finalcut/test/ftermcap-test.cpp

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/***********************************************************************
* ftermcap-test.cpp - FTermcap unit tests *
* *
* This file is part of the FINAL CUT widget toolkit *
* *
* Copyright 2021 Markus Gans *
* *
* FINAL CUT is free software; you can redistribute it and/or modify *
* it under the terms of the GNU Lesser General Public License as *
* published by the Free Software Foundation; either version 3 of *
* the License, or (at your option) any later version. *
* *
* FINAL CUT is distributed in the hope that it will be useful, but *
* WITHOUT ANY WARRANTY; without even the implied warranty of *
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
* GNU Lesser General Public License for more details. *
* *
* You should have received a copy of the GNU Lesser General Public *
* License along with this program. If not, see *
* <http://www.gnu.org/licenses/>. *
***********************************************************************/
#include <cppunit/BriefTestProgressListener.h>
#include <cppunit/CompilerOutputter.h>
#include <cppunit/extensions/HelperMacros.h>
#include <cppunit/TestFixture.h>
#include <cppunit/TestResult.h>
#include <cppunit/TestResultCollector.h>
#include <cppunit/TestRunner.h>
#include <chrono>
#include <string>
#include <final/final.h>
// FTermcap string macro
#ifdef TCAP
#undef TCAP
#endif
#define TCAP(...) finalcut::FTermcap::strings[int(finalcut::Termcap::__VA_ARGS__)].string
using std::chrono::duration_cast;
using std::chrono::milliseconds;
using std::chrono::high_resolution_clock;
#define CPPUNIT_ASSERT_CSTRING(expected, actual) \
check_c_string (expected, actual, CPPUNIT_SOURCELINE())
//----------------------------------------------------------------------
void check_c_string ( const char* s1
, const char* s2
, CppUnit::SourceLine sourceLine )
{
if ( s1 == 0 && s2 == 0 ) // Strings are equal
return;
if ( s1 && s2 && std::strcmp (s1, s2) == 0 ) // Strings are equal
return;
::CppUnit::Asserter::fail ("Strings are not equal", sourceLine);
}
//----------------------------------------------------------------------
// class FTermcapTest
//----------------------------------------------------------------------
class FTermcapTest : public CPPUNIT_NS::TestFixture
{
public:
FTermcapTest()
{ }
protected:
void classNameTest();
void initTest();
void getFlagTest();
void getNumberTest();
void getStringTest();
void encodeMotionParameterTest();
void encodeParameterTest();
void paddingPrintTest();
private:
static int putchar_test(int);
static void clear();
// Adds code needed to register the test suite
CPPUNIT_TEST_SUITE (FTermcapTest);
// Add a methods to the test suite
CPPUNIT_TEST (classNameTest);
CPPUNIT_TEST (initTest);
CPPUNIT_TEST (getFlagTest);
CPPUNIT_TEST (getNumberTest);
CPPUNIT_TEST (getStringTest);
CPPUNIT_TEST (encodeMotionParameterTest);
CPPUNIT_TEST (encodeParameterTest);
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CPPUNIT_TEST (paddingPrintTest);
// End of test suite definition
CPPUNIT_TEST_SUITE_END();
// Data member
static std::string output;
};
// static class attribute
std::string FTermcapTest::output{};
//----------------------------------------------------------------------
void FTermcapTest::classNameTest()
{
finalcut::FTermcap tcap;
const finalcut::FString& classname = tcap.getClassName();
CPPUNIT_ASSERT ( classname == "FTermcap" );
}
//----------------------------------------------------------------------
void FTermcapTest::initTest()
{
// Without a terminal type
auto& fterm_data = finalcut::FTerm::getFTermData();
CPPUNIT_ASSERT ( fterm_data.getTermType().empty() );
finalcut::FTermcap tcap;
CPPUNIT_ASSERT ( ! tcap.isInitialized() );
tcap.init();
CPPUNIT_ASSERT ( tcap.isInitialized() );
CPPUNIT_ASSERT ( ! fterm_data.getTermType().empty() );
CPPUNIT_ASSERT ( fterm_data.getTermType() == "xterm" );
// With terminal type ansi
fterm_data.setTermType("ansi");
tcap.init();
CPPUNIT_ASSERT ( fterm_data.getTermType() == "ansi" );
// With a non-existent terminal type
fterm_data.setTermType("bang!");
tcap.init();
CPPUNIT_ASSERT ( fterm_data.getTermType() == "xterm" );
setenv ("TERM", "xterm-256color", 1); // 256 color terminal
auto& term_detection = finalcut::FTerm::getFTermDetection();
CPPUNIT_ASSERT ( ! term_detection.canDisplay256Colors() );
term_detection.detect();
CPPUNIT_ASSERT ( term_detection.canDisplay256Colors() );
fterm_data.setTermType("bang!");
tcap.init();
CPPUNIT_ASSERT ( fterm_data.getTermType() == "xterm-256color" );
fterm_data.setTermType("dumb");
tcap.init();
CPPUNIT_ASSERT ( fterm_data.getTermType() == "dumb" );
}
//----------------------------------------------------------------------
void FTermcapTest::getFlagTest()
{
auto& fterm_data = finalcut::FTerm::getFTermData();
fterm_data.setTermType("ansi");
finalcut::FTermcap tcap;
tcap.init();
CPPUNIT_ASSERT ( tcap.isInitialized() );
CPPUNIT_ASSERT ( fterm_data.getTermType() == "ansi" );
CPPUNIT_ASSERT ( tcap.getFlag("am") ); // Automatic right margin
CPPUNIT_ASSERT ( ! tcap.getFlag("cc") ); // Can change color palette
CPPUNIT_ASSERT ( ! tcap.getFlag("xo") ); // Xon/Xoff flow control
}
//----------------------------------------------------------------------
void FTermcapTest::getNumberTest()
{
auto& fterm_data = finalcut::FTerm::getFTermData();
fterm_data.setTermType("xterm");
finalcut::FTermcap tcap;
tcap.init();
CPPUNIT_ASSERT ( tcap.isInitialized() );
CPPUNIT_ASSERT ( fterm_data.getTermType() == "xterm" );
CPPUNIT_ASSERT ( tcap.getNumber("Co") == 8 ); // Colors
CPPUNIT_ASSERT ( tcap.getNumber("it") == 8 ); // Tab stop
CPPUNIT_ASSERT ( tcap.getNumber("NC") == 0 ); // Attr. without color
CPPUNIT_ASSERT ( tcap.getNumber("co") == 80 ); // Columns
CPPUNIT_ASSERT ( tcap.getNumber("li") == 24 ); // Lines
}
//----------------------------------------------------------------------
void FTermcapTest::getStringTest()
{
auto& fterm_data = finalcut::FTerm::getFTermData();
fterm_data.setTermType("ansi");
finalcut::FTermcap tcap;
tcap.init();
CPPUNIT_ASSERT ( tcap.isInitialized() );
CPPUNIT_ASSERT ( fterm_data.getTermType() == "ansi" );
CPPUNIT_ASSERT_CSTRING ( tcap.getString("me"), CSI "0m" ); // Exit attribute mode
CPPUNIT_ASSERT_CSTRING ( tcap.getString("mr"), CSI "7m" ); // Enter reverse mode
CPPUNIT_ASSERT_CSTRING ( tcap.getString("us"), CSI "4m" ); // Enter underline mode
CPPUNIT_ASSERT_CSTRING ( tcap.getString("cd"), CSI "J" ); // Clear to end of screen
CPPUNIT_ASSERT_CSTRING ( tcap.getString("ce"), CSI "K" ); // Clear to end of line
CPPUNIT_ASSERT_CSTRING ( tcap.getString("cl"), CSI "H" CSI "J" ); // Clear screen
}
//----------------------------------------------------------------------
void FTermcapTest::encodeMotionParameterTest()
{
auto& fterm_data = finalcut::FTerm::getFTermData();
fterm_data.setTermType("ansi");
finalcut::FTermcap tcap;
tcap.init();
CPPUNIT_ASSERT ( tcap.isInitialized() );
CPPUNIT_ASSERT ( fterm_data.getTermType() == "ansi" );
const auto& cursor_address = tcap.getString("cm");
CPPUNIT_ASSERT ( tcap.encodeMotionParameter(cursor_address, 10, 15) == CSI "16;11H" );
CPPUNIT_ASSERT ( tcap.encodeMotionParameter(cursor_address, 25, 1) == CSI "2;26H" );
CPPUNIT_ASSERT ( tcap.encodeMotionParameter(cursor_address, 0, 0) == CSI "1;1H" );
CPPUNIT_ASSERT ( tcap.encodeMotionParameter(cursor_address, 79, 23) == CSI "24;80H" );
}
//----------------------------------------------------------------------
void FTermcapTest::encodeParameterTest()
{
auto& fterm_data = finalcut::FTerm::getFTermData();
fterm_data.setTermType("ansi");
finalcut::FTermcap tcap;
tcap.init();
CPPUNIT_ASSERT ( tcap.isInitialized() );
CPPUNIT_ASSERT ( fterm_data.getTermType() == "ansi" );
const auto& parm_insert_line = tcap.getString("AL");
CPPUNIT_ASSERT ( tcap.encodeParameter(parm_insert_line, 7) == CSI "7L" );
const auto& parm_left_cursor = tcap.getString("LE");
CPPUNIT_ASSERT ( tcap.encodeParameter(parm_left_cursor, 3) == CSI "3D" );
const auto& parm_right_cursor = tcap.getString("RI");
CPPUNIT_ASSERT ( tcap.encodeParameter(parm_right_cursor, 4) == CSI "4C" );
const auto& parm_down_cursor = tcap.getString("DO");
CPPUNIT_ASSERT ( tcap.encodeParameter(parm_down_cursor, 12) == CSI "12B" );
const auto& parm_up_cursor = tcap.getString("UP");
CPPUNIT_ASSERT ( tcap.encodeParameter(parm_up_cursor, 5) == CSI "5A" );
const auto& parm_delete_line = tcap.getString("DL");
CPPUNIT_ASSERT ( tcap.encodeParameter(parm_delete_line, 9) == CSI "9M" );
}
//----------------------------------------------------------------------
void FTermcapTest::paddingPrintTest()
{
finalcut::FTermcap tcap;
setenv ("TERM", "xterm", 1); // xterm has no padding character
unsetenv("TERMCAP");
auto& fterm_data = finalcut::FTerm::getFTermData();
fterm_data.setTermType("xterm");
CPPUNIT_ASSERT ( ! tcap.xon_xoff_flow_control );
tcap.init();
CPPUNIT_ASSERT ( tcap.isInitialized() );
CPPUNIT_ASSERT ( tcap.no_padding_char );
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// With an empty string
CPPUNIT_ASSERT ( output.empty() );
auto status = tcap.paddingPrint ({}, 1, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::Error );
CPPUNIT_ASSERT ( output.empty() );
CPPUNIT_ASSERT ( output == "" );
// '$' without '<'
CPPUNIT_ASSERT ( output.empty() );
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status = tcap.paddingPrint ("12$34567", 1, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( ! output.empty() );
CPPUNIT_ASSERT ( output == "12$34567" );
// No closing '>'
output.clear();
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status = tcap.paddingPrint ("12$3$<4567", 1, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( ! output.empty() );
CPPUNIT_ASSERT ( output == "12$3$<4567" );
// Without a digit
output.clear();
status = tcap.paddingPrint ("12$3$<x>4567", 1, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( ! output.empty() );
CPPUNIT_ASSERT ( output == "12$3$<x>4567" );
// With 2 ms print delay
output.clear();
auto start = high_resolution_clock::now();
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status = tcap.paddingPrint ("1234$<2/>567", 1, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
auto end = high_resolution_clock::now();
auto duration_ms = int(duration_cast<milliseconds>(end - start).count());
CPPUNIT_ASSERT ( duration_ms >= 2 );
CPPUNIT_ASSERT ( ! output.empty() );
CPPUNIT_ASSERT ( output == "1234567" );
// With 20 ms print delay
output.clear();
start = high_resolution_clock::now();
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status = tcap.paddingPrint ("12$3$<45$<20/>67", 1, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
end = high_resolution_clock::now();
duration_ms = int(duration_cast<milliseconds>(end - start).count());
CPPUNIT_ASSERT ( duration_ms >= 20 );
CPPUNIT_ASSERT ( ! output.empty() );
CPPUNIT_ASSERT ( output == "12$3$<4567" );
// With a high a delay (9.999 seconds)
output.clear();
start = high_resolution_clock::now();
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status = tcap.paddingPrint ("1234$<9999/>567", 1, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
end = high_resolution_clock::now();
duration_ms = int(duration_cast<milliseconds>(end - start).count());
CPPUNIT_ASSERT ( duration_ms >= 9999 );
CPPUNIT_ASSERT ( ! output.empty() );
CPPUNIT_ASSERT ( output == "1234567" );
// With too high a delay (delay > 9999 ms = 9.999 sec)
output.clear();
start = high_resolution_clock::now();
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status = tcap.paddingPrint ("1234$<10000>567", 1, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
end = high_resolution_clock::now();
duration_ms = int(duration_cast<milliseconds>(end - start).count());
CPPUNIT_ASSERT ( duration_ms < 20 );
CPPUNIT_ASSERT ( ! output.empty() );
CPPUNIT_ASSERT ( output == "1234$<10000>567" );
// Beep has delayed output and flush
output.clear();
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status = tcap.paddingPrint (TCAP(t_bell), 1, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( ! output.empty() );
CPPUNIT_ASSERT ( output == std::string(TCAP(t_bell)) );
// Flash screen has delayed output and flush
output.clear();
start = high_resolution_clock::now();
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status = tcap.paddingPrint ("\033[?5h$<100/>\033[?5l", 1, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
end = high_resolution_clock::now();
duration_ms = int(duration_cast<milliseconds>(end - start).count());
CPPUNIT_ASSERT ( duration_ms >= 100 );
CPPUNIT_ASSERT ( ! output.empty() );
CPPUNIT_ASSERT ( output == std::string("\033[?5h\033[?5l") );
// With 5 ms prints 21 padding chars ('\0')
setenv ("TERM", "ansi", 1); // ansi terminals used for delay padding character
fterm_data.setTermType("ansi");
tcap.init();
CPPUNIT_ASSERT ( ! tcap.no_padding_char );
CPPUNIT_ASSERT ( ! tcap.xon_xoff_flow_control );
output.clear();
tcap.setBaudrate (38400);
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status = tcap.paddingPrint ("1234$<5*/>567", 1, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
const auto& str1_with_0 = "1234" "\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0" "567";
std::string target_output(std::begin(str1_with_0), std::end(str1_with_0) - 1);
CPPUNIT_ASSERT ( ! output.empty() );
CPPUNIT_ASSERT ( output.length() == 28 );
CPPUNIT_ASSERT ( output == target_output );
// Wait 2 ms with padding characters and with 1 affected line
output.clear();
tcap.setBaudrate (9600);
tcap.padding_baudrate = 0; // no padding baudrate
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status = tcap.paddingPrint ("abc$<2*>def", 1, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 6 );
CPPUNIT_ASSERT ( output == "abcdef" );
output.clear();
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status = tcap.paddingPrint ("abc$<2*/>def", 1, FTermcapTest::putchar_test); // with "*/"
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
const auto& str2_with_0 = "abc" "\0\0" "def";
target_output = std::string(std::begin(str2_with_0), std::end(str2_with_0) - 1);
CPPUNIT_ASSERT ( output.length() == 8 );
CPPUNIT_ASSERT ( output == target_output );
output.clear();
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status = tcap.paddingPrint ("abc$<2/*>def", 1, FTermcapTest::putchar_test); // with "/*"
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 8 );
CPPUNIT_ASSERT ( output == target_output );
output.clear();
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status = tcap.paddingPrint ("abc$<2/x*>def", 1, FTermcapTest::putchar_test); // defekt
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 13 );
CPPUNIT_ASSERT ( output == "abc$<2/x*>def" );
output.clear();
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status = tcap.paddingPrint ("abc$<2/*x>def", 1, FTermcapTest::putchar_test); // defekt
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 13 );
CPPUNIT_ASSERT ( output == "abc$<2/*x>def" );
output.clear();
tcap.padding_baudrate = 19200; // baudrate < padding baudrate
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status = tcap.paddingPrint ("abc$<2*>def", 1, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 6 );
CPPUNIT_ASSERT ( output == "abcdef" );
output.clear();
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status = tcap.paddingPrint ("abc$<2*/>def", 1, FTermcapTest::putchar_test); // with "*/"
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 8 );
CPPUNIT_ASSERT ( output == target_output );
output.clear();
tcap.padding_baudrate = 9600; // baudrate >= padding baudrate
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status = tcap.paddingPrint ("abc$<2*>def", 1, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 8 );
CPPUNIT_ASSERT ( output == target_output );
// Wait 2 ms with padding characters and with 2 affected line
output.clear();
tcap.padding_baudrate = 0; // no padding baudrate
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status = tcap.paddingPrint ("abc$<2*>>def", 2, FTermcapTest::putchar_test); // double >>
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 7 );
CPPUNIT_ASSERT ( output == "abc>def" );
output.clear();
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status = tcap.paddingPrint ("abc$<2*/>def", 2, FTermcapTest::putchar_test); // with "*/"
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
const auto& str3_with_0 = "abc" "\0\0\0\0" "def";
target_output = std::string(std::begin(str3_with_0), std::end(str3_with_0) - 1);
CPPUNIT_ASSERT ( output.length() == 10 );
CPPUNIT_ASSERT ( output == target_output );
output.clear();
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status = tcap.paddingPrint ("abc$<2/*>def", 2, FTermcapTest::putchar_test); // with "/*"
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 10 );
CPPUNIT_ASSERT ( output == target_output );
output.clear();
tcap.padding_baudrate = 19200; // baudrate < padding baudrate
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status = tcap.paddingPrint ("abc$<2*>def", 2, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 6 );
CPPUNIT_ASSERT ( output == "abcdef" );
output.clear();
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status = tcap.paddingPrint ("abc$<2*/>def", 2, FTermcapTest::putchar_test); // with "*/"
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 10 );
CPPUNIT_ASSERT ( output == target_output );
output.clear();
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status = tcap.paddingPrint ("abc$<2/*>def", 2, FTermcapTest::putchar_test); // with "/*"
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 10 );
CPPUNIT_ASSERT ( output == target_output );
output.clear();
tcap.padding_baudrate = 9600; // baudrate >= padding baudrate
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status = tcap.paddingPrint ("abc$<2*>def", 2, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 10 );
CPPUNIT_ASSERT ( output == target_output );
// Wait 2 ms with padding characters and with 3 affected line
output.clear();
tcap.padding_baudrate = 0; // no padding baudrate
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status = tcap.paddingPrint ("abc$<2*>def", 3, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output == "abcdef" );
output.clear();
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status = tcap.paddingPrint ("abc$<2*/>def", 3, FTermcapTest::putchar_test); // with "*/"
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
const auto& str4_with_0 = "abc" "\0\0\0\0\0\0" "def";
target_output = std::string(std::begin(str4_with_0), std::end(str4_with_0) - 1);
CPPUNIT_ASSERT ( output.length() == 12 );
CPPUNIT_ASSERT ( output == target_output );
output.clear();
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status = tcap.paddingPrint ("abc$<2/*>def", 3, FTermcapTest::putchar_test); // with "/*"
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 12 );
CPPUNIT_ASSERT ( output == target_output );
output.clear();
tcap.padding_baudrate = 19200; // baudrate < padding baudrate
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status = tcap.paddingPrint ("abc$<2*>def", 3, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 6 );
CPPUNIT_ASSERT ( output == "abcdef" );
output.clear();
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status = tcap.paddingPrint ("abc$<2*/>def", 3, FTermcapTest::putchar_test); // with "*/"
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 12 );
CPPUNIT_ASSERT ( output == target_output );
output.clear();
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status = tcap.paddingPrint ("abc$<2/*>def", 3, FTermcapTest::putchar_test); // with "/*"
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 12 );
CPPUNIT_ASSERT ( output == target_output );
output.clear();
tcap.padding_baudrate = 9600; // baudrate >= padding baudrate
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status = tcap.paddingPrint ("abc$<2*>def", 3, FTermcapTest::putchar_test);
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 12 );
CPPUNIT_ASSERT ( output == target_output );
// With decimal point
output.clear();
tcap.setBaudrate(19200);
tcap.padding_baudrate = 19200; // baudrate == padding baudrate
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status = tcap.paddingPrint ("abc$<2.>def", 1, FTermcapTest::putchar_test); // 2.
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
const auto& str5_with_0 = "abc" "\0\0\0\0" "def";
target_output = std::string(std::begin(str5_with_0), std::end(str5_with_0) - 1);
CPPUNIT_ASSERT ( output.length() == 10 );
CPPUNIT_ASSERT ( output == target_output );
output.clear();
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status = tcap.paddingPrint ("abc$<2.0>def", 1, FTermcapTest::putchar_test); // 2.0
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 10 );
CPPUNIT_ASSERT ( output == target_output );
output.clear();
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status = tcap.paddingPrint ("abc$<2.7>def", 1, FTermcapTest::putchar_test); // 2.7
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 10 );
CPPUNIT_ASSERT ( output == target_output );
output.clear();
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status = tcap.paddingPrint ("abc$<2.77>def", 1, FTermcapTest::putchar_test); // 2.77
CPPUNIT_ASSERT ( status == finalcut::FTermcap::Status::OK );
CPPUNIT_ASSERT ( output.length() == 10 );
CPPUNIT_ASSERT ( output == target_output );
}
//----------------------------------------------------------------------
int FTermcapTest::putchar_test (int ch)
{
//std::cout << std::hex << "0x" << ch << "," << std::flush;
output.push_back(char(ch));
return ch;
}
//----------------------------------------------------------------------
void FTermcapTest::clear()
{
output.clear();
}
//----------------------------------------------------------------------
// Put the test suite in the registry
CPPUNIT_TEST_SUITE_REGISTRATION (FTermcapTest);
// The general unit test main part
#include <main-test.inc>