// Copyright 2014 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // Routines for encoding and decoding a small number of bits into an image // in a way that is decodable even after scaling/encoding/cropping. // // The encoding is very simple: // // #### #### ######## #### #### #### // #### #### ######## #### #### #### // #### #### ######## #### #### #### // #### #### ######## #### #### #### // 1 2 3 4 5 6 7 8 9 10 11 12 13 14 // <-----start----><--one-bit-><-zero bit-><----stop----> // // We use a basic unit, depicted here as four characters wide. // We start with 1u black 1u white 1u black 1u white. (1-4 above) // From there on, a "one" bit is encoded as 2u black and 1u white, // and a zero bit is encoded as 1u black and 2u white. After // all the bits we end the pattern with the same pattern as the // start of the pattern. #include #include #include "base/logging.h" #include "media/base/video_frame.h" #include "media/cast/test/utility/barcode.h" namespace media { namespace cast { namespace test { const int kBlackThreshold = 256 * 2 / 3; const int kWhiteThreshold = 256 / 3; bool EncodeBarcode(const std::vector& bits, scoped_refptr output_frame) { DCHECK(output_frame->format() == PIXEL_FORMAT_YV12 || output_frame->format() == PIXEL_FORMAT_YV16 || output_frame->format() == PIXEL_FORMAT_I420); int row_bytes = output_frame->row_bytes(VideoFrame::kYPlane); std::vector bytes(row_bytes); for (int i = 0; i < row_bytes; i++) { bytes[i] = 255; } size_t units = bits.size() * 3 + 7; // White or black bar where size matters. // We only use 60% of the image to make sure it works even if // the image gets cropped. size_t unit_size = row_bytes * 6 / 10 / units; if (unit_size < 1) return false; size_t bytes_required = unit_size * units; size_t padding = (row_bytes - bytes_required) / 2; unsigned char *pos = &bytes[padding]; // Two leading black bars. memset(pos, 0, unit_size); pos += unit_size * 2; memset(pos, 0, unit_size); pos += unit_size * 2; for (size_t bit = 0; bit < bits.size(); bit++) { memset(pos, 0, bits[bit] ? unit_size * 2: unit_size); pos += unit_size * 3; } memset(pos, 0, unit_size); pos += unit_size * 2; memset(pos, 0, unit_size); pos += unit_size; DCHECK_LE(pos - &bytes.front(), row_bytes); // Now replicate this one row into all rows in kYPlane. for (int row = 0; row < output_frame->rows(VideoFrame::kYPlane); row++) { memcpy(output_frame->data(VideoFrame::kYPlane) + output_frame->stride(VideoFrame::kYPlane) * row, &bytes.front(), row_bytes); } return true; } namespace { bool DecodeBarCodeRows(const scoped_refptr& frame, std::vector* output, int min_row, int max_row) { // Do a basic run-length encoding std::deque runs; bool is_black = true; int length = 0; for (int pos = 0; pos < frame->row_bytes(VideoFrame::kYPlane); pos++) { float value = 0.0; for (int row = min_row; row < max_row; row++) { value += frame->data(VideoFrame::kYPlane)[ frame->stride(VideoFrame::kYPlane) * row + pos]; } value /= max_row - min_row; if (is_black ? value > kBlackThreshold : value < kWhiteThreshold) { is_black = !is_black; runs.push_back(length); length = 1; } else { length++; } } runs.push_back(length); // Try decoding starting at each white-black transition. while (runs.size() >= output->size() * 2 + 7) { std::deque::const_iterator i = runs.begin(); double unit_size = (i[1] + i[2] + i[3] + i[4]) / 4; bool valid = true; if (i[0] > unit_size * 2 || i[0] < unit_size / 2) valid = false; if (i[1] > unit_size * 2 || i[1] < unit_size / 2) valid = false; if (i[2] > unit_size * 2 || i[2] < unit_size / 2) valid = false; if (i[3] > unit_size * 2 || i[3] < unit_size / 2) valid = false; i += 4; for (size_t bit = 0; valid && bit < output->size(); bit++) { if (i[0] > unit_size / 2 && i[0] <= unit_size * 1.5 && i[1] > unit_size * 1.5 && i[1] <= unit_size * 3) { (*output)[bit] = false; } else if (i[1] > unit_size / 2 && i[1] <= unit_size * 1.5 && i[0] > unit_size * 1.5 && i[0] <= unit_size * 3) { (*output)[bit] = true; } else { // Not a valid code valid = false; } i += 2; } if (i[0] > unit_size * 2 || i[0] < unit_size / 2) valid = false; if (i[1] > unit_size * 2 || i[1] < unit_size / 2) valid = false; if (i[2] > unit_size * 2 || i[2] < unit_size / 2) valid = false; i += 3; DCHECK(i <= runs.end()); if (valid) { // Decoding successful, return true return true; } runs.pop_front(); runs.pop_front(); } return false; } } // namespace // Note that "output" is assumed to be the right size already. This // could be inferred from the data, but the decoding is more robust // if we can assume that we know how many bits we want. bool DecodeBarcode(const scoped_refptr& frame, std::vector* output) { DCHECK(frame->format() == PIXEL_FORMAT_YV12 || frame->format() == PIXEL_FORMAT_YV16 || frame->format() == PIXEL_FORMAT_I420); int rows = frame->rows(VideoFrame::kYPlane); // Middle 10 lines if (DecodeBarCodeRows(frame, output, std::max(0, rows / 2 - 5), std::min(rows, rows / 2 + 5))) { return true; } // Top 5 lines if (DecodeBarCodeRows(frame, output, 0, std::min(5, rows))) { return true; } return false; } } // namespace test } // namespace cast } // namespace media