/*********************************************************************** * foptimove.cpp - Cursor movement optimization * * * * This file is part of the Final Cut widget toolkit * * * * Copyright 2015-2019 Markus Gans * * * * The 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. * * * * The 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 * * . * ***********************************************************************/ #include #include "final/fc.h" #include "final/foptimove.h" namespace finalcut { //---------------------------------------------------------------------- // class FOptiMove //---------------------------------------------------------------------- // constructors and destructor //---------------------------------------------------------------------- FOptiMove::FOptiMove (int baud) : baudrate(baud) { assert ( baud >= 0 ); calculateCharDuration(); // ANSI set cursor address preset for undefined terminals set_cursor_address (C_STR(CSI "%i%p1%d;%p2%dH")); // Set carriage return preset set_carriage_return (C_STR("\r")); // Set cursor down preset set_cursor_down (C_STR("\n")); } //---------------------------------------------------------------------- FOptiMove::~FOptiMove() // destructor { } // public methods of FOptiMove //---------------------------------------------------------------------- void FOptiMove::setBaudRate (int baud) { assert ( baud >= 0 ); baudrate = baud; calculateCharDuration(); } //---------------------------------------------------------------------- void FOptiMove::setTabStop (int t) { assert ( t > 0 ); tabstop = t; } //---------------------------------------------------------------------- void FOptiMove::setTermSize (std::size_t w, std::size_t h) { assert ( w > 0 ); assert ( h > 0 ); screen_width = w; screen_height = h; } //---------------------------------------------------------------------- void FOptiMove::setTermEnvironment (termEnv& term_env) { // Set all required termcap values at once set_cursor_home (term_env.t_cursor_home); set_cursor_to_ll (term_env.t_cursor_to_ll); set_carriage_return (term_env.t_carriage_return); set_tabular (term_env.t_tab); set_back_tab (term_env.t_back_tab); set_cursor_up (term_env.t_cursor_up); set_cursor_down (term_env.t_cursor_down); set_cursor_left (term_env.t_cursor_left); set_cursor_right (term_env.t_cursor_right); set_cursor_address (term_env.t_cursor_address); set_column_address (term_env.t_column_address); set_row_address (term_env.t_row_address); set_parm_up_cursor (term_env.t_parm_up_cursor); set_parm_down_cursor (term_env.t_parm_down_cursor); set_parm_left_cursor (term_env.t_parm_left_cursor); set_parm_right_cursor (term_env.t_parm_right_cursor); set_erase_chars (term_env.t_erase_chars); set_repeat_char (term_env.t_repeat_char); set_clr_bol (term_env.t_clr_bol); set_clr_eol (term_env.t_clr_eol); setTabStop (term_env.tabstop); set_auto_left_margin (term_env.automatic_left_margin); set_eat_newline_glitch (term_env.eat_nl_glitch); } //---------------------------------------------------------------------- void FOptiMove::set_cursor_home (char cap[]) { if ( cap ) { F_cursor_home.cap = cap; F_cursor_home.duration = capDuration (cap, 0); F_cursor_home.length = capDurationToLength (F_cursor_home.duration); } else { F_cursor_home.cap = nullptr; F_cursor_home.duration = \ F_cursor_home.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_cursor_to_ll (char cap[]) { if ( cap ) { F_cursor_to_ll.cap = cap; F_cursor_to_ll.duration = capDuration (cap, 0); F_cursor_to_ll.length = capDurationToLength (F_cursor_to_ll.duration); } else { F_cursor_to_ll.cap = nullptr; F_cursor_to_ll.duration = \ F_cursor_to_ll.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_carriage_return (char cap[]) { if ( cap ) { F_carriage_return.cap = cap; F_carriage_return.duration = capDuration (cap, 0); F_carriage_return.length = capDurationToLength (F_carriage_return.duration); } else { F_carriage_return.cap = nullptr; F_carriage_return.duration = \ F_carriage_return.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_tabular (char cap[]) { if ( cap ) { F_tab.cap = cap; F_tab.duration = capDuration (cap, 0); F_tab.length = capDurationToLength (F_tab.duration); } else { F_tab.cap = nullptr; F_tab.duration = \ F_tab.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_back_tab (char cap[]) { if ( cap ) { F_back_tab.cap = cap; F_back_tab.duration = capDuration (cap, 0); F_back_tab.length = capDurationToLength (F_back_tab.duration); } else { F_back_tab.cap = nullptr; F_back_tab.duration = \ F_back_tab.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_cursor_up (char cap[]) { if ( cap ) { F_cursor_up.cap = cap; F_cursor_up.duration = capDuration (cap, 0); F_cursor_up.length = capDurationToLength (F_cursor_up.duration); } else { F_cursor_up.cap = nullptr; F_cursor_up.duration = \ F_cursor_up.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_cursor_down (char cap[]) { if ( cap ) { F_cursor_down.cap = cap; F_cursor_down.duration = capDuration (cap, 0); F_cursor_down.length = capDurationToLength (F_cursor_down.duration); } else { F_cursor_down.cap = nullptr; F_cursor_down.duration = \ F_cursor_down.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_cursor_left (char cap[]) { if ( cap ) { F_cursor_left.cap = cap; F_cursor_left.duration = capDuration (cap, 0); F_cursor_left.length = capDurationToLength (F_cursor_left.duration); } else { F_cursor_left.cap = nullptr; F_cursor_left.duration = \ F_cursor_left.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_cursor_right (char cap[]) { if ( cap ) { F_cursor_right.cap = cap; F_cursor_right.duration = capDuration (cap, 0); F_cursor_right.length = capDurationToLength (F_cursor_right.duration); } else { F_cursor_right.cap = nullptr; F_cursor_right.duration = \ F_cursor_right.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_cursor_address (char cap[]) { if ( cap ) { char* temp = tgoto(cap, 23, 23); F_cursor_address.cap = cap; F_cursor_address.duration = capDuration (temp, 1); F_cursor_address.length = capDurationToLength (F_cursor_address.duration); } else { F_cursor_address.cap = nullptr; F_cursor_address.duration = \ F_cursor_address.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_column_address (char cap[]) { if ( cap ) { char* temp = tparm(cap, 23, 0, 0, 0, 0, 0, 0, 0, 0); F_column_address.cap = cap; F_column_address.duration = capDuration (temp, 1); F_column_address.length = capDurationToLength (F_column_address.duration); } else { F_column_address.cap = nullptr; F_column_address.duration = \ F_column_address.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_row_address (char cap[]) { if ( cap ) { char* temp = tparm(cap, 23, 0, 0, 0, 0, 0, 0, 0, 0); F_row_address.cap = cap; F_row_address.duration = capDuration (temp, 1); F_row_address.length = capDurationToLength (F_row_address.duration); } else { F_row_address.cap = nullptr; F_row_address.duration = \ F_row_address.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_parm_up_cursor (char cap[]) { if ( cap ) { char* temp = tparm(cap, 23, 0, 0, 0, 0, 0, 0, 0, 0); F_parm_up_cursor.cap = cap; F_parm_up_cursor.duration = capDuration (temp, 1); F_parm_up_cursor.length = capDurationToLength (F_parm_up_cursor.duration); } else { F_parm_up_cursor.cap = nullptr; F_parm_up_cursor.duration = \ F_parm_up_cursor.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_parm_down_cursor (char cap[]) { if ( cap ) { char* temp = tparm(cap, 23, 0, 0, 0, 0, 0, 0, 0, 0); F_parm_down_cursor.cap = cap; F_parm_down_cursor.duration = capDuration (temp, 1); F_parm_down_cursor.length = capDurationToLength (F_parm_down_cursor.duration); } else { F_parm_down_cursor.cap = nullptr; F_parm_down_cursor.duration = \ F_parm_down_cursor.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_parm_left_cursor (char cap[]) { if ( cap ) { char* temp = tparm(cap, 23, 0, 0, 0, 0, 0, 0, 0, 0); F_parm_left_cursor.cap = cap; F_parm_left_cursor.duration = capDuration (temp, 1); F_parm_left_cursor.length = capDurationToLength (F_parm_left_cursor.duration); } else { F_parm_left_cursor.cap = nullptr; F_parm_left_cursor.duration = \ F_parm_left_cursor.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_parm_right_cursor (char cap[]) { if ( cap ) { char* temp = tparm(cap, 23, 0, 0, 0, 0, 0, 0, 0, 0); F_parm_right_cursor.cap = cap; F_parm_right_cursor.duration = capDuration (temp, 1); F_parm_right_cursor.length = capDurationToLength (F_parm_right_cursor.duration); } else { F_parm_right_cursor.cap = nullptr; F_parm_right_cursor.duration = \ F_parm_right_cursor.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_erase_chars (char cap[]) { if ( cap ) { char* temp = tparm(cap, 23, 0, 0, 0, 0, 0, 0, 0, 0); F_erase_chars.cap = cap; F_erase_chars.duration = capDuration (temp, 1); F_erase_chars.length = capDurationToLength (F_erase_chars.duration); } else { F_erase_chars.cap = nullptr; F_erase_chars.duration = \ F_erase_chars.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_repeat_char (char cap[]) { if ( cap ) { char* temp = tparm(cap, ' ', 23, 0, 0, 0, 0, 0, 0, 0); F_repeat_char.cap = cap; F_repeat_char.duration = capDuration (temp, 1); F_repeat_char.length = capDurationToLength (F_repeat_char.duration); } else { F_repeat_char.cap = nullptr; F_repeat_char.duration = \ F_repeat_char.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_clr_bol (char cap[]) { if ( cap ) { F_clr_bol.cap = cap; F_clr_bol.duration = capDuration (cap, 0); F_clr_bol.length = capDurationToLength (F_clr_bol.duration); } else { F_clr_bol.cap = nullptr; F_clr_bol.duration = \ F_clr_bol.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::set_clr_eol (char cap[]) { if ( cap ) { F_clr_eol.cap = cap; F_clr_eol.duration = capDuration (cap, 0); F_clr_eol.length = capDurationToLength (F_clr_eol.duration); } else { F_clr_eol.cap = nullptr; F_clr_eol.duration = \ F_clr_eol.length = LONG_DURATION; } } //---------------------------------------------------------------------- void FOptiMove::check_boundaries ( int& xold, int& yold , int& xnew, int& ynew ) { if ( xold < 0 || xold >= int(screen_width) ) xold = -1; if ( yold < 0 || yold >= int(screen_height) ) yold = -1; if ( xnew < 0 ) xnew = 0; if ( ynew < 0 ) ynew = 0; if ( xnew >= int(screen_width) ) xnew = int(screen_width) - 1; if ( ynew >= int(screen_height) ) ynew = int(screen_height) - 1; } //---------------------------------------------------------------------- char* FOptiMove::moveCursor (int xold, int yold, int xnew, int ynew) { int method{0}; int move_time{LONG_DURATION}; check_boundaries (xold, yold, xnew, ynew); // Method 0: direct cursor addressing if ( isMethod0Faster(move_time, xnew, ynew) ) { if ( xold < 0 || yold < 0 || isWideMove (xold, yold, xnew, ynew) ) { return ( move_time < LONG_DURATION ) ? move_buf : 0; } } // Method 1: local movement if ( isMethod1Faster(move_time, xold, yold, xnew, ynew) ) method = 1; // Method 2: carriage-return + local movement if ( isMethod2Faster(move_time, yold, xnew, ynew) ) method = 2; // Method 3: home-cursor + local movement if ( isMethod3Faster(move_time, xnew, ynew) ) method = 3; // Method 4: home-down + local movement if ( isMethod4Faster(move_time, xnew, ynew) ) method = 4; // Method 5: left margin for wrap to right-hand side if ( isMethod5Faster(move_time, yold, xnew, ynew) ) method = 5; // Copy the escape sequence for the chosen method in move_buf moveByMethod (method, xold, yold, xnew, ynew); if ( move_time < LONG_DURATION ) return move_buf; else return 0; } // private methods of FApplication //---------------------------------------------------------------------- void FOptiMove::calculateCharDuration() { if ( baudrate != 0 ) { static constexpr int baudbyte = 9; // = 7 bit + 1 parity + 1 stop char_duration = (baudbyte * 1000 * 10) / (baudrate > 0 ? baudrate : 9600); // milliseconds if ( char_duration <= 0 ) char_duration = 1; } else char_duration = 1; } //---------------------------------------------------------------------- int FOptiMove::capDuration (char cap[], int affcnt) { // calculate the duration in milliseconds of a given operation // cap - the term capability // affcnt - the number of lines affected if ( ! cap ) return LONG_DURATION; float ms{0}; for (const char* p = cap; *p; p++) { // check for delay with padding character if ( p[0] == '$' && p[1] == '<' && std::strchr(p, '>') ) { float num = 0; for (p += 2; *p != '>'; p++) { if ( std::isdigit(uChar(*p)) ) num = num * 10 + float(*p - '0'); else if ( *p == '*' ) num *= float(affcnt); else if ( *p == '.' && *++p != '>' && std::isdigit(uChar(*p)) ) num += float((*p - '0') / 10.0); } ms += num * 10; } else ms += float(char_duration); } return int(ms); } //---------------------------------------------------------------------- int FOptiMove::capDurationToLength (int duration) { if ( duration != LONG_DURATION ) return (duration + char_duration - 1) / char_duration; else return LONG_DURATION; } //---------------------------------------------------------------------- int FOptiMove::repeatedAppend ( const capability& o , volatile int count , char* dst ) { std::size_t src_len = std::strlen(o.cap); std::size_t dst_len = ( dst != nullptr ) ? std::strlen(dst) : 0; int total{0}; if ( (dst_len + uInt(count) * src_len) < BUF_SIZE - 1 ) { total += count * o.duration; if ( dst ) { dst += dst_len; std::size_t free = BUF_SIZE - dst_len - 2; while ( count-- > 0 ) { std::strncpy (dst, o.cap, free); dst += src_len; free -= src_len; } } } else total = LONG_DURATION; return total; } //---------------------------------------------------------------------- int FOptiMove::relativeMove ( char move[] , int from_x, int from_y , int to_x, int to_y ) { int vtime{0}; int htime{0}; if ( move ) move[0] = '\0'; if ( to_y != from_y ) // vertical move { vtime = verticalMove (move, from_y, to_y); if ( vtime >= LONG_DURATION ) return LONG_DURATION; } if ( to_x != from_x ) // horizontal move { char hmove[BUF_SIZE]{}; htime = horizontalMove (hmove, from_x, to_x); if ( htime >= LONG_DURATION ) return LONG_DURATION; if ( move ) { if ( *move ) std::strncat (move, hmove, BUF_SIZE - std::strlen(move)); else std::strncpy (move, hmove, BUF_SIZE); move[BUF_SIZE - 1] = '\0'; } } return vtime + htime; } //---------------------------------------------------------------------- inline int FOptiMove::verticalMove (char move[], int from_y, int to_y) { int vtime{LONG_DURATION}; if ( F_row_address.cap ) { if ( move ) { std::strncpy ( move , tparm(F_row_address.cap, to_y, 0, 0, 0, 0, 0, 0, 0, 0) , BUF_SIZE ); move[BUF_SIZE - 1] = '\0'; } vtime = F_row_address.duration; } if ( to_y > from_y ) downMove (move, vtime, from_y, to_y); else // to_y < from_y upMove (move, vtime, from_y, to_y); return vtime; } //---------------------------------------------------------------------- inline void FOptiMove::downMove ( char move[], int& vtime , int from_y, int to_y ) { int num = to_y - from_y; if ( F_parm_down_cursor.cap && F_parm_down_cursor.duration < vtime ) { if ( move ) { std::strncpy ( move , tparm(F_parm_down_cursor.cap, num, 0, 0, 0, 0, 0, 0, 0, 0) , BUF_SIZE ); move[BUF_SIZE - 1] = '\0'; } vtime = F_parm_down_cursor.duration; } if ( F_cursor_down.cap && (num * F_cursor_down.duration < vtime) ) { if ( move ) move[0] = '\0'; vtime = repeatedAppend (F_cursor_down, num, move); } } //---------------------------------------------------------------------- inline void FOptiMove::upMove ( char move[], int& vtime , int from_y, int to_y ) { int num = from_y - to_y; if ( F_parm_up_cursor.cap && F_parm_up_cursor.duration < vtime ) { if ( move ) { std::strncpy ( move , tparm(F_parm_up_cursor.cap, num, 0, 0, 0, 0, 0, 0, 0, 0) , BUF_SIZE ); move[BUF_SIZE - 1] = '\0'; } vtime = F_parm_up_cursor.duration; } if ( F_cursor_up.cap && (num * F_cursor_up.duration < vtime) ) { if ( move ) move[0] = '\0'; vtime = repeatedAppend (F_cursor_up, num, move); } } //---------------------------------------------------------------------- inline int FOptiMove::horizontalMove (char hmove[], int from_x, int to_x) { int htime{LONG_DURATION}; if ( F_column_address.cap ) { // Move to fixed column position1 std::strncat ( hmove , tparm(F_column_address.cap, to_x, 0, 0, 0, 0, 0, 0, 0, 0) , BUF_SIZE - std::strlen(hmove) - 1 ); hmove[BUF_SIZE - 1] = '\0'; htime = F_column_address.duration; } if ( to_x > from_x ) rightMove (hmove, htime, from_x, to_x); else // to_x < from_x leftMove (hmove, htime, from_x, to_x); return htime; } //---------------------------------------------------------------------- inline void FOptiMove::rightMove ( char hmove[], int& htime , int from_x, int to_x ) { int num = to_x - from_x; if ( F_parm_right_cursor.cap && F_parm_right_cursor.duration < htime ) { std::strncpy ( hmove , tparm(F_parm_right_cursor.cap, num, 0, 0, 0, 0, 0, 0, 0, 0) , BUF_SIZE - 1); hmove[BUF_SIZE - 1] = '\0'; htime = F_parm_right_cursor.duration; } if ( F_cursor_right.cap ) { char str[BUF_SIZE]{}; int htime_r{0}; str[0] = '\0'; // try to use tab if ( tabstop > 0 && F_tab.cap ) { int pos = from_x; while ( true ) { int tab_pos = pos + tabstop - (pos % tabstop); if ( tab_pos > to_x ) break; htime_r += repeatedAppend (F_tab, 1, str); if ( htime_r >= LONG_DURATION ) break; pos = tab_pos; } num = to_x - pos; } htime_r += repeatedAppend (F_cursor_right, num, str); if ( htime_r < htime ) { std::strncpy (hmove, str, BUF_SIZE); hmove[BUF_SIZE - 1] = '\0'; htime = htime_r; } } } //---------------------------------------------------------------------- inline void FOptiMove::leftMove ( char hmove[], int& htime , int from_x, int to_x ) { int num = from_x - to_x; if ( F_parm_left_cursor.cap && F_parm_left_cursor.duration < htime ) { std::strncpy ( hmove , tparm(F_parm_left_cursor.cap, num, 0, 0, 0, 0, 0, 0, 0, 0) , BUF_SIZE - 1); hmove[BUF_SIZE - 1] = '\0'; htime = F_parm_left_cursor.duration; } if ( F_cursor_left.cap ) { char str[BUF_SIZE]{}; int htime_l{0}; str[0] = '\0'; // try to use backward tab if ( tabstop > 0 && F_back_tab.cap ) { int pos = from_x; while ( true ) { int tab_pos = ( pos > 0 ) ? ((pos - 1) / tabstop) * tabstop : -1; if ( tab_pos < to_x ) break; htime_l += repeatedAppend (F_back_tab, 1, str); if ( htime_l >= LONG_DURATION ) break; pos = tab_pos; } num = pos - to_x; } htime_l += repeatedAppend (F_cursor_left, num, str); if ( htime_l < htime ) { std::strncpy (hmove, str, BUF_SIZE); hmove[BUF_SIZE - 1] = '\0'; htime = htime_l; } } } //---------------------------------------------------------------------- inline bool FOptiMove::isWideMove ( int xold, int yold , int xnew, int ynew ) { return bool ( xnew > MOVE_LIMIT && xnew < int(screen_width) - 1 - MOVE_LIMIT && std::abs(xnew - xold) + std::abs(ynew - yold) > MOVE_LIMIT ); } //---------------------------------------------------------------------- inline bool FOptiMove::isMethod0Faster ( int& move_time , int xnew, int ynew ) { // Test method 0: direct cursor addressing char* move_xy = tgoto(F_cursor_address.cap, xnew, ynew); if ( move_xy ) { char* move_ptr = move_buf; std::strncpy (move_ptr, move_xy, BUF_SIZE - 1); move_ptr[BUF_SIZE - 1] = '\0'; move_time = F_cursor_address.duration; return true; } return false; } //---------------------------------------------------------------------- inline bool FOptiMove::isMethod1Faster ( int& move_time , int xold, int yold , int xnew, int ynew ) { // Test method 1: local movement if ( xold >= 0 && yold >= 0 ) { char null_result[BUF_SIZE]; int new_time = relativeMove (null_result, xold, yold, xnew, ynew); if ( new_time < LONG_DURATION && new_time < move_time ) { move_time = new_time; return true; } } return false; } //---------------------------------------------------------------------- inline bool FOptiMove::isMethod2Faster ( int& move_time , int yold , int xnew, int ynew ) { // Test method 2: carriage-return + local movement if ( yold >= 0 && F_carriage_return.cap ) { char null_result[BUF_SIZE]; int new_time = relativeMove (null_result, 0, yold, xnew, ynew); if ( new_time < LONG_DURATION && F_carriage_return.duration + new_time < move_time ) { move_time = F_carriage_return.duration + new_time; return true; } } return false; } //---------------------------------------------------------------------- inline bool FOptiMove::isMethod3Faster ( int& move_time , int xnew, int ynew ) { // Test method 3: home-cursor + local movement if ( F_cursor_home.cap ) { char null_result[BUF_SIZE]; int new_time = relativeMove (null_result, 0, 0, xnew, ynew); if ( new_time < LONG_DURATION && F_cursor_home.duration + new_time < move_time ) { move_time = F_cursor_home.duration + new_time; return true; } } return false; } //---------------------------------------------------------------------- inline bool FOptiMove::isMethod4Faster ( int& move_time , int xnew, int ynew ) { // Test method 4: home-down + local movement if ( F_cursor_to_ll.cap ) { char null_result[BUF_SIZE]; int new_time = relativeMove ( null_result , 0, int(screen_height) - 1 , xnew, ynew ); if ( new_time < LONG_DURATION && F_cursor_to_ll.duration + new_time < move_time ) { move_time = F_cursor_to_ll.duration + new_time; return true; } } return false; } //---------------------------------------------------------------------- inline bool FOptiMove::isMethod5Faster ( int& move_time , int yold , int xnew, int ynew ) { // Test method 5: left margin for wrap to right-hand side if ( automatic_left_margin && ! eat_nl_glitch && yold > 0 && F_cursor_left.cap ) { char null_result[BUF_SIZE]; int new_time = relativeMove ( null_result , int(screen_width) - 1, yold - 1 , xnew, ynew ); if ( new_time < LONG_DURATION && F_carriage_return.cap && F_carriage_return.duration + F_cursor_left.duration + new_time < move_time ) { move_time = F_carriage_return.duration + F_cursor_left.duration + new_time; return true; } } return false; } //---------------------------------------------------------------------- void FOptiMove::moveByMethod ( int method , int xold, int yold , int xnew, int ynew ) { char* move_ptr = move_buf; switch ( method ) { case 1: relativeMove (move_ptr, xold, yold, xnew, ynew); break; case 2: if ( F_carriage_return.cap ) { std::strncpy (move_ptr, F_carriage_return.cap, BUF_SIZE - 1); move_ptr[BUF_SIZE - 1] ='\0'; move_ptr += F_carriage_return.length; relativeMove (move_ptr, 0, yold, xnew, ynew); } break; case 3: std::strncpy (move_ptr, F_cursor_home.cap, BUF_SIZE - 1); move_ptr[BUF_SIZE - 1] ='\0'; move_ptr += F_cursor_home.length; relativeMove (move_ptr, 0, 0, xnew, ynew); break; case 4: std::strncpy (move_ptr, F_cursor_to_ll.cap, BUF_SIZE - 1); move_ptr[BUF_SIZE - 1] ='\0'; move_ptr += F_cursor_to_ll.length; relativeMove (move_ptr, 0, int(screen_height) - 1, xnew, ynew); break; case 5: move_buf[0] = '\0'; if ( xold >= 0 ) std::strncat ( move_ptr , F_carriage_return.cap , BUF_SIZE - std::strlen(move_ptr) - 1 ); std::strncat ( move_ptr , F_cursor_left.cap , BUF_SIZE - std::strlen(move_ptr) - 1); move_ptr[BUF_SIZE - 1] ='\0'; move_ptr += std::strlen(move_buf); relativeMove (move_ptr, int(screen_width) - 1, yold - 1, xnew, ynew); break; default: break; } } // FOptiMove non-member function //---------------------------------------------------------------------- void printDurations (const FOptiMove& om) { std::cout << " speed: " << om.baudrate << " baud\r\n"; std::cout << " char_duration: " << om.char_duration << " ms\r\n"; std::cout << " cursor_home: " << om.F_cursor_home.duration << " ms\r\n"; std::cout << " cursor_to_ll: " << om.F_cursor_to_ll.duration << " ms\r\n"; std::cout << " carriage_return: " << om.F_carriage_return.duration << " ms\r\n"; std::cout << " tab: " << om.F_tab.duration << " ms\r\n"; std::cout << " back_tab: " << om.F_back_tab.duration << " ms\r\n"; std::cout << " cursor_up: " << om.F_cursor_up.duration << " ms\r\n"; std::cout << " cursor_down: " << om.F_cursor_down.duration << " ms\r\n"; std::cout << " cursor_left: " << om.F_cursor_left.duration << " ms\r\n"; std::cout << " cursor_right: " << om.F_cursor_right.duration << " ms\r\n"; std::cout << " cursor_address: " << om.F_cursor_address.duration << " ms\r\n"; std::cout << " column_address: " << om.F_column_address.duration << " ms\r\n"; std::cout << " row_address: " << om.F_row_address.duration << " ms\r\n"; std::cout << " parm_up_cursor: " << om.F_parm_up_cursor.duration << " ms\r\n"; std::cout << " parm_down_cursor: " << om.F_parm_down_cursor.duration << " ms\r\n"; std::cout << " parm_left_cursor: " << om.F_parm_left_cursor.duration << " ms\r\n"; std::cout << "parm_right_cursor: " << om.F_parm_right_cursor.duration << " ms\r\n"; } } // namespace finalcut