/* * Copyright (C) 2019 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 "CameraExifUtils" #define ATRACE_TAG ATRACE_TAG_CAMERA //#define LOG_NDEBUG 0 #include "ExifUtils.h" #include #include #include #include #include #include #include "../EmulatedSensor.h" extern "C" { #include } namespace std { template <> struct default_delete { inline void operator()(ExifEntry* entry) const { exif_entry_unref(entry); } }; } // namespace std namespace android { class ExifUtilsImpl : public ExifUtils { public: ExifUtilsImpl(SensorCharacteristics sensor_chars); virtual ~ExifUtilsImpl(); // Initialize() can be called multiple times. The setting of Exif tags will be // cleared. virtual bool Initialize(); // set all known fields from a metadata structure virtual bool SetFromMetadata(const HalCameraMetadata& metadata, size_t image_width, size_t image_height); // sets the len aperture. // Returns false if memory allocation fails. virtual bool SetAperture(float aperture); // sets the color space. // Returns false if memory allocation fails. virtual bool SetColorSpace(uint16_t color_space); // sets the date and time of image last modified. It takes local time. The // name of the tag is DateTime in IFD0. // Returns false if memory allocation fails. virtual bool SetDateTime(const struct tm& t); // sets the digital zoom ratio. If the numerator is 0, it means digital zoom // was not used. // Returns false if memory allocation fails. virtual bool SetDigitalZoomRatio(uint32_t crop_width, uint32_t crop_height, uint32_t sensor_width, uint32_t sensor_height); // Sets the exposure bias. // Returns false if memory allocation fails. virtual bool SetExposureBias(int32_t ev, uint32_t ev_step_numerator, uint32_t ev_step_denominator); // sets the exposure mode set when the image was shot. // Returns false if memory allocation fails. virtual bool SetExposureMode(uint8_t exposure_mode); // sets the exposure time, given in seconds. // Returns false if memory allocation fails. virtual bool SetExposureTime(float exposure_time); // sets the status of flash. // Returns false if memory allocation fails. virtual bool SetFlash(uint8_t flash_available, uint8_t flash_state, uint8_t ae_mode); // sets the F number. // Returns false if memory allocation fails. virtual bool SetFNumber(float f_number); // sets the focal length of lens used to take the image in millimeters. // Returns false if memory allocation fails. virtual bool SetFocalLength(float focal_length); // sets the focal length of lens for 35mm film used to take the image in // millimeters. Returns false if memory allocation fails. virtual bool SetFocalLengthIn35mmFilm(float focal_length, float sensor_size_x, float sensor_size_y); // sets make & model virtual bool SetMake(const std::string& make); virtual bool SetModel(const std::string& model); // sets the altitude in meters. // Returns false if memory allocation fails. virtual bool SetGpsAltitude(double altitude); // sets the latitude with degrees minutes seconds format. // Returns false if memory allocation fails. virtual bool SetGpsLatitude(double latitude); // sets the longitude with degrees minutes seconds format. // Returns false if memory allocation fails. virtual bool SetGpsLongitude(double longitude); // sets GPS processing method. // Returns false if memory allocation fails. virtual bool SetGpsProcessingMethod(const std::string& method); // sets GPS date stamp and time stamp (atomic clock). It takes UTC time. // Returns false if memory allocation fails. virtual bool SetGpsTimestamp(const struct tm& t); // sets the length (number of rows) of main image. // Returns false if memory allocation fails. virtual bool SetImageHeight(uint32_t length); // sets the width (number of columes) of main image. // Returns false if memory allocation fails. virtual bool SetImageWidth(uint32_t width); // sets the ISO speed. // Returns false if memory allocation fails. virtual bool SetIsoSpeedRating(uint16_t iso_speed_ratings); // sets the smallest F number of the lens. // Returns false if memory allocation fails. virtual bool SetMaxAperture(float aperture); // sets image orientation. // Returns false if memory allocation fails. virtual bool SetOrientation(uint16_t degrees); // sets image orientation. // Returns false if memory allocation fails. virtual bool SetOrientationValue(ExifOrientation orientation_value); // sets the shutter speed. // Returns false if memory allocation fails. virtual bool SetShutterSpeed(float exposure_time); // sets the distance to the subject, given in meters. // Returns false if memory allocation fails. virtual bool SetSubjectDistance(float diopters); // sets the fractions of seconds for the tag. // Returns false if memory allocation fails. virtual bool SetSubsecTime(const std::string& subsec_time); // sets the white balance mode set when the image was shot. // Returns false if memory allocation fails. virtual bool SetWhiteBalance(uint8_t white_balance); // Generates APP1 segment. // Returns false if generating APP1 segment fails. virtual bool GenerateApp1(unsigned char* thumbnail_buffer, uint32_t size); // Gets buffer of APP1 segment. This method must be called only after calling // GenerateAPP1(). virtual const uint8_t* GetApp1Buffer(); // Gets length of APP1 segment. This method must be called only after calling // GenerateAPP1(). virtual unsigned int GetApp1Length(); protected: // sets the version of this standard supported. // Returns false if memory allocation fails. virtual bool SetExifVersion(const std::string& exif_version); // Resets the pointers and memories. virtual void Reset(); // Adds a variable length tag to |exif_data_|. It will remove the original one // if the tag exists. // Returns the entry of the tag. The reference count of returned ExifEntry is // two. virtual std::unique_ptr AddVariableLengthEntry(ExifIfd ifd, ExifTag tag, ExifFormat format, uint64_t components, unsigned int size); // Adds a entry of |tag| in |exif_data_|. It won't remove the original one if // the tag exists. // Returns the entry of the tag. It adds one reference count to returned // ExifEntry. virtual std::unique_ptr AddEntry(ExifIfd ifd, ExifTag tag); // Helpe functions to add exif data with different types. virtual bool SetShort(ExifIfd ifd, ExifTag tag, uint16_t value, const std::string& msg); virtual bool SetLong(ExifIfd ifd, ExifTag tag, uint32_t value, const std::string& msg); virtual bool SetRational(ExifIfd ifd, ExifTag tag, uint32_t numerator, uint32_t denominator, const std::string& msg); virtual bool SetSRational(ExifIfd ifd, ExifTag tag, int32_t numerator, int32_t denominator, const std::string& msg); virtual bool SetString(ExifIfd ifd, ExifTag tag, ExifFormat format, const std::string& buffer, const std::string& msg); float ConvertToApex(float val) { return 2.0f * log2f(val); } // Destroys the buffer of APP1 segment if exists. virtual void DestroyApp1(); // The Exif data (APP1). Owned by this class. ExifData* exif_data_; // The raw data of APP1 segment. It's allocated by ExifMem in |exif_data_| but // owned by this class. uint8_t* app1_buffer_; // The length of |app1_buffer_|. unsigned int app1_length_; // How precise the float-to-rational conversion for EXIF tags would be. const static int kRationalPrecision = 10000; SensorCharacteristics sensor_chars_; }; #define SET_SHORT(ifd, tag, value) \ do { \ if (SetShort(ifd, tag, value, #tag) == false) return false; \ } while (0); #define SET_LONG(ifd, tag, value) \ do { \ if (SetLong(ifd, tag, value, #tag) == false) return false; \ } while (0); #define SET_RATIONAL(ifd, tag, numerator, denominator) \ do { \ if (SetRational(ifd, tag, numerator, denominator, #tag) == false) \ return false; \ } while (0); #define SET_SRATIONAL(ifd, tag, numerator, denominator) \ do { \ if (SetSRational(ifd, tag, numerator, denominator, #tag) == false) \ return false; \ } while (0); #define SET_STRING(ifd, tag, format, buffer) \ do { \ if (SetString(ifd, tag, format, buffer, #tag) == false) return false; \ } while (0); // This comes from the Exif Version 2.2 standard table 6. const char gExifAsciiPrefix[] = {0x41, 0x53, 0x43, 0x49, 0x49, 0x0, 0x0, 0x0}; static void SetLatitudeOrLongitudeData(unsigned char* data, double num) { // Take the integer part of |num|. ExifLong degrees = static_cast(num); ExifLong minutes = static_cast(60 * (num - degrees)); ExifLong microseconds = static_cast(3600000000u * (num - degrees - minutes / 60.0)); exif_set_rational(data, EXIF_BYTE_ORDER_INTEL, {degrees, 1}); exif_set_rational(data + sizeof(ExifRational), EXIF_BYTE_ORDER_INTEL, {minutes, 1}); exif_set_rational(data + 2 * sizeof(ExifRational), EXIF_BYTE_ORDER_INTEL, {microseconds, 1000000}); } ExifUtils* ExifUtils::Create(SensorCharacteristics sensor_chars) { return new ExifUtilsImpl(sensor_chars); } ExifUtils::~ExifUtils() { } ExifUtilsImpl::ExifUtilsImpl(SensorCharacteristics sensor_chars) : exif_data_(nullptr), app1_buffer_(nullptr), app1_length_(0), sensor_chars_(sensor_chars) { } ExifUtilsImpl::~ExifUtilsImpl() { Reset(); } bool ExifUtilsImpl::Initialize() { Reset(); exif_data_ = exif_data_new(); if (exif_data_ == nullptr) { ALOGE("%s: allocate memory for exif_data_ failed", __FUNCTION__); return false; } // set the image options. exif_data_set_option(exif_data_, EXIF_DATA_OPTION_FOLLOW_SPECIFICATION); exif_data_set_data_type(exif_data_, EXIF_DATA_TYPE_COMPRESSED); exif_data_set_byte_order(exif_data_, EXIF_BYTE_ORDER_INTEL); // set exif version to 2.2. if (!SetExifVersion("0220")) { return false; } return true; } bool ExifUtilsImpl::SetAperture(float aperture) { float apex_value = ConvertToApex(aperture); SET_RATIONAL( EXIF_IFD_EXIF, EXIF_TAG_APERTURE_VALUE, static_cast(std::round(apex_value * kRationalPrecision)), kRationalPrecision); return true; } bool ExifUtilsImpl::SetColorSpace(uint16_t color_space) { SET_SHORT(EXIF_IFD_EXIF, EXIF_TAG_COLOR_SPACE, color_space); return true; } bool ExifUtilsImpl::SetDateTime(const struct tm& t) { // The length is 20 bytes including NULL for termination in Exif standard. char str[20]; int result = snprintf(str, sizeof(str), "%04i:%02i:%02i %02i:%02i:%02i", t.tm_year + 1900, t.tm_mon + 1, t.tm_mday, t.tm_hour, t.tm_min, t.tm_sec); if (result != sizeof(str) - 1) { ALOGW("%s: Input time is invalid", __FUNCTION__); return false; } std::string buffer(str); SET_STRING(EXIF_IFD_0, EXIF_TAG_DATE_TIME, EXIF_FORMAT_ASCII, buffer); SET_STRING(EXIF_IFD_EXIF, EXIF_TAG_DATE_TIME_ORIGINAL, EXIF_FORMAT_ASCII, buffer); SET_STRING(EXIF_IFD_EXIF, EXIF_TAG_DATE_TIME_DIGITIZED, EXIF_FORMAT_ASCII, buffer); return true; } bool ExifUtilsImpl::SetDigitalZoomRatio(uint32_t crop_width, uint32_t crop_height, uint32_t sensor_width, uint32_t sensor_height) { float zoom_ratio_x = (crop_width == 0) ? 1.0 : 1.0 * sensor_width / crop_width; float zoom_ratio_y = (crop_height == 0) ? 1.0 : 1.0 * sensor_height / crop_height; float zoom_ratio = std::max(zoom_ratio_x, zoom_ratio_y); const static float no_zoom_threshold = 1.02f; if (zoom_ratio <= no_zoom_threshold) { SET_RATIONAL(EXIF_IFD_EXIF, EXIF_TAG_DIGITAL_ZOOM_RATIO, 0, 1); } else { SET_RATIONAL( EXIF_IFD_EXIF, EXIF_TAG_DIGITAL_ZOOM_RATIO, static_cast(std::round(zoom_ratio * kRationalPrecision)), kRationalPrecision); } return true; } bool ExifUtilsImpl::SetExposureMode(uint8_t exposure_mode) { uint16_t mode = (exposure_mode == ANDROID_CONTROL_AE_MODE_OFF) ? 1 : 0; SET_SHORT(EXIF_IFD_EXIF, EXIF_TAG_EXPOSURE_MODE, mode); return true; } bool ExifUtilsImpl::SetExposureTime(float exposure_time) { SET_RATIONAL( EXIF_IFD_EXIF, EXIF_TAG_EXPOSURE_TIME, static_cast(std::round(exposure_time * kRationalPrecision)), kRationalPrecision); return true; } bool ExifUtilsImpl::SetFlash(uint8_t flash_available, uint8_t flash_state, uint8_t ae_mode) { // EXIF_TAG_FLASH bits layout per EXIF standard: // Bit 0: 0 - did not fire // 1 - fired // Bit 1-2: status of return light // Bit 3-4: 0 - unknown // 1 - compulsory flash firing // 2 - compulsory flash suppression // 3 - auto mode // Bit 5: 0 - flash function present // 1 - no flash function // Bit 6: 0 - no red-eye reduction mode or unknown // 1 - red-eye reduction supported uint16_t flash = 0x20; if (flash_available == ANDROID_FLASH_INFO_AVAILABLE_TRUE) { flash = 0x00; if (flash_state == ANDROID_FLASH_STATE_FIRED) { flash |= 0x1; } if (ae_mode == ANDROID_CONTROL_AE_MODE_ON_AUTO_FLASH_REDEYE) { flash |= 0x40; } uint16_t flash_mode = 0; switch (ae_mode) { case ANDROID_CONTROL_AE_MODE_ON_AUTO_FLASH: case ANDROID_CONTROL_AE_MODE_ON_AUTO_FLASH_REDEYE: flash_mode = 3; // AUTO break; case ANDROID_CONTROL_AE_MODE_ON_ALWAYS_FLASH: case ANDROID_CONTROL_AE_MODE_ON_EXTERNAL_FLASH: flash_mode = 1; // ON break; case ANDROID_CONTROL_AE_MODE_OFF: case ANDROID_CONTROL_AE_MODE_ON: flash_mode = 2; // OFF break; default: flash_mode = 0; // UNKNOWN break; } flash |= (flash_mode << 3); } SET_SHORT(EXIF_IFD_EXIF, EXIF_TAG_FLASH, flash); return true; } bool ExifUtilsImpl::SetFNumber(float f_number) { SET_RATIONAL(EXIF_IFD_EXIF, EXIF_TAG_FNUMBER, static_cast(std::round(f_number * kRationalPrecision)), kRationalPrecision); return true; } bool ExifUtilsImpl::SetFocalLength(float focal_length) { uint32_t numerator = static_cast(std::round(focal_length * kRationalPrecision)); SET_RATIONAL(EXIF_IFD_EXIF, EXIF_TAG_FOCAL_LENGTH, numerator, kRationalPrecision); return true; } bool ExifUtilsImpl::SetFocalLengthIn35mmFilm(float focal_length, float sensor_size_x, float sensor_size_y) { static const float film_diagonal = 43.27; // diagonal of 35mm film static const float min_sensor_diagonal = 0.01; float sensor_diagonal = std::sqrt(sensor_size_x * sensor_size_x + sensor_size_y * sensor_size_y); sensor_diagonal = std::max(sensor_diagonal, min_sensor_diagonal); float focal_length35mm_film = std::round(focal_length * film_diagonal / sensor_diagonal); focal_length35mm_film = std::min(1.0f * 65535, focal_length35mm_film); SET_SHORT(EXIF_IFD_EXIF, EXIF_TAG_FOCAL_LENGTH_IN_35MM_FILM, static_cast(focal_length35mm_film)); return true; } bool ExifUtilsImpl::SetGpsAltitude(double altitude) { ExifTag ref_tag = static_cast(EXIF_TAG_GPS_ALTITUDE_REF); std::unique_ptr ref_entry = AddVariableLengthEntry(EXIF_IFD_GPS, ref_tag, EXIF_FORMAT_BYTE, 1, 1); if (!ref_entry) { ALOGE("%s: Adding GPSAltitudeRef exif entry failed", __FUNCTION__); return false; } if (altitude >= 0) { *ref_entry->data = 0; } else { *ref_entry->data = 1; altitude *= -1; } ExifTag tag = static_cast(EXIF_TAG_GPS_ALTITUDE); std::unique_ptr entry = AddVariableLengthEntry( EXIF_IFD_GPS, tag, EXIF_FORMAT_RATIONAL, 1, sizeof(ExifRational)); if (!entry) { exif_content_remove_entry(exif_data_->ifd[EXIF_IFD_GPS], ref_entry.get()); ALOGE("%s: Adding GPSAltitude exif entry failed", __FUNCTION__); return false; } exif_set_rational(entry->data, EXIF_BYTE_ORDER_INTEL, {static_cast(altitude * 1000), 1000}); return true; } bool ExifUtilsImpl::SetGpsLatitude(double latitude) { const ExifTag ref_tag = static_cast(EXIF_TAG_GPS_LATITUDE_REF); std::unique_ptr ref_entry = AddVariableLengthEntry(EXIF_IFD_GPS, ref_tag, EXIF_FORMAT_ASCII, 2, 2); if (!ref_entry) { ALOGE("%s: Adding GPSLatitudeRef exif entry failed", __FUNCTION__); return false; } if (latitude >= 0) { memcpy(ref_entry->data, "N", sizeof("N")); } else { memcpy(ref_entry->data, "S", sizeof("S")); latitude *= -1; } const ExifTag tag = static_cast(EXIF_TAG_GPS_LATITUDE); std::unique_ptr entry = AddVariableLengthEntry( EXIF_IFD_GPS, tag, EXIF_FORMAT_RATIONAL, 3, 3 * sizeof(ExifRational)); if (!entry) { exif_content_remove_entry(exif_data_->ifd[EXIF_IFD_GPS], ref_entry.get()); ALOGE("%s: Adding GPSLatitude exif entry failed", __FUNCTION__); return false; } SetLatitudeOrLongitudeData(entry->data, latitude); return true; } bool ExifUtilsImpl::SetGpsLongitude(double longitude) { ExifTag ref_tag = static_cast(EXIF_TAG_GPS_LONGITUDE_REF); std::unique_ptr ref_entry = AddVariableLengthEntry(EXIF_IFD_GPS, ref_tag, EXIF_FORMAT_ASCII, 2, 2); if (!ref_entry) { ALOGE("%s: Adding GPSLongitudeRef exif entry failed", __FUNCTION__); return false; } if (longitude >= 0) { memcpy(ref_entry->data, "E", sizeof("E")); } else { memcpy(ref_entry->data, "W", sizeof("W")); longitude *= -1; } ExifTag tag = static_cast(EXIF_TAG_GPS_LONGITUDE); std::unique_ptr entry = AddVariableLengthEntry( EXIF_IFD_GPS, tag, EXIF_FORMAT_RATIONAL, 3, 3 * sizeof(ExifRational)); if (!entry) { exif_content_remove_entry(exif_data_->ifd[EXIF_IFD_GPS], ref_entry.get()); ALOGE("%s: Adding GPSLongitude exif entry failed", __FUNCTION__); return false; } SetLatitudeOrLongitudeData(entry->data, longitude); return true; } bool ExifUtilsImpl::SetGpsProcessingMethod(const std::string& method) { std::string buffer = std::string(gExifAsciiPrefix, sizeof(gExifAsciiPrefix)) + method; SET_STRING(EXIF_IFD_GPS, static_cast(EXIF_TAG_GPS_PROCESSING_METHOD), EXIF_FORMAT_UNDEFINED, buffer); return true; } bool ExifUtilsImpl::SetGpsTimestamp(const struct tm& t) { const ExifTag date_tag = static_cast(EXIF_TAG_GPS_DATE_STAMP); const size_t kGpsDateStampSize = 11; std::unique_ptr entry = AddVariableLengthEntry(EXIF_IFD_GPS, date_tag, EXIF_FORMAT_ASCII, kGpsDateStampSize, kGpsDateStampSize); if (!entry) { ALOGE("%s: Adding GPSDateStamp exif entry failed", __FUNCTION__); return false; } int result = snprintf(reinterpret_cast(entry->data), kGpsDateStampSize, "%04i:%02i:%02i", t.tm_year + 1900, t.tm_mon + 1, t.tm_mday); if (result != kGpsDateStampSize - 1) { ALOGW("%s: Input time is invalid", __FUNCTION__); return false; } const ExifTag time_tag = static_cast(EXIF_TAG_GPS_TIME_STAMP); entry = AddVariableLengthEntry(EXIF_IFD_GPS, time_tag, EXIF_FORMAT_RATIONAL, 3, 3 * sizeof(ExifRational)); if (!entry) { ALOGE("%s: Adding GPSTimeStamp exif entry failed", __FUNCTION__); return false; } exif_set_rational(entry->data, EXIF_BYTE_ORDER_INTEL, {static_cast(t.tm_hour), 1}); exif_set_rational(entry->data + sizeof(ExifRational), EXIF_BYTE_ORDER_INTEL, {static_cast(t.tm_min), 1}); exif_set_rational(entry->data + 2 * sizeof(ExifRational), EXIF_BYTE_ORDER_INTEL, {static_cast(t.tm_sec), 1}); return true; } bool ExifUtilsImpl::SetImageHeight(uint32_t length) { SET_SHORT(EXIF_IFD_0, EXIF_TAG_IMAGE_LENGTH, length); SET_SHORT(EXIF_IFD_EXIF, EXIF_TAG_PIXEL_Y_DIMENSION, length); return true; } bool ExifUtilsImpl::SetImageWidth(uint32_t width) { SET_SHORT(EXIF_IFD_0, EXIF_TAG_IMAGE_WIDTH, width); SET_SHORT(EXIF_IFD_EXIF, EXIF_TAG_PIXEL_X_DIMENSION, width); return true; } bool ExifUtilsImpl::SetIsoSpeedRating(uint16_t iso_speed_ratings) { SET_SHORT(EXIF_IFD_EXIF, EXIF_TAG_ISO_SPEED_RATINGS, iso_speed_ratings); return true; } bool ExifUtilsImpl::SetMaxAperture(float aperture) { float maxAperture = ConvertToApex(aperture); SET_RATIONAL( EXIF_IFD_EXIF, EXIF_TAG_MAX_APERTURE_VALUE, static_cast(std::round(maxAperture * kRationalPrecision)), kRationalPrecision); return true; } bool ExifUtilsImpl::SetExposureBias(int32_t ev, uint32_t ev_step_numerator, uint32_t ev_step_denominator) { SET_RATIONAL(EXIF_IFD_EXIF, EXIF_TAG_EXPOSURE_BIAS_VALUE, ev * ev_step_numerator, ev_step_denominator); return true; } bool ExifUtilsImpl::SetOrientation(uint16_t degrees) { ExifOrientation value = ExifOrientation::ORIENTATION_0_DEGREES; switch (degrees) { case 90: value = ExifOrientation::ORIENTATION_90_DEGREES; break; case 180: value = ExifOrientation::ORIENTATION_180_DEGREES; break; case 270: value = ExifOrientation::ORIENTATION_270_DEGREES; break; default: break; } return SetOrientationValue(value); } bool ExifUtilsImpl::SetOrientationValue(ExifOrientation orientation_value) { SET_SHORT(EXIF_IFD_0, EXIF_TAG_ORIENTATION, orientation_value); return true; } bool ExifUtilsImpl::SetShutterSpeed(float exposure_time) { float shutter_speed = -log2f(exposure_time); SET_SRATIONAL(EXIF_IFD_EXIF, EXIF_TAG_SHUTTER_SPEED_VALUE, static_cast(shutter_speed * kRationalPrecision), kRationalPrecision); return true; } bool ExifUtilsImpl::SetSubjectDistance(float diopters) { const static float kInfinityDiopters = 1.0e-6; uint32_t numerator, denominator; uint16_t distance_range; if (diopters > kInfinityDiopters) { float focus_distance = 1.0f / diopters; numerator = static_cast(std::round(focus_distance * kRationalPrecision)); denominator = kRationalPrecision; if (focus_distance < 1.0f) { distance_range = 1; // Macro } else if (focus_distance < 3.0f) { distance_range = 2; // Close } else { distance_range = 3; // Distant } } else { numerator = 0xFFFFFFFF; denominator = 1; distance_range = 3; // Distant } SET_RATIONAL(EXIF_IFD_EXIF, EXIF_TAG_SUBJECT_DISTANCE, numerator, denominator); SET_SHORT(EXIF_IFD_EXIF, EXIF_TAG_SUBJECT_DISTANCE_RANGE, distance_range); return true; } bool ExifUtilsImpl::SetSubsecTime(const std::string& subsec_time) { SET_STRING(EXIF_IFD_EXIF, EXIF_TAG_SUB_SEC_TIME, EXIF_FORMAT_ASCII, subsec_time); SET_STRING(EXIF_IFD_EXIF, EXIF_TAG_SUB_SEC_TIME_ORIGINAL, EXIF_FORMAT_ASCII, subsec_time); SET_STRING(EXIF_IFD_EXIF, EXIF_TAG_SUB_SEC_TIME_DIGITIZED, EXIF_FORMAT_ASCII, subsec_time); return true; } bool ExifUtilsImpl::SetWhiteBalance(uint8_t white_balance) { uint16_t whiteBalance = (white_balance == ANDROID_CONTROL_AWB_MODE_AUTO) ? 0 : 1; SET_SHORT(EXIF_IFD_EXIF, EXIF_TAG_WHITE_BALANCE, whiteBalance); return true; } bool ExifUtilsImpl::GenerateApp1(unsigned char* thumbnail_buffer, uint32_t size) { DestroyApp1(); exif_data_->data = thumbnail_buffer; exif_data_->size = size; // Save the result into |app1_buffer_|. exif_data_save_data(exif_data_, &app1_buffer_, &app1_length_); if (!app1_length_) { ALOGE("%s: Allocate memory for app1_buffer_ failed", __FUNCTION__); return false; } /* * The JPEG segment size is 16 bits in spec. The size of APP1 segment should * be smaller than 65533 because there are two bytes for segment size field. */ if (app1_length_ > 65533) { DestroyApp1(); ALOGE("%s: The size of APP1 segment is too large", __FUNCTION__); return false; } return true; } const uint8_t* ExifUtilsImpl::GetApp1Buffer() { return app1_buffer_; } unsigned int ExifUtilsImpl::GetApp1Length() { return app1_length_; } bool ExifUtilsImpl::SetExifVersion(const std::string& exif_version) { SET_STRING(EXIF_IFD_EXIF, EXIF_TAG_EXIF_VERSION, EXIF_FORMAT_UNDEFINED, exif_version); return true; } bool ExifUtilsImpl::SetMake(const std::string& make) { SET_STRING(EXIF_IFD_0, EXIF_TAG_MAKE, EXIF_FORMAT_UNDEFINED, make); return true; } bool ExifUtilsImpl::SetModel(const std::string& model) { SET_STRING(EXIF_IFD_0, EXIF_TAG_MODEL, EXIF_FORMAT_UNDEFINED, model); return true; } void ExifUtilsImpl::Reset() { DestroyApp1(); if (exif_data_) { /* * Since we decided to ignore the original APP1, we are sure that there is * no thumbnail allocated by libexif. |exif_data_->data| is actually * allocated by JpegCompressor. sets |exif_data_->data| to nullptr to * prevent exif_data_unref() destroy it incorrectly. */ exif_data_->data = nullptr; exif_data_->size = 0; exif_data_unref(exif_data_); exif_data_ = nullptr; } } std::unique_ptr ExifUtilsImpl::AddVariableLengthEntry( ExifIfd ifd, ExifTag tag, ExifFormat format, uint64_t components, unsigned int size) { // Remove old entry if exists. exif_content_remove_entry(exif_data_->ifd[ifd], exif_content_get_entry(exif_data_->ifd[ifd], tag)); ExifMem* mem = exif_mem_new_default(); if (!mem) { ALOGE("%s: Allocate memory for exif entry failed", __FUNCTION__); return nullptr; } std::unique_ptr entry(exif_entry_new_mem(mem)); if (!entry) { ALOGE("%s: Allocate memory for exif entry failed", __FUNCTION__); exif_mem_unref(mem); return nullptr; } void* tmp_buffer = exif_mem_alloc(mem, size); if (!tmp_buffer) { ALOGE("%s: Allocate memory for exif entry failed", __FUNCTION__); exif_mem_unref(mem); return nullptr; } entry->data = static_cast(tmp_buffer); entry->tag = tag; entry->format = format; entry->components = components; entry->size = size; exif_content_add_entry(exif_data_->ifd[ifd], entry.get()); exif_mem_unref(mem); return entry; } std::unique_ptr ExifUtilsImpl::AddEntry(ExifIfd ifd, ExifTag tag) { std::unique_ptr entry( exif_content_get_entry(exif_data_->ifd[ifd], tag)); if (entry) { // exif_content_get_entry() won't ref the entry, so we ref here. exif_entry_ref(entry.get()); return entry; } entry.reset(exif_entry_new()); if (!entry) { ALOGE("%s: Allocate memory for exif entry failed", __FUNCTION__); return nullptr; } entry->tag = tag; exif_content_add_entry(exif_data_->ifd[ifd], entry.get()); exif_entry_initialize(entry.get(), tag); return entry; } bool ExifUtilsImpl::SetShort(ExifIfd ifd, ExifTag tag, uint16_t value, const std::string& msg) { std::unique_ptr entry = AddEntry(ifd, tag); if (!entry) { ALOGE("%s: Adding '%s' entry failed", __FUNCTION__, msg.c_str()); return false; } exif_set_short(entry->data, EXIF_BYTE_ORDER_INTEL, value); return true; } bool ExifUtilsImpl::SetLong(ExifIfd ifd, ExifTag tag, uint32_t value, const std::string& msg) { std::unique_ptr entry = AddEntry(ifd, tag); if (!entry) { ALOGE("%s: Adding '%s' entry failed", __FUNCTION__, msg.c_str()); return false; } exif_set_long(entry->data, EXIF_BYTE_ORDER_INTEL, value); return true; } bool ExifUtilsImpl::SetRational(ExifIfd ifd, ExifTag tag, uint32_t numerator, uint32_t denominator, const std::string& msg) { std::unique_ptr entry = AddEntry(ifd, tag); if (!entry) { ALOGE("%s: Adding '%s' entry failed", __FUNCTION__, msg.c_str()); return false; } exif_set_rational(entry->data, EXIF_BYTE_ORDER_INTEL, {numerator, denominator}); return true; } bool ExifUtilsImpl::SetSRational(ExifIfd ifd, ExifTag tag, int32_t numerator, int32_t denominator, const std::string& msg) { std::unique_ptr entry = AddEntry(ifd, tag); if (!entry) { ALOGE("%s: Adding '%s' entry failed", __FUNCTION__, msg.c_str()); return false; } exif_set_srational(entry->data, EXIF_BYTE_ORDER_INTEL, {numerator, denominator}); return true; } bool ExifUtilsImpl::SetString(ExifIfd ifd, ExifTag tag, ExifFormat format, const std::string& buffer, const std::string& msg) { size_t entry_size = buffer.length(); // Since the exif format is undefined, NULL termination is not necessary. if (format == EXIF_FORMAT_ASCII) { entry_size++; } std::unique_ptr entry = AddVariableLengthEntry(ifd, tag, format, entry_size, entry_size); if (!entry) { ALOGE("%s: Adding '%s' entry failed", __FUNCTION__, msg.c_str()); return false; } memcpy(entry->data, buffer.c_str(), entry_size); return true; } void ExifUtilsImpl::DestroyApp1() { /* * Since there is no API to access ExifMem in ExifData->priv, we use free * here, which is the default free function in libexif. See * exif_data_save_data() for detail. */ free(app1_buffer_); app1_buffer_ = nullptr; app1_length_ = 0; } bool ExifUtilsImpl::SetFromMetadata(const HalCameraMetadata& metadata, size_t image_width, size_t image_height) { if (!SetImageWidth(image_width) || !SetImageHeight(image_height)) { ALOGE("%s: setting image resolution failed.", __FUNCTION__); return false; } struct timespec tp; struct tm time_info; bool time_available = clock_gettime(CLOCK_REALTIME, &tp) != -1; localtime_r(&tp.tv_sec, &time_info); if (!SetDateTime(time_info)) { ALOGE("%s: setting data time failed.", __FUNCTION__); return false; } float focal_length; camera_metadata_ro_entry entry; auto ret = metadata.Get(ANDROID_LENS_FOCAL_LENGTH, &entry); if (ret == OK) { focal_length = entry.data.f[0]; if (!SetFocalLength(focal_length)) { ALOGE("%s: setting focal length failed.", __FUNCTION__); return false; } if (!SetFocalLengthIn35mmFilm(focal_length, sensor_chars_.physical_size[0], sensor_chars_.physical_size[1])) { ALOGE("%s: setting focal length in 35mm failed.", __FUNCTION__); return false; } } else { ALOGV("%s: Cannot find focal length in metadata.", __FUNCTION__); } ret = metadata.Get(ANDROID_SCALER_CROP_REGION, &entry); if (ret == OK) { if (!SetDigitalZoomRatio(entry.data.i32[2], entry.data.i32[3], sensor_chars_.full_res_width, sensor_chars_.full_res_height)) { ALOGE("%s: setting digital zoom ratio failed.", __FUNCTION__); return false; } } ret = metadata.Get(ANDROID_JPEG_GPS_COORDINATES, &entry); if (ret == OK) { if (entry.count < 3) { ALOGE("%s: Gps coordinates in metadata is not complete.", __FUNCTION__); return false; } if (!SetGpsLatitude(entry.data.d[0])) { ALOGE("%s: setting gps latitude failed.", __FUNCTION__); return false; } if (!SetGpsLongitude(entry.data.d[1])) { ALOGE("%s: setting gps longitude failed.", __FUNCTION__); return false; } if (!SetGpsAltitude(entry.data.d[2])) { ALOGE("%s: setting gps altitude failed.", __FUNCTION__); return false; } } ret = metadata.Get(ANDROID_JPEG_GPS_PROCESSING_METHOD, &entry); if (ret == OK) { std::string method_str(reinterpret_cast(entry.data.u8)); if (!SetGpsProcessingMethod(method_str)) { ALOGE("%s: setting gps processing method failed.", __FUNCTION__); return false; } } ret = metadata.Get(ANDROID_JPEG_GPS_TIMESTAMP, &entry); if (time_available && (ret == OK)) { time_t timestamp = static_cast(entry.data.i64[0]); if (gmtime_r(×tamp, &time_info)) { if (!SetGpsTimestamp(time_info)) { ALOGE("%s: setting gps timestamp failed.", __FUNCTION__); return false; } } else { ALOGE("%s: Time transformation failed.", __FUNCTION__); return false; } } ret = metadata.Get(ANDROID_JPEG_ORIENTATION, &entry); if (ret == OK) { if (!SetOrientation(entry.data.i32[0])) { ALOGE("%s: setting orientation failed.", __FUNCTION__); return false; } } ret = metadata.Get(ANDROID_SENSOR_EXPOSURE_TIME, &entry); if (ret == OK) { float exposure_time = 1.0f * entry.data.i64[0] / 1e9; if (!SetExposureTime(exposure_time)) { ALOGE("%s: setting exposure time failed.", __FUNCTION__); return false; } if (!SetShutterSpeed(exposure_time)) { ALOGE("%s: setting shutter speed failed.", __FUNCTION__); return false; } } ret = metadata.Get(ANDROID_LENS_FOCUS_DISTANCE, &entry); if (ret == OK) { if (!SetSubjectDistance(entry.data.f[0])) { ALOGE("%s: setting subject distance failed.", __FUNCTION__); return false; } } ret = metadata.Get(ANDROID_SENSOR_SENSITIVITY, &entry); if (ret == OK) { int32_t iso = entry.data.i32[0]; camera_metadata_ro_entry post_raw_sens_entry; metadata.Get(ANDROID_CONTROL_POST_RAW_SENSITIVITY_BOOST, &post_raw_sens_entry); if (post_raw_sens_entry.count > 0) { iso = iso * post_raw_sens_entry.data.i32[0] / 100; } if (!SetIsoSpeedRating(static_cast(iso))) { ALOGE("%s: setting iso rating failed.", __FUNCTION__); return false; } } ret = metadata.Get(ANDROID_LENS_APERTURE, &entry); if (ret == OK) { if (!SetFNumber(entry.data.f[0])) { ALOGE("%s: setting F number failed.", __FUNCTION__); return false; } if (!SetAperture(entry.data.f[0])) { ALOGE("%s: setting aperture failed.", __FUNCTION__); return false; } } static const uint16_t kSRGBColorSpace = 1; if (!SetColorSpace(kSRGBColorSpace)) { ALOGE("%s: setting color space failed.", __FUNCTION__); return false; } camera_metadata_ro_entry flash_state_entry; metadata.Get(ANDROID_FLASH_STATE, &flash_state_entry); camera_metadata_ro_entry ae_mode_entry; metadata.Get(ANDROID_CONTROL_AE_MODE, &ae_mode_entry); uint8_t flash_state = flash_state_entry.count > 0 ? flash_state_entry.data.u8[0] : ANDROID_FLASH_STATE_UNAVAILABLE; uint8_t ae_mode = ae_mode_entry.count > 0 ? ae_mode_entry.data.u8[0] : ANDROID_CONTROL_AE_MODE_OFF; if (!SetFlash(sensor_chars_.is_flash_supported, flash_state, ae_mode)) { ALOGE("%s: setting flash failed.", __FUNCTION__); return false; } ret = metadata.Get(ANDROID_CONTROL_AWB_MODE, &entry); if (ret == OK) { if (!SetWhiteBalance(entry.data.u8[0])) { ALOGE("%s: setting white balance failed.", __FUNCTION__); return false; } } ret = metadata.Get(ANDROID_CONTROL_AE_MODE, &entry); if (ret == OK) { if (!SetExposureMode(entry.data.u8[0])) { ALOGE("%s: setting exposure mode failed.", __FUNCTION__); return false; } } if (time_available) { char str[4]; if (snprintf(str, sizeof(str), "%03ld", tp.tv_nsec / 1000000) < 0) { ALOGE("%s: Subsec is invalid: %ld", __FUNCTION__, tp.tv_nsec); return false; } if (!SetSubsecTime(std::string(str))) { ALOGE("%s: setting subsec time failed.", __FUNCTION__); return false; } } return true; } } // namespace android