// (C) Copyright 2017, Google Inc. // 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. #include #include #include "include_gunit.h" #include "log.h" // for LOG #include "serialis.h" #include "tprintf.h" #include "unicharcompress.h" namespace tesseract { class UnicharcompressTest : public ::testing::Test { protected: void SetUp() override { std::locale::global(std::locale("")); file::MakeTmpdir(); } // Loads and compresses the given unicharset. void LoadUnicharset(const std::string &unicharset_name) { std::string radical_stroke_file = file::JoinPath(LANGDATA_DIR, "radical-stroke.txt"); std::string unicharset_file = file::JoinPath(TESTDATA_DIR, unicharset_name); std::string radical_data; CHECK_OK(file::GetContents(radical_stroke_file, &radical_data, file::Defaults())); CHECK(unicharset_.load_from_file(unicharset_file.c_str())); std::string radical_str(radical_data.c_str()); null_char_ = unicharset_.has_special_codes() ? UNICHAR_BROKEN : unicharset_.size(); compressed_.ComputeEncoding(unicharset_, null_char_, &radical_str); // Get the encoding of the null char. RecodedCharID code; compressed_.EncodeUnichar(null_char_, &code); encoded_null_char_ = code(0); std::string output_name = file::JoinPath(FLAGS_test_tmpdir, unicharset_name) + ".encoding.txt"; std::string encoding = compressed_.GetEncodingAsString(unicharset_); std::string encoding_str(&encoding[0], encoding.size()); CHECK_OK(file::SetContents(output_name, encoding_str, file::Defaults())); LOG(INFO) << "Wrote encoding to:" << output_name; } // Serializes and de-serializes compressed_ over itself. void SerializeAndUndo() { std::vector data; TFile wfp; wfp.OpenWrite(&data); EXPECT_TRUE(compressed_.Serialize(&wfp)); TFile rfp; rfp.Open(&data[0], data.size()); EXPECT_TRUE(compressed_.DeSerialize(&rfp)); } // Returns true if the lang is in CJK. bool IsCJKLang(const std::string &lang) { return lang == "chi_sim" || lang == "chi_tra" || lang == "kor" || lang == "jpn"; } // Returns true if the lang is Indic. bool IsIndicLang(const std::string &lang) { return lang == "asm" || lang == "ben" || lang == "bih" || lang == "hin" || lang == "mar" || lang == "nep" || lang == "san" || lang == "bod" || lang == "dzo" || lang == "guj" || lang == "kan" || lang == "mal" || lang == "ori" || lang == "pan" || lang == "sin" || lang == "tam" || lang == "tel"; } // Expects the appropriate results from the compressed_ unicharset_. void ExpectCorrect(const std::string &lang) { // Count the number of times each code is used in each element of // RecodedCharID. RecodedCharID zeros; for (int i = 0; i < RecodedCharID::kMaxCodeLen; ++i) { zeros.Set(i, 0); } int code_range = compressed_.code_range(); std::vector times_seen(code_range, zeros); for (int u = 0; u <= unicharset_.size(); ++u) { if (u != UNICHAR_SPACE && u != null_char_ && (u == unicharset_.size() || (unicharset_.has_special_codes() && u < SPECIAL_UNICHAR_CODES_COUNT))) { continue; // Not used so not encoded. } RecodedCharID code; int len = compressed_.EncodeUnichar(u, &code); // Check round-trip encoding. int unichar_id; std::vector normed_ids; if (u == null_char_ || u == unicharset_.size()) { unichar_id = null_char_; } else { unichar_id = u; } EXPECT_EQ(unichar_id, compressed_.DecodeUnichar(code)); // Check that the codes are valid. for (int i = 0; i < len; ++i) { int code_val = code(i); EXPECT_GE(code_val, 0); EXPECT_LT(code_val, code_range); times_seen[code_val].Set(i, times_seen[code_val](i) + 1); } } // Check that each code is used in at least one position. for (int c = 0; c < code_range; ++c) { int num_used = 0; for (int i = 0; i < RecodedCharID::kMaxCodeLen; ++i) { if (times_seen[c](i) != 0) { ++num_used; } } EXPECT_GE(num_used, 1) << "c=" << c << "/" << code_range; } // Check that GetNextCodes/GetFinalCodes lists match the times_seen, // and create valid codes. RecodedCharID code; CheckCodeExtensions(code, times_seen); // Finally, we achieved all that using a codebook < 10% of the size of // the original unicharset, for CK or Indic, and 20% with J, but just // no bigger for all others. if (IsCJKLang(lang) || IsIndicLang(lang)) { EXPECT_LT(code_range, unicharset_.size() / (lang == "jpn" ? 5 : 10)); } else { EXPECT_LE(code_range, unicharset_.size() + 1); } LOG(INFO) << "Compressed unicharset of " << unicharset_.size() << " to " << code_range; } // Checks for extensions of the current code that either finish a code, or // extend it and checks those extensions recursively. void CheckCodeExtensions(const RecodedCharID &code, const std::vector ×_seen) { RecodedCharID extended = code; int length = code.length(); const std::vector *final_codes = compressed_.GetFinalCodes(code); if (final_codes != nullptr) { for (int ending : *final_codes) { EXPECT_GT(times_seen[ending](length), 0); extended.Set(length, ending); int unichar_id = compressed_.DecodeUnichar(extended); EXPECT_NE(INVALID_UNICHAR_ID, unichar_id); } } const std::vector *next_codes = compressed_.GetNextCodes(code); if (next_codes != nullptr) { for (int extension : *next_codes) { EXPECT_GT(times_seen[extension](length), 0); extended.Set(length, extension); CheckCodeExtensions(extended, times_seen); } } } UnicharCompress compressed_; UNICHARSET unicharset_; int null_char_; // The encoding of the null_char_. int encoded_null_char_; }; TEST_F(UnicharcompressTest, DoesChinese) { LOG(INFO) << "Testing chi_tra"; LoadUnicharset("chi_tra.unicharset"); ExpectCorrect("chi_tra"); LOG(INFO) << "Testing chi_sim"; LoadUnicharset("chi_sim.unicharset"); ExpectCorrect("chi_sim"); } TEST_F(UnicharcompressTest, DoesJapanese) { LOG(INFO) << "Testing jpn"; LoadUnicharset("jpn.unicharset"); ExpectCorrect("jpn"); } TEST_F(UnicharcompressTest, DoesKorean) { LOG(INFO) << "Testing kor"; LoadUnicharset("kor.unicharset"); ExpectCorrect("kor"); } TEST_F(UnicharcompressTest, DoesKannada) { LOG(INFO) << "Testing kan"; LoadUnicharset("kan.unicharset"); ExpectCorrect("kan"); SerializeAndUndo(); ExpectCorrect("kan"); } TEST_F(UnicharcompressTest, DoesMarathi) { LOG(INFO) << "Testing mar"; LoadUnicharset("mar.unicharset"); ExpectCorrect("mar"); } TEST_F(UnicharcompressTest, DoesEnglish) { LOG(INFO) << "Testing eng"; LoadUnicharset("eng.unicharset"); ExpectCorrect("eng"); } // Tests that a unicharset that contains double-letter ligatures (eg ff) has // no null char in the encoding at all. TEST_F(UnicharcompressTest, DoesLigaturesWithDoubles) { LOG(INFO) << "Testing por with ligatures"; LoadUnicharset("por.unicharset"); ExpectCorrect("por"); // Check that any unichar-id that is encoded with multiple codes has the // correct encoded_nulll_char_ in between. for (int u = 0; u <= unicharset_.size(); ++u) { RecodedCharID code; int len = compressed_.EncodeUnichar(u, &code); if (len > 1) { // The should not be any null char in the code. for (int i = 0; i < len; ++i) { EXPECT_NE(encoded_null_char_, code(i)); } } } } // Tests that GetEncodingAsString returns the right result for a trivial // unicharset. TEST_F(UnicharcompressTest, GetEncodingAsString) { LoadUnicharset("trivial.unicharset"); ExpectCorrect("trivial"); std::string encoding = compressed_.GetEncodingAsString(unicharset_); std::string encoding_str(&encoding[0], encoding.length()); std::vector lines = split(encoding_str, '\n'); EXPECT_EQ(5, lines.size()); // The first line is always space. EXPECT_EQ("0\t ", lines[0]); // Next we have i. EXPECT_EQ("1\ti", lines[1]); // Next we have f. EXPECT_EQ("2\tf", lines[2]); // Next we have the fi ligature: fi. There are no nulls in it, as there are no // repeated letter ligatures in this unicharset, unlike por.unicharset above. EXPECT_EQ("2,1\tfi", lines[3]); // Finally the null character. EXPECT_EQ("3\t", lines[4]); } } // namespace tesseract