/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2002 by Alan Korr * * All files in this archive are subject to the GNU General Public License. * See the file COPYING in the source tree root for full license agreement. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include "config.h" #include "hwcompat.h" #ifdef HAVE_LCD_CHARCELLS #include "lcd.h" #include "kernel.h" #include "thread.h" #include #include #include "file.h" #include "debug.h" #include "system.h" #include "font.h" #include "lcd-player-charset.h" #include "rbunicode.h" /*** definitions ***/ #define OLD_LCD_CONTRAST_SET ((char)0xA8) #define OLD_LCD_CRAM ((char)0xB0) /* Characters */ #define OLD_LCD_PRAM ((char)0x80) /* Patterns */ #define OLD_LCD_IRAM ((char)0xE0) /* Icons */ #define NEW_LCD_CONTRAST_SET ((char)0x50) #define NEW_LCD_CRAM ((char)0x80) /* Characters */ #define NEW_LCD_PRAM ((char)0xC0) /* Patterns */ #define NEW_LCD_IRAM ((char)0x40) /* Icons */ #define NEW_LCD_FUNCTION_SET ((char)0x10) #define NEW_LCD_POWER_SAVE_MODE_OSC_CONTROL_SET ((char)0x0c) #define NEW_LCD_POWER_CONTROL_REGISTER_SET ((char)0x20) #define NEW_LCD_DISPLAY_CONTROL_SET ((char)0x28) #define LCD_CURSOR(x,y) ((char)(lcd_cram+((y)*16+(x)))) #define LCD_ICON(i) ((char)(lcd_iram+i)) #define SCROLLABLE_LINES 2 #define SCROLL_MODE_OFF 0 #define SCROLL_MODE_PAUSE 1 #define SCROLL_MODE_RUN 2 extern unsigned short new_lcd_rocklatin1_to_xlcd[]; extern unsigned short old_lcd_rocklatin1_to_xlcd[]; extern const unsigned char lcd_player_extended_lcd_to_rocklatin1[]; extern unsigned char extended_font_player[NO_EXTENDED_LCD_CHARS][8]; /*** generic code ***/ #define MAX_CURSOR_CHARS 8 struct cursorinfo { int len; char text[MAX_CURSOR_CHARS]; int textpos; int y_pos; int x_pos; int divider; int downcount; } cursor; static void scroll_thread(void); static char scroll_stack[DEFAULT_STACK_SIZE]; static const char scroll_name[] = "scroll"; static int scroll_ticks = 12; /* # of ticks between updates */ static int scroll_delay = HZ/2; /* delay before starting scroll */ static int jump_scroll_delay = HZ/4; /* delay between jump scroll jumps */ static int scroll_spacing = 3; /* spaces between end and start of text */ static int bidir_limit = 50; /* percent */ static int jump_scroll = 0; /* 0=off, 1=once, ..., JUMP_SCROLL_ALWAYS */ static struct scrollinfo scroll[SCROLLABLE_LINES]; static char extended_chars_mapped[NO_EXTENDED_LCD_CHARS]; static char extended_pattern_content[8]; /* Which char is mapped in pattern */ static char extended_pattern_usage[8]; /* Counting number of times used */ static char pattern_size; /* Last pattern, 3 for old LCD, 7 for new LCD */ static bool new_lcd; unsigned short *lcd_ascii; static char lcd_contrast_set; static char lcd_cram; static char lcd_pram; static char lcd_iram; unsigned short buffer_xlcd[11][2]; unsigned short buffer_lcd_mirror[11][2]; #ifdef SIMULATOR unsigned char hardware_buffer_lcd[11][2]; #else static unsigned char lcd_data_byte; /* global write buffer */ #endif #define NO_CHAR -1 static void lcd_free_pat(int map_ch) { int x, y; unsigned char substitute_char; int pat; pat=extended_chars_mapped[map_ch]; if (pat!=NO_CHAR) { substitute_char=lcd_player_extended_lcd_to_rocklatin1[map_ch]; /* TODO: use a define for the screen width! */ for (x=0; x<11; x++) { /* TODO: use a define for the screen height! */ for (y=0; y<2; y++) { if (map_ch==lcd_ascii[buffer_xlcd[x][y]]-512) { buffer_xlcd[x][y]=substitute_char; buffer_lcd_mirror[x][y]=substitute_char; #ifdef SIMULATOR hardware_buffer_lcd[x][y]=substitute_char; #else lcd_write_command(LCD_CURSOR(x, y)); lcd_write_data(&substitute_char, 1); #endif } } } extended_chars_mapped[map_ch]=NO_CHAR; extended_pattern_content[pat]=NO_CHAR; extended_pattern_usage[pat]=0; } #ifdef SIMULATOR lcd_update(); #endif } static int lcd_get_free_pat(int ch) { int pat; int last_pat=0; static int last_used_pat=0; int loop; pat=last_used_pat; for (loop=0; loop<=pattern_size; loop++) { pat=(pat+1)&pattern_size; /* Keep 'pat' within limits */ if (extended_pattern_usage[pat]==0) { int map_ch=extended_pattern_content[pat]; if (map_ch != NO_CHAR) { extended_chars_mapped[map_ch]=NO_CHAR; extended_pattern_content[pat]=NO_CHAR; } last_used_pat=pat; return pat; } if (extended_pattern_content[pat]>extended_pattern_content[last_pat]) last_pat=pat; } if (ch<32) { /* Prioritized char */ /* Remove last_pat */ lcd_free_pat(extended_pattern_content[last_pat]); last_used_pat=last_pat; return last_pat; } return NO_CHAR; } void xlcd_update(void) { int x, y; for (x=0; x<11; x++) { for (y=0; y<2; y++) { unsigned short ch=buffer_xlcd[x][y]; unsigned char hw_ch=0xff; if (ch==buffer_lcd_mirror[x][y]) continue; /* No need to redraw */ buffer_lcd_mirror[x][y]=ch; if (ch>=256 && ch<512) { hw_ch=ch-256; } else { int map_ch=lcd_ascii[ch]; if (map_ch<512) { hw_ch=map_ch; } else { map_ch=map_ch-512; if (extended_chars_mapped[map_ch]!=NO_CHAR) { hw_ch=extended_chars_mapped[map_ch]; extended_pattern_usage[hw_ch]++; } else { int pat; pat=lcd_get_free_pat(map_ch); if (pat<0) { /* Find substitute char */ map_ch= lcd_player_extended_lcd_to_rocklatin1[map_ch]; hw_ch=lcd_ascii[map_ch]; } else { #ifdef DEBUG if (extended_pattern_usage[pat]!=0) { DEBUGF("***Pattern %d is not zero!\n", pat); } #endif extended_chars_mapped[map_ch]=pat; extended_pattern_content[pat]=map_ch; extended_pattern_usage[pat]=1; lcd_define_hw_pattern(pat*8, extended_font_player[map_ch], 8); hw_ch=pat; } } } } #ifdef SIMULATOR hardware_buffer_lcd[x][y]=hw_ch; #else lcd_write_command(LCD_CURSOR(x,y)); lcd_write_data(&hw_ch, 1); #endif } } lcd_update(); } bool lcdx_putc(int x, int y, unsigned short ch) { int lcd_char; if (buffer_xlcd[x][y]==ch) return false; /* Same char, ignore any update */ lcd_char=lcd_ascii[buffer_xlcd[x][y]]; if (lcd_char>=512) { /* The removed char is a defined pattern, count down the reference. */ extended_pattern_usage[(int)extended_chars_mapped[lcd_char-512]]--; #ifdef DEBUG if (extended_pattern_usage[(int)extended_chars_mapped[lcd_char]]<0) { DEBUGF("**** Mapped char %02x is less than 0!\n", lcd_char); } #endif } buffer_xlcd[x][y]=ch; lcd_char=lcd_ascii[ch]; if (lcd_char>=256) return true; /* Caller shall call xlcd_update() when done */ buffer_lcd_mirror[x][y]=lcd_char; #ifdef SIMULATOR hardware_buffer_lcd[x][y]=lcd_char; #else lcd_data_byte = (unsigned char) lcd_char; lcd_write_command(LCD_CURSOR(x, y)); lcd_write_data(&lcd_data_byte, 1); #endif return false; } void lcd_clear_display(void) { int i; bool update=false; lcd_stop_scroll(); cursor.len=0; /* Stop cursor */ for (i=0;i<22;i++) update|=lcdx_putc(i%11, i/11, ' '); if (update) xlcd_update(); } static void lcd_puts_cont_scroll(int x, int y, const unsigned char *string) { bool update=false; for (; *string && x<11; x++) { /* We should check if char is over 256 */ update|=lcdx_putc(x, y, *(unsigned char*)string++); } for (; x<11; x++) update|=lcdx_putc(x, y, ' '); if (update) xlcd_update(); #ifdef SIMULATOR lcd_update(); #endif } void lcd_puts(int x, int y, const unsigned char *string) { int i=0; unsigned short ucs; const unsigned char *utf8 = string; unsigned char tmp[12]; while (*utf8 && i<11) { utf8 = utf8decode(utf8, &ucs); if (ucs < 256) tmp[i++] = ucs; else tmp[i++] = '?'; } tmp[i] = 0; scroll[y].mode=SCROLL_MODE_OFF; return lcd_puts_cont_scroll(x, y, tmp); } void lcd_put_cursor(int x, int y, char cursor_char) { if (cursor.len == 0) { cursor.text[0]=buffer_xlcd[x][y]; cursor.text[1]=cursor_char; cursor.len=2; cursor.textpos=0; cursor.y_pos=y; cursor.x_pos=x; cursor.downcount=0; cursor.divider=4; } } void lcd_remove_cursor(void) { if (cursor.len!=0) { bool up; cursor.len=0; up = lcdx_putc(cursor.x_pos, cursor.y_pos, cursor.text[0]); #ifdef SIMULATOR if(up) lcd_update(); #endif } } void lcd_putc(int x, int y, unsigned short ch) { bool update; if (x<0 || y<0) { return; } update=lcdx_putc(x, y, ch); if (update) xlcd_update(); } unsigned char lcd_get_locked_pattern(void) { unsigned char pat=1; while (pattextlen = strlen(tmp); if ( s->textlen > 11-x ) { s->mode = SCROLL_MODE_RUN; s->scroll_start_tick = current_tick + scroll_delay; s->offset=0; s->startx=x; s->starty=y; s->direction=+1; s->jump_scroll=0; s->jump_scroll_steps=0; if (jump_scroll && jump_scroll_delaytextlen-11+x)) { s->jump_scroll_steps=11-x; s->jump_scroll=jump_scroll; } strncpy(s->text,tmp,sizeof s->text); s->turn_offset=-1; if (bidir_limit && (s->textlen < ((11-x)*(100+bidir_limit))/100)) { s->turn_offset=s->textlen+x-11; } else { for (i=0; itextlen<(int)sizeof(s->text); i++) { s->text[s->textlen++]=' '; } } if (s->textlen<(int)sizeof(s->text)) s->text[s->textlen]=' '; s->text[sizeof s->text - 1] = 0; } else s->mode = SCROLL_MODE_OFF; } void lcd_stop_scroll(void) { struct scrollinfo* s; int index; for ( index = 0; index < SCROLLABLE_LINES; index++ ) { s = &scroll[index]; if ( s->mode == SCROLL_MODE_RUN || s->mode == SCROLL_MODE_PAUSE ) { /* restore scrolled row */ lcd_puts(s->startx, s->starty, s->text); } } lcd_update(); } static const char scroll_tick_table[16] = { /* Hz values: 1, 1.25, 1.55, 2, 2.5, 3.12, 4, 5, 6.25, 8.33, 10, 12.5, 16.7, 20, 25, 33 */ 100, 80, 64, 50, 40, 32, 25, 20, 16, 12, 10, 8, 6, 5, 4, 3 }; void lcd_scroll_speed(int speed) { scroll_ticks = scroll_tick_table[speed]; } void lcd_scroll_delay(int ms) { scroll_delay = ms / (HZ / 10); } void lcd_jump_scroll_delay(int ms) { jump_scroll_delay = ms / (HZ / 10); } static void scroll_thread(void) { struct scrollinfo* s; int index; int i, o; bool update; /* initialize scroll struct array */ for (index = 0; index < SCROLLABLE_LINES; index++) { scroll[index].mode = SCROLL_MODE_OFF; } while ( 1 ) { update = false; for ( index = 0; index < SCROLLABLE_LINES; index++ ) { s = &scroll[index]; if ( s->mode == SCROLL_MODE_RUN ) { if ( TIME_AFTER(current_tick, s->scroll_start_tick) ) { char buffer[12]; int jumping_scroll=s->jump_scroll; update = true; if (s->jump_scroll) { /* Find new position to start jump scroll by * finding last white space within * jump_scroll_steps */ int i; o = s->offset = s->offset + s->jump_scroll_steps; for (i = 0; i < s->jump_scroll_steps; i++, o--) { if (o < s->textlen && ((0x20 <= s->text[o] && s->text[o] <= 0x2f) || s->text[o] == '_')) { s->offset = o; break; } } s->scroll_start_tick = current_tick + jump_scroll_delay; /* Eat space */ while (s->offset < s->textlen && ((0x20 <= s->text[s->offset] && s->text[s->offset] <= 0x2f) || s->text[s->offset] == '_')) { s->offset++; } if (s->offset >= s->textlen) { s->offset=0; s->scroll_start_tick = current_tick + scroll_delay; if (s->jump_scroll != JUMP_SCROLL_ALWAYS) { s->jump_scroll--; s->direction=1; } } } else { if ( s->offset < s->textlen-1 ) { s->offset+=s->direction; if (s->offset==0) { s->direction=+1; s->scroll_start_tick = current_tick + scroll_delay; } else { if (s->offset == s->turn_offset) { s->direction=-1; s->scroll_start_tick = current_tick + scroll_delay; } } } else { s->offset = 0; } } i=0; o=s->offset; while (i<11) { buffer[i++]=s->text[o++]; if (o==s->textlen /* || (jump_scroll && buffer[i-1] == ' ') */) break; } o=0; if (s->turn_offset == -1 && !jumping_scroll) { while (i<11) { buffer[i++]=s->text[o++]; } } else { while (i<11) { buffer[i++]=' '; } } buffer[11]=0; lcd_puts_cont_scroll(s->startx, s->starty, buffer); } } if (cursor.len>0) { if (cursor.downcount--<0) { cursor.downcount=cursor.divider; cursor.textpos++; if (cursor.textpos>=cursor.len) cursor.textpos=0; #ifdef SIMULATOR lcdx_putc(cursor.x_pos, cursor.y_pos, cursor.text[cursor.textpos]); update=true; #else update|=lcdx_putc(cursor.x_pos, cursor.y_pos, cursor.text[cursor.textpos]); #endif } } if (update) { lcd_update(); } } sleep(scroll_ticks); } } #endif /* HAVE_LCD_CHARCELLS */