// Copyright 2017 The Ebiten Authors // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // +build !js package mp3 // #include "pdmp3.h" // // extern t_mpeg1_main_data g_main_data; // extern t_mpeg1_side_info g_side_info; // extern t_mpeg1_header g_frame_header; import "C" import ( "math" ) var ( powtab34 = make([]float64, 8207) pretab = []float64{0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 3, 3, 3, 2} ) func init() { for i := range powtab34 { powtab34[i] = math.Pow(float64(i), 4.0/3.0) } } func requantizeProcessLong(gr, ch, is_pos, sfb int) { sf_mult := 0.5 if C.g_side_info.scalefac_scale[gr][ch] != 0 { sf_mult = 1.0 } tmp1 := 1.0 // https://github.com/technosaurus/PDMP3/issues/4 if sfb < 21 { pf_x_pt := float64(C.g_side_info.preflag[gr][ch]) * pretab[sfb] tmp1 = math.Pow(2.0, -(sf_mult * (float64(C.g_main_data.scalefac_l[gr][ch][sfb]) + pf_x_pt))) } tmp2 := math.Pow(2.0, 0.25*(float64(C.g_side_info.global_gain[gr][ch])-210)) tmp3 := 0.0 if C.g_main_data.is[gr][ch][is_pos] < 0.0 { tmp3 = -powtab34[int(-C.g_main_data.is[gr][ch][is_pos])] } else { tmp3 = powtab34[int(C.g_main_data.is[gr][ch][is_pos])] } C.g_main_data.is[gr][ch][is_pos] = C.float(tmp1 * tmp2 * tmp3) } func requantizeProcessShort(gr, ch, is_pos, sfb, win int) { sf_mult := 0.5 if C.g_side_info.scalefac_scale[gr][ch] != 0 { sf_mult = 1.0 } tmp1 := 1.0 // https://github.com/technosaurus/PDMP3/issues/4 if sfb < 12 { tmp1 = math.Pow(2.0, -(sf_mult * float64(C.g_main_data.scalefac_s[gr][ch][sfb][win]))) } tmp2 := math.Pow(2.0, 0.25*(float64(C.g_side_info.global_gain[gr][ch])-210.0- 8.0*float64(C.g_side_info.subblock_gain[gr][ch][win]))) tmp3 := 0.0 if C.g_main_data.is[gr][ch][is_pos] < 0 { tmp3 = -powtab34[int(-C.g_main_data.is[gr][ch][is_pos])] } else { tmp3 = powtab34[int(C.g_main_data.is[gr][ch][is_pos])] } C.g_main_data.is[gr][ch][is_pos] = C.float(tmp1 * tmp2 * tmp3) } type sfBandIndices struct { l []int s []int } var ( sfBandIndicesSet = []sfBandIndices{ { l: []int{0, 4, 8, 12, 16, 20, 24, 30, 36, 44, 52, 62, 74, 90, 110, 134, 162, 196, 238, 288, 342, 418, 576}, s: []int{0, 4, 8, 12, 16, 22, 30, 40, 52, 66, 84, 106, 136, 192}, }, { l: []int{0, 4, 8, 12, 16, 20, 24, 30, 36, 42, 50, 60, 72, 88, 106, 128, 156, 190, 230, 276, 330, 384, 576}, s: []int{0, 4, 8, 12, 16, 22, 28, 38, 50, 64, 80, 100, 126, 192}, }, { l: []int{0, 4, 8, 12, 16, 20, 24, 30, 36, 44, 54, 66, 82, 102, 126, 156, 194, 240, 296, 364, 448, 550, 576}, s: []int{0, 4, 8, 12, 16, 22, 30, 42, 58, 78, 104, 138, 180, 192}, }, } ) func l3Requantize(gr int, ch int) { /* Setup sampling frequency index */ sfreq := C.g_frame_header.sampling_frequency /* Determine type of block to process */ if (C.g_side_info.win_switch_flag[gr][ch] == 1) && (C.g_side_info.block_type[gr][ch] == 2) { /* Short blocks */ /* Check if the first two subbands *(=2*18 samples = 8 long or 3 short sfb's) uses long blocks */ if C.g_side_info.mixed_block_flag[gr][ch] != 0 { /* 2 longbl. sb first */ /* First process the 2 long block subbands at the start */ sfb := 0 next_sfb := sfBandIndicesSet[sfreq].l[sfb+1] for i := 0; i < 36; i++ { if i == next_sfb { sfb++ next_sfb = sfBandIndicesSet[sfreq].l[sfb+1] } requantizeProcessLong(int(gr), int(ch), i, sfb) } /* And next the remaining,non-zero,bands which uses short blocks */ sfb = 3 next_sfb = sfBandIndicesSet[sfreq].s[sfb+1] * 3 win_len := sfBandIndicesSet[sfreq].s[sfb+1] - sfBandIndicesSet[sfreq].s[sfb] for i := 36; i < int(C.g_side_info.count1[gr][ch]); /* i++ done below! */ { /* Check if we're into the next scalefac band */ if i == next_sfb { /* Yes */ sfb++ next_sfb = sfBandIndicesSet[sfreq].s[sfb+1] * 3 win_len = sfBandIndicesSet[sfreq].s[sfb+1] - sfBandIndicesSet[sfreq].s[sfb] } for win := 0; win < 3; win++ { for j := 0; j < win_len; j++ { requantizeProcessShort(int(gr), int(ch), i, sfb, win) i++ } } } } else { /* Only short blocks */ sfb := 0 next_sfb := sfBandIndicesSet[sfreq].s[sfb+1] * 3 win_len := sfBandIndicesSet[sfreq].s[sfb+1] - sfBandIndicesSet[sfreq].s[sfb] for i := 0; i < int(C.g_side_info.count1[gr][ch]); /* i++ done below! */ { /* Check if we're into the next scalefac band */ if i == next_sfb { sfb++ next_sfb = sfBandIndicesSet[sfreq].s[sfb+1] * 3 win_len = sfBandIndicesSet[sfreq].s[sfb+1] - sfBandIndicesSet[sfreq].s[sfb] } for win := 0; win < 3; win++ { for j := 0; j < win_len; j++ { requantizeProcessShort(int(gr), int(ch), i, sfb, win) i++ } } } } } else { /* Only long blocks */ sfb := 0 next_sfb := sfBandIndicesSet[sfreq].l[sfb+1] for i := 0; i < int(C.g_side_info.count1[gr][ch]); i++ { if i == next_sfb { sfb++ next_sfb = sfBandIndicesSet[sfreq].l[sfb+1] } requantizeProcessLong(int(gr), int(ch), i, sfb) } } } func l3Reorder(gr int, ch int) { re := make([]float32, 576) sfreq := C.g_frame_header.sampling_frequency /* Setup sampling freq index */ /* Only reorder short blocks */ if (C.g_side_info.win_switch_flag[gr][ch] == 1) && (C.g_side_info.block_type[gr][ch] == 2) { /* Short blocks */ /* Check if the first two subbands *(=2*18 samples = 8 long or 3 short sfb's) uses long blocks */ sfb := 0 /* 2 longbl. sb first */ if C.g_side_info.mixed_block_flag[gr][ch] != 0 { sfb = 3 } next_sfb := sfBandIndicesSet[sfreq].s[sfb+1] * 3 win_len := sfBandIndicesSet[sfreq].s[sfb+1] - sfBandIndicesSet[sfreq].s[sfb] i := 36 if sfb == 0 { i = 0 } for i < 576 { /* Check if we're into the next scalefac band */ if i == next_sfb { /* Copy reordered data back to the original vector */ for j := 0; j < 3*win_len; j++ { C.g_main_data.is[gr][ch][3*sfBandIndicesSet[sfreq].s[sfb]+j] = C.float(re[j]) } /* Check if this band is above the rzero region,if so we're done */ if C.uint(i) >= C.g_side_info.count1[gr][ch] { return } sfb++ next_sfb = sfBandIndicesSet[sfreq].s[sfb+1] * 3 win_len = sfBandIndicesSet[sfreq].s[sfb+1] - sfBandIndicesSet[sfreq].s[sfb] } for win := 0; win < 3; win++ { /* Do the actual reordering */ for j := 0; j < win_len; j++ { re[j*3+win] = float32(C.g_main_data.is[gr][ch][i]) i++ } } } /* Copy reordered data of last band back to original vector */ for j := 0; j < 3*win_len; j++ { C.g_main_data.is[gr][ch][3*sfBandIndicesSet[sfreq].s[12]+j] = C.float(re[j]) } } } var ( is_ratios = [6]float32{0.000000, 0.267949, 0.577350, 1.000000, 1.732051, 3.732051} ) func stereoProcessIntensityLong(gr int, sfb int) { is_ratio_l := float32(0) is_ratio_r := float32(0) /* Check that((is_pos[sfb]=scalefac) != 7) => no intensity stereo */ is_pos := C.g_main_data.scalefac_l[gr][0][sfb] if is_pos != 7 { sfreq := C.g_frame_header.sampling_frequency /* Setup sampling freq index */ sfb_start := sfBandIndicesSet[sfreq].l[sfb] sfb_stop := sfBandIndicesSet[sfreq].l[sfb+1] if is_pos == 6 { /* tan((6*PI)/12 = PI/2) needs special treatment! */ is_ratio_l = 1.0 is_ratio_r = 0.0 } else { is_ratio_l = is_ratios[is_pos] / (1.0 + is_ratios[is_pos]) is_ratio_r = 1.0 / (1.0 + is_ratios[is_pos]) } /* Now decode all samples in this scale factor band */ for i := sfb_start; i < sfb_stop; i++ { C.g_main_data.is[gr][0][i] *= C.float(is_ratio_l) C.g_main_data.is[gr][1][i] *= C.float(is_ratio_r) } } } func stereoProcessIntensityShort(gr int, sfb int) { is_ratio_l := float32(0) is_ratio_r := float32(0) sfreq := C.g_frame_header.sampling_frequency /* Setup sampling freq index */ /* The window length */ win_len := sfBandIndicesSet[sfreq].s[sfb+1] - sfBandIndicesSet[sfreq].s[sfb] /* The three windows within the band has different scalefactors */ for win := 0; win < 3; win++ { /* Check that((is_pos[sfb]=scalefac) != 7) => no intensity stereo */ is_pos := C.g_main_data.scalefac_s[gr][0][sfb][win] if is_pos != 7 { sfb_start := sfBandIndicesSet[sfreq].s[sfb]*3 + win_len*win sfb_stop := sfb_start + win_len if is_pos == 6 { /* tan((6*PI)/12 = PI/2) needs special treatment! */ is_ratio_l = 1.0 is_ratio_r = 0.0 } else { is_ratio_l = is_ratios[is_pos] / (1.0 + is_ratios[is_pos]) is_ratio_r = 1.0 / (1.0 + is_ratios[is_pos]) } /* Now decode all samples in this scale factor band */ for i := sfb_start; i < sfb_stop; i++ { // https://github.com/technosaurus/PDMP3/issues/3 C.g_main_data.is[gr][0][i] *= C.float(is_ratio_l) C.g_main_data.is[gr][1][i] *= C.float(is_ratio_r) } } } } func l3Stereo(gr int) { /* Do nothing if joint stereo is not enabled */ if (C.g_frame_header.mode != 1) || (C.g_frame_header.mode_extension == 0) { return } /* Do Middle/Side("normal") stereo processing */ if (C.g_frame_header.mode_extension & 0x2) != 0 { /* Determine how many frequency lines to transform */ i := 0 if C.g_side_info.count1[gr][0] > C.g_side_info.count1[gr][1] { i = 1 } max_pos := int(C.g_side_info.count1[gr][i]) /* Do the actual processing */ const invSqrt2 = math.Sqrt2 / 2 for i := 0; i < max_pos; i++ { left := (C.g_main_data.is[gr][0][i] + C.g_main_data.is[gr][1][i]) * invSqrt2 right := (C.g_main_data.is[gr][0][i] - C.g_main_data.is[gr][1][i]) * invSqrt2 C.g_main_data.is[gr][0][i] = left C.g_main_data.is[gr][1][i] = right } } /* Do intensity stereo processing */ if (C.g_frame_header.mode_extension & 0x1) != 0 { /* Setup sampling frequency index */ sfreq := C.g_frame_header.sampling_frequency /* First band that is intensity stereo encoded is first band scale factor * band on or above count1 frequency line. N.B.: Intensity stereo coding is * only done for higher subbands, but logic is here for lower subbands. */ /* Determine type of block to process */ if (C.g_side_info.win_switch_flag[gr][0] == 1) && (C.g_side_info.block_type[gr][0] == 2) { /* Short blocks */ /* Check if the first two subbands *(=2*18 samples = 8 long or 3 short sfb's) uses long blocks */ if C.g_side_info.mixed_block_flag[gr][0] != 0 { /* 2 longbl. sb first */ for sfb := 0; sfb < 8; sfb++ { /* First process 8 sfb's at start */ /* Is this scale factor band above count1 for the right channel? */ if C.unsigned(sfBandIndicesSet[sfreq].l[sfb]) >= C.g_side_info.count1[gr][1] { stereoProcessIntensityLong(int(gr), int(sfb)) } } /* And next the remaining bands which uses short blocks */ for sfb := 3; sfb < 12; sfb++ { /* Is this scale factor band above count1 for the right channel? */ if C.unsigned(sfBandIndicesSet[sfreq].s[sfb])*3 >= C.g_side_info.count1[gr][1] { stereoProcessIntensityShort(int(gr), int(sfb)) /* intensity stereo processing */ } } } else { /* Only short blocks */ for sfb := 0; sfb < 12; sfb++ { /* Is this scale factor band above count1 for the right channel? */ if C.unsigned(sfBandIndicesSet[sfreq].s[sfb])*3 >= C.g_side_info.count1[gr][1] { stereoProcessIntensityShort(int(gr), int(sfb)) /* intensity stereo processing */ } } } } else { /* Only long blocks */ for sfb := 0; sfb < 21; sfb++ { /* Is this scale factor band above count1 for the right channel? */ if C.unsigned(sfBandIndicesSet[sfreq].l[sfb]) >= C.g_side_info.count1[gr][1] { /* Perform the intensity stereo processing */ stereoProcessIntensityLong(int(gr), int(sfb)) } } } } } var ( cs = [8]float32{0.857493, 0.881742, 0.949629, 0.983315, 0.995518, 0.999161, 0.999899, 0.999993} ca = [8]float32{-0.514496, -0.471732, -0.313377, -0.181913, -0.094574, -0.040966, -0.014199, -0.003700} ) func l3Antialias(gr int, ch int) { /* No antialiasing is done for short blocks */ if (C.g_side_info.win_switch_flag[gr][ch] == 1) && (C.g_side_info.block_type[gr][ch] == 2) && (C.g_side_info.mixed_block_flag[gr][ch]) == 0 { return } /* Setup the limit for how many subbands to transform */ sblim := 32 if (C.g_side_info.win_switch_flag[gr][ch] == 1) && (C.g_side_info.block_type[gr][ch] == 2) && (C.g_side_info.mixed_block_flag[gr][ch] == 1) { sblim = 2 } /* Do the actual antialiasing */ for sb := 1; sb < sblim; sb++ { for i := 0; i < 8; i++ { li := 18*sb - 1 - i ui := 18*sb + i lb := C.g_main_data.is[gr][ch][li]*C.float(cs[i]) - C.g_main_data.is[gr][ch][ui]*C.float(ca[i]) ub := C.g_main_data.is[gr][ch][ui]*C.float(cs[i]) + C.g_main_data.is[gr][ch][li]*C.float(ca[i]) C.g_main_data.is[gr][ch][li] = lb C.g_main_data.is[gr][ch][ui] = ub } } } var store = [2][32][18]float32{} func l3HybridSynthesis(gr int, ch int) { for sb := 0; sb < 32; sb++ { /* Loop through all 32 subbands */ /* Determine blocktype for this subband */ bt := int(C.g_side_info.block_type[gr][ch]) if (C.g_side_info.win_switch_flag[gr][ch] == 1) && (C.g_side_info.mixed_block_flag[gr][ch] == 1) && (sb < 2) { bt = 0 } /* Do the inverse modified DCT and windowing */ in := make([]float32, 18) for i := range in { in[i] = float32(C.g_main_data.is[gr][ch][sb*18+i]) } rawout := imdctWin(in, bt) for i := 0; i < 18; i++ { /* Overlapp add with stored vector into main_data vector */ C.g_main_data.is[gr][ch][sb*18+i] = C.float(rawout[i] + store[ch][sb][i]) store[ch][sb][i] = rawout[i+18] } } } func l3FrequencyInversion(gr int, ch int) { for sb := 1; sb < 32; sb += 2 { //OPT? : for(sb = 18; sb < 576; sb += 36) for i := 1; i < 18; i += 2 { C.g_main_data.is[gr][ch][sb*18+i] = -C.g_main_data.is[gr][ch][sb*18+i] } } } var ( g_synth_n_win = [64][32]float32{} v_vec = [2][1024]float32{} ) func init() { for i := 0; i < 64; i++ { for j := 0; j < 32; j++ { g_synth_n_win[i][j] = float32(math.Cos(float64((16+i)*(2*j+1)) * (math.Pi / 64.0))) } } } var g_synth_dtbl = [512]float32{ 0.000000000, -0.000015259, -0.000015259, -0.000015259, -0.000015259, -0.000015259, -0.000015259, -0.000030518, -0.000030518, -0.000030518, -0.000030518, -0.000045776, -0.000045776, -0.000061035, -0.000061035, -0.000076294, -0.000076294, -0.000091553, -0.000106812, -0.000106812, -0.000122070, -0.000137329, -0.000152588, -0.000167847, -0.000198364, -0.000213623, -0.000244141, -0.000259399, -0.000289917, -0.000320435, -0.000366211, -0.000396729, -0.000442505, -0.000473022, -0.000534058, -0.000579834, -0.000625610, -0.000686646, -0.000747681, -0.000808716, -0.000885010, -0.000961304, -0.001037598, -0.001113892, -0.001205444, -0.001296997, -0.001388550, -0.001480103, -0.001586914, -0.001693726, -0.001785278, -0.001907349, -0.002014160, -0.002120972, -0.002243042, -0.002349854, -0.002456665, -0.002578735, -0.002685547, -0.002792358, -0.002899170, -0.002990723, -0.003082275, -0.003173828, 0.003250122, 0.003326416, 0.003387451, 0.003433228, 0.003463745, 0.003479004, 0.003479004, 0.003463745, 0.003417969, 0.003372192, 0.003280640, 0.003173828, 0.003051758, 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-0.003387451, -0.003326416, 0.003250122, 0.003173828, 0.003082275, 0.002990723, 0.002899170, 0.002792358, 0.002685547, 0.002578735, 0.002456665, 0.002349854, 0.002243042, 0.002120972, 0.002014160, 0.001907349, 0.001785278, 0.001693726, 0.001586914, 0.001480103, 0.001388550, 0.001296997, 0.001205444, 0.001113892, 0.001037598, 0.000961304, 0.000885010, 0.000808716, 0.000747681, 0.000686646, 0.000625610, 0.000579834, 0.000534058, 0.000473022, 0.000442505, 0.000396729, 0.000366211, 0.000320435, 0.000289917, 0.000259399, 0.000244141, 0.000213623, 0.000198364, 0.000167847, 0.000152588, 0.000137329, 0.000122070, 0.000106812, 0.000106812, 0.000091553, 0.000076294, 0.000076294, 0.000061035, 0.000061035, 0.000045776, 0.000045776, 0.000030518, 0.000030518, 0.000030518, 0.000030518, 0.000015259, 0.000015259, 0.000015259, 0.000015259, 0.000015259, 0.000015259, } func l3SubbandSynthesis(gr int, ch int, out []uint32) { u_vec := make([]float32, 512) s_vec := make([]float32, 32) /* Number of channels(1 for mono and 2 for stereo) */ nch := 2 if C.g_frame_header.mode == C.mpeg1_mode_single_channel { nch = 1 } /* Setup the n_win windowing vector and the v_vec intermediate vector */ for ss := 0; ss < 18; ss++ { /* Loop through 18 samples in 32 subbands */ for i := 1023; i > 63; i-- { /* Shift up the V vector */ v_vec[ch][i] = v_vec[ch][i-64] } for i := 0; i < 32; i++ { /* Copy next 32 time samples to a temp vector */ s_vec[i] = float32(C.g_main_data.is[gr][ch][i*18+ss]) } for i := 0; i < 64; i++ { /* Matrix multiply input with n_win[][] matrix */ sum := float32(0) for j := 0; j < 32; j++ { sum += g_synth_n_win[i][j] * s_vec[j] } v_vec[ch][i] = sum } for i := 0; i < 8; i++ { /* Build the U vector */ for j := 0; j < 32; j++ { /* <<7 == *128 */ u_vec[(i<<6)+j] = v_vec[ch][(i<<7)+j] u_vec[(i<<6)+j+32] = v_vec[ch][(i<<7)+j+96] } } for i := 0; i < 512; i++ { /* Window by u_vec[i] with g_synth_dtbl[i] */ u_vec[i] *= g_synth_dtbl[i] } for i := 0; i < 32; i++ { /* Calc 32 samples,store in outdata vector */ sum := float32(0) for j := 0; j < 16; j++ { /* sum += u_vec[j*32 + i]; */ sum += u_vec[(j<<5)+i] } /* sum now contains time sample 32*ss+i. Convert to 16-bit signed int */ samp := int(sum * 32767) if samp > 32767 { samp = 32767 } else if samp < -32767 { samp = -32767 } samp &= 0xffff s := uint32(samp) if ch == 0 { /* This function must be called for channel 0 first */ /* We always run in stereo mode,& duplicate channels here for mono */ if nch == 1 { out[32*ss+i] = (s << 16) | (s) } else { out[32*ss+i] = s << 16 } } else { out[32*ss+i] |= s } } } }