crashtest-r0ket/firmware/l0dable/nick_life.c

247 lines
6.1 KiB
C

#include <sysinit.h>
#include "basic/basic.h"
#include "lcd/render.h"
#include "lcd/display.h"
#include "basic/config.h"
#include "usetable.h"
#define BITSET_X (RESX+2)
#define BITSET_Y (RESY+2)
#define BITSET_SIZE (BITSET_X*BITSET_Y)
#define BITSETCHUNKSIZE 32
#define one ((uint32_t)1)
struct bitset {
uint16_t size;
uint32_t bits[BITSET_SIZE/BITSETCHUNKSIZE+1];
};
typedef uint8_t uchar;
int pattern=0;
#define PATTERNCOUNT 3
uchar stepmode=0;
uchar randdensity=0;
//uint8_t bl=0;
struct bitset _buf1,*buf1=&_buf1;
struct bitset _buf2,*buf2=&_buf2;
struct bitset *life =&_buf1;
struct bitset *new =&_buf2;
static void draw_area();
static void calc_area();
static void random_area(struct bitset *area, uchar x0, uchar y0, uchar x1, uchar y1,uchar value);
static void reset_area();
static void nextledcycle();
void ram(void) {
getInputWaitRelease();
reset_area();
random_area(life,1,1,RESX,RESY,40);
lcdClear();
setExtFont(GLOBAL(nickfont));
DoString(20,20,GLOBAL(nickname));
#if 0
gpioSetValue (RB_LED0, CFG_LED_ON);
gpioSetValue (RB_LED1, CFG_LED_ON);
gpioSetValue (RB_LED2, CFG_LED_ON);
gpioSetValue (RB_LED3, CFG_LED_ON);
#endif
while (1) {
draw_area(); // xor life pattern over display content
lcdDisplay();
draw_area(); // xor life pattern again to restore original display content
lcdShift(1,-2,1);
if(getInputRaw())
return;
delayms_queue(10);
calc_area();
}
return;
}
static inline void bitset_set(struct bitset *bs,uint16_t index, uint8_t value) {
uint16_t base=index/BITSETCHUNKSIZE;
uint16_t offset=index%BITSETCHUNKSIZE;
if(value) {
bs->bits[base]|=(one<<offset);
} else {
bs->bits[base]&=~(one<<offset);
}
}
static inline void bitset_xor(struct bitset *bs,uint16_t index, uint8_t value) {
uint16_t base=index/BITSETCHUNKSIZE;
uint16_t offset=index%BITSETCHUNKSIZE;
if(value) {
bs->bits[base]^=(one<<offset);
}
}
static inline uint8_t bitset_get(struct bitset *bs,uint16_t index) {
uint16_t base=index/BITSETCHUNKSIZE;
uint16_t offset=index%BITSETCHUNKSIZE;
return (bs->bits[base]&(one<<offset))==(one<<offset);;
}
static inline uint16_t bitset_offset2(uint8_t x, uint8_t y) {
return ((uint16_t)x)+((uint16_t)y)*BITSET_X;
}
static inline void bitset_set2(struct bitset *bs, uint8_t x, uint8_t y, uint8_t value) {
bitset_set(bs,bitset_offset2(x,y),value);
}
static inline void bitset_xor2(struct bitset *bs, uint8_t x, uint8_t y, uint8_t value) {
bitset_xor(bs,bitset_offset2(x,y),value);
}
static inline uint8_t bitset_get2(struct bitset *bs,uint8_t x,uint8_t y) {
return bitset_get(bs,bitset_offset2(x,y));
}
static void draw_rect(char x0, char y0, char x1, char y1) {
for(char x=x0; x<=x1; ++x) {
lcdSetPixel(x,y0,true);
lcdSetPixel(x,y1,true);
}
for(char y=y0+1; y<y1; ++y) {
lcdSetPixel(x0,y,true);
lcdSetPixel(x1,y,true);
}
}
static void fill_rect(char x0, char y0, char x1, char y1) {
for(char x=x0; x<=x1; ++x) {
for(char y=y0; y<=y1; ++y) {
lcdSetPixel(x,y,true);
}
}
}
#define STARTVALUE 10
static void swap_areas() {
struct bitset *tmp=life;
life=new;
new=tmp;
}
static void fill_area(struct bitset *area, uchar x0, uchar y0, uchar x1, uchar y1,uchar value) {
for(uchar x=x0; x<=x1; ++x) {
for(uchar y=y0; y<=y1; ++y) {
bitset_set2(area,x,y,value);
}
}
}
static bool find_area(struct bitset *area, uchar x0, uchar y0, uchar x1, uchar y1,uchar value) {
for(uchar x=x0; x<=x1; ++x) {
for(uchar y=y0; y<=y1; ++y) {
if(bitset_get2(area,x,y)==value) return true;
}
}
return false;
}
static uint32_t sum_area(struct bitset *area, uchar x0, uchar y0, uchar x1, uchar y1) {
uint32_t sum=0;
for(uchar x=x0; x<=x1; ++x) {
for(uchar y=y0; y<=y1; ++y) {
sum+=bitset_get2(area,x,y);
}
}
return sum;
}
static void draw_area() {
for(uchar x=0; x<RESX; ++x) {
for(uchar y=0; y<RESY; ++y) {
lcdSetPixel(x,y,lcdGetPixel(x,y)^bitset_get2(life,x+1,y+1));
}
}
}
static void calc_area() {
#ifdef SIMULATOR
static unsigned long iter=0;
fprintf(stderr,"Iteration %d \n",++iter);
#endif
for(uchar x=1; x<=RESX; ++x) {
for(uchar y=1; y<=RESY; ++y) {
uchar sum=sum_area(life,x-1,y-1,x+1,y+1)-bitset_get2(life,x,y);
bitset_set2(new,x,y,sum==3||(sum==2&&bitset_get2(life,x,y)));
}
}
swap_areas();
}
static void reset_area() {
fill_area(life,0,0,RESX+1,RESY+1,0);
fill_area(new,0,0,RESX+1,RESY+1,0);
switch(pattern) {
case 0:
bitset_set2(life,41,40,1);
bitset_set2(life,42,40,1);
bitset_set2(life,41,41,1);
bitset_set2(life,40,41,1);
bitset_set2(life,41,42,1);
break;
#if 0
case 1:
for(int i=0; i<RESX/2; ++i) bitset_set2(life,i,0,1);
bitset_set2(life,40,40,1);
bitset_set2(life,41,40,1);
bitset_set2(life,41,41,1);
break;
case 2:
bitset_set2(life,40,40,1);
bitset_set2(life,41,40,1);
bitset_set2(life,42,40,1);
bitset_set2(life,42,41,1);
bitset_set2(life,42,42,1);
bitset_set2(life,40,41,1);
bitset_set2(life,40,42,1);
break;
#endif
}
}
static void random_area(struct bitset *area, uchar x0, uchar y0, uchar x1, uchar y1,uchar value) {
for(uchar x=x0; x<=x1; ++x) {
for(uchar y=y0; y<=y1; ++y) {
bitset_set2(area,x,y,(getRandom()>>24)<value);
}
}
}
#define LEDINTERVAL 1
static void nextledcycle() {
static uint8_t ledcycle=3;
ledcycle=(ledcycle+1)%(8*LEDINTERVAL);
uint8_t a=ledcycle/LEDINTERVAL;
switch(a) {
case 0: gpioSetValue (RB_LED0, CFG_LED_ON); break;
case 4: gpioSetValue (RB_LED0, CFG_LED_OFF); break;
case 1: gpioSetValue (RB_LED1, CFG_LED_ON); break;
case 5: gpioSetValue (RB_LED1, CFG_LED_OFF); break;
case 2: gpioSetValue (RB_LED2, CFG_LED_ON); break;
case 6: gpioSetValue (RB_LED2, CFG_LED_OFF); break;
case 3: gpioSetValue (RB_LED3, CFG_LED_ON); break;
case 7: gpioSetValue (RB_LED3, CFG_LED_OFF); break;
}
}