ref: e11c7aa718df592bd69de53ce1d6498cc870f256
dir: /appl/wm/mpeg/fixidct.b/
implement IDCT; include "sys.m"; include "mpegio.m"; init() { } # IDCT based on Arai, Agui, and Nakajima, using flow chart Figure 4.8 # of Pennebaker & Mitchell, JPEG: Still Image Data Compression Standard. # Remember IDCT is reverse of flow of DCT. # Nasty truncated integer version (not compliant). B0: con 16; B1: con 16; M: con (1 << B0); N: con (1 << B1); a0: con 1.414; a1: con 0.707; a2: con 0.541; a3: con 0.707; a4: con 1.307; a5: con -0.383; A0: con int (a0 * real N); A1: con int (a1 * real M); A2: con int (a2 * real M); A3: con int (a3 * real M); A4: con int (a4 * real M); A5: con int (a5 * real M); # scaling factors from eqn 4-35 of P&M s1: con 1.0196; s2: con 1.0823; s3: con 1.2026; s4: con 1.4142; s5: con 1.8000; s6: con 2.6131; s7: con 5.1258; S1: con int (s1 * real N); S2: con int (s2 * real N); S3: con int (s3 * real N); S4: con int (s4 * real N); S5: con int (s5 * real N); S6: con int (s6 * real N); S7: con int (s7 * real N); # overall normalization of 1/16, folded into premultiplication on vertical pass S: con 4; scale: con 0.0625; idct(b: array of int) { x, y: int; r := array[8*8] of int; # transform horizontally for(y=0; y<8; y++){ eighty := y<<3; # if all non-DC components are zero, just propagate the DC term if(b[eighty+1]==0) if(b[eighty+2]==0 && b[eighty+3]==0) if(b[eighty+4]==0 && b[eighty+5]==0) if(b[eighty+6]==0 && b[eighty+7]==0){ v := b[eighty]*A0; r[eighty+0] = v; r[eighty+1] = v; r[eighty+2] = v; r[eighty+3] = v; r[eighty+4] = v; r[eighty+5] = v; r[eighty+6] = v; r[eighty+7] = v; continue; } # step 5 in1 := S1*b[eighty+1]; in3 := S3*b[eighty+3]; in5 := S5*b[eighty+5]; in7 := S7*b[eighty+7]; f2 := S2*b[eighty+2]; f3 := S6*b[eighty+6]; f5 := (in1+in7); f7 := (in5+in3); # step 4 g2 := f2-f3; g4 := (in5-in3); g6 := (in1-in7); g7 := f5+f7; # step 3.5 t := ((g4+g6)>>B0)*A5; # step 3 f0 := A0*b[eighty+0]; f1 := S4*b[eighty+4]; f3 += f2; f2 = A1*(g2>>B0); # step 2 g0 := f0+f1; g1 := f0-f1; g3 := f2+f3; g4 = t-A2*(g4>>B0); g5 := A3*((f5-f7)>>B0); g6 = A4*(g6>>B0)+t; # step 1 f0 = g0+g3; f1 = g1+f2; f2 = g1-f2; f3 = g0-g3; f5 = g5-g4; f6 := g5+g6; f7 = g6+g7; # step 6 r[eighty+0] = (f0+f7); r[eighty+1] = (f1+f6); r[eighty+2] = (f2+f5); r[eighty+3] = (f3-g4); r[eighty+4] = (f3+g4); r[eighty+5] = (f2-f5); r[eighty+6] = (f1-f6); r[eighty+7] = (f0-f7); } # transform vertically for(x=0; x<8; x++){ # step 5 in1 := S1*(r[x+8]>>(B1+S)); in3 := S3*(r[x+24]>>(B1+S)); in5 := S5*(r[x+40]>>(B1+S)); in7 := S7*(r[x+56]>>(B1+S)); f2 := S2*(r[x+16]>>(B1+S)); f3 := S6*(r[x+48]>>(B1+S)); f5 := (in1+in7); f7 := (in5+in3); # step 4 g2 := f2-f3; g4 := (in5-in3); g6 := (in1-in7); g7 := f5+f7; # step 3.5 t := ((g4+g6)>>B0)*A5; # step 3 f0 := A0*(r[x]>>(B1+S)); f1 := S4*(r[x+32]>>(B1+S)); f3 += f2; f2 = A1*(g2>>B0); # step 2 g0 := f0+f1; g1 := f0-f1; g3 := f2+f3; g4 = t-A2*(g4>>B0); g5 := A3*((f5-f7)>>B0); g6 = A4*(g6>>B0)+t; # step 1 f0 = g0+g3; f1 = g1+f2; f2 = g1-f2; f3 = g0-g3; f5 = g5-g4; f6 := g5+g6; f7 = g6+g7; # step 6 b[x] = (f0+f7)>>B1; b[x+8] = (f1+f6)>>B1; b[x+16] = (f2+f5)>>B1; b[x+24] = (f3-g4)>>B1; b[x+32] = (f3+g4)>>B1; b[x+40] = (f2-f5)>>B1; b[x+48] = (f1-f6)>>B1; b[x+56] = (f0-f7)>>B1; } }