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qemu-android / qemu-android / 6bd10928e498d4bc2bc7b130edd4072d7c6b460a / . / android-qemu2-glue / main.cpp
blob: 373501972e6ab400bd3e5e5db2c7d4573470b6d5 [file] [log] [blame]
// Copyright 2015 The Android Open Source Project
//
// This software is licensed under the terms of the GNU General Public
// License version 2, as published by the Free Software Foundation, and
// may be copied, distributed, and modified under those terms.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
#include "android/base/containers/StringVector.h"
#include "android/base/files/PathUtils.h"
#include "android/base/Log.h"
#include "android/base/memory/ScopedPtr.h"
#include "android/base/StringFormat.h"
#include "android/base/system/System.h"
#include "android/android.h"
#include "android/avd/hw-config.h"
#include "android/cmdline-option.h"
#include "android/constants.h"
#include "android/crashreport/crash-handler.h"
#include "android/emulation/ConfigDirs.h"
#include "android/error-messages.h"
#include "android/featurecontrol/FeatureControl.h"
#include "android/filesystems/ext4_resize.h"
#include "android/filesystems/ext4_utils.h"
#include "android/globals.h"
#include "android/help.h"
#include "android/kernel/kernel_utils.h"
#include "android/main-common.h"
#include "android/main-common-ui.h"
#include "android/main-kernel-parameters.h"
#include "android/opengl/emugl_config.h"
#include "android/process_setup.h"
#include "android/utils/bufprint.h"
#include "android/utils/debug.h"
#include "android/utils/file_io.h"
#include "android/utils/path.h"
#include "android/utils/lineinput.h"
#include "android/utils/property_file.h"
#include "android/utils/filelock.h"
#include "android/utils/stralloc.h"
#include "android/utils/string.h"
#include "android/utils/tempfile.h"
#include "android/utils/win32_cmdline_quote.h"
#include "android/skin/winsys.h"
#include "config-target.h"
extern "C" {
#include "android/skin/charmap.h"
}
#include "android/ui-emu-agent.h"
#include "android-qemu2-glue/emulation/serial_line.h"
#include "android-qemu2-glue/qemu-control-impl.h"
#ifdef TARGET_AARCH64
#define TARGET_ARM64
#endif
#ifdef TARGET_I386
#define TARGET_X86
#endif
#include <algorithm>
#include <assert.h>
#include <limits.h>
#include <stdio.h>
#include <unistd.h>
#include "android/version.h"
#define D(...) do { if (VERBOSE_CHECK(init)) dprint(__VA_ARGS__); } while (0)
int android_base_port;
int android_serial_number_port;
extern bool android_op_wipe_data;
extern bool android_op_writable_system;
using namespace android::base;
using android::base::System;
namespace {
enum ImageType {
IMAGE_TYPE_SYSTEM = 0,
IMAGE_TYPE_CACHE,
IMAGE_TYPE_USER_DATA,
IMAGE_TYPE_SD_CARD,
IMAGE_TYPE_ENCRYPTION_KEY,
};
const int kMaxPartitions = 5;
const int kMaxTargetQemuParams = 16;
/*
* A structure used to model information about a given target CPU architecture.
* |androidArch| is the architecture name, following Android conventions.
* |qemuArch| is the same name, following QEMU conventions, used to locate
* the final qemu-system-<qemuArch> binary.
* |qemuCpu| is the QEMU -cpu parameter value.
* |ttyPrefix| is the prefix to use for TTY devices.
* |storageDeviceType| is the QEMU storage device type.
* |networkDeviceType| is the QEMU network device type.
* |imagePartitionTypes| defines the order of how the image partitions are
* listed in the command line, because the command line order determines which
* mount point the partition is attached to. For x86, the first partition
* listed in command line is mounted first, i.e. to /dev/block/vda,
* the next one to /dev/block/vdb, etc. However, for arm/mips, it's reversed;
* the last one is mounted to /dev/block/vda. the 2nd last to /dev/block/vdb.
* So far, we have 4(kMaxPartitions) types defined for system, cache, userdata
* and sdcard images.
* |qemuExtraArgs| are the qemu parameters specific to the target platform.
* this is a NULL-terminated list of string pointers of at most
* kMaxTargetQemuParams(16).
*/
struct TargetInfo {
const char* androidArch;
const char* qemuArch;
const char* qemuCpu;
const char* ttyPrefix;
const char* storageDeviceType;
const char* networkDeviceType;
const ImageType imagePartitionTypes[kMaxPartitions];
const char* qemuExtraArgs[kMaxTargetQemuParams];
};
// The current target architecture information!
const TargetInfo kTarget = {
#ifdef TARGET_ARM64
"arm64",
"aarch64",
"cortex-a57",
"ttyAMA",
"virtio-blk-device",
"virtio-net-device",
{IMAGE_TYPE_SD_CARD, IMAGE_TYPE_ENCRYPTION_KEY, IMAGE_TYPE_USER_DATA, IMAGE_TYPE_CACHE, IMAGE_TYPE_SYSTEM},
{NULL},
#elif defined(TARGET_ARM)
"arm",
"arm",
"cortex-a15",
"ttyAMA",
"virtio-blk-device",
"virtio-net-device",
{IMAGE_TYPE_SD_CARD, IMAGE_TYPE_ENCRYPTION_KEY, IMAGE_TYPE_USER_DATA, IMAGE_TYPE_CACHE, IMAGE_TYPE_SYSTEM},
{NULL},
#elif defined(TARGET_MIPS64)
"mips64",
"mips64el",
"MIPS64R6-generic",
"ttyGF",
"virtio-blk-device",
"virtio-net-device",
{IMAGE_TYPE_SD_CARD, IMAGE_TYPE_ENCRYPTION_KEY, IMAGE_TYPE_USER_DATA, IMAGE_TYPE_CACHE, IMAGE_TYPE_SYSTEM},
{NULL},
#elif defined(TARGET_MIPS)
"mips",
"mipsel",
"74Kf",
"ttyGF",
"virtio-blk-device",
"virtio-net-device",
{IMAGE_TYPE_SD_CARD, IMAGE_TYPE_ENCRYPTION_KEY, IMAGE_TYPE_USER_DATA, IMAGE_TYPE_CACHE, IMAGE_TYPE_SYSTEM},
{NULL},
#elif defined(TARGET_X86_64)
"x86_64",
"x86_64",
"android64",
"ttyS",
"virtio-blk-pci",
"virtio-net-pci",
{IMAGE_TYPE_SYSTEM, IMAGE_TYPE_CACHE, IMAGE_TYPE_USER_DATA, IMAGE_TYPE_ENCRYPTION_KEY, IMAGE_TYPE_SD_CARD},
{"-vga", "none", NULL},
#elif defined(TARGET_I386) // Both i386 and x86_64 targets define this macro
"x86",
"i386",
"android32",
"ttyS",
"virtio-blk-pci",
"virtio-net-pci",
{IMAGE_TYPE_SYSTEM, IMAGE_TYPE_CACHE, IMAGE_TYPE_USER_DATA, IMAGE_TYPE_ENCRYPTION_KEY, IMAGE_TYPE_SD_CARD},
{"-vga", "none", NULL},
#else
#error No target platform is defined
#endif
};
static std::string getNthParentDir(const char* path, size_t n) {
StringVector dir = PathUtils::decompose(path);
PathUtils::simplifyComponents(&dir);
if (dir.size() < n + 1U) {
return std::string("");
}
dir.resize(dir.size() - n);
return PathUtils::recompose(dir);
}
/* generate parameters for each partition by type.
* Param:
* args - array to hold parameters for qemu
* argsPosition - current index in the parameter array
* driveIndex - a sequence number for the drive parameter
* hw - the hardware configuration that conatains image info.
* type - what type of partition parameter to generate
*/
static void makePartitionCmd(const char** args, int* argsPosition, int* driveIndex,
AndroidHwConfig* hw, ImageType type, bool writable,
int apiLevel, const char* avdContentPath) {
int n = *argsPosition;
int idx = *driveIndex;
#if defined(TARGET_X86_64) || defined(TARGET_I386)
/* for x86, 'if=none' is necessary for virtio blk*/
std::string driveParam("if=none,");
#else
std::string driveParam;
#endif
std::string deviceParam;
switch (type) {
case IMAGE_TYPE_SYSTEM:
driveParam += StringFormat("index=%d,id=system,file=%s"
PATH_SEP "system.img.qcow2",
idx++,
avdContentPath);
// API 15 and under images need a read+write
// system image.
if (apiLevel > 15) {
// API > 15 uses read-only system partition.
// You can override this explicitly
// by passing -writable-system to emulator.
if (!writable)
driveParam += ",read-only";
}
deviceParam = StringFormat("%s,drive=system",
kTarget.storageDeviceType);
break;
case IMAGE_TYPE_CACHE:
driveParam += StringFormat("index=%d,id=cache,file=%s.qcow2",
idx++,
hw->disk_cachePartition_path);
deviceParam = StringFormat("%s,drive=cache",
kTarget.storageDeviceType);
break;
case IMAGE_TYPE_USER_DATA:
driveParam += StringFormat("index=%d,id=userdata,file=%s.qcow2",
idx++,
hw->disk_dataPartition_path);
deviceParam = StringFormat("%s,drive=userdata",
kTarget.storageDeviceType);
break;
case IMAGE_TYPE_SD_CARD:
if (hw->hw_sdCard_path != NULL && strcmp(hw->hw_sdCard_path, "")) {
driveParam += StringFormat("index=%d,id=sdcard,file=%s.qcow2",
idx++, hw->hw_sdCard_path);
deviceParam = StringFormat("%s,drive=sdcard",
kTarget.storageDeviceType);
} else {
/* no sdcard is defined */
return;
}
break;
case IMAGE_TYPE_ENCRYPTION_KEY:
if (android::featurecontrol::isEnabled(android::featurecontrol::EncryptUserData) &&
hw->disk_encryptionKeyPartition_path != NULL && strcmp(hw->disk_encryptionKeyPartition_path, "")) {
driveParam += StringFormat("index=%d,id=encrypt,file=%s.qcow2",
idx++, hw->disk_encryptionKeyPartition_path);
deviceParam = StringFormat("%s,drive=encrypt",
kTarget.storageDeviceType);
} else {
/* no encryption partition is defined */
return;
}
break;
default:
dwarning("Unknown Image type %d\n", type);
return;
}
args[n++] = "-drive";
args[n++] = ASTRDUP(driveParam.c_str());
args[n++] = "-device";
args[n++] = ASTRDUP(deviceParam.c_str());
/* update the index */
*argsPosition = n;
*driveIndex = idx;
}
} // namespace
extern "C" int run_qemu_main(int argc, const char **argv);
static void enter_qemu_main_loop(int argc, char **argv) {
#ifndef _WIN32
sigset_t set;
sigemptyset(&set);
pthread_sigmask(SIG_SETMASK, &set, NULL);
#endif
D("Starting QEMU main loop");
run_qemu_main(argc, (const char**)argv);
D("Done with QEMU main loop");
if (android_init_error_occurred()) {
skin_winsys_error_dialog(android_init_error_get_message(), "Error");
}
}
#if defined(_WIN32)
// On Windows, link against qtmain.lib which provides a WinMain()
// implementation, that later calls qMain().
#define main qt_main
#endif
static bool createInitalEncryptionKeyPartition(AndroidHwConfig* hw) {
char* userdata_dir = path_dirname(hw->disk_dataPartition_path);
if (!userdata_dir) {
derror("no userdata_dir");
return false;
}
hw->disk_encryptionKeyPartition_path = path_join(userdata_dir, "encryptionkey.img");
free(userdata_dir);
if (path_exists(hw->disk_systemPartition_initPath)) {
char* sysimg_dir = path_dirname(hw->disk_systemPartition_initPath);
if (!sysimg_dir) {
derror("no sysimg_dir %s", hw->disk_systemPartition_initPath);
return false;
}
char* init_encryptionkey_img_path = path_join(sysimg_dir, "encryptionkey.img");
free(sysimg_dir);
if (path_exists(init_encryptionkey_img_path)) {
if (path_copy_file(hw->disk_encryptionKeyPartition_path, init_encryptionkey_img_path) >= 0) {
free(init_encryptionkey_img_path);
return true;
}
} else {
derror("no init encryptionkey.img");
}
free(init_encryptionkey_img_path);
} else {
derror("no system partition %s", hw->disk_systemPartition_initPath);
}
return false;
}
extern "C" int main(int argc, char **argv) {
process_early_setup(argc, argv);
if (argc < 1) {
fprintf(stderr, "Invalid invocation (no program path)\n");
return 1;
}
/* The emulator always uses the first serial port for kernel messages
* and the second one for qemud. So start at the third if we need one
* for logcat or 'shell'
*/
const char* args[128];
args[0] = argv[0];
int n = 1; // next parameter index
AndroidHwConfig* hw = android_hw;
AvdInfo* avd;
AndroidOptions opts[1];
int exitStatus = 0;
if (!emulator_parseCommonCommandLineOptions(&argc,
&argv,
kTarget.androidArch,
true, // is_qemu2
opts,
hw,
&android_avdInfo,
&exitStatus)) {
// Special case for QEMU positional parameters.
if (exitStatus == EMULATOR_EXIT_STATUS_POSITIONAL_QEMU_PARAMETER) {
// Copy all QEMU options to |args|, and set |n| to the number
// of options in |args| (|argc| must be positive here).
for (n = 1; n <= argc; ++n) {
args[n] = argv[n - 1];
}
// Skip the translation of command-line options and jump
// straight to qemu_main().
enter_qemu_main_loop(n, (char**)args);
return 0;
}
// Normal exit.
return exitStatus;
}
// just because we know that we're in the new emulator as we got here
opts->ranchu = 1;
avd = android_avdInfo;
if (!emulator_parseUiCommandLineOptions(opts, avd, hw)) {
return 1;
}
char boot_prop_ip[128] = {};
if (opts->shared_net_id) {
char* end;
long shared_net_id = strtol(opts->shared_net_id, &end, 0);
if (end == NULL || *end || shared_net_id < 1 || shared_net_id > 255) {
fprintf(stderr, "option -shared-net-id must be an integer between 1 and 255\n");
return 1;
}
snprintf(boot_prop_ip, sizeof(boot_prop_ip),
"net.shared_net_ip=10.1.2.%ld", shared_net_id);
}
if (boot_prop_ip[0]) {
args[n++] = "-boot-property";
args[n++] = boot_prop_ip;
}
#ifdef CONFIG_NAND_LIMITS
if (opts->nand_limits) {
args[n++] = "-nand-limits";
args[n++] = opts->nand_limits;
}
#endif
if (opts->timezone) {
args[n++] = "-timezone";
args[n++] = opts->timezone;
}
if (opts->audio && !strcmp(opts->audio, "none")) {
args[n++] = "-no-audio";
}
if (opts->cpu_delay) {
args[n++] = "-cpu-delay";
args[n++] = opts->cpu_delay;
}
if (opts->dns_server) {
args[n++] = "-dns-server";
args[n++] = opts->dns_server;
}
if (opts->skip_adb_auth) {
args[n++] = "-skip-adb-auth";
}
/** SNAPSHOT STORAGE HANDLING */
/* If we have a valid snapshot storage path */
if (opts->snapstorage) {
// NOTE: If QEMU2_SNAPSHOT_SUPPORT is not defined, a warning has been
// already printed by emulator_parseCommonCommandLineOptions().
#ifdef QEMU2_SNAPSHOT_SUPPORT
/* We still use QEMU command-line options for the following since
* they can change from one invokation to the next and don't really
* correspond to the hardware configuration itself.
*/
if (!opts->no_snapshot_load) {
args[n++] = "-loadvm";
args[n++] = ASTRDUP(opts->snapshot);
}
if (!opts->no_snapshot_save) {
args[n++] = "-savevm-on-exit";
args[n++] = ASTRDUP(opts->snapshot);
}
if (opts->no_snapshot_update_time) {
args[n++] = "-snapshot-no-time-update";
}
#endif // QEMU2_SNAPSHOT_SUPPORT
}
{
// Always setup a single serial port, that can be connected
// either to the 'null' chardev, or the -shell-serial one,
// which by default will be either 'stdout' (Posix) or 'con:'
// (Windows).
const char* serial =
(opts->shell || opts->logcat || opts->show_kernel)
? opts->shell_serial : "null";
args[n++] = "-serial";
args[n++] = serial;
}
if (opts->radio) {
args[n++] = "-radio";
args[n++] = opts->radio;
}
if (opts->gps) {
args[n++] = "-gps";
args[n++] = opts->gps;
}
if (opts->code_profile) {
args[n++] = "-code-profile";
args[n++] = opts->code_profile;
}
/* Pass boot properties to the core. First, those from boot.prop,
* then those from the command-line */
const FileData* bootProperties = avdInfo_getBootProperties(avd);
if (!fileData_isEmpty(bootProperties)) {
PropertyFileIterator iter[1];
propertyFileIterator_init(iter,
bootProperties->data,
bootProperties->size);
while (propertyFileIterator_next(iter)) {
char temp[MAX_PROPERTY_NAME_LEN + MAX_PROPERTY_VALUE_LEN + 2];
snprintf(temp, sizeof temp, "%s=%s", iter->name, iter->value);
args[n++] = "-boot-property";
args[n++] = ASTRDUP(temp);
}
}
if (opts->prop != NULL) {
ParamList* pl = opts->prop;
for ( ; pl != NULL; pl = pl->next ) {
args[n++] = "-boot-property";
args[n++] = pl->param;
}
}
if (opts->ports) {
args[n++] = "-android-ports";
args[n++] = opts->ports;
}
if (opts->port) {
int console_port = -1;
int adb_port = -1;
if (!android_parse_port_option(opts->port, &console_port, &adb_port)) {
return 1;
}
std::string portsOption = StringFormat("%d,%d",
console_port, adb_port);
args[n++] = "-android-ports";
args[n++] = strdup(portsOption.c_str());
}
if (opts->report_console) {
args[n++] = "-android-report-console";
args[n++] = opts->report_console;
}
if (opts->http_proxy) {
args[n++] = "-http-proxy";
args[n++] = opts->http_proxy;
}
if (!opts->charmap) {
/* Try to find a valid charmap name */
char* charmap = avdInfo_getCharmapFile(avd, hw->hw_keyboard_charmap);
if (charmap != NULL) {
D("autoconfig: -charmap %s", charmap);
opts->charmap = charmap;
}
}
if (opts->charmap) {
char charmap_name[SKIN_CHARMAP_NAME_SIZE];
if (!path_exists(opts->charmap)) {
derror("Charmap file does not exist: %s", opts->charmap);
return 1;
}
/* We need to store the charmap name in the hardware configuration.
* However, the charmap file itself is only used by the UI component
* and doesn't need to be set to the emulation engine.
*/
kcm_extract_charmap_name(opts->charmap, charmap_name,
sizeof(charmap_name));
reassign_string(&hw->hw_keyboard_charmap, charmap_name);
}
// TODO: imement network
#if 0
/* Set up the interfaces for inter-emulator networking */
if (opts->shared_net_id) {
unsigned int shared_net_id = atoi(opts->shared_net_id);
char nic[37];
args[n++] = "-net";
args[n++] = "nic,vlan=0";
args[n++] = "-net";
args[n++] = "user,vlan=0";
args[n++] = "-net";
snprintf(nic, sizeof nic, "nic,vlan=1,macaddr=52:54:00:12:34:%02x", shared_net_id);
args[n++] = strdup(nic);
args[n++] = "-net";
args[n++] = "socket,vlan=1,mcast=230.0.0.10:1234";
}
#endif
// Create userdata file from init version if needed.
if (android_op_wipe_data || !path_exists(hw->disk_dataPartition_path)) {
std::unique_ptr<char[]> initDir(avdInfo_getDataInitDirPath(avd));
if (path_exists(initDir.get())) {
std::string dataPath = PathUtils::join(
avdInfo_getContentPath(avd), "data");
path_copy_dir(dataPath.c_str(), initDir.get());
std::string adbKeyPath = PathUtils::join(
android::ConfigDirs::getUserDirectory(), "adbkey.pub");
if (path_is_regular(adbKeyPath.c_str())
&& path_can_read(adbKeyPath.c_str())) {
std::string guestAdbKeyDir = PathUtils::join(
dataPath, "misc", "adb");
std::string guestAdbKeyPath = PathUtils::join(
guestAdbKeyDir, "adb_keys");
path_mkdir_if_needed(guestAdbKeyDir.c_str(), 0777);
path_copy_file(
guestAdbKeyPath.c_str(),
adbKeyPath.c_str());
android_chmod(guestAdbKeyPath.c_str(), 0777);
} else {
dwarning("cannot read adb public key file: %d",
adbKeyPath.c_str());
}
android_createExt4ImageFromDir(hw->disk_dataPartition_path,
dataPath.c_str(),
android_hw->disk_dataPartition_size,
"data");
// TODO: remove dataPath folder
} else if (path_exists(hw->disk_dataPartition_initPath)) {
D("Creating: %s\n", hw->disk_dataPartition_path);
if (path_copy_file(hw->disk_dataPartition_path,
hw->disk_dataPartition_initPath) < 0) {
derror("Could not create %s: %s", hw->disk_dataPartition_path,
strerror(errno));
return 1;
}
resizeExt4Partition(android_hw->disk_dataPartition_path,
android_hw->disk_dataPartition_size);
} else {
derror("Missing initial data partition file: %s",
hw->disk_dataPartition_initPath);
}
}
else {
// Resize userdata-qemu.img if the size is smaller than what config.ini
// says.
// This can happen as user wants a larger data partition without wiping
// it.
// b.android.com/196926
System::FileSize current_data_size;
if (System::get()->pathFileSize(hw->disk_dataPartition_path,
&current_data_size)) {
System::FileSize partition_size = static_cast<System::FileSize>(
android_hw->disk_dataPartition_size);
if (android_hw->disk_dataPartition_size > 0 &&
current_data_size < partition_size) {
dwarning("userdata partition is resized from %d M to %d M\n",
(int)(current_data_size / (1024 * 1024)),
(int)(partition_size / (1024 * 1024)));
resizeExt4Partition(android_hw->disk_dataPartition_path,
android_hw->disk_dataPartition_size);
}
}
}
//create encryptionkey.img file if needed
if (android::featurecontrol::isEnabled(android::featurecontrol::EncryptUserData)) {
if (hw->disk_encryptionKeyPartition_path == NULL) {
if(!createInitalEncryptionKeyPartition(hw)) {
derror("Encryption is requested but failed to create encrypt partition.");
return 1;
}
}
} else {
dwarning("encryption is off");
}
bool createEmptyCacheFile = false;
// Make sure there's a temp cache partition if there wasn't a permanent one
if (!hw->disk_cachePartition_path ||
strcmp(hw->disk_cachePartition_path, "") == 0) {
str_reset(&hw->disk_cachePartition_path,
tempfile_path(tempfile_create()));
createEmptyCacheFile = true;
}
createEmptyCacheFile |= !path_exists(hw->disk_cachePartition_path);
if (createEmptyCacheFile) {
D("Creating empty ext4 cache partition: %s",
hw->disk_cachePartition_path);
int ret = android_createEmptyExt4Image(
hw->disk_cachePartition_path,
hw->disk_cachePartition_size,
"cache");
if (ret < 0) {
derror("Could not create %s: %s", hw->disk_cachePartition_path,
strerror(-ret));
return 1;
}
}
// Make sure we always use the custom Android CPU definition.
args[n++] = "-cpu";
args[n++] = kTarget.qemuCpu;
// Set env var to "on" for Intel PMU if the feature is enabled.
// cpu.c will then read that.
if (android::featurecontrol::isEnabled(android::featurecontrol::IntelPerformanceMonitoringUnit)) {
System::get()->envSet("ANDROID_EMU_FEATURE_IntelPerformanceMonitoringUnit", "on");
}
#if defined(TARGET_X86_64) || defined(TARGET_I386)
char* accel_status = NULL;
CpuAccelMode accel_mode = ACCEL_AUTO;
const bool accel_ok = handleCpuAcceleration(opts, avd,
&accel_mode, &accel_status);
if (accel_mode == ACCEL_ON) { // 'accel on' is specified'
if (!accel_ok) {
derror("CPU acceleration is not supported on this machine!");
derror("Reason: %s", accel_status);
return 1;
}
args[n++] = ASTRDUP(kEnableAccelerator);
} else if (accel_mode == ACCEL_AUTO) {
if (accel_ok) {
args[n++] = ASTRDUP(kEnableAccelerator);
}
} // else accel is off and we don't need to add anything else
AFREE(accel_status);
#else // !TARGET_X86_64 && !TARGET_I386
args[n++] = "-machine";
args[n++] = "type=ranchu";
#endif // !TARGET_X86_64 && !TARGET_I386
#if defined(TARGET_X86_64) || defined(TARGET_I386)
// SMP Support.
std::string ncores;
if (hw->hw_cpu_ncore > 1) {
args[n++] = "-smp";
#ifdef _WIN32
if (hw->hw_cpu_ncore > 16) {
dwarning("HAXM does not support more than 16 cores. Number of cores set to 16");
hw->hw_cpu_ncore = 16;
}
#endif
ncores = StringFormat("cores=%ld", hw->hw_cpu_ncore);
args[n++] = ncores.c_str();
}
#endif // !TARGET_X86_64 && !TARGET_I386
// Memory size
args[n++] = "-m";
std::string memorySize = StringFormat("%ld", hw->hw_ramSize);
args[n++] = memorySize.c_str();
// Kernel command-line parameters.
AndroidGlesEmulationMode glesMode = kAndroidGlesEmulationOff;
if (hw->hw_gpu_enabled) {
if (!strcmp(hw->hw_gpu_mode, "guest")) {
glesMode = kAndroidGlesEmulationGuest;
} else {
glesMode = kAndroidGlesEmulationHost;
}
}
uint64_t glesFramebufferCMA = 0ULL;
if ((glesMode == kAndroidGlesEmulationGuest) ||
(opts->gpu && !strcmp(opts->gpu, "guest")) ||
!hw->hw_gpu_enabled) {
// Set CMA (continguous memory allocation) to values that depend on
// the desired resolution.
// We will assume a double buffered 32-bit framebuffer
// in the calculation.
int framebuffer_width = hw->hw_lcd_width;
int framebuffer_height = hw->hw_lcd_height;
uint64_t bytes = framebuffer_width * framebuffer_height * 4;
const uint64_t one_MB = 1024ULL * 1024;
glesFramebufferCMA = (2 * bytes + one_MB - 1) / one_MB;
VERBOSE_PRINT(init, "Adjusting Contiguous Memory Allocation "
"of %dx%d framebuffer for software renderer to %"
PRIu64 "MB.", framebuffer_width, framebuffer_height,
glesFramebufferCMA);
} else {
VERBOSE_PRINT(init, "Using default value for kernel "
"Contiguous Memory Allocation.");
}
int apiLevel = avd ? avdInfo_getApiLevel(avd) : 1000;
char* kernel_parameters = emulator_getKernelParameters(
opts, kTarget.androidArch, apiLevel, kTarget.ttyPrefix,
hw->kernel_parameters, glesMode, glesFramebufferCMA,
true // isQemu2
);
if (!kernel_parameters) {
return 1;
}
args[n++] = "-append";
args[n++] = kernel_parameters;
// Support for changing default lcd-density
std::string lcd_density;
if (hw->hw_lcd_density) {
args[n++] = "-lcd-density";
lcd_density = StringFormat("%d", hw->hw_lcd_density);
args[n++] = lcd_density.c_str();
}
// Kernel image
args[n++] = "-kernel";
args[n++] = hw->kernel_path;
// Ramdisk
args[n++] = "-initrd";
args[n++] = hw->disk_ramdisk_path;
/*
* add partition parameters with the sequence
* pre-defined in targetInfo.imagePartitionTypes
*/
int s;
int drvIndex = 0;
for (s = 0; s < kMaxPartitions; s++) {
bool writable = (kTarget.imagePartitionTypes[s] == IMAGE_TYPE_SYSTEM) ?
android_op_writable_system : true;
makePartitionCmd(args, &n, &drvIndex, hw,
kTarget.imagePartitionTypes[s], writable, apiLevel,
avdInfo_getContentPath(avd));
}
// Network
args[n++] = "-netdev";
args[n++] = "user,id=mynet";
args[n++] = "-device";
std::string netDevice =
StringFormat("%s,netdev=mynet", kTarget.networkDeviceType);
args[n++] = netDevice.c_str();
args[n++] = "-show-cursor";
// TODO: the following *should* re-enable -tcpdump in QEMU2 when we have
// rebased to at least QEMU 2.5 - the standard -tcpdump flag
// See http://wiki.qemu.org/ChangeLog/2.5#Network_2 and
// http://wiki.qemu.org/download/qemu-doc.html#index-_002dobject
// std::string tcpdumpArg;
// if (opts->tcpdump) {
// args[n++] = "-object";
// tcpdumpArg = StringFormat("filter-dump,id=mytcpdump,netdev=mynet,file=%s",
// opts->tcpdump);
// args[n++] = tcpdumpArg.c_str();
// }
if (opts->tcpdump) {
dwarning("The -tcpdump flag is not supported in QEMU2 yet and will "
"be ignored.");
}
// Graphics
if (opts->no_window) {
args[n++] = "-nographic";
// also disable the qemu monitor which will otherwise grab stdio
args[n++] = "-monitor";
args[n++] = "none";
}
// Data directory (for keymaps and PC Bios).
args[n++] = "-L";
std::string dataDir = getNthParentDir(args[0], 3U);
if (dataDir.empty()) {
dataDir = "lib/pc-bios";
} else {
dataDir += "/lib/pc-bios";
}
args[n++] = dataDir.c_str();
// Audio enable hda by default for x86 and x64 platforms
#if defined(TARGET_X86_64) || defined(TARGET_I386)
args[n++] = "-soundhw";
args[n++] = "hda";
#endif
/* append extra qemu parameters if any */
for (int idx = 0; kTarget.qemuExtraArgs[idx] != NULL; idx++) {
args[n++] = kTarget.qemuExtraArgs[idx];
}
/* append the options after -qemu */
for (int i = 0; i < argc; ++i) {
args[n++] = argv[i];
}
/* Generate a hardware-qemu.ini for this AVD. The real hardware
* configuration is ususally stored in several files, e.g. the AVD's
* config.ini plus the skin-specific hardware.ini.
*
* The new file will group all definitions and will be used to
* launch the core with the -android-hw <file> option.
*/
{
const char* coreHwIniPath = avdInfo_getCoreHwIniPath(avd);
const auto hwIni = android::base::makeCustomScopedPtr(
iniFile_newEmpty(NULL), iniFile_free);
androidHwConfig_write(hw, hwIni.get());
if (filelock_create(coreHwIniPath) == NULL) {
// The AVD is already in use
derror("There's another emulator instance running with "
"the current AVD '%s'. Exiting...\n", avdInfo_getName(avd));
return 1;
}
/* While saving HW config, ignore valueless entries. This will not break
* anything, but will significantly simplify comparing the current HW
* config with the one that has been associated with a snapshot (in case
* VM starts from a snapshot for this instance of emulator). */
if (iniFile_saveToFileClean(hwIni.get(), coreHwIniPath) < 0) {
derror("Could not write hardware.ini to %s: %s", coreHwIniPath, strerror(errno));
return 2;
}
args[n++] = "-android-hw";
args[n++] = strdup(coreHwIniPath);
crashhandler_copy_attachment(CRASH_AVD_HARDWARE_INFO, coreHwIniPath);
/* In verbose mode, dump the file's content */
if (VERBOSE_CHECK(init)) {
FILE* file = fopen(coreHwIniPath, "rt");
if (file == NULL) {
derror("Could not open hardware configuration file: %s\n",
coreHwIniPath);
} else {
LineInput* input = lineInput_newFromStdFile(file);
const char* line;
printf("Content of hardware configuration file:\n");
while ((line = lineInput_getLine(input)) != NULL) {
printf(" %s\n", line);
}
printf(".\n");
lineInput_free(input);
fclose(file);
}
}
}
args[n] = NULL;
// Check if we had enough slots in |args|.
assert(n < (int)(sizeof(args)/sizeof(args[0])));
if(VERBOSE_CHECK(init)) {
int i;
printf("QEMU options list:\n");
for(i = 0; i < n; i++) {
printf("emulator: argv[%02d] = \"%s\"\n", i, args[i]);
}
/* Dump final command-line option to make debugging the core easier */
printf("Concatenated QEMU options:\n");
for (i = 0; i < n; i++) {
/* To make it easier to copy-paste the output to a command-line,
* quote anything that contains spaces.
*/
if (strchr(args[i], ' ') != NULL) {
printf(" '%s'", args[i]);
} else {
printf(" %s", args[i]);
}
}
printf("\n");
}
qemu2_android_serialline_init();
static UiEmuAgent uiEmuAgent;
uiEmuAgent.battery = gQAndroidBatteryAgent;
uiEmuAgent.cellular = gQAndroidCellularAgent;
uiEmuAgent.clipboard = gQAndroidClipboardAgent;
uiEmuAgent.finger = gQAndroidFingerAgent;
uiEmuAgent.location = gQAndroidLocationAgent;
uiEmuAgent.sensors = gQAndroidSensorsAgent;
uiEmuAgent.telephony = gQAndroidTelephonyAgent;
uiEmuAgent.userEvents = gQAndroidUserEventAgent;
uiEmuAgent.window = gQAndroidEmulatorWindowAgent;
// for now there's no uses of SettingsAgent, so we don't set it
uiEmuAgent.settings = NULL;
/* Setup SDL UI just before calling the code */
#ifndef _WIN32
sigset_t set;
sigfillset(&set);
pthread_sigmask(SIG_SETMASK, &set, NULL);
#endif // !_WIN32
skin_winsys_init_args(argc, argv);
if (!emulator_initUserInterface(opts, &uiEmuAgent)) {
return 1;
}
skin_winsys_spawn_thread(opts->no_window, enter_qemu_main_loop, n, (char**)args);
skin_winsys_enter_main_loop(opts->no_window);
emulator_finiUserInterface();
process_late_teardown();
return 0;
}