#include "All.h"
#ifdef BACKWARDS_COMPATIBILITY
#include "Anti-Predictor.h"
#ifdef ENABLE_COMPRESSION_MODE_HIGH
void CAntiPredictorHigh0000To3320::AntiPredict(int *pInputArray, int *pOutputArray, int NumberOfElements)
{
// variable declares
int p, pw;
int q;
int m;
// short frame handling
if (NumberOfElements < 32)
{
memcpy(pOutputArray, pInputArray, NumberOfElements * 4);
return;
}
////////////////////////////////////////
// order 5
////////////////////////////////////////
memcpy(pOutputArray, pInputArray, 32);
// initialize values
m = 0;
for (q = 8; q < NumberOfElements; q++)
{
p = (5 * pOutputArray[q - 1]) - (10 * pOutputArray[q - 2]) + (12 * pOutputArray[q - 3]) - (7 * pOutputArray[q - 4]) + pOutputArray[q - 5];
pw = (p * m) >> 12;
pOutputArray[q] = pInputArray[q] + pw;
// adjust m
if (pInputArray[q] > 0)
(p > 0) ? m += 1 : m -= 1;
else if (pInputArray[q] < 0)
(p > 0) ? m -= 1 : m += 1;
}
///////////////////////////////////////
// order 4
///////////////////////////////////////
memcpy(pInputArray, pOutputArray, 32);
m = 0;
for (q = 8; q < NumberOfElements; q++)
{
p = (4 * pInputArray[q - 1]) - (6 * pInputArray[q - 2]) + (4 * pInputArray[q - 3]) - pInputArray[q - 4];
pw = (p * m) >> 12;
pInputArray[q] = pOutputArray[q] + pw;
// adjust m
if (pOutputArray[q] > 0)
(p > 0) ? m += 2 : m -= 2;
else if (pOutputArray[q] < 0)
(p > 0) ? m -= 2 : m += 2;
}
CAntiPredictorNormal0000To3320 AntiPredictor;
AntiPredictor.AntiPredict(pInputArray, pOutputArray, NumberOfElements);
}
void CAntiPredictorHigh3320To3600::AntiPredict(int *pInputArray, int *pOutputArray, int NumberOfElements)
{
// short frame handling
if (NumberOfElements < 8)
{
memcpy(pOutputArray, pInputArray, NumberOfElements * 4);
return;
}
// do the offset anti-prediction
CAntiPredictorOffset AntiPredictorOffset;
AntiPredictorOffset.AntiPredict(pInputArray, pOutputArray, NumberOfElements, 2, 12);
AntiPredictorOffset.AntiPredict(pOutputArray, pInputArray, NumberOfElements, 3, 12);
AntiPredictorOffset.AntiPredict(pInputArray, pOutputArray, NumberOfElements, 4, 12);
AntiPredictorOffset.AntiPredict(pOutputArray, pInputArray, NumberOfElements, 5, 12);
AntiPredictorOffset.AntiPredict(pInputArray, pOutputArray, NumberOfElements, 6, 12);
AntiPredictorOffset.AntiPredict(pOutputArray, pInputArray, NumberOfElements, 7, 12);
// use the normal mode
CAntiPredictorNormal3320To3800 AntiPredictor;
AntiPredictor.AntiPredict(pInputArray, pOutputArray, NumberOfElements);
}
void CAntiPredictorHigh3600To3700::AntiPredict(int *pInputArray, int *pOutputArray, int NumberOfElements)
{
// variable declares
int q;
// short frame handling
if (NumberOfElements < 16)
{
memcpy(pOutputArray, pInputArray, NumberOfElements * 4);
return;
}
// make the first five samples identical in both arrays
memcpy(pOutputArray, pInputArray, 13 * 4);
// initialize values
int bm1 = 0;
int bm2 = 0;
int bm3 = 0;
int bm4 = 0;
int bm5 = 0;
int bm6 = 0;
int bm7 = 0;
int bm8 = 0;
int bm9 = 0;
int bm10 = 0;
int bm11 = 0;
int bm12 = 0;
int bm13 = 0;
int m2 = 64;
int m3 = 28;
int m4 = 16;
int OP0;
int OP1 = pOutputArray[12];
int p4 = pInputArray[12];
int p3 = (pInputArray[12] - pInputArray[11]) << 1;
int p2 = pInputArray[12] + ((pInputArray[10] - pInputArray[11]) << 3);// - pInputArray[3] + pInputArray[2];
int bp1 = pOutputArray[12];
int bp2 = pOutputArray[11];
int bp3 = pOutputArray[10];
int bp4 = pOutputArray[9];
int bp5 = pOutputArray[8];
int bp6 = pOutputArray[7];
int bp7 = pOutputArray[6];
int bp8 = pOutputArray[5];
int bp9 = pOutputArray[4];
int bp10 = pOutputArray[3];
int bp11 = pOutputArray[2];
int bp12 = pOutputArray[1];
int bp13 = pOutputArray[0];
for (q = 13; q < NumberOfElements; q++)
{
pInputArray[q] = pInputArray[q] - 1;
OP0 = (pInputArray[q] - ((bp1 * bm1) >> 8) + ((bp2 * bm2) >> 8) - ((bp3 * bm3) >> 8) - ((bp4 * bm4) >> 8) - ((bp5 * bm5) >> 8) - ((bp6 * bm6) >> 8) - ((bp7 * bm7) >> 8) - ((bp8 * bm8) >> 8) - ((bp9 * bm9) >> 8) + ((bp10 * bm10) >> 8) + ((bp11 * bm11) >> 8) + ((bp12 * bm12) >> 8) + ((bp13 * bm13) >> 8));
if (pInputArray[q] > 0)
{
bm1 -= bp1 > 0 ? 1 : -1;
bm2 += bp2 >= 0 ? 1 : -1;
bm3 -= bp3 > 0 ? 1 : -1;
bm4 -= bp4 >= 0 ? 1 : -1;
bm5 -= bp5 > 0 ? 1 : -1;
bm6 -= bp6 >= 0 ? 1 : -1;
bm7 -= bp7 > 0 ? 1 : -1;
bm8 -= bp8 >= 0 ? 1 : -1;
bm9 -= bp9 > 0 ? 1 : -1;
bm10 += bp10 >= 0 ? 1 : -1;
bm11 += bp11 > 0 ? 1 : -1;
bm12 += bp12 >= 0 ? 1 : -1;
bm13 += bp13 > 0 ? 1 : -1;
}
else if (pInputArray[q] < 0)
{
bm1 -= bp1 <= 0 ? 1 : -1;
bm2 += bp2 < 0 ? 1 : -1;
bm3 -= bp3 <= 0 ? 1 : -1;
bm4 -= bp4 < 0 ? 1 : -1;
bm5 -= bp5 <= 0 ? 1 : -1;
bm6 -= bp6 < 0 ? 1 : -1;
bm7 -= bp7 <= 0 ? 1 : -1;
bm8 -= bp8 < 0 ? 1 : -1;
bm9 -= bp9 <= 0 ? 1 : -1;
bm10 += bp10 < 0 ? 1 : -1;
bm11 += bp11 <= 0 ? 1 : -1;
bm12 += bp12 < 0 ? 1 : -1;
bm13 += bp13 <= 0 ? 1 : -1;
}
bp13 = bp12;
bp12 = bp11;
bp11 = bp10;
bp10 = bp9;
bp9 = bp8;
bp8 = bp7;
bp7 = bp6;
bp6 = bp5;
bp5 = bp4;
bp4 = bp3;
bp3 = bp2;
bp2 = bp1;
bp1 = OP0;
pInputArray[q] = OP0 + ((p2 * m2) >> 11) + ((p3 * m3) >> 9) + ((p4 * m4) >> 9);
if (OP0 > 0)
{
m2 -= p2 > 0 ? -1 : 1;
m3 -= p3 > 0 ? -1 : 1;
m4 -= p4 > 0 ? -1 : 1;
}
else if (OP0 < 0)
{
m2 -= p2 > 0 ? 1 : -1;
m3 -= p3 > 0 ? 1 : -1;
m4 -= p4 > 0 ? 1 : -1;
}
p2 = pInputArray[q] + ((pInputArray[q - 2] - pInputArray[q - 1]) << 3);
p3 = (pInputArray[q] - pInputArray[q - 1]) << 1;
p4 = pInputArray[q];
pOutputArray[q] = pInputArray[q];// + ((p3 * m3) >> 9);
}
m4 = 370;
int m5 = 3900;
pOutputArray[1] = pInputArray[1] + pOutputArray[0];
pOutputArray[2] = pInputArray[2] + pOutputArray[1];
pOutputArray[3] = pInputArray[3] + pOutputArray[2];
pOutputArray[4] = pInputArray[4] + pOutputArray[3];
pOutputArray[5] = pInputArray[5] + pOutputArray[4];
pOutputArray[6] = pInputArray[6] + pOutputArray[5];
pOutputArray[7] = pInputArray[7] + pOutputArray[6];
pOutputArray[8] = pInputArray[8] + pOutputArray[7];
pOutputArray[9] = pInputArray[9] + pOutputArray[8];
pOutputArray[10] = pInputArray[10] + pOutputArray[9];
pOutputArray[11] = pInputArray[11] + pOutputArray[10];
pOutputArray[12] = pInputArray[12] + pOutputArray[11];
p4 = (2 * pInputArray[12]) - pInputArray[11];
int p6 = 0;
int p5 = pOutputArray[12];
int IP0, IP1;
int m6 = 0;
IP1 = pInputArray[12];
for (q = 13; q < NumberOfElements; q++)
{
IP0 = pOutputArray[q] + ((p4 * m4) >> 9) - ((p6 * m6) >> 10);
(pOutputArray[q] ^ p4) >= 0 ? m4++ : m4--;
(pOutputArray[q] ^ p6) >= 0 ? m6-- : m6++;
p4 = (2 * IP0) - IP1;
p6 = IP0;
pOutputArray[q] = IP0 + ((p5 * 31) >> 5);
p5 = pOutputArray[q];
IP1 = IP0;
}
}
void CAntiPredictorHigh3700To3800::AntiPredict(int *pInputArray, int *pOutputArray, int NumberOfElements)
{
// the frame to start prediction on
#define FIRST_ELEMENT 16
int x = 100;
int y = -25;
// short frame handling
if (NumberOfElements < 20)
{
memcpy(pOutputArray, pInputArray, NumberOfElements * 4);
return;
}
// make the first five samples identical in both arrays
memcpy(pOutputArray, pInputArray, FIRST_ELEMENT * 4);
// variable declares and initializations
int bm[FIRST_ELEMENT]; memset(bm, 0, FIRST_ELEMENT * 4);
int m2 = 64, m3 = 115, m4 = 64, m5 = 740, m6 = 0;
int p4 = pInputArray[FIRST_ELEMENT - 1];
int p3 = (pInputArray[FIRST_ELEMENT - 1] - pInputArray[FIRST_ELEMENT - 2]) << 1;
int p2 = pInputArray[FIRST_ELEMENT - 1] + ((pInputArray[FIRST_ELEMENT - 3] - pInputArray[FIRST_ELEMENT - 2]) << 3);// - pInputArray[3] + pInputArray[2];
int *op = &pOutputArray[FIRST_ELEMENT];
int *ip = &pInputArray[FIRST_ELEMENT];
int IPP2 = ip[-2];
int IPP1 = ip[-1];
int p7 = 2 * ip[-1] - ip[-2];
int opp = op[-1];
int Original;
// undo the initial prediction stuff
for (int q = 1; q < FIRST_ELEMENT; q++) {
pOutputArray[q] += pOutputArray[q - 1];
}
// pump the primary loop
for (;op < &pOutputArray[NumberOfElements]; op++, ip++) {
Original = *ip - 1;
*ip = Original - (((ip[-1] * bm[0]) + (ip[-2] * bm[1]) + (ip[-3] * bm[2]) + (ip[-4] * bm[3]) + (ip[-5] * bm[4]) + (ip[-6] * bm[5]) + (ip[-7] * bm[6]) + (ip[-8] * bm[7]) + (ip[-9] * bm[8]) + (ip[-10] * bm[9]) + (ip[-11] * bm[10]) + (ip[-12] * bm[11]) + (ip[-13] * bm[12]) + (ip[-14] * bm[13]) + (ip[-15] * bm[14]) + (ip[-16] * bm[15])) >> 8);
if (Original > 0)
{
bm[0] -= ip[-1] > 0 ? 1 : -1;
bm[1] += ((unsigned int(ip[-2]) >> 30) & 2) - 1;
bm[2] -= ip[-3] > 0 ? 1 : -1;
bm[3] += ((unsigned int(ip[-4]) >> 30) & 2) - 1;
bm[4] -= ip[-5] > 0 ? 1 : -1;
bm[5] += ((unsigned int(ip[-6]) >> 30) & 2) - 1;
bm[6] -= ip[-7] > 0 ? 1 : -1;
bm[7] += ((unsigned int(ip[-8]) >> 30) & 2) - 1;
bm[8] -= ip[-9] > 0 ? 1 : -1;
bm[9] += ((unsigned int(ip[-10]) >> 30) & 2) - 1;
bm[10] -= ip[-11] > 0 ? 1 : -1;
bm[11] += ((unsigned int(ip[-12]) >> 30) & 2) - 1;
bm[12] -= ip[-13] > 0 ? 1 : -1;
bm[13] += ((unsigned int(ip[-14]) >> 30) & 2) - 1;
bm[14] -= ip[-15] > 0 ? 1 : -1;
bm[15] += ((unsigned int(ip[-16]) >> 30) & 2) - 1;
}
else if (Original < 0)
{
bm[0] -= ip[-1] <= 0 ? 1 : -1;
bm[1] -= ((unsigned int(ip[-2]) >> 30) & 2) - 1;
bm[2] -= ip[-3] <= 0 ? 1 : -1;
bm[3] -= ((unsigned int(ip[-4]) >> 30) & 2) - 1;
bm[4] -= ip[-5] <= 0 ? 1 : -1;
bm[5] -= ((unsigned int(ip[-6]) >> 30) & 2) - 1;
bm[6] -= ip[-7] <= 0 ? 1 : -1;
bm[7] -= ((unsigned int(ip[-8]) >> 30) & 2) - 1;
bm[8] -= ip[-9] <= 0 ? 1 : -1;
bm[9] -= ((unsigned int(ip[-10]) >> 30) & 2) - 1;
bm[10] -= ip[-11] <= 0 ? 1 : -1;
bm[11] -= ((unsigned int(ip[-12]) >> 30) & 2) - 1;
bm[12] -= ip[-13] <= 0 ? 1 : -1;
bm[13] -= ((unsigned int(ip[-14]) >> 30) & 2) - 1;
bm[14] -= ip[-15] <= 0 ? 1 : -1;
bm[15] -= ((unsigned int(ip[-16]) >> 30) & 2) - 1;
}
/////////////////////////////////////////////
*op = *ip + (((p2 * m2) + (p3 * m3) + (p4 * m4)) >> 11);
if (*ip > 0)
{
m2 -= p2 > 0 ? -1 : 1;
m3 -= p3 > 0 ? -4 : 4;
m4 -= p4 > 0 ? -4 : 4;
}
else if (*ip < 0)
{
m2 -= p2 > 0 ? 1 : -1;
m3 -= p3 > 0 ? 4 : -4;
m4 -= p4 > 0 ? 4 : -4;
}
p4 = *op;
p2 = p4 + ((IPP2 - IPP1) << 3);
p3 = (p4 - IPP1) << 1;
IPP2 = IPP1;
IPP1 = p4;
/////////////////////////////////////////////
*op += (((p7 * m5) - (opp * m6)) >> 10);
(IPP1 ^ p7) >= 0 ? m5+=2 : m5-=2;
(IPP1 ^ opp) >= 0 ? m6-- : m6++;
p7 = 2 * *op - opp;
opp = *op;
/////////////////////////////////////////////
*op += ((op[-1] * 31) >> 5);
}
}
void CAntiPredictorHigh3800ToCurrent::AntiPredict(int *pInputArray, int *pOutputArray, int NumberOfElements)
{
// the frame to start prediction on
#define FIRST_ELEMENT 16
// short frame handling
if (NumberOfElements < 20)
{
memcpy(pOutputArray, pInputArray, NumberOfElements * 4);
return;
}
// make the first five samples identical in both arrays
memcpy(pOutputArray, pInputArray, FIRST_ELEMENT * 4);
// variable declares and initializations
int bm[FIRST_ELEMENT]; memset(bm, 0, FIRST_ELEMENT * 4);
int m2 = 64, m3 = 115, m4 = 64, m5 = 740, m6 = 0;
int p4 = pInputArray[FIRST_ELEMENT - 1];
int p3 = (pInputArray[FIRST_ELEMENT - 1] - pInputArray[FIRST_ELEMENT - 2]) << 1;
int p2 = pInputArray[FIRST_ELEMENT - 1] + ((pInputArray[FIRST_ELEMENT - 3] - pInputArray[FIRST_ELEMENT - 2]) << 3);// - pInputArray[3] + pInputArray[2];
int *op = &pOutputArray[FIRST_ELEMENT];
int *ip = &pInputArray[FIRST_ELEMENT];
int IPP2 = ip[-2];
int IPP1 = ip[-1];
int p7 = 2 * ip[-1] - ip[-2];
int opp = op[-1];
// undo the initial prediction stuff
for (int q = 1; q < FIRST_ELEMENT; q++)
{
pOutputArray[q] += pOutputArray[q - 1];
}
// pump the primary loop
for (;op < &pOutputArray[NumberOfElements]; op++, ip++)
{
unsigned int *pip = (unsigned int *) &ip[-FIRST_ELEMENT];
int *pbm = &bm[0];
int nDotProduct = 0;
if (*ip > 0)
{
EXPAND_16_TIMES(nDotProduct += *pip * *pbm; *pbm++ += ((*pip++ >> 30) & 2) - 1;)
}
else if (*ip < 0)
{
EXPAND_16_TIMES(nDotProduct += *pip * *pbm; *pbm++ -= ((*pip++ >> 30) & 2) - 1;)
}
else
{
EXPAND_16_TIMES(nDotProduct += *pip++ * *pbm++;)
}
*ip -= (nDotProduct >> 9);
/////////////////////////////////////////////
*op = *ip + (((p2 * m2) + (p3 * m3) + (p4 * m4)) >> 11);
if (*ip > 0)
{
m2 -= ((p2 >> 30) & 2) - 1;
m3 -= ((p3 >> 28) & 8) - 4;
m4 -= ((p4 >> 28) & 8) - 4;
}
else if (*ip < 0)
{
m2 += ((p2 >> 30) & 2) - 1;
m3 += ((p3 >> 28) & 8) - 4;
m4 += ((p4 >> 28) & 8) - 4;
}
p2 = *op + ((IPP2 - p4) << 3);
p3 = (*op - p4) << 1;
IPP2 = p4;
p4 = *op;
/////////////////////////////////////////////
*op += (((p7 * m5) - (opp * m6)) >> 10);
if (p4 > 0)
{
m5 -= ((p7 >> 29) & 4) - 2;
m6 += ((opp >> 30) & 2) - 1;
}
else if (p4 < 0)
{
m5 += ((p7 >> 29) & 4) - 2;
m6 -= ((opp >> 30) & 2) - 1;
}
p7 = 2 * *op - opp;
opp = *op;
/////////////////////////////////////////////
*op += ((op[-1] * 31) >> 5);
}
#undef FIRST_ELEMENT
}
#endif // #ifdef ENABLE_COMPRESSION_MODE_HIGH
#endif // #ifdef BACKWARDS_COMPATIBILITY