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noise.cpp
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noise.cpp
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#define FASTLED_INTERNAL
#include "FastLED.h"
#include <string.h>
FASTLED_NAMESPACE_BEGIN
#define P(x) FL_PGM_READ_BYTE_NEAR(p + x)
FL_PROGMEM static uint8_t const p[] = {
151, 160, 137, 91, 90, 15, 131, 13, 201, 95, 96, 53, 194, 233, 7, 225,
140, 36, 103, 30, 69, 142, 8, 99, 37, 240, 21, 10, 23, 190, 6, 148,
247, 120, 234, 75, 0, 26, 197, 62, 94, 252, 219, 203, 117, 35, 11, 32,
57, 177, 33, 88, 237, 149, 56, 87, 174, 20, 125, 136, 171, 168, 68, 175,
74, 165, 71, 134, 139, 48, 27, 166, 77, 146, 158, 231, 83, 111, 229, 122,
60, 211, 133, 230, 220, 105, 92, 41, 55, 46, 245, 40, 244, 102, 143, 54,
65, 25, 63, 161, 1, 216, 80, 73, 209, 76, 132, 187, 208, 89, 18, 169,
200, 196, 135, 130, 116, 188, 159, 86, 164, 100, 109, 198, 173, 186, 3, 64,
52, 217, 226, 250, 124, 123, 5, 202, 38, 147, 118, 126, 255, 82, 85, 212,
207, 206, 59, 227, 47, 16, 58, 17, 182, 189, 28, 42, 223, 183, 170, 213,
119, 248, 152, 2, 44, 154, 163, 70, 221, 153, 101, 155, 167, 43, 172, 9,
129, 22, 39, 253, 19, 98, 108, 110, 79, 113, 224, 232, 178, 185, 112, 104,
218, 246, 97, 228, 251, 34, 242, 193, 238, 210, 144, 12, 191, 179, 162, 241,
81, 51, 145, 235, 249, 14, 239, 107, 49, 192, 214, 31, 181, 199, 106, 157,
184, 84, 204, 176, 115, 121, 50, 45, 127, 4, 150, 254, 138, 236, 205, 93,
222, 114, 67, 29, 24, 72, 243, 141, 128, 195, 78, 66, 215, 61, 156, 180,
151};
#if FASTLED_NOISE_ALLOW_AVERAGE_TO_OVERFLOW == 1
#define AVG15(U,V) (((U)+(V)) >> 1)
#else
// See if we should use the inlined avg15 for AVR with MUL instruction
#if defined(__AVR__) && (LIB8_ATTINY == 0)
#define AVG15(U,V) (avg15_inline_avr_mul((U),(V)))
// inlined copy of avg15 for AVR with MUL instruction; cloned from math8.h
// Forcing this inline in the 3-D 16bit noise produces a 12% speedup overall,
// at a cost of just +8 bytes of net code size.
static int16_t inline __attribute__((always_inline)) avg15_inline_avr_mul( int16_t i, int16_t j)
{
asm volatile(
/* first divide j by 2, throwing away lowest bit */
"asr %B[j] \n\t"
"ror %A[j] \n\t"
/* now divide i by 2, with lowest bit going into C */
"asr %B[i] \n\t"
"ror %A[i] \n\t"
/* add j + C to i */
"adc %A[i], %A[j] \n\t"
"adc %B[i], %B[j] \n\t"
: [i] "+a" (i)
: [j] "a" (j) );
return i;
}
#else
#define AVG15(U,V) (avg15((U),(V)))
#endif
#endif
// See fastled_config.h for notes on this;
// "#define FASTLED_NOISE_FIXED 1" is the correct value
#if FASTLED_NOISE_FIXED == 0
#define EASE8(x) (FADE(x) )
#define EASE16(x) (FADE(x) )
#else
#define EASE8(x) (ease8InOutQuad(x) )
#define EASE16(x) (ease16InOutQuad(x))
#endif
//
// #define FADE_12
#define FADE_16
#ifdef FADE_12
#define FADE logfade12
#define LERP(a,b,u) lerp15by12(a,b,u)
#else
#define FADE(x) scale16(x,x)
#define LERP(a,b,u) lerp15by16(a,b,u)
#endif
static int16_t inline __attribute__((always_inline)) grad16(uint8_t hash, int16_t x, int16_t y, int16_t z) {
#if 0
switch(hash & 0xF) {
case 0: return (( x) + ( y))>>1;
case 1: return ((-x) + ( y))>>1;
case 2: return (( x) + (-y))>>1;
case 3: return ((-x) + (-y))>>1;
case 4: return (( x) + ( z))>>1;
case 5: return ((-x) + ( z))>>1;
case 6: return (( x) + (-z))>>1;
case 7: return ((-x) + (-z))>>1;
case 8: return (( y) + ( z))>>1;
case 9: return ((-y) + ( z))>>1;
case 10: return (( y) + (-z))>>1;
case 11: return ((-y) + (-z))>>1;
case 12: return (( y) + ( x))>>1;
case 13: return ((-y) + ( z))>>1;
case 14: return (( y) + (-x))>>1;
case 15: return ((-y) + (-z))>>1;
}
#else
hash = hash&15;
int16_t u = hash<8?x:y;
int16_t v = hash<4?y:hash==12||hash==14?x:z;
if(hash&1) { u = -u; }
if(hash&2) { v = -v; }
return AVG15(u,v);
#endif
}
static int16_t inline __attribute__((always_inline)) grad16(uint8_t hash, int16_t x, int16_t y) {
hash = hash & 7;
int16_t u,v;
if(hash < 4) { u = x; v = y; } else { u = y; v = x; }
if(hash&1) { u = -u; }
if(hash&2) { v = -v; }
return AVG15(u,v);
}
static int16_t inline __attribute__((always_inline)) grad16(uint8_t hash, int16_t x) {
hash = hash & 15;
int16_t u,v;
if(hash > 8) { u=x;v=x; }
else if(hash < 4) { u=x;v=1; }
else { u=1;v=x; }
if(hash&1) { u = -u; }
if(hash&2) { v = -v; }
return AVG15(u,v);
}
// selectBasedOnHashBit performs this:
// result = (hash & (1<<bitnumber)) ? a : b
// but with an AVR asm version that's smaller and quicker than C
// (and probably not worth including in lib8tion)
static int8_t inline __attribute__((always_inline)) selectBasedOnHashBit(uint8_t hash, uint8_t bitnumber, int8_t a, int8_t b) {
int8_t result;
#if !defined(__AVR__)
result = (hash & (1<<bitnumber)) ? a : b;
#else
asm volatile(
"mov %[result],%[a] \n\t"
"sbrs %[hash],%[bitnumber] \n\t"
"mov %[result],%[b] \n\t"
: [result] "=r" (result)
: [hash] "r" (hash),
[bitnumber] "M" (bitnumber),
[a] "r" (a),
[b] "r" (b)
);
#endif
return result;
}
static int8_t inline __attribute__((always_inline)) grad8(uint8_t hash, int8_t x, int8_t y, int8_t z) {
#if 0
switch(hash & 0xF) {
case 0: return (( x) + ( y))>>1;
case 1: return ((-x) + ( y))>>1;
case 2: return (( x) + (-y))>>1;
case 3: return ((-x) + (-y))>>1;
case 4: return (( x) + ( z))>>1;
case 5: return ((-x) + ( z))>>1;
case 6: return (( x) + (-z))>>1;
case 7: return ((-x) + (-z))>>1;
case 8: return (( y) + ( z))>>1;
case 9: return ((-y) + ( z))>>1;
case 10: return (( y) + (-z))>>1;
case 11: return ((-y) + (-z))>>1;
case 12: return (( y) + ( x))>>1;
case 13: return ((-y) + ( z))>>1;
case 14: return (( y) + (-x))>>1;
case 15: return ((-y) + (-z))>>1;
}
#else
hash &= 0xF;
int8_t u, v;
//u = (hash&8)?y:x;
u = selectBasedOnHashBit( hash, 3, y, x);
#if 1
v = hash<4?y:hash==12||hash==14?x:z;
#else
// Verbose version for analysis; generates idenitical code.
if( hash < 4) { // 00 01 02 03
v = y;
} else {
if( hash==12 || hash==14) { // 0C 0E
v = x;
} else {
v = z; // 04 05 06 07 08 09 0A 0B 0D 0F
}
}
#endif
if(hash&1) { u = -u; }
if(hash&2) { v = -v; }
return avg7(u,v);
#endif
}
static int8_t inline __attribute__((always_inline)) grad8(uint8_t hash, int8_t x, int8_t y)
{
// since the tests below can be done bit-wise on the bottom
// three bits, there's no need to mask off the higher bits
// hash = hash & 7;
int8_t u,v;
if( hash & 4) {
u = y; v = x;
} else {
u = x; v = y;
}
if(hash&1) { u = -u; }
if(hash&2) { v = -v; }
return avg7(u,v);
}
static int8_t inline __attribute__((always_inline)) grad8(uint8_t hash, int8_t x)
{
// since the tests below can be done bit-wise on the bottom
// four bits, there's no need to mask off the higher bits
// hash = hash & 15;
int8_t u,v;
if(hash & 8) {
u=x; v=x;
} else {
if(hash & 4) {
u=1; v=x;
} else {
u=x; v=1;
}
}
if(hash&1) { u = -u; }
if(hash&2) { v = -v; }
return avg7(u,v);
}
#ifdef FADE_12
uint16_t logfade12(uint16_t val) {
return scale16(val,val)>>4;
}
static int16_t inline __attribute__((always_inline)) lerp15by12( int16_t a, int16_t b, fract16 frac)
{
//if(1) return (lerp(frac,a,b));
int16_t result;
if( b > a) {
uint16_t delta = b - a;
uint16_t scaled = scale16(delta,frac<<4);
result = a + scaled;
} else {
uint16_t delta = a - b;
uint16_t scaled = scale16(delta,frac<<4);
result = a - scaled;
}
return result;
}
#endif
static int8_t inline __attribute__((always_inline)) lerp7by8( int8_t a, int8_t b, fract8 frac)
{
// int8_t delta = b - a;
// int16_t prod = (uint16_t)delta * (uint16_t)frac;
// int8_t scaled = prod >> 8;
// int8_t result = a + scaled;
// return result;
int8_t result;
if( b > a) {
uint8_t delta = b - a;
uint8_t scaled = scale8( delta, frac);
result = a + scaled;
} else {
uint8_t delta = a - b;
uint8_t scaled = scale8( delta, frac);
result = a - scaled;
}
return result;
}
int16_t inoise16_raw(uint32_t x, uint32_t y, uint32_t z)
{
// Find the unit cube containing the point
uint8_t X = (x>>16)&0xFF;
uint8_t Y = (y>>16)&0xFF;
uint8_t Z = (z>>16)&0xFF;
// Hash cube corner coordinates
uint8_t A = P(X)+Y;
uint8_t AA = P(A)+Z;
uint8_t AB = P(A+1)+Z;
uint8_t B = P(X+1)+Y;
uint8_t BA = P(B) + Z;
uint8_t BB = P(B+1)+Z;
// Get the relative position of the point in the cube
uint16_t u = x & 0xFFFF;
uint16_t v = y & 0xFFFF;
uint16_t w = z & 0xFFFF;
// Get a signed version of the above for the grad function
int16_t xx = (u >> 1) & 0x7FFF;
int16_t yy = (v >> 1) & 0x7FFF;
int16_t zz = (w >> 1) & 0x7FFF;
uint16_t N = 0x8000L;
u = EASE16(u); v = EASE16(v); w = EASE16(w);
// skip the log fade adjustment for the moment, otherwise here we would
// adjust fade values for u,v,w
int16_t X1 = LERP(grad16(P(AA), xx, yy, zz), grad16(P(BA), xx - N, yy, zz), u);
int16_t X2 = LERP(grad16(P(AB), xx, yy-N, zz), grad16(P(BB), xx - N, yy - N, zz), u);
int16_t X3 = LERP(grad16(P(AA+1), xx, yy, zz-N), grad16(P(BA+1), xx - N, yy, zz-N), u);
int16_t X4 = LERP(grad16(P(AB+1), xx, yy-N, zz-N), grad16(P(BB+1), xx - N, yy - N, zz - N), u);
int16_t Y1 = LERP(X1,X2,v);
int16_t Y2 = LERP(X3,X4,v);
int16_t ans = LERP(Y1,Y2,w);
return ans;
}
uint16_t inoise16(uint32_t x, uint32_t y, uint32_t z) {
int32_t ans = inoise16_raw(x,y,z);
ans = ans + 19052L;
uint32_t pan = ans;
// pan = (ans * 220L) >> 7. That's the same as:
// pan = (ans * 440L) >> 8. And this way avoids a 7X four-byte shift-loop on AVR.
// Identical math, except for the highest bit, which we don't care about anyway,
// since we're returning the 'middle' 16 out of a 32-bit value anyway.
pan *= 440L;
return (pan>>8);
// // return scale16by8(pan,220)<<1;
// return ((inoise16_raw(x,y,z)+19052)*220)>>7;
// return scale16by8(inoise16_raw(x,y,z)+19052,220)<<1;
}
int16_t inoise16_raw(uint32_t x, uint32_t y)
{
// Find the unit cube containing the point
uint8_t X = x>>16;
uint8_t Y = y>>16;
// Hash cube corner coordinates
uint8_t A = P(X)+Y;
uint8_t AA = P(A);
uint8_t AB = P(A+1);
uint8_t B = P(X+1)+Y;
uint8_t BA = P(B);
uint8_t BB = P(B+1);
// Get the relative position of the point in the cube
uint16_t u = x & 0xFFFF;
uint16_t v = y & 0xFFFF;
// Get a signed version of the above for the grad function
int16_t xx = (u >> 1) & 0x7FFF;
int16_t yy = (v >> 1) & 0x7FFF;
uint16_t N = 0x8000L;
u = EASE16(u); v = EASE16(v);
int16_t X1 = LERP(grad16(P(AA), xx, yy), grad16(P(BA), xx - N, yy), u);
int16_t X2 = LERP(grad16(P(AB), xx, yy-N), grad16(P(BB), xx - N, yy - N), u);
int16_t ans = LERP(X1,X2,v);
return ans;
}
uint16_t inoise16(uint32_t x, uint32_t y) {
int32_t ans = inoise16_raw(x,y);
ans = ans + 17308L;
uint32_t pan = ans;
// pan = (ans * 242L) >> 7. That's the same as:
// pan = (ans * 484L) >> 8. And this way avoids a 7X four-byte shift-loop on AVR.
// Identical math, except for the highest bit, which we don't care about anyway,
// since we're returning the 'middle' 16 out of a 32-bit value anyway.
pan *= 484L;
return (pan>>8);
// return (uint32_t)(((int32_t)inoise16_raw(x,y)+(uint32_t)17308)*242)>>7;
// return scale16by8(inoise16_raw(x,y)+17308,242)<<1;
}
int16_t inoise16_raw(uint32_t x)
{
// Find the unit cube containing the point
uint8_t X = x>>16;
// Hash cube corner coordinates
uint8_t A = P(X);
uint8_t AA = P(A);
uint8_t B = P(X+1);
uint8_t BA = P(B);
// Get the relative position of the point in the cube
uint16_t u = x & 0xFFFF;
// Get a signed version of the above for the grad function
int16_t xx = (u >> 1) & 0x7FFF;
uint16_t N = 0x8000L;
u = EASE16(u);
int16_t ans = LERP(grad16(P(AA), xx), grad16(P(BA), xx - N), u);
return ans;
}
uint16_t inoise16(uint32_t x) {
return ((uint32_t)((int32_t)inoise16_raw(x) + 17308L)) << 1;
}
int8_t inoise8_raw(uint16_t x, uint16_t y, uint16_t z)
{
// Find the unit cube containing the point
uint8_t X = x>>8;
uint8_t Y = y>>8;
uint8_t Z = z>>8;
// Hash cube corner coordinates
uint8_t A = P(X)+Y;
uint8_t AA = P(A)+Z;
uint8_t AB = P(A+1)+Z;
uint8_t B = P(X+1)+Y;
uint8_t BA = P(B) + Z;
uint8_t BB = P(B+1)+Z;
// Get the relative position of the point in the cube
uint8_t u = x;
uint8_t v = y;
uint8_t w = z;
// Get a signed version of the above for the grad function
int8_t xx = ((uint8_t)(x)>>1) & 0x7F;
int8_t yy = ((uint8_t)(y)>>1) & 0x7F;
int8_t zz = ((uint8_t)(z)>>1) & 0x7F;
uint8_t N = 0x80;
u = EASE8(u); v = EASE8(v); w = EASE8(w);
int8_t X1 = lerp7by8(grad8(P(AA), xx, yy, zz), grad8(P(BA), xx - N, yy, zz), u);
int8_t X2 = lerp7by8(grad8(P(AB), xx, yy-N, zz), grad8(P(BB), xx - N, yy - N, zz), u);
int8_t X3 = lerp7by8(grad8(P(AA+1), xx, yy, zz-N), grad8(P(BA+1), xx - N, yy, zz-N), u);
int8_t X4 = lerp7by8(grad8(P(AB+1), xx, yy-N, zz-N), grad8(P(BB+1), xx - N, yy - N, zz - N), u);
int8_t Y1 = lerp7by8(X1,X2,v);
int8_t Y2 = lerp7by8(X3,X4,v);
int8_t ans = lerp7by8(Y1,Y2,w);
return ans;
}
uint8_t inoise8(uint16_t x, uint16_t y, uint16_t z) {
//return scale8(76+(inoise8_raw(x,y,z)),215)<<1;
int8_t n = inoise8_raw( x, y, z); // -64..+64
n+= 64; // 0..128
uint8_t ans = qadd8( n, n); // 0..255
return ans;
}
int8_t inoise8_raw(uint16_t x, uint16_t y)
{
// Find the unit cube containing the point
uint8_t X = x>>8;
uint8_t Y = y>>8;
// Hash cube corner coordinates
uint8_t A = P(X)+Y;
uint8_t AA = P(A);
uint8_t AB = P(A+1);
uint8_t B = P(X+1)+Y;
uint8_t BA = P(B);
uint8_t BB = P(B+1);
// Get the relative position of the point in the cube
uint8_t u = x;
uint8_t v = y;
// Get a signed version of the above for the grad function
int8_t xx = ((uint8_t)(x)>>1) & 0x7F;
int8_t yy = ((uint8_t)(y)>>1) & 0x7F;
uint8_t N = 0x80;
u = EASE8(u); v = EASE8(v);
int8_t X1 = lerp7by8(grad8(P(AA), xx, yy), grad8(P(BA), xx - N, yy), u);
int8_t X2 = lerp7by8(grad8(P(AB), xx, yy-N), grad8(P(BB), xx - N, yy - N), u);
int8_t ans = lerp7by8(X1,X2,v);
return ans;
// return scale8((70+(ans)),234)<<1;
}
uint8_t inoise8(uint16_t x, uint16_t y) {
//return scale8(69+inoise8_raw(x,y),237)<<1;
int8_t n = inoise8_raw( x, y); // -64..+64
n+= 64; // 0..128
uint8_t ans = qadd8( n, n); // 0..255
return ans;
}
// output range = -64 .. +64
int8_t inoise8_raw(uint16_t x)
{
// Find the unit cube containing the point
uint8_t X = x>>8;
// Hash cube corner coordinates
uint8_t A = P(X);
uint8_t AA = P(A);
uint8_t B = P(X+1);
uint8_t BA = P(B);
// Get the relative position of the point in the cube
uint8_t u = x;
// Get a signed version of the above for the grad function
int8_t xx = ((uint8_t)(x)>>1) & 0x7F;
uint8_t N = 0x80;
u = EASE8( u);
int8_t ans = lerp7by8(grad8(P(AA), xx), grad8(P(BA), xx - N), u);
return ans;
}
uint8_t inoise8(uint16_t x) {
int8_t n = inoise8_raw(x); //-64..+64
n += 64; // 0..128
uint8_t ans = qadd8(n,n); // 0..255
return ans;
}
// struct q44 {
// uint8_t i:4;
// uint8_t f:4;
// q44(uint8_t _i, uint8_t _f) {i=_i; f=_f; }
// };
// uint32_t mul44(uint32_t v, q44 mulby44) {
// return (v *mulby44.i) + ((v * mulby44.f) >> 4);
// }
//
// uint16_t mul44_16(uint16_t v, q44 mulby44) {
// return (v *mulby44.i) + ((v * mulby44.f) >> 4);
// }
void fill_raw_noise8(uint8_t *pData, uint8_t num_points, uint8_t octaves, uint16_t x, int scale, uint16_t time) {
uint32_t _xx = x;
uint32_t scx = scale;
for(int o = 0; o < octaves; o++) {
for(int i = 0,xx=_xx; i < num_points; i++, xx+=scx) {
pData[i] = qadd8(pData[i],inoise8(xx,time)>>o);
}
_xx <<= 1;
scx <<= 1;
}
}
void fill_raw_noise16into8(uint8_t *pData, uint8_t num_points, uint8_t octaves, uint32_t x, int scale, uint32_t time) {
uint32_t _xx = x;
uint32_t scx = scale;
for(int o = 0; o < octaves; o++) {
for(int i = 0,xx=_xx; i < num_points; i++, xx+=scx) {
uint32_t accum = (inoise16(xx,time))>>o;
accum += (pData[i]<<8);
if(accum > 65535) { accum = 65535; }
pData[i] = accum>>8;
}
_xx <<= 1;
scx <<= 1;
}
}
void fill_raw_2dnoise8(uint8_t *pData, int width, int height, uint8_t octaves, q44 freq44, fract8 amplitude, int skip, uint16_t x, int scalex, uint16_t y, int scaley, uint16_t time) {
if(octaves > 1) {
fill_raw_2dnoise8(pData, width, height, octaves-1, freq44, amplitude, skip+1, x*freq44, freq44 * scalex, y*freq44, freq44 * scaley, time);
} else {
// amplitude is always 255 on the lowest level
amplitude=255;
}
scalex *= skip;
scaley *= skip;
fract8 invamp = 255-amplitude;
uint16_t xx = x;
for(int i = 0; i < height; i++, y+=scaley) {
uint8_t *pRow = pData + (i*width);
xx = x;
for(int j = 0; j < width; j++, xx+=scalex) {
uint8_t noise_base = inoise8(xx,y,time);
noise_base = (0x80 & noise_base) ? (noise_base - 127) : (127 - noise_base);
noise_base = scale8(noise_base<<1,amplitude);
if(skip == 1) {
pRow[j] = scale8(pRow[j],invamp) + noise_base;
} else {
for(int ii = i; ii<(i+skip) && ii<height; ii++) {
uint8_t *pRow = pData + (ii*width);
for(int jj=j; jj<(j+skip) && jj<width; jj++) {
pRow[jj] = scale8(pRow[jj],invamp) + noise_base;
}
}
}
}
}
}
void fill_raw_2dnoise8(uint8_t *pData, int width, int height, uint8_t octaves, uint16_t x, int scalex, uint16_t y, int scaley, uint16_t time) {
fill_raw_2dnoise8(pData, width, height, octaves, q44(2,0), 128, 1, x, scalex, y, scaley, time);
}
void fill_raw_2dnoise16(uint16_t *pData, int width, int height, uint8_t octaves, q88 freq88, fract16 amplitude, int skip, uint32_t x, int scalex, uint32_t y, int scaley, uint32_t time) {
if(octaves > 1) {
fill_raw_2dnoise16(pData, width, height, octaves-1, freq88, amplitude, skip, x *freq88 , scalex *freq88, y * freq88, scaley * freq88, time);
} else {
// amplitude is always 255 on the lowest level
amplitude=65535;
}
scalex *= skip;
scaley *= skip;
fract16 invamp = 65535-amplitude;
for(int i = 0; i < height; i+=skip, y+=scaley) {
uint16_t *pRow = pData + (i*width);
for(int j = 0,xx=x; j < width; j+=skip, xx+=scalex) {
uint16_t noise_base = inoise16(xx,y,time);
noise_base = (0x8000 & noise_base) ? noise_base - (32767) : 32767 - noise_base;
noise_base = scale16(noise_base<<1, amplitude);
if(skip==1) {
pRow[j] = scale16(pRow[j],invamp) + noise_base;
} else {
for(int ii = i; ii<(i+skip) && ii<height; ii++) {
uint16_t *pRow = pData + (ii*width);
for(int jj=j; jj<(j+skip) && jj<width; jj++) {
pRow[jj] = scale16(pRow[jj],invamp) + noise_base;
}
}
}
}
}
}
int32_t nmin=11111110;
int32_t nmax=0;
void fill_raw_2dnoise16into8(uint8_t *pData, int width, int height, uint8_t octaves, q44 freq44, fract8 amplitude, int skip, uint32_t x, int scalex, uint32_t y, int scaley, uint32_t time) {
if(octaves > 1) {
fill_raw_2dnoise16into8(pData, width, height, octaves-1, freq44, amplitude, skip+1, x*freq44, scalex *freq44, y*freq44, scaley * freq44, time);
} else {
// amplitude is always 255 on the lowest level
amplitude=255;
}
scalex *= skip;
scaley *= skip;
uint32_t xx;
fract8 invamp = 255-amplitude;
for(int i = 0; i < height; i+=skip, y+=scaley) {
uint8_t *pRow = pData + (i*width);
xx = x;
for(int j = 0; j < width; j+=skip, xx+=scalex) {
uint16_t noise_base = inoise16(xx,y,time);
noise_base = (0x8000 & noise_base) ? noise_base - (32767) : 32767 - noise_base;
noise_base = scale8(noise_base>>7,amplitude);
if(skip==1) {
pRow[j] = qadd8(scale8(pRow[j],invamp),noise_base);
} else {
for(int ii = i; ii<(i+skip) && ii<height; ii++) {
uint8_t *pRow = pData + (ii*width);
for(int jj=j; jj<(j+skip) && jj<width; jj++) {
pRow[jj] = scale8(pRow[jj],invamp) + noise_base;
}
}
}
}
}
}
void fill_raw_2dnoise16into8(uint8_t *pData, int width, int height, uint8_t octaves, uint32_t x, int scalex, uint32_t y, int scaley, uint32_t time) {
fill_raw_2dnoise16into8(pData, width, height, octaves, q44(2,0), 171, 1, x, scalex, y, scaley, time);
}
void fill_noise8(CRGB *leds, int num_leds,
uint8_t octaves, uint16_t x, int scale,
uint8_t hue_octaves, uint16_t hue_x, int hue_scale,
uint16_t time) {
uint8_t V[num_leds];
uint8_t H[num_leds];
memset(V,0,num_leds);
memset(H,0,num_leds);
fill_raw_noise8(V,num_leds,octaves,x,scale,time);
fill_raw_noise8(H,num_leds,hue_octaves,hue_x,hue_scale,time);
for(int i = 0; i < num_leds; i++) {
leds[i] = CHSV(H[i],255,V[i]);
}
}
void fill_noise16(CRGB *leds, int num_leds,
uint8_t octaves, uint16_t x, int scale,
uint8_t hue_octaves, uint16_t hue_x, int hue_scale,
uint16_t time, uint8_t hue_shift) {
uint8_t V[num_leds];
uint8_t H[num_leds];
memset(V,0,num_leds);
memset(H,0,num_leds);
fill_raw_noise16into8(V,num_leds,octaves,x,scale,time);
fill_raw_noise8(H,num_leds,hue_octaves,hue_x,hue_scale,time);
for(int i = 0; i < num_leds; i++) {
leds[i] = CHSV(H[i] + hue_shift,255,V[i]);
}
}
void fill_2dnoise8(CRGB *leds, int width, int height, bool serpentine,
uint8_t octaves, uint16_t x, int xscale, uint16_t y, int yscale, uint16_t time,
uint8_t hue_octaves, uint16_t hue_x, int hue_xscale, uint16_t hue_y, uint16_t hue_yscale,uint16_t hue_time,bool blend) {
uint8_t V[height][width];
uint8_t H[height][width];
memset(V,0,height*width);
memset(H,0,height*width);
fill_raw_2dnoise8((uint8_t*)V,width,height,octaves,x,xscale,y,yscale,time);
fill_raw_2dnoise8((uint8_t*)H,width,height,hue_octaves,hue_x,hue_xscale,hue_y,hue_yscale,hue_time);
int w1 = width-1;
int h1 = height-1;
for(int i = 0; i < height; i++) {
int wb = i*width;
for(int j = 0; j < width; j++) {
CRGB led(CHSV(H[h1-i][w1-j],255,V[i][j]));
int pos = j;
if(serpentine && (i & 0x1)) {
pos = w1-j;
}
if(blend) {
leds[wb+pos] >>= 1; leds[wb+pos] += (led>>=1);
} else {
leds[wb+pos] = led;
}
}
}
}
void fill_2dnoise16(CRGB *leds, int width, int height, bool serpentine,
uint8_t octaves, uint32_t x, int xscale, uint32_t y, int yscale, uint32_t time,
uint8_t hue_octaves, uint16_t hue_x, int hue_xscale, uint16_t hue_y, uint16_t hue_yscale,uint16_t hue_time, bool blend, uint16_t hue_shift) {
uint8_t V[height][width];
uint8_t H[height][width];
memset(V,0,height*width);
memset(H,0,height*width);
fill_raw_2dnoise16into8((uint8_t*)V,width,height,octaves,q44(2,0),171,1,x,xscale,y,yscale,time);
// fill_raw_2dnoise16into8((uint8_t*)V,width,height,octaves,x,xscale,y,yscale,time);
// fill_raw_2dnoise8((uint8_t*)V,width,height,hue_octaves,x,xscale,y,yscale,time);
fill_raw_2dnoise8((uint8_t*)H,width,height,hue_octaves,hue_x,hue_xscale,hue_y,hue_yscale,hue_time);
int w1 = width-1;
int h1 = height-1;
hue_shift >>= 8;
for(int i = 0; i < height; i++) {
int wb = i*width;
for(int j = 0; j < width; j++) {
CRGB led(CHSV(hue_shift + (H[h1-i][w1-j]),196,V[i][j]));
int pos = j;
if(serpentine && (i & 0x1)) {
pos = w1-j;
}
if(blend) {
leds[wb+pos] >>= 1; leds[wb+pos] += (led>>=1);
} else {
leds[wb+pos] = led;
}
}
}
}
FASTLED_NAMESPACE_END