1 files changed, 197 insertions, 0 deletions

diff --git a/source/freqshift~.c b/source/freqshift~.c
new file mode 100644
index 0000000..a7460c5
--- /dev/null
+++ b/source/freqshift~.c
@@ -0,0 +1,197 @@
+/* sIgpAck

+ * for

+ * pure-data

+ * www.weiss-archiv.de */

+

+#include "m_pd.h"

+#include <math.h>

+#ifdef _MSC_VER

+#pragma warning( disable : 4244 )

+#pragma warning( disable : 4305 )

+#define M_PI 3.14159265358979323846

+#endif

+

+/* ------------------------ sp.freqshift~ ----------------------------- */

+/* frequency shifter */

+/* code from swh_plugins by steve harris www.plugins.org.uk */

+

+#define SIN_T_SIZE 64

+#define D_SIZE 256

+#define NZEROS 200

+

+static t_class *freqshift_tilde_class;

+

+typedef struct _freqshift_tilde

+{

+    t_object x_obj;

+	t_float x_shift;//[0 - 5000]

+	float *x_delay;

+	unsigned int x_dptr;

+	t_float x_fs;

+	t_float x_last_shift;

+	t_float x_phi;

+	float *x_sint;

+	float x_f;

+} t_freqshift_tilde;

+

+static void *freqshift_tilde_new(t_floatarg shift)

+{

+	unsigned int i;

+

+    t_freqshift_tilde *x = (t_freqshift_tilde *)pd_new(freqshift_tilde_class);

+	//x->x_shift = shift;

+    outlet_new(&x->x_obj, gensym("signal"));

+	outlet_new(&x->x_obj, gensym("signal"));

+	floatinlet_new(&x->x_obj, &x->x_shift);

+	x->x_fs = sys_getsr();

+	x->x_delay = (float *)getbytes(D_SIZE * sizeof(float));

+	x->x_sint = (float *)getbytes(SIN_T_SIZE * sizeof(float));

+	x->x_dptr = 0;

+	x->x_phi = 0.0f;

+	x->x_last_shift = 0.0f;

+	x->x_f = 0;

+	for (i = 0; i < SIN_T_SIZE; i++) {

+	x->x_sint[i] = sin(2.0f * M_PI * (float)i / (float)SIN_T_SIZE);

+	}

+	if (shift) x->x_shift = shift;

+	else x->x_shift = 0;

+    return (x);

+}

+

+/* The non-zero taps of the Hilbert transformer */

+static float xcoeffs[] = {

+     +0.0008103736f, +0.0008457886f, +0.0009017196f, +0.0009793364f,

+     +0.0010798341f, +0.0012044365f, +0.0013544008f, +0.0015310235f,

+     +0.0017356466f, +0.0019696659f, +0.0022345404f, +0.0025318040f,

+     +0.0028630784f, +0.0032300896f, +0.0036346867f, +0.0040788644f,

+     +0.0045647903f, +0.0050948365f, +0.0056716186f, +0.0062980419f,

+     +0.0069773575f, +0.0077132300f, +0.0085098208f, +0.0093718901f,

+     +0.0103049226f, +0.0113152847f, +0.0124104218f, +0.0135991079f,

+     +0.0148917649f, +0.0163008758f, +0.0178415242f, +0.0195321089f,

+     +0.0213953037f, +0.0234593652f, +0.0257599469f, +0.0283426636f,

+     +0.0312667947f, +0.0346107648f, +0.0384804823f, +0.0430224431f,

+     +0.0484451086f, +0.0550553725f, +0.0633242001f, +0.0740128560f,

+     +0.0884368322f, +0.1090816773f, +0.1412745301f, +0.1988673273f,

+     +0.3326528346f, +0.9997730178f, -0.9997730178f, -0.3326528346f,

+     -0.1988673273f, -0.1412745301f, -0.1090816773f, -0.0884368322f,

+     -0.0740128560f, -0.0633242001f, -0.0550553725f, -0.0484451086f,

+     -0.0430224431f, -0.0384804823f, -0.0346107648f, -0.0312667947f,

+     -0.0283426636f, -0.0257599469f, -0.0234593652f, -0.0213953037f,

+     -0.0195321089f, -0.0178415242f, -0.0163008758f, -0.0148917649f,

+     -0.0135991079f, -0.0124104218f, -0.0113152847f, -0.0103049226f,

+     -0.0093718901f, -0.0085098208f, -0.0077132300f, -0.0069773575f,

+     -0.0062980419f, -0.0056716186f, -0.0050948365f, -0.0045647903f,

+     -0.0040788644f, -0.0036346867f, -0.0032300896f, -0.0028630784f,

+     -0.0025318040f, -0.0022345404f, -0.0019696659f, -0.0017356466f,

+     -0.0015310235f, -0.0013544008f, -0.0012044365f, -0.0010798341f,

+     -0.0009793364f, -0.0009017196f, -0.0008457886f, -0.0008103736f,

+};

+

+static float f_clamp(float x, float a, float b)

+{

+	const float x1 = fabs(x - a);

+	const float x2 = fabs(x - b);

+

+	x = x1 + a + b;

+	x -= x2;

+	x *= 0.5;

+

+	return x;

+}

+

+// Round float to int using IEEE int* hack

+static int f_round(float f) {

+        f += (3<<22);

+        return *((int*)&f) - 0x4b400000;

+}

+

+// Cubic interpolation function

+static float cube_interp(const float fr, const float inm1, const float

+                                in, const float inp1, const float inp2)

+{

+	return in + 0.5f * fr * (inp1 - inm1 +

+	 fr * (4.0f * inp1 + 2.0f * inm1 - 5.0f * in - inp2 +

+	 fr * (3.0f * (in - inp1) - inm1 + inp2)));

+}

+

+static t_int *freqshift_tilde_perform(t_int *w)

+{

+	t_freqshift_tilde *x = (t_freqshift_tilde *)(w[1]);

+    t_float *in = (t_float *)(w[2]);

+    t_float *out1 = (t_float *)(w[3]);

+	t_float *out2 = (t_float *)(w[4]);

+    int n = (int)(w[5]);

+	float f, hilb, rm1, rm2, frac_p;

+	float shift_i = x->x_last_shift;

+	float sample_count = sys_getblksize();

+	unsigned int i;

+	int int_p;

+	const float shift_c = f_clamp(x->x_shift, 0.0f, 10000.0f);

+	const float shift_inc = (shift_c - x->x_last_shift) / (float)sample_count;

+	const float freq_fix = (float)SIN_T_SIZE / x->x_fs;

+    while (n--)

+    {

+		f = *in++;

+		x->x_delay[x->x_dptr] = f;

+		/* Perform the Hilbert FIR convolution

+		 * (probably FFT would be faster) */

+		hilb = 0.0f;

+	    for (i = 0; i <= NZEROS/2; i++) {

+	        hilb += (xcoeffs[i] * x->x_delay[(x->x_dptr - i*2) & (D_SIZE - 1)]);

+		}

+

+	    /* Calcuate the table positions for the sine modulator */

+	    int_p = f_round(floor(x->x_phi));

+

+	    /* Calculate ringmod1, the transformed input modulated with a shift Hz

+	     * sinewave. This creates a +180 degree sideband at source-shift Hz and

+	     * a 0 degree sindeband at source+shift Hz */

+	    frac_p = x->x_phi - int_p;

+	    rm1 = hilb * cube_interp(frac_p, x->x_sint[int_p], x->x_sint[int_p+1],

+	                             x->x_sint[int_p+2], x->x_sint[int_p+3]);

+

+	    /* Calcuate the table positions for the cosine modulator */

+	    int_p = (int_p + SIN_T_SIZE / 4) & (SIN_T_SIZE - 1);

+

+	    /* Calculate ringmod2, the delayed input modulated with a shift Hz

+	     * cosinewave. This creates a 0 degree sideband at source+shift Hz

+	     * and a -180 degree sindeband at source-shift Hz */

+	    rm2 = x->x_delay[(x->x_dptr - 100) & (D_SIZE - 1)] * cube_interp(frac_p,

+	          x->x_sint[int_p], x->x_sint[int_p+1], x->x_sint[int_p+2], x->x_sint[int_p+3]);

+

+		/* Output the sum and differences of the ringmods. The +/-180 degree

+	     * sidebands cancel (more of less) and just leave the shifted

+	     * components */

+	    *out1++ = (rm2 - rm1) * 0.5f; /*downshifting*/

+	    *out2++ = (rm2 + rm1) * 0.5f; /*upshifting*/

+

+		x->x_dptr = (x->x_dptr + 1) & (D_SIZE - 1);

+	    x->x_phi += shift_i * freq_fix;

+	    while (x->x_phi > SIN_T_SIZE) {

+			x->x_phi -= SIN_T_SIZE;

+		}

+		shift_i += shift_inc;

+	}	

+    return (w+6);

+}

+

+static void freqshift_tilde_dsp(t_freqshift_tilde *x, t_signal **sp)

+{

+    dsp_add(freqshift_tilde_perform, 5, x, sp[0]->s_vec, sp[1]->s_vec, sp[2]->s_vec, sp[0]->s_n);

+}

+

+static void freqshift_tilde_free(t_freqshift_tilde *x)

+{

+	if(x->x_delay)

+		freebytes(x->x_delay, D_SIZE * sizeof(float));

+	if(x->x_sint)

+		freebytes(x->x_sint, SIN_T_SIZE + 4 * sizeof(float));

+}

+

+void freqshift_tilde_setup(void)

+{

+    freqshift_tilde_class = class_new(gensym("sp.freqshift~"), (t_newmethod)freqshift_tilde_new, (t_method)freqshift_tilde_free,

+    	sizeof(t_freqshift_tilde), 0, A_DEFFLOAT, 0);

+    CLASS_MAINSIGNALIN(freqshift_tilde_class, t_freqshift_tilde, x_f);

+    class_addmethod(freqshift_tilde_class, (t_method)freqshift_tilde_dsp, gensym("dsp"), 0);

+}