RGB Matrix Overhaul (#5372)

* RGB Matrix overhaul
Breakout of animations to separate files
Integration of optimized int based math lib
Overhaul of rgb_matrix.c and animations for performance

* Updating effect function api for future extensions

* Combined the keypresses || keyreleases define checks into a single define so I stop forgetting it where necessary

* Moving define RGB_MATRIX_KEYREACTIVE_ENABLED earlier in the include chain

7 files changed, 2643 insertions, 0 deletions

diff --git a/lib/lib8tion/LICENSE b/lib/lib8tion/LICENSE
new file mode 100644
index 000000000..ebe476330
--- /dev/null
+++ b/lib/lib8tion/LICENSE
@@ -0,0 +1,20 @@
+The MIT License (MIT)
+
+Copyright (c) 2013 FastLED
+
+Permission is hereby granted, free of charge, to any person obtaining a copy of
+this software and associated documentation files (the "Software"), to deal in
+the Software without restriction, including without limitation the rights to
+use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of
+the Software, and to permit persons to whom the Software is furnished to do so,
+subject to the following conditions:
+
+The above copyright notice and this permission notice shall be included in all
+copies or substantial portions of the Software.
+
+THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
+IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS
+FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR
+COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
+IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
+CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
diff --git a/lib/lib8tion/lib8tion.c b/lib/lib8tion/lib8tion.c
new file mode 100644
index 000000000..84b3e9c61
--- /dev/null
+++ b/lib/lib8tion/lib8tion.c
@@ -0,0 +1,242 @@
+#define FASTLED_INTERNAL
+#include <stdint.h>
+
+#define RAND16_SEED  1337
+uint16_t rand16seed = RAND16_SEED;
+
+
+// memset8, memcpy8, memmove8:
+//  optimized avr replacements for the standard "C" library
+//  routines memset, memcpy, and memmove.
+//
+//  There are two techniques that make these routines
+//  faster than the standard avr-libc routines.
+//  First, the loops are unrolled 2X, meaning that
+//  the average loop overhead is cut in half.
+//  And second, the compare-and-branch at the bottom
+//  of each loop decrements the low byte of the
+//  counter, and if the carry is clear, it branches
+//  back up immediately.  Only if the low byte math
+//  causes carry do we bother to decrement the high
+//  byte and check that result for carry as well.
+//  Results for a 100-byte buffer are 20-40% faster
+//  than standard avr-libc, at a cost of a few extra
+//  bytes of code.
+
+#if defined(__AVR__)
+//__attribute__ ((noinline))
+void * memset8 ( void * ptr, uint8_t val, uint16_t num )
+{
+    asm volatile(
+         "  movw r26, %[ptr]        \n\t"
+         "  sbrs %A[num], 0         \n\t"
+         "  rjmp Lseteven_%=        \n\t"
+         "  rjmp Lsetodd_%=         \n\t"
+         "Lsetloop_%=:              \n\t"
+         "  st X+, %[val]           \n\t"
+         "Lsetodd_%=:               \n\t"
+         "  st X+, %[val]           \n\t"
+         "Lseteven_%=:              \n\t"
+         "  subi %A[num], 2         \n\t"
+         "  brcc Lsetloop_%=        \n\t"
+         "  sbci %B[num], 0         \n\t"
+         "  brcc Lsetloop_%=        \n\t"
+         : [num] "+r" (num)
+         : [ptr]  "r" (ptr),
+           [val]  "r" (val)
+         : "memory"
+         );
+    return ptr;
+}
+
+
+
+//__attribute__ ((noinline))
+void * memcpy8 ( void * dst, const void* src, uint16_t num )
+{
+    asm volatile(
+         "  movw r30, %[src]        \n\t"
+         "  movw r26, %[dst]        \n\t"
+         "  sbrs %A[num], 0         \n\t"
+         "  rjmp Lcpyeven_%=        \n\t"
+         "  rjmp Lcpyodd_%=         \n\t"
+         "Lcpyloop_%=:              \n\t"
+         "  ld __tmp_reg__, Z+      \n\t"
+         "  st X+, __tmp_reg__      \n\t"
+         "Lcpyodd_%=:               \n\t"
+         "  ld __tmp_reg__, Z+      \n\t"
+         "  st X+, __tmp_reg__      \n\t"
+         "Lcpyeven_%=:              \n\t"
+         "  subi %A[num], 2         \n\t"
+         "  brcc Lcpyloop_%=        \n\t"
+         "  sbci %B[num], 0         \n\t"
+         "  brcc Lcpyloop_%=        \n\t"
+         : [num] "+r" (num)
+         : [src] "r" (src),
+           [dst] "r" (dst)
+         : "memory"
+         );
+    return dst;
+}
+
+//__attribute__ ((noinline))
+void * memmove8 ( void * dst, const void* src, uint16_t num )
+{
+    if( src > dst) {
+        // if src > dst then we can use the forward-stepping memcpy8
+        return memcpy8( dst, src, num);
+    } else {
+        // if src < dst then we have to step backward:
+        dst = (char*)dst + num;
+        src = (char*)src + num;
+        asm volatile(
+             "  movw r30, %[src]        \n\t"
+             "  movw r26, %[dst]        \n\t"
+             "  sbrs %A[num], 0         \n\t"
+             "  rjmp Lmoveven_%=        \n\t"
+             "  rjmp Lmovodd_%=         \n\t"
+             "Lmovloop_%=:              \n\t"
+             "  ld __tmp_reg__, -Z      \n\t"
+             "  st -X, __tmp_reg__      \n\t"
+             "Lmovodd_%=:               \n\t"
+             "  ld __tmp_reg__, -Z      \n\t"
+             "  st -X, __tmp_reg__      \n\t"
+             "Lmoveven_%=:              \n\t"
+             "  subi %A[num], 2         \n\t"
+             "  brcc Lmovloop_%=        \n\t"
+             "  sbci %B[num], 0         \n\t"
+             "  brcc Lmovloop_%=        \n\t"
+             : [num] "+r" (num)
+             : [src] "r" (src),
+               [dst] "r" (dst)
+             : "memory"
+             );
+        return dst;
+    }
+}
+
+#endif /* AVR */
+
+
+
+
+#if 0
+// TEST / VERIFICATION CODE ONLY BELOW THIS POINT
+#include <Arduino.h>
+#include "lib8tion.h"
+
+void test1abs( int8_t i)
+{
+    Serial.print("abs("); Serial.print(i); Serial.print(") = ");
+    int8_t j = abs8(i);
+    Serial.print(j); Serial.println(" ");
+}
+
+void testabs()
+{
+    delay(5000);
+    for( int8_t q = -128; q != 127; q++) {
+        test1abs(q);
+    }
+    for(;;){};
+}
+
+
+void testmul8()
+{
+    delay(5000);
+    byte r, c;
+
+    Serial.println("mul8:");
+    for( r = 0; r <= 20; r += 1) {
+        Serial.print(r); Serial.print(" : ");
+        for( c = 0; c <= 20; c += 1) {
+            byte t;
+            t = mul8( r, c);
+            Serial.print(t); Serial.print(' ');
+        }
+        Serial.println(' ');
+    }
+    Serial.println("done.");
+    for(;;){};
+}
+
+
+void testscale8()
+{
+    delay(5000);
+    byte r, c;
+
+    Serial.println("scale8:");
+    for( r = 0; r <= 240; r += 10) {
+        Serial.print(r); Serial.print(" : ");
+        for( c = 0; c <= 240; c += 10) {
+            byte t;
+            t = scale8( r, c);
+            Serial.print(t); Serial.print(' ');
+        }
+        Serial.println(' ');
+    }
+
+    Serial.println(' ');
+    Serial.println("scale8_video:");
+
+    for( r = 0; r <= 100; r += 4) {
+        Serial.print(r); Serial.print(" : ");
+        for( c = 0; c <= 100; c += 4) {
+            byte t;
+            t = scale8_video( r, c);
+            Serial.print(t); Serial.print(' ');
+        }
+        Serial.println(' ');
+    }
+
+    Serial.println("done.");
+    for(;;){};
+}
+
+
+
+void testqadd8()
+{
+    delay(5000);
+    byte r, c;
+    for( r = 0; r <= 240; r += 10) {
+        Serial.print(r); Serial.print(" : ");
+        for( c = 0; c <= 240; c += 10) {
+            byte t;
+            t = qadd8( r, c);
+            Serial.print(t); Serial.print(' ');
+        }
+        Serial.println(' ');
+    }
+    Serial.println("done.");
+    for(;;){};
+}
+
+void testnscale8x3()
+{
+    delay(5000);
+    byte r, g, b, sc;
+    for( byte z = 0; z < 10; z++) {
+        r = random8(); g = random8(); b = random8(); sc = random8();
+
+        Serial.print("nscale8x3_video( ");
+        Serial.print(r); Serial.print(", ");
+        Serial.print(g); Serial.print(", ");
+        Serial.print(b); Serial.print(", ");
+        Serial.print(sc); Serial.print(") = [ ");
+
+        nscale8x3_video( r, g, b, sc);
+
+        Serial.print(r); Serial.print(", ");
+        Serial.print(g); Serial.print(", ");
+        Serial.print(b); Serial.print("]");
+
+        Serial.println(' ');
+    }
+    Serial.println("done.");
+    for(;;){};
+}
+
+#endif
diff --git a/lib/lib8tion/lib8tion.h b/lib/lib8tion/lib8tion.h
new file mode 100644
index 000000000..d93c748e6
--- /dev/null
+++ b/lib/lib8tion/lib8tion.h
@@ -0,0 +1,934 @@
+#ifndef __INC_LIB8TION_H
+#define __INC_LIB8TION_H
+
+/*
+
+ Fast, efficient 8-bit math functions specifically
+ designed for high-performance LED programming.
+
+ Because of the AVR(Arduino) and ARM assembly language
+ implementations provided, using these functions often
+ results in smaller and faster code than the equivalent
+ program using plain "C" arithmetic and logic.
+
+
+ Included are:
+
+
+ - Saturating unsigned 8-bit add and subtract.
+   Instead of wrapping around if an overflow occurs,
+   these routines just 'clamp' the output at a maxumum
+   of 255, or a minimum of 0.  Useful for adding pixel
+   values.  E.g., qadd8( 200, 100) = 255.
+
+     qadd8( i, j) == MIN( (i + j), 0xFF )
+     qsub8( i, j) == MAX( (i - j), 0 )
+
+ - Saturating signed 8-bit ("7-bit") add.
+     qadd7( i, j) == MIN( (i + j), 0x7F)
+
+
+ - Scaling (down) of unsigned 8- and 16- bit values.
+   Scaledown value is specified in 1/256ths.
+     scale8( i, sc) == (i * sc) / 256
+     scale16by8( i, sc) == (i * sc) / 256
+
+   Example: scaling a 0-255 value down into a
+   range from 0-99:
+     downscaled = scale8( originalnumber, 100);
+
+   A special version of scale8 is provided for scaling
+   LED brightness values, to make sure that they don't
+   accidentally scale down to total black at low
+   dimming levels, since that would look wrong:
+     scale8_video( i, sc) = ((i * sc) / 256) +? 1
+
+   Example: reducing an LED brightness by a
+   dimming factor:
+     new_bright = scale8_video( orig_bright, dimming);
+
+
+ - Fast 8- and 16- bit unsigned random numbers.
+   Significantly faster than Arduino random(), but
+   also somewhat less random.  You can add entropy.
+     random8()       == random from 0..255
+     random8( n)     == random from 0..(N-1)
+     random8( n, m)  == random from N..(M-1)
+
+     random16()      == random from 0..65535
+     random16( n)    == random from 0..(N-1)
+     random16( n, m) == random from N..(M-1)
+
+     random16_set_seed( k)    ==  seed = k
+     random16_add_entropy( k) ==  seed += k
+
+
+ - Absolute value of a signed 8-bit value.
+     abs8( i)     == abs( i)
+
+
+ - 8-bit math operations which return 8-bit values.
+   These are provided mostly for completeness,
+   not particularly for performance.
+     mul8( i, j)  == (i * j) & 0xFF
+     add8( i, j)  == (i + j) & 0xFF
+     sub8( i, j)  == (i - j) & 0xFF
+
+
+ - Fast 16-bit approximations of sin and cos.
+   Input angle is a uint16_t from 0-65535.
+   Output is a signed int16_t from -32767 to 32767.
+      sin16( x)  == sin( (x/32768.0) * pi) * 32767
+      cos16( x)  == cos( (x/32768.0) * pi) * 32767
+   Accurate to more than 99% in all cases.
+
+ - Fast 8-bit approximations of sin and cos.
+   Input angle is a uint8_t from 0-255.
+   Output is an UNsigned uint8_t from 0 to 255.
+       sin8( x)  == (sin( (x/128.0) * pi) * 128) + 128
+       cos8( x)  == (cos( (x/128.0) * pi) * 128) + 128
+   Accurate to within about 2%.
+
+
+ - Fast 8-bit "easing in/out" function.
+     ease8InOutCubic(x) == 3(x^i) - 2(x^3)
+     ease8InOutApprox(x) ==
+       faster, rougher, approximation of cubic easing
+     ease8InOutQuad(x) == quadratic (vs cubic) easing
+
+ - Cubic, Quadratic, and Triangle wave functions.
+   Input is a uint8_t representing phase withing the wave,
+     similar to how sin8 takes an angle 'theta'.
+   Output is a uint8_t representing the amplitude of
+     the wave at that point.
+       cubicwave8( x)
+       quadwave8( x)
+       triwave8( x)
+
+ - Square root for 16-bit integers.  About three times
+   faster and five times smaller than Arduino's built-in
+   generic 32-bit sqrt routine.
+     sqrt16( uint16_t x ) == sqrt( x)
+
+ - Dimming and brightening functions for 8-bit
+   light values.
+     dim8_video( x)  == scale8_video( x, x)
+     dim8_raw( x)    == scale8( x, x)
+     dim8_lin( x)    == (x<128) ? ((x+1)/2) : scale8(x,x)
+     brighten8_video( x) == 255 - dim8_video( 255 - x)
+     brighten8_raw( x) == 255 - dim8_raw( 255 - x)
+     brighten8_lin( x) == 255 - dim8_lin( 255 - x)
+   The dimming functions in particular are suitable
+   for making LED light output appear more 'linear'.
+
+
+ - Linear interpolation between two values, with the
+   fraction between them expressed as an 8- or 16-bit
+   fixed point fraction (fract8 or fract16).
+     lerp8by8(   fromU8, toU8, fract8 )
+     lerp16by8(  fromU16, toU16, fract8 )
+     lerp15by8(  fromS16, toS16, fract8 )
+       == from + (( to - from ) * fract8) / 256)
+     lerp16by16( fromU16, toU16, fract16 )
+       == from + (( to - from ) * fract16) / 65536)
+     map8( in, rangeStart, rangeEnd)
+       == map( in, 0, 255, rangeStart, rangeEnd);
+
+ - Optimized memmove, memcpy, and memset, that are
+   faster than standard avr-libc 1.8.
+      memmove8( dest, src,  bytecount)
+      memcpy8(  dest, src,  bytecount)
+      memset8(  buf, value, bytecount)
+
+ - Beat generators which return sine or sawtooth
+   waves in a specified number of Beats Per Minute.
+   Sine wave beat generators can specify a low and
+   high range for the output.  Sawtooth wave beat
+   generators always range 0-255 or 0-65535.
+     beatsin8( BPM, low8, high8)
+         = (sine(beatphase) * (high8-low8)) + low8
+     beatsin16( BPM, low16, high16)
+         = (sine(beatphase) * (high16-low16)) + low16
+     beatsin88( BPM88, low16, high16)
+         = (sine(beatphase) * (high16-low16)) + low16
+     beat8( BPM)  = 8-bit repeating sawtooth wave
+     beat16( BPM) = 16-bit repeating sawtooth wave
+     beat88( BPM88) = 16-bit repeating sawtooth wave
+   BPM is beats per minute in either simple form
+   e.g. 120, or Q8.8 fixed-point form.
+   BPM88 is beats per minute in ONLY Q8.8 fixed-point
+   form.
+
+Lib8tion is pronounced like 'libation': lie-BAY-shun
+
+*/
+
+
+
+#include <stdint.h>
+
+#define LIB8STATIC __attribute__ ((unused)) static inline
+#define LIB8STATIC_ALWAYS_INLINE __attribute__ ((always_inline)) static inline
+
+#if !defined(__AVR__)
+#include <string.h>
+// for memmove, memcpy, and memset if not defined here
+#endif
+
+#if defined(__arm__)
+
+#if defined(FASTLED_TEENSY3)
+// Can use Cortex M4 DSP instructions
+#define QADD8_C 0
+#define QADD7_C 0
+#define QADD8_ARM_DSP_ASM 1
+#define QADD7_ARM_DSP_ASM 1
+#else
+// Generic ARM
+#define QADD8_C 1
+#define QADD7_C 1
+#endif
+
+#define QSUB8_C 1
+#define SCALE8_C 1
+#define SCALE16BY8_C 1
+#define SCALE16_C 1
+#define ABS8_C 1
+#define MUL8_C 1
+#define QMUL8_C 1
+#define ADD8_C 1
+#define SUB8_C 1
+#define EASE8_C 1
+#define AVG8_C 1
+#define AVG7_C 1
+#define AVG16_C 1
+#define AVG15_C 1
+#define BLEND8_C 1
+
+
+#elif defined(__AVR__)
+
+// AVR ATmega and friends Arduino
+
+#define QADD8_C 0
+#define QADD7_C 0
+#define QSUB8_C 0
+#define ABS8_C 0
+#define ADD8_C 0
+#define SUB8_C 0
+#define AVG8_C 0
+#define AVG7_C 0
+#define AVG16_C 0
+#define AVG15_C 0
+
+#define QADD8_AVRASM 1
+#define QADD7_AVRASM 1
+#define QSUB8_AVRASM 1
+#define ABS8_AVRASM 1
+#define ADD8_AVRASM 1
+#define SUB8_AVRASM 1
+#define AVG8_AVRASM 1
+#define AVG7_AVRASM 1
+#define AVG16_AVRASM 1
+#define AVG15_AVRASM 1
+
+// Note: these require hardware MUL instruction
+//       -- sorry, ATtiny!
+#if !defined(LIB8_ATTINY)
+#define SCALE8_C 0
+#define SCALE16BY8_C 0
+#define SCALE16_C 0
+#define MUL8_C 0
+#define QMUL8_C 0
+#define EASE8_C 0
+#define BLEND8_C 0
+#define SCALE8_AVRASM 1
+#define SCALE16BY8_AVRASM 1
+#define SCALE16_AVRASM 1
+#define MUL8_AVRASM 1
+#define QMUL8_AVRASM 1
+#define EASE8_AVRASM 1
+#define CLEANUP_R1_AVRASM 1
+#define BLEND8_AVRASM 1
+#else
+// On ATtiny, we just use C implementations
+#define SCALE8_C 1
+#define SCALE16BY8_C 1
+#define SCALE16_C 1
+#define MUL8_C 1
+#define QMUL8_C 1
+#define EASE8_C 1
+#define BLEND8_C 1
+#define SCALE8_AVRASM 0
+#define SCALE16BY8_AVRASM 0
+#define SCALE16_AVRASM 0
+#define MUL8_AVRASM 0
+#define QMUL8_AVRASM 0
+#define EASE8_AVRASM 0
+#define BLEND8_AVRASM 0
+#endif
+
+#else
+
+// unspecified architecture, so
+// no ASM, everything in C
+#define QADD8_C 1
+#define QADD7_C 1
+#define QSUB8_C 1
+#define SCALE8_C 1
+#define SCALE16BY8_C 1
+#define SCALE16_C 1
+#define ABS8_C 1
+#define MUL8_C 1
+#define QMUL8_C 1
+#define ADD8_C 1
+#define SUB8_C 1
+#define EASE8_C 1
+#define AVG8_C 1
+#define AVG7_C 1
+#define AVG16_C 1
+#define AVG15_C 1
+#define BLEND8_C 1
+
+#endif
+
+///@defgroup lib8tion Fast math functions
+///A variety of functions for working with numbers.
+///@{
+
+
+///////////////////////////////////////////////////////////////////////
+//
+// typdefs for fixed-point fractional types.
+//
+// sfract7 should be interpreted as signed 128ths.
+// fract8 should be interpreted as unsigned 256ths.
+// sfract15 should be interpreted as signed 32768ths.
+// fract16 should be interpreted as unsigned 65536ths.
+//
+// Example: if a fract8 has the value "64", that should be interpreted
+//          as 64/256ths, or one-quarter.
+//
+//
+//  fract8   range is 0 to 0.99609375
+//                 in steps of 0.00390625
+//
+//  sfract7  range is -0.9921875 to 0.9921875
+//                 in steps of 0.0078125
+//
+//  fract16  range is 0 to 0.99998474121
+//                 in steps of 0.00001525878
+//
+//  sfract15 range is -0.99996948242 to 0.99996948242
+//                 in steps of 0.00003051757
+//
+
+/// ANSI unsigned short _Fract.  range is 0 to 0.99609375
+///                 in steps of 0.00390625
+typedef uint8_t   fract8;   ///< ANSI: unsigned short _Fract
+
+///  ANSI: signed short _Fract.  range is -0.9921875 to 0.9921875
+///                 in steps of 0.0078125
+typedef int8_t    sfract7;  ///< ANSI: signed   short _Fract
+
+///  ANSI: unsigned _Fract.  range is 0 to 0.99998474121
+///                 in steps of 0.00001525878
+typedef uint16_t  fract16;  ///< ANSI: unsigned       _Fract
+
+///  ANSI: signed _Fract.  range is -0.99996948242 to 0.99996948242
+///                 in steps of 0.00003051757
+typedef int16_t   sfract15; ///< ANSI: signed         _Fract
+
+
+// accumXY types should be interpreted as X bits of integer,
+//         and Y bits of fraction.
+//         E.g., accum88 has 8 bits of int, 8 bits of fraction
+
+typedef uint16_t  accum88;  ///< ANSI: unsigned short _Accum.  8 bits int, 8 bits fraction
+typedef int16_t   saccum78; ///< ANSI: signed   short _Accum.  7 bits int, 8 bits fraction
+typedef uint32_t  accum1616;///< ANSI: signed         _Accum. 16 bits int, 16 bits fraction
+typedef int32_t   saccum1516;///< ANSI: signed         _Accum. 15 bits int, 16 bits fraction
+typedef uint16_t  accum124; ///< no direct ANSI counterpart. 12 bits int, 4 bits fraction
+typedef int32_t   saccum114;///< no direct ANSI counterpart. 1 bit int, 14 bits fraction
+
+
+
+#include "math8.h"
+#include "scale8.h"
+#include "random8.h"
+#include "trig8.h"
+
+///////////////////////////////////////////////////////////////////////
+
+
+
+
+
+
+
+///////////////////////////////////////////////////////////////////////
+//
+// float-to-fixed and fixed-to-float conversions
+//
+// Note that anything involving a 'float' on AVR will be slower.
+
+/// sfract15ToFloat: conversion from sfract15 fixed point to
+///                  IEEE754 32-bit float.
+LIB8STATIC float sfract15ToFloat( sfract15 y)
+{
+    return y / 32768.0;
+}
+
+/// conversion from IEEE754 float in the range (-1,1)
+///                  to 16-bit fixed point.  Note that the extremes of
+///                  one and negative one are NOT representable.  The
+///                  representable range is basically
+LIB8STATIC sfract15 floatToSfract15( float f)
+{
+    return f * 32768.0;
+}
+
+
+
+///////////////////////////////////////////////////////////////////////
+//
+// memmove8, memcpy8, and memset8:
+//   alternatives to memmove, memcpy, and memset that are
+//   faster on AVR than standard avr-libc 1.8
+
+#if defined(__AVR__)
+void * memmove8( void * dst, const void * src, uint16_t num );
+void * memcpy8 ( void * dst, const void * src, uint16_t num )  __attribute__ ((noinline));
+void * memset8 ( void * ptr, uint8_t value, uint16_t num ) __attribute__ ((noinline)) ;
+#else
+// on non-AVR platforms, these names just call standard libc.
+#define memmove8 memmove
+#define memcpy8 memcpy
+#define memset8 memset
+#endif
+
+
+///////////////////////////////////////////////////////////////////////
+//
+// linear interpolation, such as could be used for Perlin noise, etc.
+//
+
+// A note on the structure of the lerp functions:
+// The cases for b>a and b<=a are handled separately for
+// speed: without knowing the relative order of a and b,
+// the value (a-b) might be overflow the width of a or b,
+// and have to be promoted to a wider, slower type.
+// To avoid that, we separate the two cases, and are able
+// to do all the math in the same width as the arguments,
+// which is much faster and smaller on AVR.
+
+/// linear interpolation between two unsigned 8-bit values,
+/// with 8-bit fraction
+LIB8STATIC uint8_t lerp8by8( uint8_t a, uint8_t b, fract8 frac)
+{
+    uint8_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;
+}
+
+/// linear interpolation between two unsigned 16-bit values,
+/// with 16-bit fraction
+LIB8STATIC uint16_t lerp16by16( uint16_t a, uint16_t b, fract16 frac)
+{
+    uint16_t result;
+    if( b > a ) {
+        uint16_t delta = b - a;
+        uint16_t scaled = scale16(delta, frac);
+        result = a + scaled;
+    } else {
+        uint16_t delta = a - b;
+        uint16_t scaled = scale16( delta, frac);
+        result = a - scaled;
+    }
+    return result;
+}
+
+/// linear interpolation between two unsigned 16-bit values,
+/// with 8-bit fraction
+LIB8STATIC uint16_t lerp16by8( uint16_t a, uint16_t b, fract8 frac)
+{
+    uint16_t result;
+    if( b > a) {
+        uint16_t delta = b - a;
+        uint16_t scaled = scale16by8( delta, frac);
+        result = a + scaled;
+    } else {
+        uint16_t delta = a - b;
+        uint16_t scaled = scale16by8( delta, frac);
+        result = a - scaled;
+    }
+    return result;
+}
+
+/// linear interpolation between two signed 15-bit values,
+/// with 8-bit fraction
+LIB8STATIC int16_t lerp15by8( int16_t a, int16_t b, fract8 frac)
+{
+    int16_t result;
+    if( b > a) {
+        uint16_t delta = b - a;
+        uint16_t scaled = scale16by8( delta, frac);
+        result = a + scaled;
+    } else {
+        uint16_t delta = a - b;
+        uint16_t scaled = scale16by8( delta, frac);
+        result = a - scaled;
+    }
+    return result;
+}
+
+/// linear interpolation between two signed 15-bit values,
+/// with 8-bit fraction
+LIB8STATIC int16_t lerp15by16( int16_t a, int16_t b, fract16 frac)
+{
+    int16_t result;
+    if( b > a) {
+        uint16_t delta = b - a;
+        uint16_t scaled = scale16( delta, frac);
+        result = a + scaled;
+    } else {
+        uint16_t delta = a - b;
+        uint16_t scaled = scale16( delta, frac);
+        result = a - scaled;
+    }
+    return result;
+}
+
+///  map8: map from one full-range 8-bit value into a narrower
+/// range of 8-bit values, possibly a range of hues.
+///
+/// E.g. map myValue into a hue in the range blue..purple..pink..red
+/// hue = map8( myValue, HUE_BLUE, HUE_RED);
+///
+/// Combines nicely with the waveform functions (like sin8, etc)
+/// to produce continuous hue gradients back and forth:
+///
+///          hue = map8( sin8( myValue), HUE_BLUE, HUE_RED);
+///
+/// Mathematically simiar to lerp8by8, but arguments are more
+/// like Arduino's "map"; this function is similar to
+///
+///          map( in, 0, 255, rangeStart, rangeEnd)
+///
+/// but faster and specifically designed for 8-bit values.
+LIB8STATIC uint8_t map8( uint8_t in, uint8_t rangeStart, uint8_t rangeEnd)
+{
+    uint8_t rangeWidth = rangeEnd - rangeStart;
+    uint8_t out = scale8( in, rangeWidth);
+    out += rangeStart;
+    return out;
+}
+
+
+///////////////////////////////////////////////////////////////////////
+//
+// easing functions; see http://easings.net
+//
+
+/// ease8InOutQuad: 8-bit quadratic ease-in / ease-out function
+///                Takes around 13 cycles on AVR
+#if EASE8_C == 1
+LIB8STATIC uint8_t ease8InOutQuad( uint8_t i)
+{
+    uint8_t j = i;
+    if( j & 0x80 ) {
+        j = 255 - j;
+    }
+    uint8_t jj  = scale8(  j, j);
+    uint8_t jj2 = jj << 1;
+    if( i & 0x80 ) {
+        jj2 = 255 - jj2;
+    }
+    return jj2;
+}
+
+#elif EASE8_AVRASM == 1
+// This AVR asm version of ease8InOutQuad preserves one more
+// low-bit of precision than the C version, and is also slightly
+// smaller and faster.
+LIB8STATIC uint8_t ease8InOutQuad(uint8_t val) {
+    uint8_t j=val;
+    asm volatile (
+      "sbrc %[val], 7 \n"
+      "com %[j]       \n"
+      "mul %[j], %[j] \n"
+      "add r0, %[j]   \n"
+      "ldi %[j], 0    \n"
+      "adc %[j], r1   \n"
+      "lsl r0         \n" // carry = high bit of low byte of mul product
+      "rol %[j]       \n" // j = (j * 2) + carry // preserve add'l bit of precision
+      "sbrc %[val], 7 \n"
+      "com %[j]       \n"
+      "clr __zero_reg__   \n"
+      : [j] "+&a" (j)
+      : [val] "a" (val)
+      : "r0", "r1"
+      );
+    return j;
+}
+
+#else
+#error "No implementation for ease8InOutQuad available."
+#endif
+
+/// ease16InOutQuad: 16-bit quadratic ease-in / ease-out function
+// C implementation at this point
+LIB8STATIC uint16_t ease16InOutQuad( uint16_t i)
+{
+    uint16_t j = i;
+    if( j & 0x8000 ) {
+        j = 65535 - j;
+    }
+    uint16_t jj  = scale16( j, j);
+    uint16_t jj2 = jj << 1;
+    if( i & 0x8000 ) {
+        jj2 = 65535 - jj2;
+    }
+    return jj2;
+}
+
+
+/// ease8InOutCubic: 8-bit cubic ease-in / ease-out function
+///                 Takes around 18 cycles on AVR
+LIB8STATIC fract8 ease8InOutCubic( fract8 i)
+{
+    uint8_t ii  = scale8_LEAVING_R1_DIRTY(  i, i);
+    uint8_t iii = scale8_LEAVING_R1_DIRTY( ii, i);
+
+    uint16_t r1 = (3 * (uint16_t)(ii)) - ( 2 * (uint16_t)(iii));
+
+    /* the code generated for the above *'s automatically
+       cleans up R1, so there's no need to explicitily call
+       cleanup_R1(); */
+
+    uint8_t result = r1;
+
+    // if we got "256", return 255:
+    if( r1 & 0x100 ) {
+        result = 255;
+    }
+    return result;
+}
+
+/// ease8InOutApprox: fast, rough 8-bit ease-in/ease-out function
+///                   shaped approximately like 'ease8InOutCubic',
+///                   it's never off by more than a couple of percent
+///                   from the actual cubic S-curve, and it executes
+///                   more than twice as fast.  Use when the cycles
+///                   are more important than visual smoothness.
+///                   Asm version takes around 7 cycles on AVR.
+
+#if EASE8_C == 1
+LIB8STATIC fract8 ease8InOutApprox( fract8 i)
+{
+    if( i < 64) {
+        // start with slope 0.5
+        i /= 2;
+    } else if( i > (255 - 64)) {
+        // end with slope 0.5
+        i = 255 - i;
+        i /= 2;
+        i = 255 - i;
+    } else {
+        // in the middle, use slope 192/128 = 1.5
+        i -= 64;
+        i += (i / 2);
+        i += 32;
+    }
+
+    return i;
+}
+
+#elif EASE8_AVRASM == 1
+LIB8STATIC uint8_t ease8InOutApprox( fract8 i)
+{
+    // takes around 7 cycles on AVR
+    asm volatile (
+        "  subi %[i], 64         \n\t"
+        "  cpi  %[i], 128        \n\t"
+        "  brcc Lshift_%=        \n\t"
+
+        // middle case
+        "  mov __tmp_reg__, %[i] \n\t"
+        "  lsr __tmp_reg__       \n\t"
+        "  add %[i], __tmp_reg__ \n\t"
+        "  subi %[i], 224        \n\t"
+        "  rjmp Ldone_%=         \n\t"
+
+        // start or end case
+        "Lshift_%=:              \n\t"
+        "  lsr %[i]              \n\t"
+        "  subi %[i], 96         \n\t"
+
+        "Ldone_%=:               \n\t"
+
+        : [i] "+&a" (i)
+        :
+        : "r0", "r1"
+        );
+    return i;
+}
+#else
+#error "No implementation for ease8 available."
+#endif
+
+
+
+/// triwave8: triangle (sawtooth) wave generator.  Useful for
+///           turning a one-byte ever-increasing value into a
+///           one-byte value that oscillates up and down.
+///
+///           input         output
+///           0..127        0..254 (positive slope)
+///           128..255      254..0 (negative slope)
+///
+/// On AVR this function takes just three cycles.
+///
+LIB8STATIC uint8_t triwave8(uint8_t in)
+{
+    if( in & 0x80) {
+        in = 255 - in;
+    }
+    uint8_t out = in << 1;
+    return out;
+}
+
+
+// quadwave8 and cubicwave8: S-shaped wave generators (like 'sine').
+//           Useful for turning a one-byte 'counter' value into a
+//           one-byte oscillating value that moves smoothly up and down,
+//           with an 'acceleration' and 'deceleration' curve.
+//
+//           These are even faster than 'sin8', and have
+//           slightly different curve shapes.
+//
+
+/// quadwave8: quadratic waveform generator.  Spends just a little more
+///            time at the limits than 'sine' does.
+LIB8STATIC uint8_t quadwave8(uint8_t in)
+{
+    return ease8InOutQuad( triwave8( in));
+}
+
+/// cubicwave8: cubic waveform generator.  Spends visibly more time
+///             at the limits than 'sine' does.
+LIB8STATIC uint8_t cubicwave8(uint8_t in)
+{
+    return ease8InOutCubic( triwave8( in));
+}
+
+/// squarewave8: square wave generator.  Useful for
+///           turning a one-byte ever-increasing value
+///           into a one-byte value that is either 0 or 255.
+///           The width of the output 'pulse' is
+///           determined by the pulsewidth argument:
+///
+///~~~
+///           If pulsewidth is 255, output is always 255.
+///           If pulsewidth < 255, then
+///             if input < pulsewidth  then output is 255
+///             if input >= pulsewidth then output is 0
+///~~~
+///
+/// the output looking like:
+///
+///~~~
+///     255   +--pulsewidth--+
+///      .    |              |
+///      0    0              +--------(256-pulsewidth)--------
+///~~~
+///
+/// @param in
+/// @param pulsewidth
+/// @returns square wave output
+LIB8STATIC uint8_t squarewave8( uint8_t in, uint8_t pulsewidth)
+{
+    if( in < pulsewidth || (pulsewidth == 255)) {
+        return 255;
+    } else {
+        return 0;
+    }
+}
+
+
+// Beat generators - These functions produce waves at a given
+//                   number of 'beats per minute'.  Internally, they use
+//                   the Arduino function 'millis' to track elapsed time.
+//                   Accuracy is a bit better than one part in a thousand.
+//
+//       beat8( BPM ) returns an 8-bit value that cycles 'BPM' times
+//                    per minute, rising from 0 to 255, resetting to zero,
+//                    rising up again, etc..  The output of this function
+//                    is suitable for feeding directly into sin8, and cos8,
+//                    triwave8, quadwave8, and cubicwave8.
+//       beat16( BPM ) returns a 16-bit value that cycles 'BPM' times
+//                    per minute, rising from 0 to 65535, resetting to zero,
+//                    rising up again, etc.  The output of this function is
+//                    suitable for feeding directly into sin16 and cos16.
+//       beat88( BPM88) is the same as beat16, except that the BPM88 argument
+//                    MUST be in Q8.8 fixed point format, e.g. 120BPM must
+//                    be specified as 120*256 = 30720.
+//       beatsin8( BPM, uint8_t low, uint8_t high) returns an 8-bit value that
+//                    rises and falls in a sine wave, 'BPM' times per minute,
+//                    between the values of 'low' and 'high'.
+//       beatsin16( BPM, uint16_t low, uint16_t high) returns a 16-bit value
+//                    that rises and falls in a sine wave, 'BPM' times per
+//                    minute, between the values of 'low' and 'high'.
+//       beatsin88( BPM88, ...) is the same as beatsin16, except that the
+//                    BPM88 argument MUST be in Q8.8 fixed point format,
+//                    e.g. 120BPM must be specified as 120*256 = 30720.
+//
+//  BPM can be supplied two ways.  The simpler way of specifying BPM is as
+//  a simple 8-bit integer from 1-255, (e.g., "120").
+//  The more sophisticated way of specifying BPM allows for fractional
+//  "Q8.8" fixed point number (an 'accum88') with an 8-bit integer part and
+//  an 8-bit fractional part.  The easiest way to construct this is to multiply
+//  a floating point BPM value (e.g. 120.3) by 256, (e.g. resulting in 30796
+//  in this case), and pass that as the 16-bit BPM argument.
+//  "BPM88" MUST always be specified in Q8.8 format.
+//
+//  Originally designed to make an entire animation project pulse with brightness.
+//  For that effect, add this line just above your existing call to "FastLED.show()":
+//
+//     uint8_t bright = beatsin8( 60 /*BPM*/, 192 /*dimmest*/, 255 /*brightest*/ ));
+//     FastLED.setBrightness( bright );
+//     FastLED.show();
+//
+//  The entire animation will now pulse between brightness 192 and 255 once per second.
+
+
+// The beat generators need access to a millisecond counter.
+// On Arduino, this is "millis()".  On other platforms, you'll
+// need to provide a function with this signature:
+//   uint32_t get_millisecond_timer();
+// that provides similar functionality.
+// You can also force use of the get_millisecond_timer function
+// by #defining USE_GET_MILLISECOND_TIMER.
+#if (defined(ARDUINO) || defined(SPARK) || defined(FASTLED_HAS_MILLIS)) && !defined(USE_GET_MILLISECOND_TIMER)
+// Forward declaration of Arduino function 'millis'.
+//uint32_t millis();
+#define GET_MILLIS millis
+#else
+uint32_t get_millisecond_timer(void);
+#define GET_MILLIS get_millisecond_timer
+#endif
+
+// beat16 generates a 16-bit 'sawtooth' wave at a given BPM,
+///        with BPM specified in Q8.8 fixed-point format; e.g.
+///        for this function, 120 BPM MUST BE specified as
+///        120*256 = 30720.
+///        If you just want to specify "120", use beat16 or beat8.
+LIB8STATIC uint16_t beat88( accum88 beats_per_minute_88, uint32_t timebase)
+{
+    // BPM is 'beats per minute', or 'beats per 60000ms'.
+    // To avoid using the (slower) division operator, we
+    // want to convert 'beats per 60000ms' to 'beats per 65536ms',
+    // and then use a simple, fast bit-shift to divide by 65536.
+    //
+    // The ratio 65536:60000 is 279.620266667:256; we'll call it 280:256.
+    // The conversion is accurate to about 0.05%, more or less,
+    // e.g. if you ask for "120 BPM", you'll get about "119.93".
+    return (((GET_MILLIS()) - timebase) * beats_per_minute_88 * 280) >> 16;
+}
+
+/// beat16 generates a 16-bit 'sawtooth' wave at a given BPM
+LIB8STATIC uint16_t beat16( accum88 beats_per_minute, uint32_t timebase)
+{
+    // Convert simple 8-bit BPM's to full Q8.8 accum88's if needed
+    if( beats_per_minute < 256) beats_per_minute <<= 8;
+    return beat88(beats_per_minute, timebase);
+}
+
+/// beat8 generates an 8-bit 'sawtooth' wave at a given BPM
+LIB8STATIC uint8_t beat8( accum88 beats_per_minute, uint32_t timebase)
+{
+    return beat16( beats_per_minute, timebase) >> 8;
+}
+
+/// beatsin88 generates a 16-bit sine wave at a given BPM,
+///           that oscillates within a given range.
+///           For this function, BPM MUST BE SPECIFIED as
+///           a Q8.8 fixed-point value; e.g. 120BPM must be
+///           specified as 120*256 = 30720.
+///           If you just want to specify "120", use beatsin16 or beatsin8.
+LIB8STATIC uint16_t beatsin88( accum88 beats_per_minute_88, uint16_t lowest, uint16_t highest, uint32_t timebase, uint16_t phase_offset)
+{
+    uint16_t beat = beat88( beats_per_minute_88, timebase);
+    uint16_t beatsin = (sin16( beat + phase_offset) + 32768);
+    uint16_t rangewidth = highest - lowest;
+    uint16_t scaledbeat = scale16( beatsin, rangewidth);
+    uint16_t result = lowest + scaledbeat;
+    return result;
+}
+
+/// beatsin16 generates a 16-bit sine wave at a given BPM,
+///           that oscillates within a given range.
+LIB8STATIC uint16_t beatsin16(accum88 beats_per_minute, uint16_t lowest, uint16_t highest, uint32_t timebase, uint16_t phase_offset)
+{
+    uint16_t beat = beat16( beats_per_minute, timebase);
+    uint16_t beatsin = (sin16( beat + phase_offset) + 32768);
+    uint16_t rangewidth = highest - lowest;
+    uint16_t scaledbeat = scale16( beatsin, rangewidth);
+    uint16_t result = lowest + scaledbeat;
+    return result;
+}
+
+/// beatsin8 generates an 8-bit sine wave at a given BPM,
+///           that oscillates within a given range.
+LIB8STATIC uint8_t beatsin8( accum88 beats_per_minute, uint8_t lowest, uint8_t highest, uint32_t timebase, uint8_t phase_offset)
+{
+    uint8_t beat = beat8( beats_per_minute, timebase);
+    uint8_t beatsin = sin8( beat + phase_offset);
+    uint8_t rangewidth = highest - lowest;
+    uint8_t scaledbeat = scale8( beatsin, rangewidth);
+    uint8_t result = lowest + scaledbeat;
+    return result;
+}
+
+
+/// Return the current seconds since boot in a 16-bit value.  Used as part of the
+/// "every N time-periods" mechanism
+LIB8STATIC uint16_t seconds16(void)
+{
+    uint32_t ms = GET_MILLIS();
+    uint16_t s16;
+    s16 = ms / 1000;
+    return s16;
+}
+
+/// Return the current minutes since boot in a 16-bit value.  Used as part of the
+/// "every N time-periods" mechanism
+LIB8STATIC uint16_t minutes16(void)
+{
+    uint32_t ms = GET_MILLIS();
+    uint16_t m16;
+    m16 = (ms / (60000L)) & 0xFFFF;
+    return m16;
+}
+
+/// Return the current hours since boot in an 8-bit value.  Used as part of the
+/// "every N time-periods" mechanism
+LIB8STATIC uint8_t hours8(void)
+{
+    uint32_t ms = GET_MILLIS();
+    uint8_t h8;
+    h8 = (ms / (3600000L)) & 0xFF;
+    return h8;
+}
+
+///@}
+
+#endif
diff --git a/lib/lib8tion/math8.h b/lib/lib8tion/math8.h
new file mode 100644
index 000000000..8c6b6c227
--- /dev/null
+++ b/lib/lib8tion/math8.h
@@ -0,0 +1,552 @@
+#ifndef __INC_LIB8TION_MATH_H
+#define __INC_LIB8TION_MATH_H
+
+#include "scale8.h"
+
+///@ingroup lib8tion
+
+///@defgroup Math Basic math operations
+/// Fast, efficient 8-bit math functions specifically
+/// designed for high-performance LED programming.
+///
+/// Because of the AVR(Arduino) and ARM assembly language
+/// implementations provided, using these functions often
+/// results in smaller and faster code than the equivalent
+/// program using plain "C" arithmetic and logic.
+///@{
+
+
+/// add one byte to another, saturating at 0xFF
+/// @param i - first byte to add
+/// @param j - second byte to add
+/// @returns the sum of i & j, capped at 0xFF
+LIB8STATIC_ALWAYS_INLINE uint8_t qadd8( uint8_t i, uint8_t j)
+{
+#if QADD8_C == 1
+    uint16_t t = i + j;
+    if (t > 255) t = 255;
+    return t;
+#elif QADD8_AVRASM == 1
+    asm volatile(
+         /* First, add j to i, conditioning the C flag */
+         "add %0, %1    \n\t"
+
+         /* Now test the C flag.
+           If C is clear, we branch around a load of 0xFF into i.
+           If C is set, we go ahead and load 0xFF into i.
+         */
+         "brcc L_%=     \n\t"
+         "ldi %0, 0xFF  \n\t"
+         "L_%=: "
+         : "+a" (i)
+         : "a"  (j) );
+    return i;
+#elif QADD8_ARM_DSP_ASM == 1
+    asm volatile( "uqadd8 %0, %0, %1" : "+r" (i) : "r" (j));
+    return i;
+#else
+#error "No implementation for qadd8 available."
+#endif
+}
+
+/// Add one byte to another, saturating at 0x7F
+/// @param i - first byte to add
+/// @param j - second byte to add
+/// @returns the sum of i & j, capped at 0xFF
+LIB8STATIC_ALWAYS_INLINE int8_t qadd7( int8_t i, int8_t j)
+{
+#if QADD7_C == 1
+    int16_t t = i + j;
+    if (t > 127) t = 127;
+    return t;
+#elif QADD7_AVRASM == 1
+    asm volatile(
+         /* First, add j to i, conditioning the V flag */
+         "add %0, %1    \n\t"
+
+         /* Now test the V flag.
+          If V is clear, we branch around a load of 0x7F into i.
+          If V is set, we go ahead and load 0x7F into i.
+          */
+         "brvc L_%=     \n\t"
+         "ldi %0, 0x7F  \n\t"
+         "L_%=: "
+         : "+a" (i)
+         : "a"  (j) );
+
+    return i;
+#elif QADD7_ARM_DSP_ASM == 1
+    asm volatile( "qadd8 %0, %0, %1" : "+r" (i) : "r" (j));
+    return i;
+#else
+#error "No implementation for qadd7 available."
+#endif
+}
+
+/// subtract one byte from another, saturating at 0x00
+/// @returns i - j with a floor of 0
+LIB8STATIC_ALWAYS_INLINE uint8_t qsub8( uint8_t i, uint8_t j)
+{
+#if QSUB8_C == 1
+    int16_t t = i - j;
+    if (t < 0) t = 0;
+    return t;
+#elif QSUB8_AVRASM == 1
+
+    asm volatile(
+         /* First, subtract j from i, conditioning the C flag */
+         "sub %0, %1    \n\t"
+
+         /* Now test the C flag.
+          If C is clear, we branch around a load of 0x00 into i.
+          If C is set, we go ahead and load 0x00 into i.
+          */
+         "brcc L_%=     \n\t"
+         "ldi %0, 0x00  \n\t"
+         "L_%=: "
+         : "+a" (i)
+         : "a"  (j) );
+
+    return i;
+#else
+#error "No implementation for qsub8 available."
+#endif
+}
+
+/// add one byte to another, with one byte result
+LIB8STATIC_ALWAYS_INLINE uint8_t add8( uint8_t i, uint8_t j)
+{
+#if ADD8_C == 1
+    uint16_t t = i + j;
+    return t;
+#elif ADD8_AVRASM == 1
+    // Add j to i, period.
+    asm volatile( "add %0, %1" : "+a" (i) : "a" (j));
+    return i;
+#else
+#error "No implementation for add8 available."
+#endif
+}
+
+/// add one byte to another, with one byte result
+LIB8STATIC_ALWAYS_INLINE uint16_t add8to16( uint8_t i, uint16_t j)
+{
+#if ADD8_C == 1
+    uint16_t t = i + j;
+    return t;
+#elif ADD8_AVRASM == 1
+    // Add i(one byte) to j(two bytes)
+    asm volatile( "add %A[j], %[i]              \n\t"
+                  "adc %B[j], __zero_reg__      \n\t"
+                 : [j] "+a" (j)
+                 : [i] "a"  (i)
+                 );
+    return i;
+#else
+#error "No implementation for add8to16 available."
+#endif
+}
+
+
+/// subtract one byte from another, 8-bit result
+LIB8STATIC_ALWAYS_INLINE uint8_t sub8( uint8_t i, uint8_t j)
+{
+#if SUB8_C == 1
+    int16_t t = i - j;
+    return t;
+#elif SUB8_AVRASM == 1
+    // Subtract j from i, period.
+    asm volatile( "sub %0, %1" : "+a" (i) : "a" (j));
+    return i;
+#else
+#error "No implementation for sub8 available."
+#endif
+}
+
+/// Calculate an integer average of two unsigned
+///       8-bit integer values (uint8_t).
+///       Fractional results are rounded down, e.g. avg8(20,41) = 30
+LIB8STATIC_ALWAYS_INLINE uint8_t avg8( uint8_t i, uint8_t j)
+{
+#if AVG8_C == 1
+    return (i + j) >> 1;
+#elif AVG8_AVRASM == 1
+    asm volatile(
+         /* First, add j to i, 9th bit overflows into C flag */
+         "add %0, %1    \n\t"
+         /* Divide by two, moving C flag into high 8th bit */
+         "ror %0        \n\t"
+         : "+a" (i)
+         : "a"  (j) );
+    return i;
+#else
+#error "No implementation for avg8 available."
+#endif
+}
+
+/// Calculate an integer average of two unsigned
+///       16-bit integer values (uint16_t).
+///       Fractional results are rounded down, e.g. avg16(20,41) = 30
+LIB8STATIC_ALWAYS_INLINE uint16_t avg16( uint16_t i, uint16_t j)
+{
+#if AVG16_C == 1
+    return (uint32_t)((uint32_t)(i) + (uint32_t)(j)) >> 1;
+#elif AVG16_AVRASM == 1
+    asm volatile(
+                 /* First, add jLo (heh) to iLo, 9th bit overflows into C flag */
+                 "add %A[i], %A[j]    \n\t"
+                 /* Now, add C + jHi to iHi, 17th bit overflows into C flag */
+                 "adc %B[i], %B[j]    \n\t"
+                 /* Divide iHi by two, moving C flag into high 16th bit, old 9th bit now in C */
+                 "ror %B[i]        \n\t"
+                 /* Divide iLo by two, moving C flag into high 8th bit */
+                 "ror %A[i]        \n\t"
+                 : [i] "+a" (i)
+                 : [j] "a"  (j) );
+    return i;
+#else
+#error "No implementation for avg16 available."
+#endif
+}
+
+
+/// Calculate an integer average of two signed 7-bit
+///       integers (int8_t)
+///       If the first argument is even, result is rounded down.
+///       If the first argument is odd, result is result up.
+LIB8STATIC_ALWAYS_INLINE int8_t avg7( int8_t i, int8_t j)
+{
+#if AVG7_C == 1
+    return ((i + j) >> 1) + (i & 0x1);
+#elif AVG7_AVRASM == 1
+    asm volatile(
+                 "asr %1        \n\t"
+                 "asr %0        \n\t"
+                 "adc %0, %1    \n\t"
+                 : "+a" (i)
+                 : "a"  (j) );
+    return i;
+#else
+#error "No implementation for avg7 available."
+#endif
+}
+
+/// Calculate an integer average of two signed 15-bit
+///       integers (int16_t)
+///       If the first argument is even, result is rounded down.
+///       If the first argument is odd, result is result up.
+LIB8STATIC_ALWAYS_INLINE int16_t avg15( int16_t i, int16_t j)
+{
+#if AVG15_C == 1
+    return ((int32_t)((int32_t)(i) + (int32_t)(j)) >> 1) + (i & 0x1);
+#elif AVG15_AVRASM == 1
+    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
+#error "No implementation for avg15 available."
+#endif
+}
+
+
+///       Calculate the remainder of one unsigned 8-bit
+///       value divided by anoter, aka A % M.
+///       Implemented by repeated subtraction, which is
+///       very compact, and very fast if A is 'probably'
+///       less than M.  If A is a large multiple of M,
+///       the loop has to execute multiple times.  However,
+///       even in that case, the loop is only two
+///       instructions long on AVR, i.e., quick.
+LIB8STATIC_ALWAYS_INLINE uint8_t mod8( uint8_t a, uint8_t m)
+{
+#if defined(__AVR__)
+    asm volatile (
+                  "L_%=:  sub %[a],%[m]    \n\t"
+                  "       brcc L_%=        \n\t"
+                  "       add %[a],%[m]    \n\t"
+                  : [a] "+r" (a)
+                  : [m] "r"  (m)
+                  );
+#else
+    while( a >= m) a -= m;
+#endif
+    return a;
+}
+
+///          Add two numbers, and calculate the modulo
+///          of the sum and a third number, M.
+///          In other words, it returns (A+B) % M.
+///          It is designed as a compact mechanism for
+///          incrementing a 'mode' switch and wrapping
+///          around back to 'mode 0' when the switch
+///          goes past the end of the available range.
+///          e.g. if you have seven modes, this switches
+///          to the next one and wraps around if needed:
+///            mode = addmod8( mode, 1, 7);
+///LIB8STATIC_ALWAYS_INLINESee 'mod8' for notes on performance.
+LIB8STATIC uint8_t addmod8( uint8_t a, uint8_t b, uint8_t m)
+{
+#if defined(__AVR__)
+    asm volatile (
+                  "       add %[a],%[b]    \n\t"
+                  "L_%=:  sub %[a],%[m]    \n\t"
+                  "       brcc L_%=        \n\t"
+                  "       add %[a],%[m]    \n\t"
+                  : [a] "+r" (a)
+                  : [b] "r"  (b), [m] "r" (m)
+                  );
+#else
+    a += b;
+    while( a >= m) a -= m;
+#endif
+    return a;
+}
+
+///          Subtract two numbers, and calculate the modulo
+///          of the difference and a third number, M.
+///          In other words, it returns (A-B) % M.
+///          It is designed as a compact mechanism for
+///          incrementing a 'mode' switch and wrapping
+///          around back to 'mode 0' when the switch
+///          goes past the end of the available range.
+///          e.g. if you have seven modes, this switches
+///          to the next one and wraps around if needed:
+///            mode = addmod8( mode, 1, 7);
+///LIB8STATIC_ALWAYS_INLINESee 'mod8' for notes on performance.
+LIB8STATIC uint8_t submod8( uint8_t a, uint8_t b, uint8_t m)
+{
+#if defined(__AVR__)
+    asm volatile (
+                  "       sub %[a],%[b]    \n\t"
+                  "L_%=:  sub %[a],%[m]    \n\t"
+                  "       brcc L_%=        \n\t"
+                  "       add %[a],%[m]    \n\t"
+                  : [a] "+r" (a)
+                  : [b] "r"  (b), [m] "r" (m)
+                  );
+#else
+    a -= b;
+    while( a >= m) a -= m;
+#endif
+    return a;
+}
+
+/// 8x8 bit multiplication, with 8 bit result
+LIB8STATIC_ALWAYS_INLINE uint8_t mul8( uint8_t i, uint8_t j)
+{
+#if MUL8_C == 1
+    return ((uint16_t)i * (uint16_t)(j) ) & 0xFF;
+#elif MUL8_AVRASM == 1
+    asm volatile(
+         /* Multiply 8-bit i * 8-bit j, giving 16-bit r1,r0 */
+         "mul %0, %1          \n\t"
+         /* Extract the LOW 8-bits (r0) */
+         "mov %0, r0          \n\t"
+         /* Restore r1 to "0"; it's expected to always be that */
+         "clr __zero_reg__    \n\t"
+         : "+a" (i)
+         : "a"  (j)
+         : "r0", "r1");
+
+    return i;
+#else
+#error "No implementation for mul8 available."
+#endif
+}
+
+
+/// saturating 8x8 bit multiplication, with 8 bit result
+/// @returns the product of i * j, capping at 0xFF
+LIB8STATIC_ALWAYS_INLINE uint8_t qmul8( uint8_t i, uint8_t j)
+{
+#if QMUL8_C == 1
+    int p = ((uint16_t)i * (uint16_t)(j) );
+    if( p > 255) p = 255;
+    return p;
+#elif QMUL8_AVRASM == 1
+    asm volatile(
+                 /* Multiply 8-bit i * 8-bit j, giving 16-bit r1,r0 */
+                 "  mul %0, %1          \n\t"
+                 /* If high byte of result is zero, all is well. */
+                 "  tst r1              \n\t"
+                 "  breq Lnospill_%=    \n\t"
+                 /* If high byte of result > 0, saturate low byte to 0xFF */
+                 "  ldi %0,0xFF         \n\t"
+                 "  rjmp Ldone_%=       \n\t"
+                 "Lnospill_%=:          \n\t"
+                 /* Extract the LOW 8-bits (r0) */
+                 "  mov %0, r0          \n\t"
+                 "Ldone_%=:             \n\t"
+                 /* Restore r1 to "0"; it's expected to always be that */
+                 "  clr __zero_reg__    \n\t"
+                 : "+a" (i)
+                 : "a"  (j)
+                 : "r0", "r1");
+
+    return i;
+#else
+#error "No implementation for qmul8 available."
+#endif
+}
+
+
+/// take abs() of a signed 8-bit uint8_t
+LIB8STATIC_ALWAYS_INLINE int8_t abs8( int8_t i)
+{
+#if ABS8_C == 1
+    if( i < 0) i = -i;
+    return i;
+#elif ABS8_AVRASM == 1
+
+
+    asm volatile(
+         /* First, check the high bit, and prepare to skip if it's clear */
+         "sbrc %0, 7 \n"
+
+         /* Negate the value */
+         "neg %0     \n"
+
+         : "+r" (i) : "r" (i) );
+    return i;
+#else
+#error "No implementation for abs8 available."
+#endif
+}
+
+///         square root for 16-bit integers
+///         About three times faster and five times smaller
+///         than Arduino's general sqrt on AVR.
+LIB8STATIC uint8_t sqrt16(uint16_t x)
+{
+    if( x <= 1) {
+        return x;
+    }
+
+    uint8_t low = 1; // lower bound
+    uint8_t hi, mid;
+
+    if( x > 7904) {
+        hi = 255;
+    } else {
+        hi = (x >> 5) + 8; // initial estimate for upper bound
+    }
+
+    do {
+        mid = (low + hi) >> 1;
+        if ((uint16_t)(mid * mid) > x) {
+            hi = mid - 1;
+        } else {
+            if( mid == 255) {
+                return 255;
+            }
+            low = mid + 1;
+        }
+    } while (hi >= low);
+
+    return low - 1;
+}
+
+/// blend a variable proproportion(0-255) of one byte to another
+/// @param a - the starting byte value
+/// @param b - the byte value to blend toward
+/// @param amountOfB - the proportion (0-255) of b to blend
+/// @returns a byte value between a and b, inclusive
+#if (FASTLED_BLEND_FIXED == 1)
+LIB8STATIC uint8_t blend8( uint8_t a, uint8_t b, uint8_t amountOfB)
+{
+#if BLEND8_C == 1
+    uint16_t partial;
+    uint8_t result;
+
+    uint8_t amountOfA = 255 - amountOfB;
+
+    partial = (a * amountOfA);
+#if (FASTLED_SCALE8_FIXED == 1)
+    partial += a;
+    //partial = add8to16( a, partial);
+#endif
+
+    partial += (b * amountOfB);
+#if (FASTLED_SCALE8_FIXED == 1)
+    partial += b;
+    //partial = add8to16( b, partial);
+#endif
+
+    result = partial >> 8;
+
+    return result;
+
+#elif BLEND8_AVRASM == 1
+    uint16_t partial;
+    uint8_t result;
+
+    asm volatile (
+        /* partial = b * amountOfB */
+        "  mul %[b], %[amountOfB]        \n\t"
+        "  movw %A[partial], r0          \n\t"
+
+        /* amountOfB (aka amountOfA) = 255 - amountOfB */
+        "  com %[amountOfB]              \n\t"
+
+        /* partial += a * amountOfB (aka amountOfA) */
+        "  mul %[a], %[amountOfB]        \n\t"
+
+        "  add %A[partial], r0           \n\t"
+        "  adc %B[partial], r1           \n\t"
+
+        "  clr __zero_reg__              \n\t"
+
+#if (FASTLED_SCALE8_FIXED == 1)
+        /* partial += a */
+        "  add %A[partial], %[a]         \n\t"
+        "  adc %B[partial], __zero_reg__ \n\t"
+
+        // partial += b
+        "  add %A[partial], %[b]         \n\t"
+        "  adc %B[partial], __zero_reg__ \n\t"
+#endif
+
+        : [partial] "=r" (partial),
+          [amountOfB] "+a" (amountOfB)
+        : [a] "a" (a),
+          [b] "a" (b)
+        : "r0", "r1"
+    );
+
+    result = partial >> 8;
+
+    return result;
+
+#else
+#error "No implementation for blend8 available."
+#endif
+}
+
+#else
+LIB8STATIC uint8_t blend8( uint8_t a, uint8_t b, uint8_t amountOfB)
+{
+    // This version loses precision in the integer math
+    // and can actually return results outside of the range
+    // from a to b.  Its use is not recommended.
+    uint8_t result;
+    uint8_t amountOfA = 255 - amountOfB;
+    result = scale8_LEAVING_R1_DIRTY( a, amountOfA)
+           + scale8_LEAVING_R1_DIRTY( b, amountOfB);
+    cleanup_R1();
+    return result;
+}
+#endif
+
+
+///@}
+#endif
diff --git a/lib/lib8tion/random8.h b/lib/lib8tion/random8.h
new file mode 100644
index 000000000..7ee67cbb3
--- /dev/null
+++ b/lib/lib8tion/random8.h
@@ -0,0 +1,94 @@
+#ifndef __INC_LIB8TION_RANDOM_H
+#define __INC_LIB8TION_RANDOM_H
+///@ingroup lib8tion
+
+///@defgroup Random Fast random number generators
+/// Fast 8- and 16- bit unsigned random numbers.
+///  Significantly faster than Arduino random(), but
+///  also somewhat less random.  You can add entropy.
+///@{
+
+// X(n+1) = (2053 * X(n)) + 13849)
+#define FASTLED_RAND16_2053  ((uint16_t)(2053))
+#define FASTLED_RAND16_13849 ((uint16_t)(13849))
+
+/// random number seed
+extern uint16_t rand16seed;// = RAND16_SEED;
+
+/// Generate an 8-bit random number
+LIB8STATIC uint8_t random8(void)
+{
+    rand16seed = (rand16seed * FASTLED_RAND16_2053) + FASTLED_RAND16_13849;
+    // return the sum of the high and low bytes, for better
+    //  mixing and non-sequential correlation
+    return (uint8_t)(((uint8_t)(rand16seed & 0xFF)) +
+                     ((uint8_t)(rand16seed >> 8)));
+}
+
+/// Generate a 16 bit random number
+LIB8STATIC uint16_t random16(void)
+{
+    rand16seed = (rand16seed * FASTLED_RAND16_2053) + FASTLED_RAND16_13849;
+    return rand16seed;
+}
+
+/// Generate an 8-bit random number between 0 and lim
+/// @param lim the upper bound for the result
+LIB8STATIC uint8_t random8_max(uint8_t lim)
+{
+    uint8_t r = random8();
+    r = (r*lim) >> 8;
+    return r;
+}
+
+/// Generate an 8-bit random number in the given range
+/// @param min the lower bound for the random number
+/// @param lim the upper bound for the random number
+LIB8STATIC uint8_t random8_min_max(uint8_t min, uint8_t lim)
+{
+    uint8_t delta = lim - min;
+    uint8_t r = random8_max(delta) + min;
+    return r;
+}
+
+/// Generate an 16-bit random number between 0 and lim
+/// @param lim the upper bound for the result
+LIB8STATIC uint16_t random16_max(uint16_t lim)
+{
+    uint16_t r = random16();
+    uint32_t p = (uint32_t)lim * (uint32_t)r;
+    r = p >> 16;
+    return r;
+}
+
+/// Generate an 16-bit random number in the given range
+/// @param min the lower bound for the random number
+/// @param lim the upper bound for the random number
+LIB8STATIC uint16_t random16_min_max( uint16_t min, uint16_t lim)
+{
+    uint16_t delta = lim - min;
+    uint16_t r = random16_max(delta) + min;
+    return r;
+}
+
+/// Set the 16-bit seed used for the random number generator
+LIB8STATIC void random16_set_seed(uint16_t seed)
+{
+    rand16seed = seed;
+}
+
+/// Get the current seed value for the random number generator
+LIB8STATIC uint16_t random16_get_seed(void)
+{
+    return rand16seed;
+}
+
+/// Add entropy into the random number generator
+LIB8STATIC void random16_add_entropy(uint16_t entropy)
+{
+    rand16seed += entropy;
+}
+
+///@}
+
+#endif
diff --git a/lib/lib8tion/scale8.h b/lib/lib8tion/scale8.h
new file mode 100644
index 000000000..9895fd4d7
--- /dev/null
+++ b/lib/lib8tion/scale8.h
@@ -0,0 +1,542 @@
+#ifndef __INC_LIB8TION_SCALE_H
+#define __INC_LIB8TION_SCALE_H
+
+///@ingroup lib8tion
+
+///@defgroup Scaling Scaling functions
+/// Fast, efficient 8-bit scaling functions specifically
+/// designed for high-performance LED programming.
+///
+/// Because of the AVR(Arduino) and ARM assembly language
+/// implementations provided, using these functions often
+/// results in smaller and faster code than the equivalent
+/// program using plain "C" arithmetic and logic.
+///@{
+
+///  scale one byte by a second one, which is treated as
+///  the numerator of a fraction whose denominator is 256
+///  In other words, it computes i * (scale / 256)
+///  4 clocks AVR with MUL, 2 clocks ARM
+LIB8STATIC_ALWAYS_INLINE uint8_t scale8( uint8_t i, fract8 scale)
+{
+#if SCALE8_C == 1
+#if (FASTLED_SCALE8_FIXED == 1)
+    return (((uint16_t)i) * (1+(uint16_t)(scale))) >> 8;
+#else
+    return ((uint16_t)i * (uint16_t)(scale) ) >> 8;
+#endif
+#elif SCALE8_AVRASM == 1
+#if defined(LIB8_ATTINY)
+#if (FASTLED_SCALE8_FIXED == 1)
+    uint8_t work=i;
+#else
+    uint8_t work=0;
+#endif
+    uint8_t cnt=0x80;
+    asm volatile(
+#if (FASTLED_SCALE8_FIXED == 1)
+        "  inc %[scale]                 \n\t"
+        "  breq DONE_%=                 \n\t"
+        "  clr %[work]                  \n\t"
+#endif
+        "LOOP_%=:                       \n\t"
+        /*"  sbrc %[scale], 0             \n\t"
+        "  add %[work], %[i]            \n\t"
+        "  ror %[work]                  \n\t"
+        "  lsr %[scale]                 \n\t"
+        "  clc                          \n\t"*/
+        "  sbrc %[scale], 0             \n\t"
+        "  add %[work], %[i]            \n\t"
+        "  ror %[work]                  \n\t"
+        "  lsr %[scale]                 \n\t"
+        "  lsr %[cnt]                   \n\t"
+        "brcc LOOP_%=                   \n\t"
+        "DONE_%=:                       \n\t"
+        : [work] "+r" (work), [cnt] "+r" (cnt)
+        : [scale] "r" (scale), [i] "r" (i)
+        :
+      );
+    return work;
+#else
+    asm volatile(
+#if (FASTLED_SCALE8_FIXED==1)
+        // Multiply 8-bit i * 8-bit scale, giving 16-bit r1,r0
+        "mul %0, %1          \n\t"
+        // Add i to r0, possibly setting the carry flag
+        "add r0, %0         \n\t"
+        // load the immediate 0 into i (note, this does _not_ touch any flags)
+        "ldi %0, 0x00       \n\t"
+        // walk and chew gum at the same time
+        "adc %0, r1          \n\t"
+#else
+         /* Multiply 8-bit i * 8-bit scale, giving 16-bit r1,r0 */
+         "mul %0, %1          \n\t"
+         /* Move the high 8-bits of the product (r1) back to i */
+         "mov %0, r1          \n\t"
+         /* Restore r1 to "0"; it's expected to always be that */
+#endif
+         "clr __zero_reg__    \n\t"
+
+         : "+a" (i)      /* writes to i */
+         : "a"  (scale)  /* uses scale */
+         : "r0", "r1"    /* clobbers r0, r1 */ );
+
+    /* Return the result */
+    return i;
+#endif
+#else
+#error "No implementation for scale8 available."
+#endif
+}
+
+
+///  The "video" version of scale8 guarantees that the output will
+///  be only be zero if one or both of the inputs are zero.  If both
+///  inputs are non-zero, the output is guaranteed to be non-zero.
+///  This makes for better 'video'/LED dimming, at the cost of
+///  several additional cycles.
+LIB8STATIC_ALWAYS_INLINE uint8_t scale8_video( uint8_t i, fract8 scale)
+{
+#if SCALE8_C == 1 || defined(LIB8_ATTINY)
+    uint8_t j = (((int)i * (int)scale) >> 8) + ((i&&scale)?1:0);
+    // uint8_t nonzeroscale = (scale != 0) ? 1 : 0;
+    // uint8_t j = (i == 0) ? 0 : (((int)i * (int)(scale) ) >> 8) + nonzeroscale;
+    return j;
+#elif SCALE8_AVRASM == 1
+    uint8_t j=0;
+    asm volatile(
+        "  tst %[i]\n\t"
+        "  breq L_%=\n\t"
+        "  mul %[i], %[scale]\n\t"
+        "  mov %[j], r1\n\t"
+        "  clr __zero_reg__\n\t"
+        "  cpse %[scale], r1\n\t"
+        "  subi %[j], 0xFF\n\t"
+        "L_%=: \n\t"
+        : [j] "+a" (j)
+        : [i] "a" (i), [scale] "a" (scale)
+        : "r0", "r1");
+
+    return j;
+    // uint8_t nonzeroscale = (scale != 0) ? 1 : 0;
+    // asm volatile(
+    //      "      tst %0           \n"
+    //      "      breq L_%=        \n"
+    //      "      mul %0, %1       \n"
+    //      "      mov %0, r1       \n"
+    //      "      add %0, %2       \n"
+    //      "      clr __zero_reg__ \n"
+    //      "L_%=:                  \n"
+
+    //      : "+a" (i)
+    //      : "a" (scale), "a" (nonzeroscale)
+    //      : "r0", "r1");
+
+    // // Return the result
+    // return i;
+#else
+#error "No implementation for scale8_video available."
+#endif
+}
+
+
+/// This version of scale8 does not clean up the R1 register on AVR
+/// If you are doing several 'scale8's in a row, use this, and
+/// then explicitly call cleanup_R1.
+LIB8STATIC_ALWAYS_INLINE uint8_t scale8_LEAVING_R1_DIRTY( uint8_t i, fract8 scale)
+{
+#if SCALE8_C == 1
+#if (FASTLED_SCALE8_FIXED == 1)
+    return (((uint16_t)i) * ((uint16_t)(scale)+1)) >> 8;
+#else
+    return ((int)i * (int)(scale) ) >> 8;
+#endif
+#elif SCALE8_AVRASM == 1
+    asm volatile(
+      #if (FASTLED_SCALE8_FIXED==1)
+              // Multiply 8-bit i * 8-bit scale, giving 16-bit r1,r0
+              "mul %0, %1          \n\t"
+              // Add i to r0, possibly setting the carry flag
+              "add r0, %0         \n\t"
+              // load the immediate 0 into i (note, this does _not_ touch any flags)
+              "ldi %0, 0x00       \n\t"
+              // walk and chew gum at the same time
+              "adc %0, r1          \n\t"
+      #else
+         /* Multiply 8-bit i * 8-bit scale, giving 16-bit r1,r0 */
+         "mul %0, %1    \n\t"
+         /* Move the high 8-bits of the product (r1) back to i */
+         "mov %0, r1    \n\t"
+      #endif
+         /* R1 IS LEFT DIRTY HERE; YOU MUST ZERO IT OUT YOURSELF  */
+         /* "clr __zero_reg__    \n\t" */
+
+         : "+a" (i)      /* writes to i */
+         : "a"  (scale)  /* uses scale */
+         : "r0", "r1"    /* clobbers r0, r1 */ );
+
+    // Return the result
+    return i;
+#else
+#error "No implementation for scale8_LEAVING_R1_DIRTY available."
+#endif
+}
+
+
+/// This version of scale8_video does not clean up the R1 register on AVR
+/// If you are doing several 'scale8_video's in a row, use this, and
+/// then explicitly call cleanup_R1.
+LIB8STATIC_ALWAYS_INLINE uint8_t scale8_video_LEAVING_R1_DIRTY( uint8_t i, fract8 scale)
+{
+#if SCALE8_C == 1 || defined(LIB8_ATTINY)
+    uint8_t j = (((int)i * (int)scale) >> 8) + ((i&&scale)?1:0);
+    // uint8_t nonzeroscale = (scale != 0) ? 1 : 0;
+    // uint8_t j = (i == 0) ? 0 : (((int)i * (int)(scale) ) >> 8) + nonzeroscale;
+    return j;
+#elif SCALE8_AVRASM == 1
+    uint8_t j=0;
+    asm volatile(
+        "  tst %[i]\n\t"
+        "  breq L_%=\n\t"
+        "  mul %[i], %[scale]\n\t"
+        "  mov %[j], r1\n\t"
+        "  breq L_%=\n\t"
+        "  subi %[j], 0xFF\n\t"
+        "L_%=: \n\t"
+        : [j] "+a" (j)
+        : [i] "a" (i), [scale] "a" (scale)
+        : "r0", "r1");
+
+    return j;
+    // uint8_t nonzeroscale = (scale != 0) ? 1 : 0;
+    // asm volatile(
+    //      "      tst %0           \n"
+    //      "      breq L_%=        \n"
+    //      "      mul %0, %1       \n"
+    //      "      mov %0, r1       \n"
+    //      "      add %0, %2       \n"
+    //      "      clr __zero_reg__ \n"
+    //      "L_%=:                  \n"
+
+    //      : "+a" (i)
+    //      : "a" (scale), "a" (nonzeroscale)
+    //      : "r0", "r1");
+
+    // // Return the result
+    // return i;
+#else
+#error "No implementation for scale8_video_LEAVING_R1_DIRTY available."
+#endif
+}
+
+/// Clean up the r1 register after a series of *LEAVING_R1_DIRTY calls
+LIB8STATIC_ALWAYS_INLINE void cleanup_R1(void)
+{
+#if CLEANUP_R1_AVRASM == 1
+    // Restore r1 to "0"; it's expected to always be that
+    asm volatile( "clr __zero_reg__  \n\t" : : : "r1" );
+#endif
+}
+
+
+/// scale a 16-bit unsigned value by an 8-bit value,
+///         considered as numerator of a fraction whose denominator
+///         is 256. In other words, it computes i * (scale / 256)
+
+LIB8STATIC_ALWAYS_INLINE uint16_t scale16by8( uint16_t i, fract8 scale )
+{
+#if SCALE16BY8_C == 1
+    uint16_t result;
+#if FASTLED_SCALE8_FIXED == 1
+    result = (i * (1+((uint16_t)scale))) >> 8;
+#else
+    result = (i * scale) / 256;
+#endif
+    return result;
+#elif SCALE16BY8_AVRASM == 1
+#if FASTLED_SCALE8_FIXED == 1
+    uint16_t result = 0;
+    asm volatile(
+                 // result.A = HighByte( (i.A x scale) + i.A )
+                 "  mul %A[i], %[scale]                 \n\t"
+                 "  add r0, %A[i]                       \n\t"
+            //   "  adc r1, [zero]                      \n\t"
+            //   "  mov %A[result], r1                  \n\t"
+                 "  adc %A[result], r1                  \n\t"
+
+                 // result.A-B += i.B x scale
+                 "  mul %B[i], %[scale]                 \n\t"
+                 "  add %A[result], r0                  \n\t"
+                 "  adc %B[result], r1                  \n\t"
+
+                 // cleanup r1
+                 "  clr __zero_reg__                    \n\t"
+
+                 // result.A-B += i.B
+                 "  add %A[result], %B[i]               \n\t"
+                 "  adc %B[result], __zero_reg__        \n\t"
+
+                 : [result] "+r" (result)
+                 : [i] "r" (i), [scale] "r" (scale)
+                 : "r0", "r1"
+                 );
+    return result;
+#else
+    uint16_t result = 0;
+    asm volatile(
+         // result.A = HighByte(i.A x j )
+         "  mul %A[i], %[scale]                 \n\t"
+         "  mov %A[result], r1                  \n\t"
+         //"  clr %B[result]                      \n\t"
+
+         // result.A-B += i.B x j
+         "  mul %B[i], %[scale]                 \n\t"
+         "  add %A[result], r0                  \n\t"
+         "  adc %B[result], r1                  \n\t"
+
+         // cleanup r1
+         "  clr __zero_reg__                    \n\t"
+
+         : [result] "+r" (result)
+         : [i] "r" (i), [scale] "r" (scale)
+         : "r0", "r1"
+         );
+    return result;
+#endif
+#else
+    #error "No implementation for scale16by8 available."
+#endif
+}
+
+/// scale a 16-bit unsigned value by a 16-bit value,
+///         considered as numerator of a fraction whose denominator
+///         is 65536. In other words, it computes i * (scale / 65536)
+
+LIB8STATIC uint16_t scale16( uint16_t i, fract16 scale )
+{
+  #if SCALE16_C == 1
+    uint16_t result;
+#if FASTLED_SCALE8_FIXED == 1
+    result = ((uint32_t)(i) * (1+(uint32_t)(scale))) / 65536;
+#else
+    result = ((uint32_t)(i) * (uint32_t)(scale)) / 65536;
+#endif
+    return result;
+#elif SCALE16_AVRASM == 1
+#if FASTLED_SCALE8_FIXED == 1
+    // implemented sort of like
+    //   result = ((i * scale) + i ) / 65536
+    //
+    // why not like this, you may ask?
+    //   result = (i * (scale+1)) / 65536
+    // the answer is that if scale is 65535, then scale+1
+    // will be zero, which is not what we want.
+    uint32_t result;
+    asm volatile(
+                 // result.A-B  = i.A x scale.A
+                 "  mul %A[i], %A[scale]                 \n\t"
+                 //  save results...
+                 // basic idea:
+                 //"  mov %A[result], r0                 \n\t"
+                 //"  mov %B[result], r1                 \n\t"
+                 // which can be written as...
+                 "  movw %A[result], r0                   \n\t"
+                 // Because we're going to add i.A-B to
+                 // result.A-D, we DO need to keep both
+                 // the r0 and r1 portions of the product
+                 // UNlike in the 'unfixed scale8' version.
+                 // So the movw here is needed.
+                 : [result] "=r" (result)
+                 : [i] "r" (i),
+                 [scale] "r" (scale)
+                 : "r0", "r1"
+                 );
+
+    asm volatile(
+                 // result.C-D  = i.B x scale.B
+                 "  mul %B[i], %B[scale]                 \n\t"
+                 //"  mov %C[result], r0                 \n\t"
+                 //"  mov %D[result], r1                 \n\t"
+                 "  movw %C[result], r0                   \n\t"
+                 : [result] "+r" (result)
+                 : [i] "r" (i),
+                 [scale] "r" (scale)
+                 : "r0", "r1"
+                 );
+
+    const uint8_t  zero = 0;
+    asm volatile(
+                 // result.B-D += i.B x scale.A
+                 "  mul %B[i], %A[scale]                 \n\t"
+
+                 "  add %B[result], r0                   \n\t"
+                 "  adc %C[result], r1                   \n\t"
+                 "  adc %D[result], %[zero]              \n\t"
+
+                 // result.B-D += i.A x scale.B
+                 "  mul %A[i], %B[scale]                 \n\t"
+
+                 "  add %B[result], r0                   \n\t"
+                 "  adc %C[result], r1                   \n\t"
+                 "  adc %D[result], %[zero]              \n\t"
+
+                 // cleanup r1
+                 "  clr r1                               \n\t"
+
+                 : [result] "+r" (result)
+                 : [i] "r" (i),
+                 [scale] "r" (scale),
+                 [zero] "r" (zero)
+                 : "r0", "r1"
+                 );
+
+    asm volatile(
+                 // result.A-D += i.A-B
+                 "  add %A[result], %A[i]                \n\t"
+                 "  adc %B[result], %B[i]                \n\t"
+                 "  adc %C[result], %[zero]              \n\t"
+                 "  adc %D[result], %[zero]              \n\t"
+                 : [result] "+r" (result)
+                 : [i] "r" (i),
+                 [zero] "r" (zero)
+                 );
+
+    result = result >> 16;
+    return result;
+#else
+    uint32_t result;
+    asm volatile(
+                 // result.A-B  = i.A x scale.A
+                 "  mul %A[i], %A[scale]                 \n\t"
+                 //  save results...
+                 // basic idea:
+                 //"  mov %A[result], r0                 \n\t"
+                 //"  mov %B[result], r1                 \n\t"
+                 // which can be written as...
+                 "  movw %A[result], r0                   \n\t"
+                 // We actually don't need to do anything with r0,
+                 // as result.A is never used again here, so we
+                 // could just move the high byte, but movw is
+                 // one clock cycle, just like mov, so might as
+                 // well, in case we want to use this code for
+                 // a generic 16x16 multiply somewhere.
+
+                 : [result] "=r" (result)
+                 : [i] "r" (i),
+                   [scale] "r" (scale)
+                 : "r0", "r1"
+                 );
+
+    asm volatile(
+                 // result.C-D  = i.B x scale.B
+                 "  mul %B[i], %B[scale]                 \n\t"
+                 //"  mov %C[result], r0                 \n\t"
+                 //"  mov %D[result], r1                 \n\t"
+                 "  movw %C[result], r0                   \n\t"
+                 : [result] "+r" (result)
+                 : [i] "r" (i),
+                   [scale] "r" (scale)
+                 : "r0", "r1"
+                 );
+
+    const uint8_t  zero = 0;
+    asm volatile(
+                 // result.B-D += i.B x scale.A
+                 "  mul %B[i], %A[scale]                 \n\t"
+
+                 "  add %B[result], r0                   \n\t"
+                 "  adc %C[result], r1                   \n\t"
+                 "  adc %D[result], %[zero]              \n\t"
+
+                 // result.B-D += i.A x scale.B
+                 "  mul %A[i], %B[scale]                 \n\t"
+
+                 "  add %B[result], r0                   \n\t"
+                 "  adc %C[result], r1                   \n\t"
+                 "  adc %D[result], %[zero]              \n\t"
+
+                 // cleanup r1
+                 "  clr r1                               \n\t"
+
+                 : [result] "+r" (result)
+                 : [i] "r" (i),
+                   [scale] "r" (scale),
+                   [zero] "r" (zero)
+                 : "r0", "r1"
+                 );
+
+    result = result >> 16;
+    return result;
+#endif
+#else
+    #error "No implementation for scale16 available."
+#endif
+}
+///@}
+
+///@defgroup Dimming Dimming and brightening functions
+///
+/// Dimming and brightening functions
+///
+/// The eye does not respond in a linear way to light.
+/// High speed PWM'd LEDs at 50% duty cycle appear far
+/// brighter then the 'half as bright' you might expect.
+///
+/// If you want your midpoint brightness leve (128) to
+/// appear half as bright as 'full' brightness (255), you
+/// have to apply a 'dimming function'.
+///@{
+
+/// Adjust a scaling value for dimming
+LIB8STATIC uint8_t dim8_raw( uint8_t x)
+{
+    return scale8( x, x);
+}
+
+/// Adjust a scaling value for dimming for video (value will never go below 1)
+LIB8STATIC uint8_t dim8_video( uint8_t x)
+{
+    return scale8_video( x, x);
+}
+
+/// Linear version of the dimming function that halves for values < 128
+LIB8STATIC uint8_t dim8_lin( uint8_t x )
+{
+    if( x & 0x80 ) {
+        x = scale8( x, x);
+    } else {
+        x += 1;
+        x /= 2;
+    }
+    return x;
+}
+
+/// inverse of the dimming function, brighten a value
+LIB8STATIC uint8_t brighten8_raw( uint8_t x)
+{
+    uint8_t ix = 255 - x;
+    return 255 - scale8( ix, ix);
+}
+
+/// inverse of the dimming function, brighten a value
+LIB8STATIC uint8_t brighten8_video( uint8_t x)
+{
+    uint8_t ix = 255 - x;
+    return 255 - scale8_video( ix, ix);
+}
+
+/// inverse of the dimming function, brighten a value
+LIB8STATIC uint8_t brighten8_lin( uint8_t x )
+{
+    uint8_t ix = 255 - x;
+    if( ix & 0x80 ) {
+        ix = scale8( ix, ix);
+    } else {
+        ix += 1;
+        ix /= 2;
+    }
+    return 255 - ix;
+}
+
+///@}
+#endif
diff --git a/lib/lib8tion/trig8.h b/lib/lib8tion/trig8.h
new file mode 100644
index 000000000..4907c6ff3
--- /dev/null
+++ b/lib/lib8tion/trig8.h
@@ -0,0 +1,259 @@
+#ifndef __INC_LIB8TION_TRIG_H
+#define __INC_LIB8TION_TRIG_H
+
+///@ingroup lib8tion
+
+///@defgroup Trig Fast trig functions
+/// Fast 8 and 16-bit approximations of sin(x) and cos(x).
+///        Don't use these approximations for calculating the
+///        trajectory of a rocket to Mars, but they're great
+///        for art projects and LED displays.
+///
+///        On Arduino/AVR, the 16-bit approximation is more than
+///        10X faster than floating point sin(x) and cos(x), while
+/// the 8-bit approximation is more than 20X faster.
+///@{
+
+#if defined(__AVR__)
+#define sin16 sin16_avr
+#else
+#define sin16 sin16_C
+#endif
+
+/// Fast 16-bit approximation of sin(x). This approximation never varies more than
+/// 0.69% from the floating point value you'd get by doing
+///
+///     float s = sin(x) * 32767.0;
+///
+/// @param theta input angle from 0-65535
+/// @returns sin of theta, value between -32767 to 32767.
+LIB8STATIC int16_t sin16_avr( uint16_t theta )
+{
+    static const uint8_t data[] =
+    { 0,         0,         49, 0, 6393%256,   6393/256, 48, 0,
+      12539%256, 12539/256, 44, 0, 18204%256, 18204/256, 38, 0,
+      23170%256, 23170/256, 31, 0, 27245%256, 27245/256, 23, 0,
+      30273%256, 30273/256, 14, 0, 32137%256, 32137/256,  4 /*,0*/ };
+
+    uint16_t offset = (theta & 0x3FFF);
+
+    // AVR doesn't have a multi-bit shift instruction,
+    // so if we say "offset >>= 3", gcc makes a tiny loop.
+    // Inserting empty volatile statements between each
+    // bit shift forces gcc to unroll the loop.
+    offset >>= 1; // 0..8191
+    asm volatile("");
+    offset >>= 1; // 0..4095
+    asm volatile("");
+    offset >>= 1; // 0..2047
+
+    if( theta & 0x4000 ) offset = 2047 - offset;
+
+    uint8_t sectionX4;
+    sectionX4 = offset / 256;
+    sectionX4 *= 4;
+
+    uint8_t m;
+
+    union {
+        uint16_t b;
+        struct {
+            uint8_t blo;
+            uint8_t bhi;
+        };
+    } u;
+
+    //in effect u.b = blo + (256 * bhi);
+    u.blo = data[ sectionX4 ];
+    u.bhi = data[ sectionX4 + 1];
+    m     = data[ sectionX4 + 2];
+
+    uint8_t secoffset8 = (uint8_t)(offset) / 2;
+
+    uint16_t mx = m * secoffset8;
+
+    int16_t  y  = mx + u.b;
+    if( theta & 0x8000 ) y = -y;
+
+    return y;
+}
+
+/// Fast 16-bit approximation of sin(x). This approximation never varies more than
+/// 0.69% from the floating point value you'd get by doing
+///
+///     float s = sin(x) * 32767.0;
+///
+/// @param theta input angle from 0-65535
+/// @returns sin of theta, value between -32767 to 32767.
+LIB8STATIC int16_t sin16_C( uint16_t theta )
+{
+    static const uint16_t base[] =
+    { 0, 6393, 12539, 18204, 23170, 27245, 30273, 32137 };
+    static const uint8_t slope[] =
+    { 49, 48, 44, 38, 31, 23, 14, 4 };
+
+    uint16_t offset = (theta & 0x3FFF) >> 3; // 0..2047
+    if( theta & 0x4000 ) offset = 2047 - offset;
+
+    uint8_t section = offset / 256; // 0..7
+    uint16_t b   = base[section];
+    uint8_t  m   = slope[section];
+
+    uint8_t secoffset8 = (uint8_t)(offset) / 2;
+
+    uint16_t mx = m * secoffset8;
+    int16_t  y  = mx + b;
+
+    if( theta & 0x8000 ) y = -y;
+
+    return y;
+}
+
+
+/// Fast 16-bit approximation of cos(x). This approximation never varies more than
+/// 0.69% from the floating point value you'd get by doing
+///
+///     float s = cos(x) * 32767.0;
+///
+/// @param theta input angle from 0-65535
+/// @returns sin of theta, value between -32767 to 32767.
+LIB8STATIC int16_t cos16( uint16_t theta)
+{
+    return sin16( theta + 16384);
+}
+
+///////////////////////////////////////////////////////////////////////
+
+// sin8 & cos8
+//        Fast 8-bit approximations of sin(x) & cos(x).
+//        Input angle is an unsigned int from 0-255.
+//        Output is an unsigned int from 0 to 255.
+//
+//        This approximation can vary to to 2%
+//        from the floating point value you'd get by doing
+//          float s = (sin( x ) * 128.0) + 128;
+//
+//        Don't use this approximation for calculating the
+//        "real" trigonometric calculations, but it's great
+//        for art projects and LED displays.
+//
+//        On Arduino/AVR, this approximation is more than
+//        20X faster than floating point sin(x) and cos(x)
+
+#if defined(__AVR__) && !defined(LIB8_ATTINY)
+#define sin8 sin8_avr
+#else
+#define sin8 sin8_C
+#endif
+
+
+const uint8_t b_m16_interleave[] = { 0, 49, 49, 41, 90, 27, 117, 10 };
+
+/// Fast 8-bit approximation of sin(x). This approximation never varies more than
+/// 2% from the floating point value you'd get by doing
+///
+///     float s = (sin(x) * 128.0) + 128;
+///
+/// @param theta input angle from 0-255
+/// @returns sin of theta, value between 0 and 255
+LIB8STATIC uint8_t  sin8_avr( uint8_t theta)
+{
+    uint8_t offset = theta;
+
+    asm volatile(
+                 "sbrc %[theta],6         \n\t"
+                 "com  %[offset]           \n\t"
+                 : [theta] "+r" (theta), [offset] "+r" (offset)
+                 );
+
+    offset &= 0x3F; // 0..63
+
+    uint8_t secoffset  = offset & 0x0F; // 0..15
+    if( theta & 0x40) secoffset++;
+
+    uint8_t m16; uint8_t b;
+
+    uint8_t section = offset >> 4; // 0..3
+    uint8_t s2 = section * 2;
+
+    const uint8_t* p = b_m16_interleave;
+    p += s2;
+    b   = *p;
+    p++;
+    m16 = *p;
+
+    uint8_t mx;
+    uint8_t xr1;
+    asm volatile(
+                 "mul %[m16],%[secoffset]   \n\t"
+                 "mov %[mx],r0              \n\t"
+                 "mov %[xr1],r1             \n\t"
+                 "eor  r1, r1               \n\t"
+                 "swap %[mx]                \n\t"
+                 "andi %[mx],0x0F           \n\t"
+                 "swap %[xr1]               \n\t"
+                 "andi %[xr1], 0xF0         \n\t"
+                 "or   %[mx], %[xr1]        \n\t"
+                 : [mx] "=d" (mx), [xr1] "=d" (xr1)
+                 : [m16] "d" (m16), [secoffset] "d" (secoffset)
+                 );
+
+    int8_t y = mx + b;
+    if( theta & 0x80 ) y = -y;
+
+    y += 128;
+
+    return y;
+}
+
+
+/// Fast 8-bit approximation of sin(x). This approximation never varies more than
+/// 2% from the floating point value you'd get by doing
+///
+///     float s = (sin(x) * 128.0) + 128;
+///
+/// @param theta input angle from 0-255
+/// @returns sin of theta, value between 0 and 255
+LIB8STATIC uint8_t sin8_C( uint8_t theta)
+{
+    uint8_t offset = theta;
+    if( theta & 0x40 ) {
+        offset = (uint8_t)255 - offset;
+    }
+    offset &= 0x3F; // 0..63
+
+    uint8_t secoffset  = offset & 0x0F; // 0..15
+    if( theta & 0x40) secoffset++;
+
+    uint8_t section = offset >> 4; // 0..3
+    uint8_t s2 = section * 2;
+    const uint8_t* p = b_m16_interleave;
+    p += s2;
+    uint8_t b   =  *p;
+    p++;
+    uint8_t m16 =  *p;
+
+    uint8_t mx = (m16 * secoffset) >> 4;
+
+    int8_t y = mx + b;
+    if( theta & 0x80 ) y = -y;
+
+    y += 128;
+
+    return y;
+}
+
+/// Fast 8-bit approximation of cos(x). This approximation never varies more than
+/// 2% from the floating point value you'd get by doing
+///
+///     float s = (cos(x) * 128.0) + 128;
+///
+/// @param theta input angle from 0-255
+/// @returns sin of theta, value between 0 and 255
+LIB8STATIC uint8_t cos8( uint8_t theta)
+{
+    return sin8( theta + 64);
+}
+
+///@}
+#endif