snes9x/apu/resampler.h

/* Simple resampler based on bsnes's ruby audio library */

#ifndef __RESAMPLER_H
#define __RESAMPLER_H

#include "ring_buffer.h"

#undef MIN
#define MIN(a, b) ((a) < (b) ? (a) : (b))

#undef CLAMP
#undef short_clamp
#define CLAMP(x, low, high) (((x) > (high)) ? (high) : (((x) < (low)) ? (low) : (x)))
#define short_clamp(n) ((short) CLAMP((n), -32768, 32767))

class Resampler : public ring_buffer
{
    protected:

        double r_step;
        double r_frac;
        int    r_left[4], r_right[4];

        double
        hermite (double mu1, double a, double b, double c, double d)
        {
            const double tension = 0.0; //-1 = low, 0 = normal, 1 = high
            const double bias    = 0.0; //-1 = left, 0 = even, 1 = right

            double mu2, mu3, m0, m1, a0, a1, a2, a3;

            mu2 = mu1 * mu1;
            mu3 = mu2 * mu1;

            m0  = (b - a) * (1 + bias) * (1 - tension) / 2;
            m0 += (c - b) * (1 - bias) * (1 - tension) / 2;
            m1  = (c - b) * (1 + bias) * (1 - tension) / 2;
            m1 += (d - c) * (1 - bias) * (1 - tension) / 2;

            a0 = +2 * mu3 - 3 * mu2 + 1;
            a1 =      mu3 - 2 * mu2 + mu1;
            a2 =      mu3 -     mu2;
            a3 = -2 * mu3 + 3 * mu2;

            return (a0 * b) + (a1 * m0) + (a2 * m1) + (a3 * c);
        }

    public:
        Resampler (int num_samples) : ring_buffer (num_samples << 1)
        {
            r_frac = 0.0;
        }

        ~Resampler ()
        {
        }

        void
        time_ratio (double ratio)
        {
            r_step = ratio;
            clear ();
        }

        void
        clear (void)
        {
            ring_buffer::clear ();
            r_frac = 0;
            r_left [0] = r_left [1] = r_left [2] = r_left [3] = 0;
            r_right[0] = r_right[1] = r_right[2] = r_right[3] = 0;
        }

        void
        read (short *data, int num_samples)
        {
            int i_position = start >> 1;
            short *internal_buffer = (short *) buffer;
            int o_position = 0;
            int consumed = 0;

            while (o_position < num_samples && consumed < buffer_size)
            {
                int s_left = internal_buffer[i_position];
                int s_right = internal_buffer[i_position + 1];
                const double margin_of_error = 1.0e-10;

                if (fabs(r_step - 1.0) < margin_of_error)
                {
                    data[o_position] = (short) s_left;
                    data[o_position + 1] = (short) s_right;

                    o_position += 2;
                    i_position = (i_position + 2) % (buffer_size >> 1);
                    consumed += 2;

                    continue;
                }

                r_left [0] = r_left [1];
                r_left [1] = r_left [2];
                r_left [2] = r_left [3];
                r_left [3] = s_left;

                r_right[0] = r_right[1];
                r_right[1] = r_right[2];
                r_right[2] = r_right[3];
                r_right[3] = s_right;

                while (r_frac <= 1.0 && o_position < num_samples)
                {
                    data[o_position]     = short_clamp (hermite (r_frac, r_left [0], r_left [1], r_left [2], r_left [3]));
                    data[o_position + 1] = short_clamp (hermite (r_frac, r_right[0], r_right[1], r_right[2], r_right[3]));

                    o_position += 2;

                    r_frac += r_step;
                }

                if (r_frac > 1.0)
                {
                    r_frac -= 1.0;
                    i_position = (i_position + 2) % (buffer_size >> 1);
                    consumed += 2;
                }
            }

            size -= consumed << 1;
            start = (start + (consumed << 1)) % buffer_size;
        }

        bool
        push (short *src, int num_samples)
        {
            if (max_write () < num_samples)
                return false;

            ring_buffer::push ((unsigned char *) src, num_samples << 1);

            return true;
        }

        int
        max_write (void)
        {
            return space_empty () >> 1;
        }

        void
        resize (int num_samples)
        {
            ring_buffer::resize (num_samples << 1);
        }

        int
        avail (void)
        {
            return (int) floor (((size >> 2) - r_frac) / r_step) * 2;
        }
};

#endif /* __RESAMPLER_H */
Initial 1.52 import 2010-09-25 15:46:12 +00:00			`/* Simple resampler based on bsnes's ruby audio library */`

			`#ifndef __RESAMPLER_H`
			`#define __RESAMPLER_H`

			`#include "ring_buffer.h"`

			`#undef MIN`
			`#define MIN(a, b) ((a) < (b) ? (a) : (b))`

			`#undef CLAMP`
			`#undef short_clamp`
			`#define CLAMP(x, low, high) (((x) > (high)) ? (high) : (((x) < (low)) ? (low) : (x)))`
			`#define short_clamp(n) ((short) CLAMP((n), -32768, 32767))`

			`class Resampler : public ring_buffer`
			`{`
			`protected:`

			`double r_step;`
			`double r_frac;`
			`int r_left[4], r_right[4];`

			`double`
			`hermite (double mu1, double a, double b, double c, double d)`
			`{`
			`const double tension = 0.0; //-1 = low, 0 = normal, 1 = high`
			`const double bias = 0.0; //-1 = left, 0 = even, 1 = right`

			`double mu2, mu3, m0, m1, a0, a1, a2, a3;`

			`mu2 = mu1 * mu1;`
			`mu3 = mu2 * mu1;`

			`m0 = (b - a) * (1 + bias) * (1 - tension) / 2;`
			`m0 += (c - b) * (1 - bias) * (1 - tension) / 2;`
			`m1 = (c - b) * (1 + bias) * (1 - tension) / 2;`
			`m1 += (d - c) * (1 - bias) * (1 - tension) / 2;`

			`a0 = +2 * mu3 - 3 * mu2 + 1;`
			`a1 = mu3 - 2 * mu2 + mu1;`
			`a2 = mu3 - mu2;`
			`a3 = -2 * mu3 + 3 * mu2;`

			`return (a0 * b) + (a1 * m0) + (a2 * m1) + (a3 * c);`
			`}`

			`public:`
			`Resampler (int num_samples) : ring_buffer (num_samples << 1)`
			`{`
			`r_frac = 0.0;`
			`}`

			`~Resampler ()`
			`{`
			`}`

			`void`
			`time_ratio (double ratio)`
			`{`
			`r_step = ratio;`
			`clear ();`
			`}`

			`void`
			`clear (void)`
			`{`
			`ring_buffer::clear ();`
			`r_frac = 0;`
			`r_left [0] = r_left [1] = r_left [2] = r_left [3] = 0;`
			`r_right[0] = r_right[1] = r_right[2] = r_right[3] = 0;`
			`}`

			`void`
			`read (short *data, int num_samples)`
			`{`
			`int i_position = start >> 1;`
			`short internal_buffer = (short ) buffer;`
			`int o_position = 0;`
			`int consumed = 0;`

			`while (o_position < num_samples && consumed < buffer_size)`
			`{`
			`int s_left = internal_buffer[i_position];`
			`int s_right = internal_buffer[i_position + 1];`
			`const double margin_of_error = 1.0e-10;`

			`if (fabs(r_step - 1.0) < margin_of_error)`
			`{`
			`data[o_position] = (short) s_left;`
			`data[o_position + 1] = (short) s_right;`

			`o_position += 2;`
			`i_position = (i_position + 2) % (buffer_size >> 1);`
			`consumed += 2;`

			`continue;`
			`}`

			`r_left [0] = r_left [1];`
			`r_left [1] = r_left [2];`
			`r_left [2] = r_left [3];`
			`r_left [3] = s_left;`

			`r_right[0] = r_right[1];`
			`r_right[1] = r_right[2];`
			`r_right[2] = r_right[3];`
			`r_right[3] = s_right;`

			`while (r_frac <= 1.0 && o_position < num_samples)`
			`{`
			`data[o_position] = short_clamp (hermite (r_frac, r_left [0], r_left [1], r_left [2], r_left [3]));`
			`data[o_position + 1] = short_clamp (hermite (r_frac, r_right[0], r_right[1], r_right[2], r_right[3]));`

			`o_position += 2;`

			`r_frac += r_step;`
			`}`

			`if (r_frac > 1.0)`
			`{`
			`r_frac -= 1.0;`
			`i_position = (i_position + 2) % (buffer_size >> 1);`
			`consumed += 2;`
			`}`
			`}`

			`size -= consumed << 1;`
			`start = (start + (consumed << 1)) % buffer_size;`
			`}`

			`bool`
			`push (short *src, int num_samples)`
			`{`
			`if (max_write () < num_samples)`
			`return false;`

			`ring_buffer::push ((unsigned char *) src, num_samples << 1);`

			`return true;`
			`}`

			`int`
			`max_write (void)`
			`{`
			`return space_empty () >> 1;`
			`}`

			`void`
			`resize (int num_samples)`
			`{`
			`ring_buffer::resize (num_samples << 1);`
			`}`

			`int`
			`avail (void)`
			`{`
			`return (int) floor (((size >> 2) - r_frac) / r_step) * 2;`
			`}`
			`};`

			`#endif /* __RESAMPLER_H */`