/* * Copyright (C) 2012 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 __STDC_LIMIT_MACROS #define LOG_TAG "common_time" #include <utils/Log.h> #include <stdint.h> #include <utils/Errors.h> #include <utils/LinearTransform.h> #include "common_clock.h" namespace android { CommonClock::CommonClock() { cur_slew_ = 0; cur_trans_valid_ = false; cur_trans_.a_zero = 0; cur_trans_.b_zero = 0; cur_trans_.a_to_b_numer = local_to_common_freq_numer_ = 1; cur_trans_.a_to_b_denom = local_to_common_freq_denom_ = 1; duration_trans_ = cur_trans_; } bool CommonClock::init(uint64_t local_freq) { Mutex::Autolock lock(&lock_); if (!local_freq) return false; uint64_t numer = kCommonFreq; uint64_t denom = local_freq; LinearTransform::reduce(&numer, &denom); if ((numer > UINT32_MAX) || (denom > UINT32_MAX)) { ALOGE("Overflow in CommonClock::init while trying to reduce %lld/%lld", kCommonFreq, local_freq); return false; } cur_trans_.a_to_b_numer = local_to_common_freq_numer_ = static_cast<uint32_t>(numer); cur_trans_.a_to_b_denom = local_to_common_freq_denom_ = static_cast<uint32_t>(denom); duration_trans_ = cur_trans_; return true; } status_t CommonClock::localToCommon(int64_t local, int64_t *common_out) const { Mutex::Autolock lock(&lock_); if (!cur_trans_valid_) return INVALID_OPERATION; if (!cur_trans_.doForwardTransform(local, common_out)) return INVALID_OPERATION; return OK; } status_t CommonClock::commonToLocal(int64_t common, int64_t *local_out) const { Mutex::Autolock lock(&lock_); if (!cur_trans_valid_) return INVALID_OPERATION; if (!cur_trans_.doReverseTransform(common, local_out)) return INVALID_OPERATION; return OK; } int64_t CommonClock::localDurationToCommonDuration(int64_t localDur) const { int64_t ret; duration_trans_.doForwardTransform(localDur, &ret); return ret; } void CommonClock::setBasis(int64_t local, int64_t common) { Mutex::Autolock lock(&lock_); cur_trans_.a_zero = local; cur_trans_.b_zero = common; cur_trans_valid_ = true; } void CommonClock::resetBasis() { Mutex::Autolock lock(&lock_); cur_trans_.a_zero = 0; cur_trans_.b_zero = 0; cur_trans_valid_ = false; } status_t CommonClock::setSlew(int64_t change_time, int32_t ppm) { Mutex::Autolock lock(&lock_); int64_t new_local_basis; int64_t new_common_basis; if (cur_trans_valid_) { new_local_basis = change_time; if (!cur_trans_.doForwardTransform(change_time, &new_common_basis)) { ALOGE("Overflow when attempting to set slew rate to %d", ppm); return INVALID_OPERATION; } } else { new_local_basis = 0; new_common_basis = 0; } cur_slew_ = ppm; uint32_t n1 = local_to_common_freq_numer_; uint32_t n2 = 1000000 + cur_slew_; uint32_t d1 = local_to_common_freq_denom_; uint32_t d2 = 1000000; // n1/d1 has already been reduced, no need to do so here. LinearTransform::reduce(&n1, &d2); LinearTransform::reduce(&n2, &d1); LinearTransform::reduce(&n2, &d2); cur_trans_.a_zero = new_local_basis; cur_trans_.b_zero = new_common_basis; cur_trans_.a_to_b_numer = n1 * n2; cur_trans_.a_to_b_denom = d1 * d2; return OK; } } // namespace android