/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2004 Pengxuan Liu (Isaac) * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ /* 00 01 21 22 23 43 44 45 65 66 67 87 88 89 109110111 00 |-----------|-----------|-----------|-----------|-----------| 01 | | | | | | |***********|***********|***********|***********|***********| |***********|***********|***********|***********|***********| 11 | | | | | | 12 |-----------|-----------|-----------|-----------|-----------| 13 |-----------|-----------|-----------|-----------|-----------| y1 14 | | | | | | | | | | | | 22 | | | | | | 23 |-----------|-----------|-----------|-----------|-----------| y2 24 | | | | | | | | | | | | 32 | | | | | | 33 |-----------|-----------|-----------|-----------|-----------| y3 34 | | | | | | | | | | | | 42 | | | | | | 43 |-----------|-----------|-----------|-----------|-----------| y4 44 | | | | | | | | | | | | 52 | | | | | | 53 |-----------|-----------|-----------|-----------|-----------| y5 54 | | | | | | | | | | | | 62 | | | | | | 63 |-----------|-----------|-----------|-----------|-----------| y6 x0 x1 x2 x3 x4 x5 */ /*--------------------------------------------------------------------------- Features: - Scientific number format core code. Support range 10^-999 ~ 10^999 - Number of significant figures up to 10 Limitations: - Right now, only accept "num, operator (+,-,*,/), num, =" input sequence. Input "3, +, 5, -, 2, =", the calculator will only do 5-2 and result = 3 You have to input "3, +, 5, =, -, 2, =" to get 3+5-2 = 6 - "*,/" have no priority. Actually you can't input 3+5*2 yet. User Instructions: use arrow button to move cursor, "play" button to select, "off" button to exit F1: if typing numbers, it's equal to "Del"; otherwise, equal to "C" F2: circle input "+, -, *, /" F3: equal to "=" "MR" : load temp memory "M+" : add currently display to temp memory "C" : reset calculator ---------------------------------------------------------------------------*/ #include "plugin.h" #include "math.h" #define M_TWOPI (M_PI * 2.0) #define BUTTON_ROWS 5 #define BUTTON_COLS 5 #define REC_HEIGHT (int)(LCD_HEIGHT / (BUTTON_ROWS + 1)) #define REC_WIDTH (int)(LCD_WIDTH / BUTTON_COLS) #define Y_6_POS (LCD_HEIGHT) /* Leave room for the border */ #define Y_5_POS (Y_6_POS - REC_HEIGHT) /* y5 = 53 */ #define Y_4_POS (Y_5_POS - REC_HEIGHT) /* y4 = 43 */ #define Y_3_POS (Y_4_POS - REC_HEIGHT) /* y3 = 33 */ #define Y_2_POS (Y_3_POS - REC_HEIGHT) /* y2 = 23 */ #define Y_1_POS (Y_2_POS - REC_HEIGHT) /* y1 = 13 */ #define Y_0_POS 0 /* y0 = 0 */ #define X_0_POS 0 /* x0 = 0 */ #define X_1_POS (X_0_POS + REC_WIDTH) /* x1 = 22 */ #define X_2_POS (X_1_POS + REC_WIDTH) /* x2 = 44 */ #define X_3_POS (X_2_POS + REC_WIDTH) /* x3 = 66 */ #define X_4_POS (X_3_POS + REC_WIDTH) /* x4 = 88 */ #define X_5_POS (X_4_POS + REC_WIDTH) /* x5 = 110, column 111 left blank */ #define SIGN(x) ((x)<0?-1:1) #ifndef ABS #define ABS(a) (((a) < 0) ? -(a) : (a)) #endif /* variable button definitions */ #if CONFIG_KEYPAD == RECORDER_PAD #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_OFF #define CALCULATOR_INPUT BUTTON_PLAY #define CALCULATOR_CALC BUTTON_F3 #define CALCULATOR_OPERATORS BUTTON_F2 #define CALCULATOR_CLEAR BUTTON_F1 #elif CONFIG_KEYPAD == ARCHOS_AV300_PAD #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_OFF #define CALCULATOR_INPUT BUTTON_SELECT #define CALCULATOR_CALC BUTTON_F3 #define CALCULATOR_OPERATORS BUTTON_F2 #define CALCULATOR_CLEAR BUTTON_F1 #elif CONFIG_KEYPAD == ONDIO_PAD #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_OFF #define CALCULATOR_INPUT_CALC_PRE BUTTON_MENU #define CALCULATOR_INPUT (BUTTON_MENU | BUTTON_REL) #define CALCULATOR_CALC (BUTTON_MENU | BUTTON_REPEAT) #elif (CONFIG_KEYPAD == IRIVER_H100_PAD) || \ (CONFIG_KEYPAD == IRIVER_H300_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_OFF #define CALCULATOR_INPUT BUTTON_SELECT #define CALCULATOR_CALC BUTTON_ON #define CALCULATOR_OPERATORS BUTTON_MODE #define CALCULATOR_CLEAR BUTTON_REC #define CALCULATOR_RC_QUIT BUTTON_RC_STOP #elif (CONFIG_KEYPAD == IPOD_4G_PAD) || \ (CONFIG_KEYPAD == IPOD_3G_PAD) || \ (CONFIG_KEYPAD == IPOD_1G2G_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP_W_SHIFT BUTTON_SCROLL_BACK #define CALCULATOR_DOWN_W_SHIFT BUTTON_SCROLL_FWD #define CALCULATOR_QUIT BUTTON_MENU #define CALCULATOR_INPUT BUTTON_SELECT #define CALCULATOR_CALC BUTTON_PLAY #elif (CONFIG_KEYPAD == IAUDIO_X5M5_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_INPUT BUTTON_SELECT #define CALCULATOR_CALC BUTTON_PLAY #define CALCULATOR_CLEAR BUTTON_REC #elif (CONFIG_KEYPAD == GIGABEAT_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_INPUT BUTTON_SELECT #define CALCULATOR_CALC BUTTON_MENU #define CALCULATOR_CLEAR BUTTON_A #elif (CONFIG_KEYPAD == SANSA_E200_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_UP_W_SHIFT BUTTON_SCROLL_BACK #define CALCULATOR_DOWN_W_SHIFT BUTTON_SCROLL_FWD #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_INPUT_CALC_PRE BUTTON_SELECT #define CALCULATOR_INPUT (BUTTON_SELECT|BUTTON_REL) #define CALCULATOR_CALC (BUTTON_SELECT|BUTTON_REPEAT) #define CALCULATOR_CLEAR BUTTON_REC #elif (CONFIG_KEYPAD == SANSA_C200_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_INPUT_CALC_PRE BUTTON_SELECT #define CALCULATOR_INPUT (BUTTON_SELECT|BUTTON_REL) #define CALCULATOR_CALC (BUTTON_SELECT|BUTTON_REPEAT) #elif (CONFIG_KEYPAD == SANSA_FUZE_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_UP_W_SHIFT BUTTON_SCROLL_BACK #define CALCULATOR_DOWN_W_SHIFT BUTTON_SCROLL_FWD #define CALCULATOR_QUIT (BUTTON_HOME|BUTTON_REPEAT) #define CALCULATOR_INPUT_CALC_PRE BUTTON_SELECT #define CALCULATOR_INPUT (BUTTON_SELECT|BUTTON_REL) #define CALCULATOR_CALC (BUTTON_SELECT|BUTTON_REPEAT) #define CALCULATOR_CLEAR BUTTON_HOME #elif (CONFIG_KEYPAD == SANSA_CLIP_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_INPUT_CALC_PRE BUTTON_SELECT #define CALCULATOR_INPUT (BUTTON_SELECT|BUTTON_REL) #define CALCULATOR_CALC (BUTTON_SELECT|BUTTON_REPEAT) #define CALCULATOR_CLEAR BUTTON_HOME #elif (CONFIG_KEYPAD == SANSA_M200_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_INPUT_CALC_PRE BUTTON_SELECT #define CALCULATOR_INPUT (BUTTON_SELECT|BUTTON_REL) #define CALCULATOR_CALC (BUTTON_SELECT|BUTTON_REPEAT) #define CALCULATOR_CLEAR (BUTTON_SELECT|BUTTON_UP) #elif (CONFIG_KEYPAD == IRIVER_H10_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_SCROLL_UP #define CALCULATOR_DOWN BUTTON_SCROLL_DOWN #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_INPUT_CALC_PRE BUTTON_PLAY #define CALCULATOR_INPUT (BUTTON_PLAY | BUTTON_REL) #define CALCULATOR_CALC (BUTTON_PLAY | BUTTON_REPEAT) #define CALCULATOR_CLEAR BUTTON_REW #elif (CONFIG_KEYPAD == GIGABEAT_S_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_BACK #define CALCULATOR_INPUT BUTTON_SELECT #define CALCULATOR_CALC BUTTON_MENU #define CALCULATOR_CLEAR BUTTON_PLAY #elif (CONFIG_KEYPAD == MROBE100_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_INPUT BUTTON_SELECT #define CALCULATOR_CALC BUTTON_MENU #define CALCULATOR_CLEAR BUTTON_DISPLAY #elif CONFIG_KEYPAD == IAUDIO_M3_PAD #define CALCULATOR_LEFT BUTTON_RC_REW #define CALCULATOR_RIGHT BUTTON_RC_FF #define CALCULATOR_UP BUTTON_RC_VOL_UP #define CALCULATOR_DOWN BUTTON_RC_VOL_DOWN #define CALCULATOR_QUIT BUTTON_RC_REC #define CALCULATOR_INPUT BUTTON_RC_PLAY #define CALCULATOR_CALC BUTTON_RC_MODE #define CALCULATOR_CLEAR BUTTON_RC_MENU #define CALCULATOR_RC_QUIT BUTTON_REC #elif (CONFIG_KEYPAD == COWON_D2_PAD) #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_CLEAR BUTTON_MENU #elif CONFIG_KEYPAD == IAUDIO67_PAD #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_VOLUP #define CALCULATOR_DOWN BUTTON_VOLDOWN #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_INPUT BUTTON_PLAY #define CALCULATOR_CALC BUTTON_MENU #define CALCULATOR_CLEAR BUTTON_STOP #define CALCULATOR_RC_QUIT (BUTTON_MENU|BUTTON_PLAY) #elif (CONFIG_KEYPAD == CREATIVEZVM_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_BACK #define CALCULATOR_INPUT BUTTON_SELECT #define CALCULATOR_CALC BUTTON_MENU #define CALCULATOR_CLEAR BUTTON_PLAY #elif CONFIG_KEYPAD == PHILIPS_HDD1630_PAD #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_INPUT BUTTON_SELECT #define CALCULATOR_CALC BUTTON_MENU #define CALCULATOR_CLEAR BUTTON_VIEW #elif CONFIG_KEYPAD == PHILIPS_HDD6330_PAD #define CALCULATOR_LEFT BUTTON_PREV #define CALCULATOR_RIGHT BUTTON_NEXT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_INPUT BUTTON_PLAY #define CALCULATOR_CALC BUTTON_MENU #define CALCULATOR_CLEAR BUTTON_RIGHT #elif CONFIG_KEYPAD == PHILIPS_SA9200_PAD #define CALCULATOR_LEFT BUTTON_PREV #define CALCULATOR_RIGHT BUTTON_NEXT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_INPUT BUTTON_PLAY #define CALCULATOR_CALC BUTTON_MENU #define CALCULATOR_CLEAR BUTTON_RIGHT #elif (CONFIG_KEYPAD == ONDAVX747_PAD) #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_CLEAR BUTTON_MENU #elif (CONFIG_KEYPAD == ONDAVX777_PAD) #define CALCULATOR_QUIT BUTTON_POWER #elif CONFIG_KEYPAD == MROBE500_PAD #define CALCULATOR_QUIT BUTTON_POWER #elif CONFIG_KEYPAD == SAMSUNG_YH_PAD #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_REC #define CALCULATOR_INPUT BUTTON_PLAY #define CALCULATOR_CALC BUTTON_FFWD #define CALCULATOR_CLEAR BUTTON_REW #elif CONFIG_KEYPAD == PBELL_VIBE500_PAD #define CALCULATOR_LEFT BUTTON_PREV #define CALCULATOR_RIGHT BUTTON_NEXT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_REC #define CALCULATOR_INPUT BUTTON_OK #define CALCULATOR_CALC BUTTON_PLAY #define CALCULATOR_CLEAR BUTTON_CANCEL #elif CONFIG_KEYPAD == MPIO_HD200_PAD #define CALCULATOR_LEFT BUTTON_REW #define CALCULATOR_RIGHT BUTTON_FF #define CALCULATOR_QUIT (BUTTON_REC|BUTTON_PLAY) #define CALCULATOR_INPUT BUTTON_FUNC #define CALCULATOR_CALC BUTTON_PLAY #define CALCULATOR_CLEAR BUTTON_REC #elif CONFIG_KEYPAD == MPIO_HD300_PAD #define CALCULATOR_LEFT BUTTON_REW #define CALCULATOR_RIGHT BUTTON_FF #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT (BUTTON_MENU|BUTTON_REPEAT) #define CALCULATOR_INPUT BUTTON_ENTER #define CALCULATOR_CALC BUTTON_PLAY #define CALCULATOR_CLEAR BUTTON_MENU #elif CONFIG_KEYPAD == SANSA_FUZEPLUS_PAD #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_INPUT BUTTON_SELECT #define CALCULATOR_CALC BUTTON_PLAYPAUSE #define CALCULATOR_CLEAR BUTTON_BACK #elif (CONFIG_KEYPAD == SANSA_CONNECT_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_UP_W_SHIFT BUTTON_SCROLL_BACK #define CALCULATOR_DOWN_W_SHIFT BUTTON_SCROLL_FWD #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_INPUT_CALC_PRE BUTTON_SELECT #define CALCULATOR_INPUT (BUTTON_SELECT|BUTTON_REL) #define CALCULATOR_CALC BUTTON_NEXT #define CALCULATOR_CLEAR BUTTON_PREV #elif (CONFIG_KEYPAD == SAMSUNG_YPR0_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_BACK #define CALCULATOR_INPUT BUTTON_SELECT #define CALCULATOR_CALC BUTTON_MENU #define CALCULATOR_CLEAR BUTTON_USER #elif (CONFIG_KEYPAD == HM60X_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_INPUT BUTTON_SELECT #define CALCULATOR_CALC (BUTTON_UP|BUTTON_POWER) #define CALCULATOR_CLEAR (BUTTON_DOWN|BUTTON_POWER) #elif (CONFIG_KEYPAD == HM801_PAD) #define CALCULATOR_LEFT BUTTON_LEFT #define CALCULATOR_RIGHT BUTTON_RIGHT #define CALCULATOR_UP BUTTON_UP #define CALCULATOR_DOWN BUTTON_DOWN #define CALCULATOR_QUIT BUTTON_POWER #define CALCULATOR_INPUT BUTTON_SELECT #define CALCULATOR_CALC BUTTON_PLAY #define CALCULATOR_CLEAR BUTTON_PREV #else #error No keymap defined! #endif #ifdef HAVE_TOUCHSCREEN #ifndef CALCULATOR_LEFT #define CALCULATOR_LEFT BUTTON_MIDLEFT #endif #ifndef CALCULATOR_RIGHT #define CALCULATOR_RIGHT BUTTON_MIDRIGHT #endif #ifndef CALCULATOR_UP #define CALCULATOR_UP BUTTON_TOPMIDDLE #endif #ifndef CALCULATOR_DOWN #define CALCULATOR_DOWN BUTTON_BOTTOMMIDDLE #endif #ifndef CALCULATOR_CALC #define CALCULATOR_CALC BUTTON_BOTTOMRIGHT #endif #ifndef CALCULATOR_INPUT #define CALCULATOR_INPUT BUTTON_CENTER #endif #ifndef CALCULATOR_CLEAR #define CALCULATOR_CLEAR BUTTON_TOPRIGHT #endif #include "lib/pluginlib_touchscreen.h" static struct ts_raster calc_raster = { X_0_POS, Y_1_POS, BUTTON_COLS*REC_WIDTH, BUTTON_ROWS*REC_HEIGHT, REC_WIDTH, REC_HEIGHT }; #endif enum { basicButtons, sciButtons } buttonGroup; unsigned char* buttonChar[2][5][5] = { { { "MR" , "M+" , "2nd" , "CE" , "C" }, { "7" , "8" , "9" , "/" , "sqr" }, { "4" , "5" , "6" , "*" , "x^2" }, { "1" , "2" , "3" , "-" , "1/x" }, { "0" , "+/-", "." , "+" , "=" } }, { { "n!" , "PI" , "1st" , "sin" , "asi" }, { "7" , "8" , "9" , "cos" , "aco" }, { "4" , "5" , "6" , "tan" , "ata" }, { "1" , "2" , "3" , "ln" , "e^x" }, { "0" , "+/-", "." , "log" , "x^y" } } }; enum { btn_MR , btn_M , btn_bas , btn_CE , btn_C , btn_7 , btn_8 , btn_9 , btn_div , btn_sqr , btn_4 , btn_5 , btn_6 , btn_time , btn_square , btn_1 , btn_2 , btn_3 , btn_minus , btn_rec , btn_0 , btn_sign , btn_dot , btn_add , btn_equal }; enum { sci_fac, sci_pi , sci_sci , sci_sin , sci_asin , sci_7 , sci_8 , sci_9 , sci_cos , sci_acos , sci_4 , sci_5 , sci_6 , sci_tan , sci_atan , sci_1 , sci_2 , sci_3 , sci_ln , sci_exp , sci_0 , sci_sign , sci_dot , sci_log , sci_xy }; #define MINIMUM 0.000000000001 /* e-12 */ /* ^ ^ ^ ^ */ /* 123456789abcdef */ #define DIGITLEN 10 /* must <= 10 */ #define SCIENTIFIC_FORMAT ( power < -(DIGITLEN-3) || power > (DIGITLEN)) /* 0.000 00000 0001 */ /* ^ ^ ^ ^ ^ ^ */ /* DIGITLEN 12345 6789a bcdef */ /* power 12 34567 89abc def */ /* 10^- 123 45678 9abcd ef */ unsigned char buf[19];/* 18 bytes of output line, buf[0] is operator buf[1] = 'M' if memTemp is not 0 buf[2] = ' ' if SCIENTIFIC_FORMAT buf[2]-buf[12] or buf[3]-buf[13] = result; format X.XXXXXXXX buf[13] or buf[14] -buf[17] = power; format eXXX or e-XXX else buf[3]-buf[6] = ' '; buf[7]-buf[17] = result; buf[18] = '\0' */ unsigned char typingbuf[DIGITLEN+2];/* byte 0 is sign or ' ', byte 1~DIGITLEN are num and '.' byte (DIGITLEN+1) is '\0' */ unsigned char* typingbufPointer = typingbuf; double result = 0; /* main operand, format 0.xxxxx */ int power = 0; /* 10^power */ double modifier = 0.1; /* position of next input */ double operand = 0; /* second operand, format 0.xxxxx */ int operandPower = 0; /* 10^power of second operand */ char oper = ' '; /* operators: + - * / */ bool operInputted = false; /* false: do calculation first and replace current oper true: just replace current oper */ double memTemp = 0; /* temp memory */ int memTempPower = 0; /* 10^^power of memTemp */ int btn_row, btn_col; /* current position index for button */ int prev_btn_row, prev_btn_col; /* previous cursor position */ #define CAL_BUTTON (btn_row*5+btn_col) int btn = BUTTON_NONE; int lastbtn = BUTTON_NONE; /* Status of calculator */ enum {cal_normal, /* 0, normal status, display result */ cal_typing, /* 1, currently typing, dot hasn't been typed */ cal_dotted, /* 2, currently typing, dot already has been typed. */ cal_error, cal_exit, cal_toDo } calStatus; /* constant table for CORDIC algorithm */ static const double cordicTable[51][2]= { /* pow(2,0) - pow(2,-50) atan(pow(2,0) - atan(pow(2,-50) */ {1e+00, 7.853981633974483e-01}, {5e-01, 4.636476090008061e-01}, {2.5e-01, 2.449786631268641e-01}, {1.25e-01, 1.243549945467614e-01}, {6.25e-02, 6.241880999595735e-02}, {3.125e-02, 3.123983343026828e-02}, {1.5625e-02, 1.562372862047683e-02}, {7.8125e-03, 7.812341060101111e-03}, {3.90625e-03, 3.906230131966972e-03}, {1.953125e-03, 1.953122516478819e-03}, {9.765625e-04, 9.765621895593195e-04}, {4.8828125e-04, 4.882812111948983e-04}, {2.44140625e-04, 2.441406201493618e-04}, {1.220703125e-04, 1.220703118936702e-04}, {6.103515625e-05, 6.103515617420877e-05}, {3.0517578125e-05, 3.051757811552610e-05}, {1.52587890625e-05, 1.525878906131576e-05}, {7.62939453125e-06, 7.629394531101970e-06}, {3.814697265625e-06, 3.814697265606496e-06}, {1.9073486328125e-06, 1.907348632810187e-06}, {9.5367431640625e-07, 9.536743164059608e-07}, {4.76837158203125e-07, 4.768371582030888e-07}, {2.384185791015625e-07, 2.384185791015580e-07}, {1.1920928955078125e-07, 1.192092895507807e-07}, {5.9604644775390625e-08, 5.960464477539055e-08}, {2.98023223876953125e-08, 2.980232238769530e-08}, {1.490116119384765625e-08, 1.490116119384765e-08}, {7.450580596923828125e-09, 7.450580596923828e-09}, {3.7252902984619140625e-09, 3.725290298461914e-09}, {1.86264514923095703125e-09, 1.862645149230957e-09}, {9.31322574615478515625e-10, 9.313225746154785e-10}, {4.656612873077392578125e-10, 4.656612873077393e-10}, {2.3283064365386962890625e-10, 2.328306436538696e-10}, {1.16415321826934814453125e-10, 1.164153218269348e-10}, {5.82076609134674072265625e-11, 5.820766091346741e-11}, {2.910383045673370361328125e-11, 2.910383045673370e-11}, {1.4551915228366851806640625e-11, 1.455191522836685e-11}, {7.2759576141834259033203125e-12, 7.275957614183426e-12}, {3.63797880709171295166015625e-12, 3.637978807091713e-12}, {1.818989403545856475830078125e-12, 1.818989403545856e-12}, {9.094947017729282379150390625e-13, 9.094947017729282e-13}, {4.5474735088646411895751953125e-13, 4.547473508864641e-13}, {2.27373675443232059478759765625e-13, 2.273736754432321e-13}, {1.136868377216160297393798828125e-13, 1.136868377216160e-13}, {5.684341886080801486968994140625e-14, 5.684341886080801e-14}, {2.8421709430404007434844970703125e-14, 2.842170943040401e-14}, {1.42108547152020037174224853515625e-14, 1.421085471520200e-14}, {7.10542735760100185871124267578125e-15, 7.105427357601002e-15}, {3.552713678800500929355621337890625e-15, 3.552713678800501e-15}, {1.7763568394002504646778106689453125e-15, 1.776356839400250e-15}, {8.8817841970012523233890533447265625e-16, 8.881784197001252e-16} }; static void doMultiple(double* operandOne, int* powerOne, double operandTwo, int powerTwo); static void doAdd (double* operandOne, int* powerOne, double operandTwo, int powerTwo); static void printResult(void); static void formatResult(void); static void oneOperand(void); static void drawLines(void); static void drawButtons(int group); /* ----------------------------------------------------------------------- Handy functions ----------------------------------------------------------------------- */ static void cleartypingbuf(void) { int k; for( k=1; k<=(DIGITLEN+1); k++) typingbuf[k] = 0; typingbuf[0] = ' '; typingbufPointer = typingbuf+1; } static void clearbuf(void) { int k; for(k=0;k<18;k++) buf[k]=' '; buf[18] = 0; } static void clearResult(void) { result = 0; power = 0; modifier = 0.1; } static void clearInput(void) { calStatus = cal_normal; clearResult(); cleartypingbuf(); rb->lcd_clear_display(); drawButtons(buttonGroup); drawLines(); } static void clearOperand(void) { operand = 0; operandPower = 0; } static void clearMemTemp(void) { memTemp = 0; memTempPower = 0; } static void clearOper(void) { oper = ' '; operInputted = false; } static void clearMem(void) { clearInput(); clearMemTemp(); clearOperand(); clearOper(); btn = BUTTON_NONE; } static void switchOperands(void) { double tempr = operand; int tempp = operandPower; operand = result; operandPower = power; result = tempr; power = tempp; } static void drawLines(void) { int i; rb->lcd_hline(0, LCD_WIDTH, Y_1_POS-1); for (i = 0; i < 5 ; i++) rb->lcd_hline(0, LCD_WIDTH, Y_1_POS+i*REC_HEIGHT); for (i = 0; i < 4 ; i++) rb->lcd_vline(X_1_POS+i*REC_WIDTH, Y_1_POS, LCD_HEIGHT); } static void drawButtons(int group) { int i, j, w, h; for (i = 0; i <= 4; i++){ for (j = 0; j <= 4; j++){ rb->lcd_getstringsize( buttonChar[group][i][j],&w,&h); if (i == btn_row && j == btn_col) /* selected item */ rb->lcd_set_drawmode(DRMODE_SOLID); else rb->lcd_set_drawmode(DRMODE_SOLID|DRMODE_INVERSEVID); rb->lcd_fillrect( X_0_POS + j*REC_WIDTH, Y_1_POS + i*REC_HEIGHT, REC_WIDTH, REC_HEIGHT+1); if (i == btn_row && j == btn_col) /* selected item */ rb->lcd_set_drawmode(DRMODE_SOLID|DRMODE_INVERSEVID); else rb->lcd_set_drawmode(DRMODE_SOLID); rb->lcd_putsxy( X_0_POS + j*REC_WIDTH + (REC_WIDTH - w)/2, Y_1_POS + i*REC_HEIGHT + (REC_HEIGHT - h)/2 + 1, buttonChar[group][i][j] ); } } rb->lcd_set_drawmode(DRMODE_SOLID); } /* ----------------------------------------------------------------------- Initiate calculator ----------------------------------------------------------------------- */ static void cal_initial (void) { int w,h; rb->lcd_getstringsize("2nd",&w,&h); if (w > REC_WIDTH || h > REC_HEIGHT) rb->lcd_setfont(FONT_SYSFIXED); rb->lcd_clear_display(); #ifdef CALCULATOR_OPERATORS /* basic operators are available through separate button */ buttonGroup = sciButtons; #else buttonGroup = basicButtons; #endif /* initially, invert button "5" */ btn_row = 2; btn_col = 1; prev_btn_row = btn_row; prev_btn_col = btn_col; drawButtons(buttonGroup); drawLines(); rb->lcd_update(); /* initial mem and output display*/ clearMem(); printResult(); /* clear button queue */ rb->button_clear_queue(); } /* ----------------------------------------------------------------------- mySqrt uses Heron's algorithm, which is the Newtone-Raphson algorhitm in it's private case for sqrt. Thanks BlueChip for his intro text and Dave Straayer for the actual name. ----------------------------------------------------------------------- */ static double mySqrt(double square) { int k = 0; double temp = 0; double root= ABS(square+1)/2; while( ABS(root - temp) > MINIMUM ){ temp = root; root = (square/temp + temp)/2; k++; if (k>10000) return 0; } return root; } /*Uses the sequence sum(x^k/k!) that tends to exp(x)*/ static double myExp (double x) { unsigned int k=0; double res=0, xPow=1,fact=1,toAdd; do { toAdd = xPow/fact; res += toAdd; xPow *= x; //xPow = x^k k++; fact*=k; //fact = k! } while (ABS(toAdd) > MINIMUM && xPow<1e302); return res; } /*myLn : uses the series ln⁡(a) = 2 * ∑(1/(2n+1) * ((a-1)/(a+1))^(2k+1) )*/ static double myLn (double a) { unsigned int k=1; double res=0,xPow,xSquare,fract=1,toAdd; xPow = (a-1)/(a+1); xSquare = xPow*xPow; do { toAdd = fract*xPow; res += toAdd; xPow *= xSquare; // ((a-1)/(a+1))^k k+=2; fract=1./k; } while (ABS(toAdd) > MINIMUM); return res * 2; } /* ----------------------------------------------------------------------- transcendFunc uses CORDIC (COordinate Rotation DIgital Computer) method transcendFunc can do sin,cos,log,exp input parameter is angle ----------------------------------------------------------------------- */ static void transcendFunc(char* func, double* tt, int* ttPower) { double t = (*tt)*M_PI/180; int tPower = *ttPower; int sign = 1; int n = 50; /* n <=50, tables are all <= 50 */ int j; double x,y,z,xt,yt,zt; if (tPower < -998) { calStatus = cal_normal; return; } if (tPower > 8) { calStatus = cal_error; return; } *ttPower = 0; calStatus = cal_normal; if( func[0] =='s' || func[0] =='S'|| func[0] =='t' || func[0] =='T') sign = SIGN(t); else { /* if( func[0] =='c' || func[0] =='C') */ sign = 1; } t = ABS(t); while (tPower > 0){ t *= 10; tPower--; } while (tPower < 0) { t /= 10; tPower++; } j = 0; while (t > j*M_TWOPI) {j++;} t -= (j-1)*M_TWOPI; if (M_PI_2 < t && t < 3*M_PI_2){ t = M_PI - t; if (func[0] =='c' || func[0] =='C') sign = -1; else if (func[0] =='t' || func[0] =='T') t*=-1; } else if ( 3*M_PI_2 <= t && t <= M_TWOPI) t -= M_TWOPI; x = 0.60725293500888; y = 0; z = t; for (j=1;j= powerTwo ){ if (*powerOne - powerTwo <= DIGITLEN+1){ while (powerTwo < *powerOne){ operandTwo /=10; powerTwo++; } *operandOne += operandTwo; } /*do nothing if operandTwo is too small*/ } else{ if (powerTwo - *powerOne <= DIGITLEN+1){ while(powerTwo > *powerOne){ *operandOne /=10; (*powerOne)++; } (*operandOne) += operandTwo; } else{/* simply copy operandTwo if operandOne is too small */ *operandOne = operandTwo; *powerOne = powerTwo; } } } /* ----------------------------------------------------------------------- multiple in scientific number format ----------------------------------------------------------------------- */ static void doMultiple(double* operandOne, int* powerOne, double operandTwo, int powerTwo) { (*operandOne) *= operandTwo; (*powerOne) += powerTwo; } /* ----------------------------------------------------------------------- Handles all one operand calculations ----------------------------------------------------------------------- */ static void oneOperand(void) { int k = 0; if (buttonGroup == basicButtons){ switch(CAL_BUTTON){ case btn_sqr: if (result<0) calStatus = cal_error; else{ if (power%2 == 1){ result = (mySqrt(result*10))/10; power = (power+1) / 2; } else{ result = mySqrt(result); power = power / 2; } calStatus = cal_normal; } break; case btn_square: power *= 2; result *= result; calStatus = cal_normal; break; case btn_rec: if (result==0) calStatus = cal_error; else{ power = -power; result = 1/result; calStatus = cal_normal; } break; default: calStatus = cal_toDo; break; /* just for the safety */ } } else{ /* sciButtons */ switch(CAL_BUTTON){ case sci_sin: transcendFunc("sin", &result, &power); break; case sci_cos: transcendFunc("cos", &result, &power); break; case sci_tan: transcendFunc("tan", &result, &power); break; case sci_fac: if (power<0 || power>8 || result<0 ) calStatus = cal_error; else if(result == 0) { result = 1; power = 0; } else{ while(power > 0) { result *= 10; power--; } if ( ( result - (int)result) > MINIMUM ) calStatus = cal_error; else { k = result; result = 1; while (k > 1){ doMultiple(&result, &power, k, 0); formatResult(); k--; } calStatus = cal_normal; } } break; case sci_exp: /*Uses the sequence (1+a/n)^n -> exp(a) */ if (power>3 || result > 1e3) calStatus = cal_error; else { while(power < 0) { result /= 10; power++; } while (power > 0){ power--; result*=10; } result = myExp(result); calStatus = cal_normal; } break; case sci_ln: if (result<=0) calStatus = cal_error; else { //ln(a*10^n) = ln(a) + n*ln(10), with ln(10) ≈ 2.30 result = myLn(result) + power * 2.302585092994046; power=0; calStatus = cal_normal; } break; case sci_log: if (result<=0) calStatus = cal_error; else { //log10(a+10^n) = ln(a)/ln(10) + n, with ln(10) ≈ 2.30 result = myLn(result)/2.302585092994046 + power; power=0; calStatus = cal_normal; } break; default: calStatus = cal_toDo; break; /* just for the safety */ } } } /* ----------------------------------------------------------------------- Handles all two operands calculations ----------------------------------------------------------------------- */ static void twoOperands(void) { switch(oper){ case '-': doAdd(&operand, &operandPower, -result, power); break; case '+': doAdd(&operand, &operandPower, result, power); break; case '*': doMultiple(&operand, &operandPower, result, power); break; case '/': if ( ABS(result) > MINIMUM ){ doMultiple(&operand, &operandPower, 1/result, -power); } else calStatus = cal_error; break; default: /* ' ' */ switchOperands(); /* counter switchOperands() below */ break; } /* switch(oper) */ switchOperands(); clearOper(); } /* First, increases *dimen1 by dimen1_delta modulo dimen1_modulo. If dimen1 wraps, increases *dimen2 by dimen2_delta modulo dimen2_modulo. */ static void move_with_wrap_and_shift( int *dimen1, int dimen1_delta, int dimen1_modulo, int *dimen2, int dimen2_delta, int dimen2_modulo) { bool wrapped = false; *dimen1 += dimen1_delta; if (*dimen1 < 0) { *dimen1 = dimen1_modulo - 1; wrapped = true; } else if (*dimen1 >= dimen1_modulo) { *dimen1 = 0; wrapped = true; } if (wrapped) { /* Make the dividend always positive to be sure about the result. Adding dimen2_modulo does not change it since we do it modulo. */ *dimen2 = (*dimen2 + dimen2_modulo + dimen2_delta) % dimen2_modulo; } } /* ----------------------------------------------------------------------- Print buttons when switching 1st and 2nd int group = {basicButtons, sciButtons} ----------------------------------------------------------------------- */ static void printButtonGroups(int group) { drawButtons(group); drawLines(); rb->lcd_update(); } /* ----------------------------------------------------------------------- flash the currently marked button ----------------------------------------------------------------------- */ static void flashButton(void) { int k, w, h; for (k=2;k>0;k--) { rb->lcd_getstringsize( buttonChar[buttonGroup][btn_row][btn_col],&w,&h); rb->lcd_set_drawmode(DRMODE_SOLID|(k==1) ? 0 : DRMODE_INVERSEVID); rb->lcd_fillrect( X_0_POS + btn_col*REC_WIDTH + 1, Y_1_POS + btn_row*REC_HEIGHT + 1, REC_WIDTH - 1, REC_HEIGHT - 1); rb->lcd_putsxy( X_0_POS + btn_col*REC_WIDTH + (REC_WIDTH - w)/2, Y_1_POS + btn_row*REC_HEIGHT + (REC_HEIGHT - h)/2 +1, buttonChar[buttonGroup][btn_row][btn_col] ); rb->lcd_update_rect( X_0_POS + btn_col*REC_WIDTH + 1, Y_1_POS + btn_row*REC_HEIGHT + 1, REC_WIDTH - 1, REC_HEIGHT - 1); if (k!= 1) rb->sleep(HZ/22); } } /* ----------------------------------------------------------------------- pos is the position that needs animation. pos = [1~18] ----------------------------------------------------------------------- */ #if defined(CALCULATOR_CLEAR) || defined(CALCULATOR_OPERATORS) static void deleteAnimation(int pos) { int k, w, h, x; if (pos<1 || pos >18) return; rb->lcd_getstringsize("0", &w, &h); x = (pos==1? 4: LCD_WIDTH - 4 - w); for (k=0;k<4;k++){ rb->lcd_set_drawmode(DRMODE_SOLID|DRMODE_INVERSEVID); rb->lcd_fillrect(x, Y_1_POS - h -1, w, h); rb->lcd_set_drawmode(DRMODE_SOLID); rb->lcd_fillrect(x + (w*k)/8, Y_1_POS - h -1 + (h*k)/8, (w*(4-k))/4, (h*(4-k))/4); rb->lcd_update_rect(x, Y_1_POS - h -1, w, h); rb->sleep(HZ/32); } } #endif /* ----------------------------------------------------------------------- result may be one of these formats: 0 xxxx.xxxx 0.xxxx 0.0000xxxx formatResult() change result to standard format: 0.xxxx if result is close to 0, let it be 0; if result is close to 1, let it be 0.1 and power++; ----------------------------------------------------------------------- */ static void formatResult(void) { int resultsign = SIGN(result); result = ABS(result); if(result > MINIMUM ){ /* doesn't check power, might have problem input wouldn't, + - * / of two formatted number wouldn't. only a calculation that makes a formatted number (0.xxxx) less than MINIMUM in only one operation */ if (result<1){ while( (int)(result*10) == 0 ){ result *= 10; power--; modifier *= 10; } } else{ /* result >= 1 */ while( (int)result != 0 ){ result /= 10; power++; modifier /= 10; } } /* if result<1 */ if (result > (1-MINIMUM)){ result = 0.1; power++; modifier /= 10; } result *= resultsign; } else { result = 0; power = 0; modifier = 0.1; } } /* ----------------------------------------------------------------------- result2typingbuf() outputs standard format result to typingbuf. case SCIENTIFIC_FORMAT, let temppower = 1; case temppower > 0: print '.' in the middle case temppower <= 0: print '.' in the begining ----------------------------------------------------------------------- */ static void result2typingbuf(void) { bool haveDot = false; char tempchar = 0; int k; double tempresult = ABS(result); /* positive num makes things simple */ int temppower; double tempmodifier = 1; int count; if(SCIENTIFIC_FORMAT) temppower = 1; /* output x.xxxx format */ else temppower = power; cleartypingbuf(); if(tempresult < MINIMUM){ /* if 0,faster display and avoid complication*/ typingbuf[0] = ' '; typingbuf[1] = '0'; } else{ /* tempresult > 0 */ typingbuf[0] = (SIGN(result)<0)?'-':' '; typingbufPointer = typingbuf; if(temppower > 0){ for (k = 0; k (tempmodifier-MINIMUM)){ count++; } tempresult -= tempmodifier*count; tempresult = ABS(tempresult); temppower-- ; *typingbufPointer = count + '0'; } else{ /* temppower == 0 */ *typingbufPointer = '.'; haveDot = true; } } /* for */ } else{ haveDot = true; typingbufPointer++; *typingbufPointer = '0'; typingbufPointer++; *typingbufPointer = '.'; for (k = 2; k(tempmodifier-MINIMUM)){ count++; } tempresult -= tempmodifier*count; tempresult = ABS(tempresult); temppower-- ; } *typingbufPointer = count + '0'; } } /* now, typingbufPointer = typingbuf + 16 */ /* backward strip off 0 and '.' */ if (haveDot){ while( (*typingbufPointer == '0') || (*typingbufPointer == '.')){ tempchar = *typingbufPointer; *typingbufPointer = 0; typingbufPointer--; if (tempchar == '.') break; } } typingbuf[DIGITLEN+1] = 0; } /* else tempresult > 0 */ } /* ----------------------------------------------------------------------- printResult() generates LCD display. ----------------------------------------------------------------------- */ static void printResult(void) { int k, w, h; char operbuf[3] = {0, 0, 0}; switch_Status: switch(calStatus){ case cal_exit: rb->lcd_clear_display(); rb->splash(HZ/3, "Bye now!"); break; case cal_error: clearbuf(); rb->snprintf(buf, 19, "%18s","Error"); break; case cal_toDo: clearbuf(); rb->snprintf(buf, 19, "%18s","Coming soon ^_* "); break; case cal_normal: formatResult(); if( power > 1000 ){ /* power -1 > 999 */ calStatus = cal_error; goto switch_Status; } if (power < -998 ) /* power -1 < -999 */ clearResult(); /* too small, let it be 0 */ result2typingbuf(); clearbuf(); operbuf[0] = oper; operbuf[1] = ( ABS(memTemp) > MINIMUM )?'M':' '; operbuf[2] = '\0'; if(SCIENTIFIC_FORMAT){ /* output format: X.XXXX eXXX */ if(power > -98){ /* power-1 >= -99, eXXX or e-XX */ rb->snprintf(buf, 12, "%11s",typingbuf); for(k=11;k<=14;k++) buf[k] = ' '; cleartypingbuf(); rb->snprintf(typingbuf, 5, "e%d",power-1); rb->snprintf(buf+11, 5, "%4s",typingbuf); } else{ /* power-1 <= -100, e-XXX */ rb->snprintf(buf, 12, "%11s",typingbuf); rb->snprintf(buf+11, 6, "e%d",power-1); } } else{ rb->snprintf(buf, 12, "%11s",typingbuf); } /* if SCIENTIFIC_FORMAT */ break; case cal_typing: case cal_dotted: clearbuf(); operbuf[0] = oper; operbuf[1] = ( ABS(memTemp) > MINIMUM )?'M':' '; rb->snprintf(buf, 12, "%11s",typingbuf); break; } rb->lcd_getstringsize(buf, &w, &h); rb->screen_clear_area(rb->screens[0], 0, 0, LCD_WIDTH, Y_1_POS - 1); rb->lcd_putsxy(4, Y_1_POS - h -1, operbuf); rb->lcd_putsxy(LCD_WIDTH - w - 4, Y_1_POS - h -1, buf); rb->lcd_update_rect(0, 1, LCD_WIDTH, Y_1_POS); } /* ----------------------------------------------------------------------- Process typing buttons: 1-9, '.', sign main operand "result" and typingbuf are processed seperately here. ----------------------------------------------------------------------- */ static void typingProcess(void){ switch( CAL_BUTTON ){ case btn_sign: if (calStatus == cal_typing || calStatus == cal_dotted) typingbuf[0] = (typingbuf[0]=='-')?' ':'-'; result = -result; break; case btn_dot: operInputted = false; switch(calStatus){ case cal_normal: clearInput(); *typingbufPointer = '0'; typingbufPointer++; case cal_typing: calStatus = cal_dotted; *typingbufPointer = '.'; if (typingbufPointer != typingbuf+DIGITLEN+1) typingbufPointer++; break; default: /* cal_dotted */ break; } break; default: /* 0-9 */ operInputted = false; /* normal,0; normal,1-9; typing,0; typing,1-9 */ switch(calStatus){ case cal_normal: if(CAL_BUTTON == btn_0 ) break; /* first input is 0, ignore */ clearInput(); /*no operator means start a new calculation*/ if (oper ==' ') clearOperand(); calStatus = cal_typing; /* go on typing, no break */ case cal_typing: case cal_dotted: switch(CAL_BUTTON){ case btn_0: *typingbufPointer = '0'; break; default: *typingbufPointer=(7+btn_col-3*(btn_row-1))+ '0'; break; } if (typingbufPointer!=typingbuf+DIGITLEN+1){ typingbufPointer++; {/* result processing */ if (calStatus == cal_typing) power++; if (CAL_BUTTON != btn_0) result= result + SIGN(result)* (7+btn_col-3*(btn_row-1))*modifier; modifier /= 10; } } else /* last byte always '\0' */ *typingbufPointer = 0; break; default: /* cal_error, cal_exit */ break; } break; /* default, 0-9 */ } /* switch( CAL_BUTTON ) */ } /* ----------------------------------------------------------------------- Handle delete operation main operand "result" and typingbuf are processed seperately here. ----------------------------------------------------------------------- */ #ifdef CALCULATOR_CLEAR static void doDelete(void){ deleteAnimation(18); switch(calStatus){ case cal_dotted: if (*(typingbufPointer-1) == '.'){ /* if dotted and deleting '.', change status and delete '.' below */ calStatus = cal_typing; } else{ /* if dotted and not deleting '.', power stays */ power++; /* counter "power--;" below */ } case cal_typing: typingbufPointer--; {/* result processing */ /* 0-9, '.' */ /* if deleting '.', do nothing */ if ( *typingbufPointer != '.'){ power--; modifier *= 10; result = result - SIGN(result)* ((*typingbufPointer)- '0')*modifier; } } *typingbufPointer = 0; /* if (only one digit left and it's 0) or no digit left, change status*/ if ( typingbufPointer == typingbuf+1 || ( typingbufPointer == typingbuf+2 && *(typingbufPointer-1) == '0' )) calStatus = cal_normal; break; default: /* normal, error, exit */ break; } } #endif /* ----------------------------------------------------------------------- Handle buttons on basic screen ----------------------------------------------------------------------- */ static void basicButtonsProcess(void){ switch (btn) { case CALCULATOR_INPUT: if (calStatus == cal_error && (CAL_BUTTON != btn_C) ) break; flashButton(); switch( CAL_BUTTON ){ case btn_MR: operInputted = false; result = memTemp; power = memTempPower; calStatus = cal_normal; break; case btn_M: formatResult(); if (memTemp > MINIMUM) doAdd(&memTemp, &memTempPower, result, power); else { /* if result is too small and memTemp = 0, doAdd will not add */ memTemp = result; memTempPower = power; } calStatus = cal_normal; break; case btn_C: clearMem(); break; case btn_CE: clearInput(); break; case btn_bas: buttonGroup = sciButtons; printButtonGroups(buttonGroup); break; /* one operand calculation, may be changed to like sin, cos, log, etc */ case btn_sqr: case btn_square: case btn_rec: formatResult(); /* not necessary, just for safty */ oneOperand(); break; case_btn_equal: /* F3 shortkey entrance */ case btn_equal: formatResult(); calStatus = cal_normal; operInputted = false; if (oper != ' ') twoOperands(); break; case btn_div: case btn_time: case btn_minus: case btn_add: if(!operInputted) {twoOperands(); operInputted = true;} oper = buttonChar[basicButtons][btn_row][btn_col][0]; #ifdef CALCULATOR_OPERATORS case_cycle_operators: /* F2 shortkey entrance */ #endif calStatus = cal_normal; formatResult(); operand = result; operandPower = power; break; case btn_sign: case btn_dot: default: /* 0-9 */ typingProcess(); break; } /* switch (CAL_BUTTON) */ break; #ifdef CALCULATOR_OPERATORS case CALCULATOR_OPERATORS: if (calStatus == cal_error) break; if (!operInputted) {twoOperands(); operInputted = true;} switch (oper){ case ' ': case '/': oper = '+'; flashButton(); break; case '+': oper = '-'; flashButton(); break; case '-': oper = '*'; flashButton(); break; case '*': oper = '/'; flashButton(); break; } goto case_cycle_operators; break; #endif case CALCULATOR_CALC: if (calStatus == cal_error) break; flashButton(); goto case_btn_equal; break; default: break; } printResult(); } /* ----------------------------------------------------------------------- Handle buttons on scientific screen ----------------------------------------------------------------------- */ static void sciButtonsProcess(void){ switch (btn) { case CALCULATOR_INPUT: if (calStatus == cal_error && (CAL_BUTTON != sci_sci) ) break; flashButton(); switch( CAL_BUTTON ){ case sci_pi: result = M_PI; power = 0; calStatus = cal_normal; break; case sci_xy: /*Not implemented yet Maybe it could use x^y = exp(y*ln(x))*/ break; case sci_sci: buttonGroup = basicButtons; printButtonGroups(basicButtons); break; case sci_fac: case sci_sin: case sci_asin: case sci_cos: case sci_acos: case sci_tan: case sci_atan: case sci_ln: case sci_exp: case sci_log: formatResult(); /* not necessary, just for safty */ oneOperand(); break; case btn_sign: case btn_dot: default: /* 0-9 */ typingProcess(); break; } /* switch (CAL_BUTTON) */ break; #ifdef CALCULATOR_OPERATORS case CALCULATOR_OPERATORS: if (calStatus == cal_error) break; if (!operInputted) {twoOperands(); operInputted = true;} switch (oper){ case ' ': oper = '+'; break; case '/': oper = '+'; deleteAnimation(1); break; case '+': oper = '-'; deleteAnimation(1); break; case '-': oper = '*'; deleteAnimation(1); break; case '*': oper = '/'; deleteAnimation(1); break; } calStatus = cal_normal; formatResult(); operand = result; operandPower = power; break; #endif case CALCULATOR_CALC: if (calStatus == cal_error) break; formatResult(); calStatus = cal_normal; operInputted = false; if (oper != ' ') twoOperands(); break; default: break; } printResult(); } /* ----------------------------------------------------------------------- move button index Invert display new button, invert back previous button ----------------------------------------------------------------------- */ static int handleButton(int button){ switch(button) { case CALCULATOR_INPUT: case CALCULATOR_CALC: #ifdef CALCULATOR_INPUT_CALC_PRE if (lastbtn != CALCULATOR_INPUT_CALC_PRE) break; /* no unconditional break; here! */ #endif #ifdef CALCULATOR_OPERATORS case CALCULATOR_OPERATORS: #endif switch(buttonGroup){ case basicButtons: basicButtonsProcess(); break; case sciButtons: sciButtonsProcess(); break; } break; #ifdef CALCULATOR_CLEAR case CALCULATOR_CLEAR: switch(calStatus){ case cal_typing: case cal_dotted: doDelete(); break; default: /* cal_normal, cal_error, cal_exit */ clearMem(); break; } printResult(); break; #endif case CALCULATOR_LEFT: case CALCULATOR_LEFT | BUTTON_REPEAT: move_with_wrap_and_shift( &btn_col, -1, BUTTON_COLS, &btn_row, 0, BUTTON_ROWS); break; case CALCULATOR_RIGHT: case CALCULATOR_RIGHT | BUTTON_REPEAT: move_with_wrap_and_shift( &btn_col, 1, BUTTON_COLS, &btn_row, 0, BUTTON_ROWS); break; #ifdef CALCULATOR_UP case CALCULATOR_UP: case CALCULATOR_UP | BUTTON_REPEAT: move_with_wrap_and_shift( &btn_row, -1, BUTTON_ROWS, &btn_col, 0, BUTTON_COLS); break; #endif #ifdef CALCULATOR_DOWN case CALCULATOR_DOWN: case CALCULATOR_DOWN | BUTTON_REPEAT: move_with_wrap_and_shift( &btn_row, 1, BUTTON_ROWS, &btn_col, 0, BUTTON_COLS); break; #endif #ifdef CALCULATOR_UP_W_SHIFT case CALCULATOR_UP_W_SHIFT: case CALCULATOR_UP_W_SHIFT | BUTTON_REPEAT: move_with_wrap_and_shift( &btn_row, -1, BUTTON_ROWS, &btn_col, -1, BUTTON_COLS); break; #endif #ifdef CALCULATOR_DOWN_W_SHIFT case CALCULATOR_DOWN_W_SHIFT: case CALCULATOR_DOWN_W_SHIFT | BUTTON_REPEAT: move_with_wrap_and_shift( &btn_row, 1, BUTTON_ROWS, &btn_col, 1, BUTTON_COLS); break; #endif #ifdef CALCULATOR_LEFT_W_SHIFT case CALCULATOR_LEFT_W_SHIFT: case CALCULATOR_LEFT_W_SHIFT | BUTTON_REPEAT: move_with_wrap_and_shift( &btn_col, -1, BUTTON_COLS, &btn_row, -1, BUTTON_ROWS); break; #endif #ifdef CALCULATOR_RIGHT_W_SHIFT case CALCULATOR_RIGHT_W_SHIFT: case CALCULATOR_RIGHT_W_SHIFT | BUTTON_REPEAT: move_with_wrap_and_shift( &btn_col, 1, BUTTON_COLS, &btn_row, 1, BUTTON_ROWS); break; #endif #ifdef CALCULATOR_RC_QUIT case CALCULATOR_RC_QUIT: #endif case CALCULATOR_QUIT: return -1; } return 0; } /* ----------------------------------------------------------------------- Main(); ----------------------------------------------------------------------- */ enum plugin_status plugin_start(const void* parameter) { (void)parameter; /* now go ahead and have fun! */ #ifdef HAVE_TOUCHSCREEN rb->touchscreen_set_mode(TOUCHSCREEN_POINT); #endif cal_initial(); while (calStatus != cal_exit ) { btn = rb->button_get_w_tmo(HZ/2); #ifdef HAVE_TOUCHSCREEN if(btn & BUTTON_TOUCHSCREEN) { struct ts_raster_result res; if(touchscreen_map_raster(&calc_raster, rb->button_get_data() >> 16, rb->button_get_data() & 0xffff, &res) == 1) { btn_row = res.y; btn_col = res.x; drawButtons(buttonGroup); drawLines(); rb->lcd_update(); prev_btn_row = btn_row; prev_btn_col = btn_col; if(btn & BUTTON_REL) { btn = CALCULATOR_INPUT; switch(buttonGroup){ case basicButtons: basicButtonsProcess(); break; case sciButtons: sciButtonsProcess(); break; } btn = BUTTON_TOUCHSCREEN; } } } #endif if (handleButton(btn) == -1) { calStatus = cal_exit; printResult(); } else { drawButtons(buttonGroup); drawLines(); } rb->lcd_update(); if(rb->default_event_handler(btn) == SYS_USB_CONNECTED) return PLUGIN_USB_CONNECTED; if (btn != BUTTON_NONE) lastbtn = btn; } /* while (calStatus != cal_exit ) */ rb->button_clear_queue(); return PLUGIN_OK; }