tests/ffi/vmspecific_highmem_32bit_test.dart - sdk.git - Git at Google

 // Copyright (c) 2019, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file

 import 'dart:ffi';
 import 'dart:io';

 import 'package:expect/expect.dart';

 import 'ffi_test_helpers.dart';

 // void* mmap(void* addr, size_t length,
 //            int prot, int flags,
 //            int fd, off_t offset)
 typedef MMapNative = Pointer<Uint8> Function(Pointer<Uint8> address, IntPtr len,
     IntPtr prot, IntPtr flags, IntPtr fd, IntPtr offset);
 typedef MMap = Pointer<Uint8> Function(
     Pointer<Uint8> address, int len, int prot, int flags, int fd, int offset);
 final mmap = processSymbols.lookupFunction<MMapNative, MMap>('mmap');

 // int munmap(void *addr, size_t length)
 typedef MUnMapNative = IntPtr Function(Pointer<Uint8> address, IntPtr len);
 typedef MUnMap = int Function(Pointer<Uint8> address, int len);
 final munmap = processSymbols.lookupFunction<MUnMapNative, MUnMap>('munmap');

 final processSymbols = DynamicLibrary.process();

 const int kProtRead = 1;
 const int kProtWrite = 2;

 const int kMapPrivate = 2;
 const int kMapFixed = 16;
 final int kMapAnonymous = Platform.isMacOS ? 0x1000 : 0x20;

 const int kMapFailed = -1;

 // On 32-bit platforms the upper 4 bytes should be ignored.
 const int kIgnoreBytesPositive = 0x1122334400000000;
 const int kIgnoreBytesNegative = 0xffddccbb00000000;

 void swapBytes(
     Pointer<Uint8> memoryView, int indexOffset, int indexA, int indexB) {
   final int oldA = memoryView[indexOffset + indexA];
   memoryView[indexOffset + indexA] = memoryView[indexOffset + indexB];
   memoryView[indexOffset + indexB] = oldA;
 }

 void testLoadsAndStores(int indexOffset, Pointer<Uint8> memory) {
   for (int i = 0; i < 10; ++i) {
     memory[indexOffset + i] = 10 + i;
   }
   Expect.listEquals(<int>[10, 11, 12, 13, 14, 15, 16, 17, 18, 19],
       memory.offsetBy(indexOffset).asTypedList(10));

   for (int i = 0; i < 9; ++i) {
     swapBytes(memory, indexOffset + 0, i, i + 1);
   }
   Expect.listEquals(<int>[11, 12, 13, 14, 15, 16, 17, 18, 19, 10],
       memory.offsetBy(indexOffset).asTypedList(10));
   for (int i = 0; i < 9; ++i) {
     swapBytes(memory, indexOffset + kIgnoreBytesPositive, i, i + 1);
   }
   Expect.listEquals(<int>[12, 13, 14, 15, 16, 17, 18, 19, 10, 11],
       memory.offsetBy(indexOffset).asTypedList(10));
   for (int i = 0; i < 9; ++i) {
     swapBytes(memory, indexOffset + kIgnoreBytesNegative, i, i + 1);
   }
   Expect.listEquals(<int>[13, 14, 15, 16, 17, 18, 19, 10, 11, 12],
       memory.offsetBy(indexOffset).asTypedList(10));
 }

 void testOnHighOrLowMemory(Pointer<Uint8> memory, int indexOffset) {
   testLoadsAndStores(indexOffset, memory);
   testLoadsAndStores(indexOffset, memory.offsetBy(5));
   testLoadsAndStores(indexOffset, memory.offsetBy(-5));
   testLoadsAndStores(indexOffset, memory.offsetBy(kIgnoreBytesPositive + 5));
   testLoadsAndStores(indexOffset, memory.offsetBy(kIgnoreBytesNegative + 5));
   testLoadsAndStores(indexOffset, memory.offsetBy(kIgnoreBytesPositive - 5));
   testLoadsAndStores(indexOffset, memory.offsetBy(kIgnoreBytesNegative - 5));
   final m2 = Pointer<Uint8>.fromAddress(kIgnoreBytesPositive + memory.address);
   Expect.equals(memory, m2); //# 01: ok
   Expect.equals(memory.address, m2.address); //# 01: ok
   testLoadsAndStores(indexOffset, m2);
   final m3 = Pointer<Uint8>.fromAddress(kIgnoreBytesNegative + memory.address);
   Expect.equals(memory, m3); //# 01: ok
   Expect.equals(memory.address, m3.address); //# 01: ok
   testLoadsAndStores(indexOffset, m3);
 }

 const int kPageSize = 4096;

 withMMapedAddress(
     Pointer<Uint8> fixedAddress, void fun(Pointer<Uint8> address)) {
   final result = mmap(fixedAddress, kPageSize, kProtRead | kProtWrite,
       kMapAnonymous | kMapFixed | kMapPrivate, 0, 0);
   if (result.address == kMapFailed) {
     throw 'Could not mmap @0x${fixedAddress.address.toRadixString(16)}!';
   }
   Expect.equals(fixedAddress, result); //# 01: ok
   Expect.equals(fixedAddress.address, result.address); //# 01: ok
   try {
     fun(result);
   } finally {
     if (munmap(result, kPageSize) != 0) {
       throw 'Failed to unmap memory!';
     }
   }
 }

 main() {
   final bool is32BitProcess = sizeOf<Pointer<Uint8>>() == 4;

   // User space processes usually have
   //   * the lower 3 GB available on Linux/Android on 32bit OS
   //   * full 4 GB available on Linux/Android on 64bit OS
   //   * full 4 GB available on MacOS
   // So we choose high and low addresses that fall into lower 3 GB.
   if (is32BitProcess && !Platform.isWindows) {
     final highMemoryAddress = Pointer<Uint8>.fromAddress(0xaaaa0000);
     final lowMemoryAddress = Pointer<Uint8>.fromAddress(0x11110000);
     withMMapedAddress(lowMemoryAddress, (Pointer<Uint8> lowMemory) {
       withMMapedAddress(highMemoryAddress, (Pointer<Uint8> highMemory) {
         testOnHighOrLowMemory(lowMemory, 2048);
         testOnHighOrLowMemory(highMemory, 2048);
         testOnHighOrLowMemory(
             lowMemory, 2048 + highMemory.address - lowMemory.address);
         testOnHighOrLowMemory(
             highMemory, 2048 + lowMemory.address - highMemory.address);
       });
     });
   }
 }
	// Copyright (c) 2019, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file

	import 'dart:ffi';
	import 'dart:io';

	import 'package:expect/expect.dart';

	import 'ffi_test_helpers.dart';

	// void* mmap(void* addr, size_t length,
	// int prot, int flags,
	// int fd, off_t offset)
	typedef MMapNative = Pointer<Uint8> Function(Pointer<Uint8> address, IntPtr len,
	IntPtr prot, IntPtr flags, IntPtr fd, IntPtr offset);
	typedef MMap = Pointer<Uint8> Function(
	Pointer<Uint8> address, int len, int prot, int flags, int fd, int offset);
	final mmap = processSymbols.lookupFunction<MMapNative, MMap>('mmap');

	// int munmap(void *addr, size_t length)
	typedef MUnMapNative = IntPtr Function(Pointer<Uint8> address, IntPtr len);
	typedef MUnMap = int Function(Pointer<Uint8> address, int len);
	final munmap = processSymbols.lookupFunction<MUnMapNative, MUnMap>('munmap');

	final processSymbols = DynamicLibrary.process();

	const int kProtRead = 1;
	const int kProtWrite = 2;

	const int kMapPrivate = 2;
	const int kMapFixed = 16;
	final int kMapAnonymous = Platform.isMacOS ? 0x1000 : 0x20;

	const int kMapFailed = -1;

	// On 32-bit platforms the upper 4 bytes should be ignored.
	const int kIgnoreBytesPositive = 0x1122334400000000;
	const int kIgnoreBytesNegative = 0xffddccbb00000000;

	void swapBytes(
	Pointer<Uint8> memoryView, int indexOffset, int indexA, int indexB) {
	final int oldA = memoryView[indexOffset + indexA];
	memoryView[indexOffset + indexA] = memoryView[indexOffset + indexB];
	memoryView[indexOffset + indexB] = oldA;
	}

	void testLoadsAndStores(int indexOffset, Pointer<Uint8> memory) {
	for (int i = 0; i < 10; ++i) {
	memory[indexOffset + i] = 10 + i;
	}
	Expect.listEquals(<int>[10, 11, 12, 13, 14, 15, 16, 17, 18, 19],
	memory.offsetBy(indexOffset).asTypedList(10));

	for (int i = 0; i < 9; ++i) {
	swapBytes(memory, indexOffset + 0, i, i + 1);
	}
	Expect.listEquals(<int>[11, 12, 13, 14, 15, 16, 17, 18, 19, 10],
	memory.offsetBy(indexOffset).asTypedList(10));
	for (int i = 0; i < 9; ++i) {
	swapBytes(memory, indexOffset + kIgnoreBytesPositive, i, i + 1);
	}
	Expect.listEquals(<int>[12, 13, 14, 15, 16, 17, 18, 19, 10, 11],
	memory.offsetBy(indexOffset).asTypedList(10));
	for (int i = 0; i < 9; ++i) {
	swapBytes(memory, indexOffset + kIgnoreBytesNegative, i, i + 1);
	}
	Expect.listEquals(<int>[13, 14, 15, 16, 17, 18, 19, 10, 11, 12],
	memory.offsetBy(indexOffset).asTypedList(10));
	}

	void testOnHighOrLowMemory(Pointer<Uint8> memory, int indexOffset) {
	testLoadsAndStores(indexOffset, memory);
	testLoadsAndStores(indexOffset, memory.offsetBy(5));
	testLoadsAndStores(indexOffset, memory.offsetBy(-5));
	testLoadsAndStores(indexOffset, memory.offsetBy(kIgnoreBytesPositive + 5));
	testLoadsAndStores(indexOffset, memory.offsetBy(kIgnoreBytesNegative + 5));
	testLoadsAndStores(indexOffset, memory.offsetBy(kIgnoreBytesPositive - 5));
	testLoadsAndStores(indexOffset, memory.offsetBy(kIgnoreBytesNegative - 5));
	final m2 = Pointer<Uint8>.fromAddress(kIgnoreBytesPositive + memory.address);
	Expect.equals(memory, m2); //# 01: ok
	Expect.equals(memory.address, m2.address); //# 01: ok
	testLoadsAndStores(indexOffset, m2);
	final m3 = Pointer<Uint8>.fromAddress(kIgnoreBytesNegative + memory.address);
	Expect.equals(memory, m3); //# 01: ok
	Expect.equals(memory.address, m3.address); //# 01: ok
	testLoadsAndStores(indexOffset, m3);
	}

	const int kPageSize = 4096;

	withMMapedAddress(
	Pointer<Uint8> fixedAddress, void fun(Pointer<Uint8> address)) {
	final result = mmap(fixedAddress, kPageSize, kProtRead \| kProtWrite,
	kMapAnonymous \| kMapFixed \| kMapPrivate, 0, 0);
	if (result.address == kMapFailed) {
	throw 'Could not mmap @0x${fixedAddress.address.toRadixString(16)}!';
	}
	Expect.equals(fixedAddress, result); //# 01: ok
	Expect.equals(fixedAddress.address, result.address); //# 01: ok
	try {
	fun(result);
	} finally {
	if (munmap(result, kPageSize) != 0) {
	throw 'Failed to unmap memory!';
	}
	}
	}

	main() {
	final bool is32BitProcess = sizeOf<Pointer<Uint8>>() == 4;

	// User space processes usually have
	// * the lower 3 GB available on Linux/Android on 32bit OS
	// * full 4 GB available on Linux/Android on 64bit OS
	// * full 4 GB available on MacOS
	// So we choose high and low addresses that fall into lower 3 GB.
	if (is32BitProcess && !Platform.isWindows) {
	final highMemoryAddress = Pointer<Uint8>.fromAddress(0xaaaa0000);
	final lowMemoryAddress = Pointer<Uint8>.fromAddress(0x11110000);
	withMMapedAddress(lowMemoryAddress, (Pointer<Uint8> lowMemory) {
	withMMapedAddress(highMemoryAddress, (Pointer<Uint8> highMemory) {
	testOnHighOrLowMemory(lowMemory, 2048);
	testOnHighOrLowMemory(highMemory, 2048);
	testOnHighOrLowMemory(
	lowMemory, 2048 + highMemory.address - lowMemory.address);
	testOnHighOrLowMemory(
	highMemory, 2048 + lowMemory.address - highMemory.address);
	});
	});
	}
	}