// This file is part of OpenCV project. // It is subject to the license terms in the LICENSE file found in the top-level directory // of this distribution and at http://opencv.org/license.html. // Copyright (c) 2020-2021 darkliang wangberlinT Certseeds #include "../precomp.hpp" #include "upcean_decoder.hpp" #include namespace cv { namespace barcode { static constexpr int DIVIDE_PART = 15; static constexpr int BIAS_PART = 2; #if 0 void UPCEANDecoder::drawDebugLine(Mat &debug_img, const Point2i &begin, const Point2i &end) const { Result result; std::vector middle; LineIterator line = LineIterator(debug_img, begin, end); middle.reserve(line.count); for (int cnt = 0; cnt < line.count; cnt++, line++) { middle.push_back(debug_img.at(line.pos())); } std::pair start_range; if (findStartGuardPatterns(middle, start_range)) { circle(debug_img, Point2i(begin.x + start_range.second, begin.y), 2, Scalar(0), 2); } result = this->decode(middle); if (result.format == Result::BARCODE_NONE) { result = this->decode(std::vector(middle.crbegin(), middle.crend())); } if (result.format == Result::BARCODE_NONE) { cv::line(debug_img, begin, end, Scalar(0), 2); cv::putText(debug_img, result.result, begin, cv::FONT_HERSHEY_PLAIN, 1, cv::Scalar(0, 0, 255), 1); } } #endif bool UPCEANDecoder::findGuardPatterns(const std::vector &row, uint rowOffset, uchar whiteFirst, const std::vector &pattern, Counter &counter, std::pair &result) { size_t patternLength = pattern.size(); size_t width = row.size(); uchar color = whiteFirst ? WHITE : BLACK; rowOffset = (int) (std::find(row.cbegin() + rowOffset, row.cend(), color) - row.cbegin()); uint counterPosition = 0; uint patternStart = rowOffset; for (uint x = rowOffset; x < width; x++) { if (row[x] == color) { counter.pattern[counterPosition]++; counter.sum++; } else { if (counterPosition == patternLength - 1) { if (patternMatch(counter, pattern, MAX_INDIVIDUAL_VARIANCE) < MAX_AVG_VARIANCE) { result.first = patternStart; result.second = x; return true; } patternStart += counter.pattern[0] + counter.pattern[1]; counter.sum -= counter.pattern[0] + counter.pattern[1]; std::copy(counter.pattern.begin() + 2, counter.pattern.end(), counter.pattern.begin()); counter.pattern[patternLength - 2] = 0; counter.pattern[patternLength - 1] = 0; counterPosition--; } else { counterPosition++; } counter.pattern[counterPosition] = 1; counter.sum++; color = (std::numeric_limits::max() - color); } } return false; } bool UPCEANDecoder::findStartGuardPatterns(const std::vector &row, std::pair &start_range) { bool is_find = false; int next_start = 0; while (!is_find) { Counter guard_counters(std::vector{0, 0, 0}); if (!findGuardPatterns(row, next_start, BLACK, BEGIN_PATTERN(), guard_counters, start_range)) { return false; } int start = static_cast(start_range.first); next_start = static_cast(start_range.second); int quiet_start = max(start - (next_start - start), 0); is_find = (quiet_start != start) && (std::find(std::begin(row) + quiet_start, std::begin(row) + start, BLACK) == std::begin(row) + start); } return true; } int UPCEANDecoder::decodeDigit(const std::vector &row, Counter &counters, uint rowOffset, const std::vector> &patterns) { fillCounter(row, rowOffset, counters); int bestMatch = -1; uint bestVariance = MAX_AVG_VARIANCE; // worst variance we'll accept int i = 0; for (const auto &pattern : patterns) { uint variance = patternMatch(counters, pattern, MAX_INDIVIDUAL_VARIANCE); if (variance < bestVariance) { bestVariance = variance; bestMatch = i; } i++; } return std::max(-1, bestMatch); // -1 is Mismatch or means error. } /*Input a ROI mat return result */ std::pair UPCEANDecoder::decodeROI(const Mat &bar_img) const { if ((size_t) bar_img.cols < this->bits_num) { return std::make_pair(Result{string(), Result::BARCODE_NONE}, 0.0F); } std::map result_vote; std::map format_vote; int vote_cnt = 0; int total_vote = 0; std::string max_result; Result::BarcodeType max_type = Result::BARCODE_NONE; const int step = bar_img.rows / (DIVIDE_PART + BIAS_PART); Result result; int row_num; for (int i = 0; i < DIVIDE_PART; ++i) { row_num = (i + BIAS_PART / 2) * step; if (row_num < 0 || row_num > bar_img.rows) { continue; } const auto *ptr = bar_img.ptr(row_num); vector line(ptr, ptr + bar_img.cols); result = decodeLine(line); if (result.format != Result::BARCODE_NONE) { total_vote++; result_vote[result.result] += 1; if (result_vote[result.result] > vote_cnt) { vote_cnt = result_vote[result.result]; max_result = result.result; max_type = result.format; } } } if (total_vote == 0 || (vote_cnt << 2) < total_vote) { return std::make_pair(Result(string(), Result::BARCODE_NONE), 0.0f); } float confidence = (float) vote_cnt / (float) DIVIDE_PART; //Check if it is UPC-A format if (max_type == Result::BARCODE_EAN_13 && max_result[0] == '0') { max_result = max_result.substr(1, 12); //UPC-A length 12 max_type = Result::BARCODE_UPC_A; } return std::make_pair(Result(max_result, max_type), confidence); } Result UPCEANDecoder::decodeLine(const vector &line) const { Result result = this->decode(line); if (result.format == Result::BARCODE_NONE) { result = this->decode(std::vector(line.crbegin(), line.crend())); } return result; } bool UPCEANDecoder::isValid(const string &result) const { if (result.size() != digit_number) { return false; } int sum = 0; for (int index = (int) result.size() - 2, i = 1; index >= 0; index--, i++) { int temp = result[index] - '0'; sum += (temp + ((i & 1) != 0 ? temp << 1 : 0)); } return (result.back() - '0') == ((10 - (sum % 10)) % 10); } // right for A const std::vector> &get_A_or_C_Patterns() { static const std::vector> A_or_C_Patterns{{3, 2, 1, 1}, // 0 {2, 2, 2, 1}, // 1 {2, 1, 2, 2}, // 2 {1, 4, 1, 1}, // 3 {1, 1, 3, 2}, // 4 {1, 2, 3, 1}, // 5 {1, 1, 1, 4}, // 6 {1, 3, 1, 2}, // 7 {1, 2, 1, 3}, // 8 {3, 1, 1, 2} // 9 }; return A_or_C_Patterns; } const std::vector> &get_AB_Patterns() { static const std::vector> AB_Patterns = [] { constexpr uint offset = 10; auto AB_Patterns_inited = std::vector>(offset << 1, std::vector(PATTERN_LENGTH, 0)); std::copy(get_A_or_C_Patterns().cbegin(), get_A_or_C_Patterns().cend(), AB_Patterns_inited.begin()); //AB pattern is for (uint i = 0; i < offset; ++i) { for (uint j = 0; j < PATTERN_LENGTH; ++j) { AB_Patterns_inited[i + offset][j] = AB_Patterns_inited[i][PATTERN_LENGTH - j - 1]; } } return AB_Patterns_inited; }(); return AB_Patterns; } const std::vector &BEGIN_PATTERN() { // it just need it's 1:1:1(black:white:black) static const std::vector BEGIN_PATTERN_(3, 1); return BEGIN_PATTERN_; } const std::vector &MIDDLE_PATTERN() { // it just need it's 1:1:1:1:1(white:black:white:black:white) static const std::vector MIDDLE_PATTERN_(5, 1); return MIDDLE_PATTERN_; } const std::array &FIRST_CHAR_ARRAY() { // use array to simulation a Hashmap, // because the data's size is small, // use a hashmap or brute-force search 10 times both can not accept static const std::array pattern{ '\x00', '\x00', '\x00', '\x00', '\x00', '\x00', '\x00', '\x06', '\x00', '\x00', '\x00', '\x09', '\x00', '\x08', '\x03', '\x00', '\x00', '\x00', '\x00', '\x05', '\x00', '\x07', '\x02', '\x00', '\x00', '\x04', '\x01', '\x00', '\x00', '\x00', '\x00', '\x00'}; // length is 32 to ensure the security // 0x00000 -> 0 -> 0 // 0x11010 -> 26 -> 1 // 0x10110 -> 22 -> 2 // 0x01110 -> 14 -> 3 // 0x11001 -> 25 -> 4 // 0x10011 -> 19 -> 5 // 0x00111 -> 7 -> 6 // 0x10101 -> 21 -> 7 // 0x01101 -> 13 -> 8 // 0x01011 -> 11 -> 9 // delete the 1-13's 2 number's bit, // it always be A which do not need to count. return pattern; } } } // namespace cv