]", FlexBuffers.getRoot(b.getBuffer()).toString());
}
public static void testSingleElementMap() {
FlexBuffersBuilder b = new FlexBuffersBuilder();
int mapPost = b.startMap();
b.putInt("myInt", 0x7fffffbbbfffffffL);
b.putString("myString", "wow");
b.putString("myString2", "incredible");
int start = b.startVector();
b.putInt(99);
b.putString("wow");
b.endVector("myVec", start, false, false);
b.putFloat("double", 0x1.ffffbbbffffffP+1023);
b.endMap(null, mapPost);
b.finish();
FlexBuffers.Reference r = FlexBuffers.getRoot(b.getBuffer());
TestEq(FlexBuffers.FBT_MAP, r.getType());
FlexBuffers.Map map = FlexBuffers.getRoot(b.getBuffer()).asMap();
TestEq(5, map.size());
TestEq(0x7fffffbbbfffffffL, map.get("myInt").asLong());
TestEq("wow", map.get("myString").asString());
TestEq("incredible", map.get("myString2").asString());
TestEq(99, map.get("myVec").asVector().get(0).asInt());
TestEq("wow", map.get("myVec").asVector().get(1).asString());
TestEq(Double.compare(0x1.ffffbbbffffffP+1023, map.get("double").asFloat()), 0);
TestEq("{ \"double\" : 1.7976894783391937E308, \"myInt\" : 9223371743723257855, \"myString\" : \"wow\", \"myString2\" : \"incredible\", \"myVec\" : [ 99, \"wow\" ] }",
FlexBuffers.getRoot(b.getBuffer()).toString());
}
public static void testFlexBuferEmpty() {
FlexBuffers.Blob blob = FlexBuffers.Blob.empty();
FlexBuffers.Map ary = FlexBuffers.Map.empty();
FlexBuffers.Vector map = FlexBuffers.Vector.empty();
FlexBuffers.TypedVector typedAry = FlexBuffers.TypedVector.empty();
TestEq(blob.size(), 0);
TestEq(map.size(), 0);
TestEq(ary.size(), 0);
TestEq(typedAry.size(), 0);
}
public static void testHashMapToMap() {
int entriesCount = 12;
HashMap<String, String> source = new HashMap<>();
for (int i = 0; i < entriesCount; i++) {
source.put("foo_param_" + i, "foo_value_" + i);
}
FlexBuffersBuilder builder = new FlexBuffersBuilder(1000);
int mapStart = builder.startMap();
for (Map.Entry<String, String> entry : source.entrySet()) {
builder.putString(entry.getKey(), entry.getValue());
}
builder.endMap(null, mapStart);
ByteBuffer bb = builder.finish();
bb.rewind();
FlexBuffers.Reference rootReference = FlexBuffers.getRoot(bb);
TestEq(rootReference.isMap(), true);
FlexBuffers.Map flexMap = rootReference.asMap();
FlexBuffers.KeyVector keys = flexMap.keys();
FlexBuffers.Vector values = flexMap.values();
TestEq(entriesCount, keys.size());
TestEq(entriesCount, values.size());
HashMap<String, String> result = new HashMap<>();
for (int i = 0; i < keys.size(); i++) {
result.put(keys.get(i).toString(), values.get(i).asString());
}
TestEq(source, result);
}
public static void testBuilderGrowth() {
FlexBuffersBuilder builder = new FlexBuffersBuilder();
String someString = "This is a small string";
builder.putString(someString);
ByteBuffer b = builder.finish();
TestEq(someString, FlexBuffers.getRoot(b).asString());
FlexBuffersBuilder failBuilder = new FlexBuffersBuilder(ByteBuffer.allocate(1));
failBuilder.putString(someString);
}
public static void testFlexBuffersUtf8Map() {
FlexBuffersBuilder builder = new FlexBuffersBuilder(ByteBuffer.allocate(512),
FlexBuffersBuilder.BUILDER_FLAG_SHARE_KEYS_AND_STRINGS);
String key0 = "😨 face1";
String key1 = "😩 face2";
String key2 = "😨 face3";
String key3 = "trademark ®";
String key4 = "€ euro";
String utf8keys[] = { "😨 face1", "😩 face2", "😨 face3", "trademark ®", "€ euro"};
int map = builder.startMap();
for (int i=0; i< utf8keys.length; i++) {
builder.putString(utf8keys[i], utf8keys[i]); // Testing key and string reuse.
}
builder.endMap(null, map);
builder.finish();
FlexBuffers.Map m = FlexBuffers.getRoot(builder.getBuffer()).asMap();
TestEq(m.size(), 5);
KeyVector kv = m.keys();
for (int i=0; i< utf8keys.length; i++) {
TestEq(kv.get(i).toString(), m.get(i).asString());
}
TestEq(m.get(key0).asString(), utf8keys[0]);
TestEq(m.get(key1).asString(), utf8keys[1]);
TestEq(m.get(key2).asString(), utf8keys[2]);
TestEq(m.get(key3).asString(), utf8keys[3]);
TestEq(m.get(key4).asString(), utf8keys[4]);
}
public static void TestFlexBuffers() {
testSingleElementByte();
testSingleElementShort();
testSingleElementInt();
testSingleElementLong();
testSingleElementFloat();
testSingleElementDouble();
testSingleElementSmallString();
testSingleElementBigString();
testSingleElementBlob();
testSingleElementVector();
testSingleFixedTypeVector();
testSingleElementUShort();
testSingleElementUInt();
testSingleElementUByte();
testSingleElementMap();
testFlexBuffersTest();
testHashMapToMap();
testFlexBuferEmpty();
testFlexBufferVectorStrings();
testDeprecatedTypedVectorString();
testBuilderGrowth();
testFlexBuffersUtf8Map();
}
static void TestVectorOfBytes() {
FlatBufferBuilder fbb = new FlatBufferBuilder(16);
int str = fbb.createString("ByteMonster");
byte[] data = new byte[] {0, 1, 2, 3, 4, 5, 6, 7, 8, 9};
int offset = Monster.createInventoryVector(fbb, data);
Monster.startMonster(fbb);
Monster.addName(fbb, str);
Monster.addInventory(fbb, offset);
int monster1 = Monster.endMonster(fbb);
Monster.finishMonsterBuffer(fbb, monster1);
Monster monsterObject = Monster.getRootAsMonster(fbb.dataBuffer());
TestEq(monsterObject.inventoryLength(), data.length);
TestEq(monsterObject.inventory(4), (int) data[4]);
TestEq(ByteBuffer.wrap(data), monsterObject.inventoryAsByteBuffer());
fbb.clear();
ByteBuffer bb = ByteBuffer.wrap(data);
offset = fbb.createByteVector(bb);
str = fbb.createString("ByteMonster");
Monster.startMonster(fbb);
Monster.addName(fbb, str);
Monster.addInventory(fbb, offset);
monster1 = Monster.endMonster(fbb);
Monster.finishMonsterBuffer(fbb, monster1);
Monster monsterObject2 = Monster.getRootAsMonster(fbb.dataBuffer());
TestEq(monsterObject2.inventoryLength(), data.length);
for (int i = 0; i < data.length; i++) {
TestEq(monsterObject2.inventory(i), (int) bb.get(i));
}
fbb.clear();
offset = fbb.createByteVector(data, 3, 4);
str = fbb.createString("ByteMonster");
Monster.startMonster(fbb);
Monster.addName(fbb, str);
Monster.addInventory(fbb, offset);
monster1 = Monster.endMonster(fbb);
Monster.finishMonsterBuffer(fbb, monster1);
Monster monsterObject3 = Monster.getRootAsMonster(fbb.dataBuffer());
TestEq(monsterObject3.inventoryLength(), 4);
TestEq(monsterObject3.inventory(0), (int) data[3]);
fbb.clear();
bb = ByteBuffer.wrap(data);
offset = Monster.createInventoryVector(fbb, bb);
str = fbb.createString("ByteMonster");
Monster.startMonster(fbb);
Monster.addName(fbb, str);
Monster.addInventory(fbb, offset);
monster1 = Monster.endMonster(fbb);
Monster.finishMonsterBuffer(fbb, monster1);
Monster monsterObject4 = Monster.getRootAsMonster(fbb.dataBuffer());
TestEq(monsterObject4.inventoryLength(), data.length);
TestEq(monsterObject4.inventory(8), (int) 8);
fbb.clear();
byte[] largeData = new byte[1024];
offset = fbb.createByteVector(largeData);
str = fbb.createString("ByteMonster");
Monster.startMonster(fbb);
Monster.addName(fbb, str);
Monster.addInventory(fbb, offset);
monster1 = Monster.endMonster(fbb);
Monster.finishMonsterBuffer(fbb, monster1);
Monster monsterObject5 = Monster.getRootAsMonster(fbb.dataBuffer());
TestEq(monsterObject5.inventoryLength(), largeData.length);
TestEq(monsterObject5.inventory(25), (int) largeData[25]);
fbb.clear();
bb = ByteBuffer.wrap(largeData);
bb.position(512);
ByteBuffer bb2 = bb.slice();
TestEq(bb2.arrayOffset(), 512);
offset = fbb.createByteVector(bb2);
str = fbb.createString("ByteMonster");
Monster.startMonster(fbb);
Monster.addName(fbb, str);
Monster.addInventory(fbb, offset);
monster1 = Monster.endMonster(fbb);
Monster.finishMonsterBuffer(fbb, monster1);
Monster monsterObject6 = Monster.getRootAsMonster(fbb.dataBuffer());
TestEq(monsterObject6.inventoryLength(), 512);
TestEq(monsterObject6.inventory(0), (int) largeData[512]);
fbb.clear();
bb = ByteBuffer.wrap(largeData);
bb.limit(256);
offset = fbb.createByteVector(bb);
str = fbb.createString("ByteMonster");
Monster.startMonster(fbb);
Monster.addName(fbb, str);
Monster.addInventory(fbb, offset);
monster1 = Monster.endMonster(fbb);
Monster.finishMonsterBuffer(fbb, monster1);
Monster monsterObject7 = Monster.getRootAsMonster(fbb.dataBuffer());
TestEq(monsterObject7.inventoryLength(), 256);
fbb.clear();
bb = ByteBuffer.allocateDirect(2048);
offset = fbb.createByteVector(bb);
str = fbb.createString("ByteMonster");
Monster.startMonster(fbb);
Monster.addName(fbb, str);
Monster.addInventory(fbb, offset);
monster1 = Monster.endMonster(fbb);
Monster.finishMonsterBuffer(fbb, monster1);
Monster monsterObject8 = Monster.getRootAsMonster(fbb.dataBuffer());
TestEq(monsterObject8.inventoryLength(), 2048);
}
static void TestSharedStringPool() {
FlatBufferBuilder fb = new FlatBufferBuilder(1);
String testString = "My string";
int offset = fb.createSharedString(testString);
for (int i=0; i< 10; i++) {
TestEq(offset, fb.createSharedString(testString));
}
}
static void TestScalarOptional() {
FlatBufferBuilder fbb = new FlatBufferBuilder(1);
ScalarStuff.startScalarStuff(fbb);
int pos = ScalarStuff.endScalarStuff(fbb);
fbb.finish(pos);
ScalarStuff scalarStuff = ScalarStuff.getRootAsScalarStuff(fbb.dataBuffer());
TestEq(scalarStuff.justI8(), (byte)0);
TestEq(scalarStuff.maybeI8(), (byte)0);
TestEq(scalarStuff.defaultI8(), (byte)42);
TestEq(scalarStuff.justU8(), 0);
TestEq(scalarStuff.maybeU8(), 0);
TestEq(scalarStuff.defaultU8(), 42);
TestEq(scalarStuff.justI16(), (short)0);
TestEq(scalarStuff.maybeI16(), (short)0);
TestEq(scalarStuff.defaultI16(), (short)42);
TestEq(scalarStuff.justU16(), 0);
TestEq(scalarStuff.maybeU16(), 0);
TestEq(scalarStuff.defaultU16(), 42);
TestEq(scalarStuff.justI32(), 0);
TestEq(scalarStuff.maybeI32(), 0);
TestEq(scalarStuff.defaultI32(), 42);
TestEq(scalarStuff.justU32(), 0L);
TestEq(scalarStuff.maybeU32(), 0L);
TestEq(scalarStuff.defaultU32(), 42L);
TestEq(scalarStuff.justI64(), 0L);
TestEq(scalarStuff.maybeI64(), 0L);
TestEq(scalarStuff.defaultI64(), 42L);
TestEq(scalarStuff.justU64(), 0L);
TestEq(scalarStuff.maybeU64(), 0L);
TestEq(scalarStuff.defaultU64(), 42L);
TestEq(scalarStuff.justF32(), 0.0f);
TestEq(scalarStuff.maybeF32(), 0f);
TestEq(scalarStuff.defaultF32(), 42.0f);
TestEq(scalarStuff.justF64(), 0.0);
TestEq(scalarStuff.maybeF64(), 0.0);
TestEq(scalarStuff.defaultF64(), 42.0);
TestEq(scalarStuff.justBool(), false);
TestEq(scalarStuff.maybeBool(), false);
TestEq(scalarStuff.defaultBool(), true);
TestEq(scalarStuff.justEnum(), OptionalByte.None);
TestEq(scalarStuff.maybeEnum(), OptionalByte.None);
TestEq(scalarStuff.defaultEnum(), OptionalByte.One);
TestEq(scalarStuff.hasMaybeI8(), false);
TestEq(scalarStuff.hasMaybeI16(), false);
TestEq(scalarStuff.hasMaybeI32(), false);
TestEq(scalarStuff.hasMaybeI64(), false);
TestEq(scalarStuff.hasMaybeU8(), false);
TestEq(scalarStuff.hasMaybeU16(), false);
TestEq(scalarStuff.hasMaybeU32(), false);
TestEq(scalarStuff.hasMaybeU64(), false);
TestEq(scalarStuff.hasMaybeF32(), false);
TestEq(scalarStuff.hasMaybeF64(), false);
TestEq(scalarStuff.hasMaybeBool(), false);
TestEq(scalarStuff.hasMaybeEnum(), false);
fbb.clear();
ScalarStuff.startScalarStuff(fbb);
ScalarStuff.addJustI8(fbb, (byte)5);
ScalarStuff.addMaybeI8(fbb, (byte)5);
ScalarStuff.addDefaultI8(fbb, (byte)5);
ScalarStuff.addJustU8(fbb, 6);
ScalarStuff.addMaybeU8(fbb, 6);
ScalarStuff.addDefaultU8(fbb, 6);
ScalarStuff.addJustI16(fbb, (short)7);
ScalarStuff.addMaybeI16(fbb, (short)7);
ScalarStuff.addDefaultI16(fbb, (short)7);
ScalarStuff.addJustU16(fbb, 8);
ScalarStuff.addMaybeU16(fbb, 8);
ScalarStuff.addDefaultU16(fbb, 8);
ScalarStuff.addJustI32(fbb, 9);
ScalarStuff.addMaybeI32(fbb, 9);
ScalarStuff.addDefaultI32(fbb, 9);
ScalarStuff.addJustU32(fbb, (long)10);
ScalarStuff.addMaybeU32(fbb, (long)10);
ScalarStuff.addDefaultU32(fbb, (long)10);
ScalarStuff.addJustI64(fbb, 11L);
ScalarStuff.addMaybeI64(fbb, 11L);
ScalarStuff.addDefaultI64(fbb, 11L);
ScalarStuff.addJustU64(fbb, 12L);
ScalarStuff.addMaybeU64(fbb, 12L);
ScalarStuff.addDefaultU64(fbb, 12L);
ScalarStuff.addJustF32(fbb, 13.0f);
ScalarStuff.addMaybeF32(fbb, 13.0f);
ScalarStuff.addDefaultF32(fbb, 13.0f);
ScalarStuff.addJustF64(fbb, 14.0);
ScalarStuff.addMaybeF64(fbb, 14.0);
ScalarStuff.addDefaultF64(fbb, 14.0);
ScalarStuff.addJustBool(fbb, true);
ScalarStuff.addMaybeBool(fbb, true);
ScalarStuff.addDefaultBool(fbb, true);
ScalarStuff.addJustEnum(fbb, OptionalByte.Two);
ScalarStuff.addMaybeEnum(fbb, OptionalByte.Two);
ScalarStuff.addDefaultEnum(fbb, OptionalByte.Two);
pos = ScalarStuff.endScalarStuff(fbb);
fbb.finish(pos);
scalarStuff = ScalarStuff.getRootAsScalarStuff(fbb.dataBuffer());
TestEq(scalarStuff.justI8(), (byte)5);
TestEq(scalarStuff.maybeI8(), (byte)5);
TestEq(scalarStuff.defaultI8(), (byte)5);
TestEq(scalarStuff.justU8(), 6);
TestEq(scalarStuff.maybeU8(), 6);
TestEq(scalarStuff.defaultU8(), 6);
TestEq(scalarStuff.justI16(), (short)7);
TestEq(scalarStuff.maybeI16(), (short)7);
TestEq(scalarStuff.defaultI16(), (short)7);
TestEq(scalarStuff.justU16(), 8);
TestEq(scalarStuff.maybeU16(), 8);
TestEq(scalarStuff.defaultU16(), 8);
TestEq(scalarStuff.justI32(), 9);
TestEq(scalarStuff.maybeI32(), 9);
TestEq(scalarStuff.defaultI32(), 9);
TestEq(scalarStuff.justU32(), 10L);
TestEq(scalarStuff.maybeU32(), 10L);
TestEq(scalarStuff.defaultU32(), 10L);
TestEq(scalarStuff.justI64(), 11L);
TestEq(scalarStuff.maybeI64(), 11L);
TestEq(scalarStuff.defaultI64(), 11L);
TestEq(scalarStuff.justU64(), 12L);
TestEq(scalarStuff.maybeU64(), 12L);
TestEq(scalarStuff.defaultU64(), 12L);
TestEq(scalarStuff.justF32(), 13.0f);
TestEq(scalarStuff.maybeF32(), 13.0f);
TestEq(scalarStuff.defaultF32(), 13.0f);
TestEq(scalarStuff.justF64(), 14.0);
TestEq(scalarStuff.maybeF64(), 14.0);
TestEq(scalarStuff.defaultF64(), 14.0);
TestEq(scalarStuff.justBool(), true);
TestEq(scalarStuff.maybeBool(), true);
TestEq(scalarStuff.defaultBool(), true);
TestEq(scalarStuff.justEnum(), OptionalByte.Two);
TestEq(scalarStuff.maybeEnum(), OptionalByte.Two);
TestEq(scalarStuff.defaultEnum(), OptionalByte.Two);
TestEq(scalarStuff.hasMaybeI8(), true);
TestEq(scalarStuff.hasMaybeI16(), true);
TestEq(scalarStuff.hasMaybeI32(), true);
TestEq(scalarStuff.hasMaybeI64(), true);
TestEq(scalarStuff.hasMaybeU8(), true);
TestEq(scalarStuff.hasMaybeU16(), true);
TestEq(scalarStuff.hasMaybeU32(), true);
TestEq(scalarStuff.hasMaybeU64(), true);
TestEq(scalarStuff.hasMaybeF32(), true);
TestEq(scalarStuff.hasMaybeF64(), true);
TestEq(scalarStuff.hasMaybeBool(), true);
TestEq(scalarStuff.hasMaybeEnum(), true);
}
static <T> void TestEq(T a, T b) {
if ((a == null && a != b) || (a != null && !a.equals(b))) {
System.out.println("" + a.getClass().getName() + " " + b.getClass().getName());
System.out.println("FlatBuffers test FAILED: \'" + a + "\' != \'" + b + "\'");
new Throwable().printStackTrace();
assert false;
System.exit(1);
}
}
}