/*
 * light weight WS2812 lib V2.0b
 *
 * Controls WS2811/WS2812/WS2812B RGB-LEDs
 * Author: Tim (cpldcpu@gmail.com)
 *
 * Jan 18th, 2014  v2.0b Initial Version
 * Nov 29th, 2015  v2.3  Added SK6812RGBW support
 *
 * This program is free software: you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation, either version 2 of the License, or
 * (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
#include "ws2812.h"
#include <avr/interrupt.h>
#include <avr/io.h>
#include <util/delay.h>

#define pinmask(pin) (_BV((pin)&0xF))

/*
 * Forward declare internal functions
 *
 * The functions take a byte-array and send to the data output as WS2812 bitstream.
 * The length is the number of bytes to send - three per LED.
 */

static inline void ws2812_sendarray_mask(uint8_t *data, uint16_t datlen, uint8_t masklo, uint8_t maskhi);

// Setleds for standard RGB
void inline ws2812_setleds(LED_TYPE *ledarray, uint16_t number_of_leds) {
    // wrap up usage of RGB_DI_PIN
    ws2812_setleds_pin(ledarray, number_of_leds, RGB_DI_PIN);
}

void ws2812_setleds_pin(LED_TYPE *ledarray, uint16_t number_of_leds, uint8_t pin) {
    DDRx_ADDRESS(RGB_DI_PIN) |= pinmask(pin);

    uint8_t masklo = ~(pinmask(pin)) & PORTx_ADDRESS(pin);
    uint8_t maskhi = pinmask(pin) | PORTx_ADDRESS(pin);

    ws2812_sendarray_mask((uint8_t *)ledarray, number_of_leds * sizeof(LED_TYPE), masklo, maskhi);

#ifdef RGBW
    _delay_us(80);
#else
    _delay_us(50);
#endif
}

/*
  This routine writes an array of bytes with RGB values to the Dataout pin
  using the fast 800kHz clockless WS2811/2812 protocol.
*/

// Timing in ns
#define w_zeropulse 350
#define w_onepulse 900
#define w_totalperiod 1250

// Fixed cycles used by the inner loop
#define w_fixedlow 2
#define w_fixedhigh 4
#define w_fixedtotal 8

// Insert NOPs to match the timing, if possible
#define w_zerocycles (((F_CPU / 1000) * w_zeropulse) / 1000000)
#define w_onecycles (((F_CPU / 1000) * w_onepulse + 500000) / 1000000)
#define w_totalcycles (((F_CPU / 1000) * w_totalperiod + 500000) / 1000000)

// w1 - nops between rising edge and falling edge - low
#define w1 (w_zerocycles - w_fixedlow)
// w2   nops between fe low and fe high
#define w2 (w_onecycles - w_fixedhigh - w1)
// w3   nops to complete loop
#define w3 (w_totalcycles - w_fixedtotal - w1 - w2)

#if w1 > 0
#    define w1_nops w1
#else
#    define w1_nops 0
#endif

// The only critical timing parameter is the minimum pulse length of the "0"
// Warn or throw error if this timing can not be met with current F_CPU settings.
#define w_lowtime ((w1_nops + w_fixedlow) * 1000000) / (F_CPU / 1000)
#if w_lowtime > 550
#    error "Light_ws2812: Sorry, the clock speed is too low. Did you set F_CPU correctly?"
#elif w_lowtime > 450
#    warning "Light_ws2812: The timing is critical and may only work on WS2812B, not on WS2812(S)."
#    warning "Please consider a higher clockspeed, if possible"
#endif

#if w2 > 0
#    define w2_nops w2
#else
#    define w2_nops 0
#endif

#if w3 > 0
#    define w3_nops w3
#else
#    define w3_nops 0
#endif

#define w_nop1 "nop      \n\t"
#define w_nop2 "rjmp .+0 \n\t"
#define w_nop4 w_nop2 w_nop2
#define w_nop8 w_nop4 w_nop4
#define w_nop16 w_nop8 w_nop8

static inline void ws2812_sendarray_mask(uint8_t *data, uint16_t datlen, uint8_t masklo, uint8_t maskhi) {
    uint8_t curbyte, ctr, sreg_prev;

    sreg_prev = SREG;
    cli();

    while (datlen--) {
        curbyte = (*data++);

        asm volatile("       ldi   %0,8  \n\t"
                     "loop%=:            \n\t"
                     "       out   %2,%3 \n\t"  //  '1' [01] '0' [01] - re
#if (w1_nops & 1)
                     w_nop1
#endif
#if (w1_nops & 2)
                         w_nop2
#endif
#if (w1_nops & 4)
                             w_nop4
#endif
#if (w1_nops & 8)
                                 w_nop8
#endif
#if (w1_nops & 16)
                                     w_nop16
#endif
                     "       sbrs  %1,7  \n\t"  //  '1' [03] '0' [02]
                     "       out   %2,%4 \n\t"  //  '1' [--] '0' [03] - fe-low
                     "       lsl   %1    \n\t"  //  '1' [04] '0' [04]
#if (w2_nops & 1)
                     w_nop1
#endif
#if (w2_nops & 2)
                         w_nop2
#endif
#if (w2_nops & 4)
                             w_nop4
#endif
#if (w2_nops & 8)
                                 w_nop8
#endif
#if (w2_nops & 16)
                                     w_nop16
#endif
                     "       out   %2,%4 \n\t"  //  '1' [+1] '0' [+1] - fe-high
#if (w3_nops & 1)
                     w_nop1
#endif
#if (w3_nops & 2)
                         w_nop2
#endif
#if (w3_nops & 4)
                             w_nop4
#endif
#if (w3_nops & 8)
                                 w_nop8
#endif
#if (w3_nops & 16)
                                     w_nop16
#endif

                     "       dec   %0    \n\t"  //  '1' [+2] '0' [+2]
                     "       brne  loop%=\n\t"  //  '1' [+3] '0' [+4]
                     : "=&d"(ctr)
                     : "r"(curbyte), "I"(_SFR_IO_ADDR(PORTx_ADDRESS(RGB_DI_PIN))), "r"(maskhi), "r"(masklo));
    }

    SREG = sreg_prev;
}