android_device_lenovo_msm89.../biometrics/BiometricsFingerprint.cpp

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2017-12-16 11:35:08 +00:00
/*
* Copyright (C) 2017 The Android Open Source Project
*
* 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.
*/
#define LOG_TAG "android.hardware.biometrics.fingerprint@2.0-service"
#define LOG_VERBOSE "android.hardware.biometrics.fingerprint@2.0-service"
#include <hardware/hw_auth_token.h>
#include <hardware/hardware.h>
#include <hardware/fingerprint.h>
#include "BiometricsFingerprint.h"
#include <cutils/properties.h>
#include <inttypes.h>
#include <unistd.h>
fingerprint_device_t* getWrapperService(fingerprint_notify_t);
namespace android {
namespace hardware {
namespace biometrics {
namespace fingerprint {
namespace V2_1 {
namespace implementation {
// Supported fingerprint HAL version
static bool is_goodix = false;
using RequestStatus =
android::hardware::biometrics::fingerprint::V2_1::RequestStatus;
BiometricsFingerprint *BiometricsFingerprint::sInstance = nullptr;
BiometricsFingerprint::BiometricsFingerprint() : mClientCallback(nullptr), mDevice(nullptr) {
sInstance = this; // keep track of the most recent instance
char vend [PROPERTY_VALUE_MAX];
property_get("ro.boot.fpsensor", vend, NULL);
if (!strcmp(vend, "fpc")) {
is_goodix = false;
mDevice = openHal();
} else if (!strcmp(vend, "gdx")) {
is_goodix = true;
mDevice = getWrapperService(BiometricsFingerprint::notify);
}
if (!mDevice) {
ALOGE("Can't open HAL module");
}
}
BiometricsFingerprint::~BiometricsFingerprint() {
ALOGV("~BiometricsFingerprint()");
if (mDevice == nullptr) {
ALOGE("No valid device");
return;
}
int err;
if (0 != (err = mDevice->common.close(
reinterpret_cast<hw_device_t*>(mDevice)))) {
ALOGE("Can't close fingerprint module, error: %d", err);
return;
}
mDevice = nullptr;
}
Return<RequestStatus> BiometricsFingerprint::ErrorFilter(int32_t error) {
switch(error) {
case 0: return RequestStatus::SYS_OK;
case -2: return RequestStatus::SYS_ENOENT;
case -4: return RequestStatus::SYS_EINTR;
case -5: return RequestStatus::SYS_EIO;
case -11: return RequestStatus::SYS_EAGAIN;
case -12: return RequestStatus::SYS_ENOMEM;
case -13: return RequestStatus::SYS_EACCES;
case -14: return RequestStatus::SYS_EFAULT;
case -16: return RequestStatus::SYS_EBUSY;
case -22: return RequestStatus::SYS_EINVAL;
case -28: return RequestStatus::SYS_ENOSPC;
case -110: return RequestStatus::SYS_ETIMEDOUT;
default:
ALOGE("An unknown error returned from fingerprint vendor library: %d", error);
return RequestStatus::SYS_UNKNOWN;
}
}
// Translate from errors returned by traditional HAL (see fingerprint.h) to
// HIDL-compliant FingerprintError.
FingerprintError BiometricsFingerprint::VendorErrorFilter(int32_t error,
int32_t* vendorCode) {
*vendorCode = 0;
switch(error) {
case FINGERPRINT_ERROR_HW_UNAVAILABLE:
return FingerprintError::ERROR_HW_UNAVAILABLE;
case FINGERPRINT_ERROR_UNABLE_TO_PROCESS:
return FingerprintError::ERROR_UNABLE_TO_PROCESS;
case FINGERPRINT_ERROR_TIMEOUT:
return FingerprintError::ERROR_TIMEOUT;
case FINGERPRINT_ERROR_NO_SPACE:
return FingerprintError::ERROR_NO_SPACE;
case FINGERPRINT_ERROR_CANCELED:
return FingerprintError::ERROR_CANCELED;
case FINGERPRINT_ERROR_UNABLE_TO_REMOVE:
return FingerprintError::ERROR_UNABLE_TO_REMOVE;
case FINGERPRINT_ERROR_LOCKOUT:
return FingerprintError::ERROR_LOCKOUT;
default:
if (error >= FINGERPRINT_ERROR_VENDOR_BASE) {
// vendor specific code.
*vendorCode = error - FINGERPRINT_ERROR_VENDOR_BASE;
return FingerprintError::ERROR_VENDOR;
}
}
ALOGE("Unknown error from fingerprint vendor library: %d", error);
return FingerprintError::ERROR_UNABLE_TO_PROCESS;
}
// Translate acquired messages returned by traditional HAL (see fingerprint.h)
// to HIDL-compliant FingerprintAcquiredInfo.
FingerprintAcquiredInfo BiometricsFingerprint::VendorAcquiredFilter(
int32_t info, int32_t* vendorCode) {
*vendorCode = 0;
switch(info) {
case FINGERPRINT_ACQUIRED_GOOD:
return FingerprintAcquiredInfo::ACQUIRED_GOOD;
case FINGERPRINT_ACQUIRED_PARTIAL:
return FingerprintAcquiredInfo::ACQUIRED_PARTIAL;
case FINGERPRINT_ACQUIRED_INSUFFICIENT:
return FingerprintAcquiredInfo::ACQUIRED_INSUFFICIENT;
case FINGERPRINT_ACQUIRED_IMAGER_DIRTY:
return FingerprintAcquiredInfo::ACQUIRED_IMAGER_DIRTY;
case FINGERPRINT_ACQUIRED_TOO_SLOW:
return FingerprintAcquiredInfo::ACQUIRED_TOO_SLOW;
case FINGERPRINT_ACQUIRED_TOO_FAST:
return FingerprintAcquiredInfo::ACQUIRED_TOO_FAST;
default:
if (info >= FINGERPRINT_ACQUIRED_VENDOR_BASE) {
// vendor specific code.
*vendorCode = info - FINGERPRINT_ACQUIRED_VENDOR_BASE;
return FingerprintAcquiredInfo::ACQUIRED_VENDOR;
}
}
ALOGE("Unknown acquiredmsg from fingerprint vendor library: %d", info);
return FingerprintAcquiredInfo::ACQUIRED_INSUFFICIENT;
}
Return<uint64_t> BiometricsFingerprint::setNotify(
const sp<IBiometricsFingerprintClientCallback>& clientCallback) {
mClientCallback = clientCallback;
// This is here because HAL 2.1 doesn't have a way to propagate a
// unique token for its driver. Subsequent versions should send a unique
// token for each call to setNotify(). This is fine as long as there's only
// one fingerprint device on the platform.
return reinterpret_cast<uint64_t>(mDevice);
}
Return<uint64_t> BiometricsFingerprint::preEnroll() {
return mDevice->pre_enroll(mDevice);
}
Return<RequestStatus> BiometricsFingerprint::enroll(const hidl_array<uint8_t, 69>& hat,
uint32_t gid, uint32_t timeoutSec) {
const hw_auth_token_t* authToken =
reinterpret_cast<const hw_auth_token_t*>(hat.data());
return ErrorFilter(mDevice->enroll(mDevice, authToken, gid, timeoutSec));
}
Return<RequestStatus> BiometricsFingerprint::postEnroll() {
return ErrorFilter(mDevice->post_enroll(mDevice));
}
Return<uint64_t> BiometricsFingerprint::getAuthenticatorId() {
return mDevice->get_authenticator_id(mDevice);
}
Return<RequestStatus> BiometricsFingerprint::cancel() {
fingerprint_msg_t msg;
msg.type = FINGERPRINT_ERROR;
msg.data.error = FINGERPRINT_ERROR_CANCELED;
mDevice->notify(&msg);
return ErrorFilter(mDevice->cancel(mDevice));
}
#define MAX_FINGERPRINTS 100
typedef int (*enumerate_2_0)(struct fingerprint_device *dev, fingerprint_finger_id_t *results,
uint32_t *max_size);
Return<RequestStatus> BiometricsFingerprint::enumerate() {
fingerprint_finger_id_t results[MAX_FINGERPRINTS];
uint32_t n = MAX_FINGERPRINTS;
enumerate_2_0 enumerate = (enumerate_2_0) mDevice->enumerate;
int ret = enumerate(mDevice, results, &n);
if (ret == 0 && mClientCallback != nullptr) {
ALOGD("Got %d enumerated templates", n);
for (uint32_t i = 0; i < n; i++) {
const uint64_t devId = reinterpret_cast<uint64_t>(mDevice);
const auto& fp = results[i];
ALOGD("onEnumerate(fid=%d, gid=%d)", fp.fid, fp.gid);
if (!mClientCallback->onEnumerate(devId, fp.fid, fp.gid, n - i - 1).isOk()) {
ALOGE("failed to invoke fingerprint onEnumerate callback");
}
}
}
return ErrorFilter(ret);
}
Return<RequestStatus> BiometricsFingerprint::remove(uint32_t gid, uint32_t fid) {
return ErrorFilter(mDevice->remove(mDevice, gid, fid));
}
Return<RequestStatus> BiometricsFingerprint::setActiveGroup(uint32_t gid,
const hidl_string& storePath) {
if (storePath.size() >= PATH_MAX || storePath.size() <= 0) {
ALOGE("Bad path length: %zd", storePath.size());
return RequestStatus::SYS_EINVAL;
}
if (access(storePath.c_str(), W_OK)) {
return RequestStatus::SYS_EINVAL;
}
int ret = mDevice->set_active_group(mDevice, gid, storePath.c_str());
if ((ret > 0) && is_goodix)
ret = 0;
return ErrorFilter(ret);
}
Return<RequestStatus> BiometricsFingerprint::authenticate(uint64_t operationId,
uint32_t gid) {
return ErrorFilter(mDevice->authenticate(mDevice, operationId, gid));
}
IBiometricsFingerprint* BiometricsFingerprint::getInstance() {
if (!sInstance) {
sInstance = new BiometricsFingerprint();
}
return sInstance;
}
fingerprint_device_t* BiometricsFingerprint::openHal() {
int err;
const hw_module_t *hw_mdl = nullptr;
ALOGD("Opening fingerprint hal library...");
if (0 != (err = hw_get_module(FINGERPRINT_HARDWARE_MODULE_ID, &hw_mdl))) {
ALOGE("Can't open fingerprint HW Module, error: %d", err);
return nullptr;
}
if (hw_mdl == nullptr) {
ALOGE("No valid fingerprint module");
return nullptr;
}
fingerprint_module_t const *module =
reinterpret_cast<const fingerprint_module_t*>(hw_mdl);
if (module->common.methods->open == nullptr) {
ALOGE("No valid open method");
return nullptr;
}
hw_device_t *device = nullptr;
if (0 != (err = module->common.methods->open(hw_mdl, nullptr, &device))) {
ALOGE("Can't open fingerprint methods, error: %d", err);
return nullptr;
}
fingerprint_device_t* fp_device =
reinterpret_cast<fingerprint_device_t*>(device);
if (0 != (err =
fp_device->set_notify(fp_device, BiometricsFingerprint::notify))) {
ALOGE("Can't register fingerprint module callback, error: %d", err);
return nullptr;
}
return fp_device;
}
void BiometricsFingerprint::notify(const fingerprint_msg_t *msg) {
BiometricsFingerprint* thisPtr = static_cast<BiometricsFingerprint*>(
BiometricsFingerprint::getInstance());
if (thisPtr == nullptr || thisPtr->mClientCallback == nullptr) {
ALOGE("Receiving callbacks before the client callback is registered.");
return;
}
const uint64_t devId = reinterpret_cast<uint64_t>(thisPtr->mDevice);
switch (msg->type) {
case FINGERPRINT_ERROR: {
int32_t vendorCode = 0;
FingerprintError result = VendorErrorFilter(msg->data.error, &vendorCode);
if (!thisPtr->mClientCallback->onError(devId, result, vendorCode).isOk()) {
ALOGE("failed to invoke fingerprint onError callback");
}
}
break;
case FINGERPRINT_ACQUIRED: {
int32_t vendorCode = 0;
FingerprintAcquiredInfo result =
VendorAcquiredFilter(msg->data.acquired.acquired_info, &vendorCode);
if (!thisPtr->mClientCallback->onAcquired(devId, result, vendorCode).isOk()) {
ALOGE("failed to invoke fingerprint onAcquired callback");
}
}
break;
case FINGERPRINT_TEMPLATE_ENROLLING:
if (!thisPtr->mClientCallback->onEnrollResult(devId,
msg->data.enroll.finger.fid,
msg->data.enroll.finger.gid,
msg->data.enroll.samples_remaining).isOk()) {
ALOGE("failed to invoke fingerprint onEnrollResult callback");
}
break;
case FINGERPRINT_TEMPLATE_REMOVED:
if (!thisPtr->mClientCallback->onRemoved(devId,
msg->data.removed.finger.fid,
msg->data.removed.finger.gid,
msg->data.removed.remaining_templates).isOk()) {
ALOGE("failed to invoke fingerprint onRemoved callback");
}
break;
case FINGERPRINT_AUTHENTICATED:
if (msg->data.authenticated.finger.fid != 0) {
const uint8_t* hat =
reinterpret_cast<const uint8_t *>(&msg->data.authenticated.hat);
const hidl_vec<uint8_t> token(
std::vector<uint8_t>(hat, hat + sizeof(msg->data.authenticated.hat)));
if (!thisPtr->mClientCallback->onAuthenticated(devId,
msg->data.authenticated.finger.fid,
msg->data.authenticated.finger.gid,
token).isOk()) {
ALOGE("failed to invoke fingerprint onAuthenticated callback");
}
} else {
// Not a recognized fingerprint
if (!thisPtr->mClientCallback->onAuthenticated(devId,
msg->data.authenticated.finger.fid,
msg->data.authenticated.finger.gid,
hidl_vec<uint8_t>()).isOk()) {
ALOGE("failed to invoke fingerprint onAuthenticated callback");
}
}
break;
case FINGERPRINT_TEMPLATE_ENUMERATING:
// ignored, won't happen for 2.0 HALs
break;
}
}
} // namespace implementation
} // namespace V2_1
} // namespace fingerprint
} // namespace biometrics
} // namespace hardware
} // namespace android