src/wasm-gc-teavm/java/com/jcraft/jorbis/StaticCodeBook.java

/* -*-mode:java; c-basic-offset:2; indent-tabs-mode:nil -*- */
/* JOrbis
 * Copyright (C) 2000 ymnk, JCraft,Inc.
 *  
 * Written by: 2000 ymnk<ymnk@jcraft.com>
 *   
 * Many thanks to 
 *   Monty <monty@xiph.org> and 
 *   The XIPHOPHORUS Company http://www.xiph.org/ .
 * JOrbis has been based on their awesome works, Vorbis codec.
 *   
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Library General Public License
 * as published by the Free Software Foundation; either version 2 of
 * the License, or (at your option) any later version.
   
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU Library General Public License for more details.
 * 
 * You should have received a copy of the GNU Library General Public
 * License along with this program; if not, write to the Free Software
 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
 */

package com.jcraft.jorbis;

import com.jcraft.jogg.*;

class StaticCodeBook {
	int dim; // codebook dimensions (elements per vector)
	int entries; // codebook entries
	int[] lengthlist; // codeword lengths in bits

	// mapping
	int maptype; // 0=none
	// 1=implicitly populated values from map column
	// 2=listed arbitrary values

	// The below does a linear, single monotonic sequence mapping.
	int q_min; // packed 32 bit float; quant value 0 maps to minval
	int q_delta; // packed 32 bit float; val 1 - val 0 == delta
	int q_quant; // bits: 0 < quant <= 16
	int q_sequencep; // bitflag

	// additional information for log (dB) mapping; the linear mapping
	// is assumed to actually be values in dB. encodebias is used to
	// assign an error weight to 0 dB. We have two additional flags:
	// zeroflag indicates if entry zero is to represent -Inf dB; negflag
	// indicates if we're to represent negative linear values in a
	// mirror of the positive mapping.

	int[] quantlist; // map == 1: (int)(entries/dim) element column map
	// map == 2: list of dim*entries quantized entry vals

	StaticCodeBook() {
	}

	int pack(Buffer opb) {
		int i;
		boolean ordered = false;

		opb.write(0x564342, 24);
		opb.write(dim, 16);
		opb.write(entries, 24);

		// pack the codewords. There are two packings; length ordered and
		// length random. Decide between the two now.

		for (i = 1; i < entries; i++) {
			if (lengthlist[i] < lengthlist[i - 1])
				break;
		}
		if (i == entries)
			ordered = true;

		if (ordered) {
			// length ordered. We only need to say how many codewords of
			// each length. The actual codewords are generated
			// deterministically

			int count = 0;
			opb.write(1, 1); // ordered
			opb.write(lengthlist[0] - 1, 5); // 1 to 32

			for (i = 1; i < entries; i++) {
				int _this = lengthlist[i];
				int _last = lengthlist[i - 1];
				if (_this > _last) {
					for (int j = _last; j < _this; j++) {
						opb.write(i - count, Util.ilog(entries - count));
						count = i;
					}
				}
			}
			opb.write(i - count, Util.ilog(entries - count));
		} else {
			// length random. Again, we don't code the codeword itself, just
			// the length. This time, though, we have to encode each length
			opb.write(0, 1); // unordered

			// algortihmic mapping has use for 'unused entries', which we tag
			// here. The algorithmic mapping happens as usual, but the unused
			// entry has no codeword.
			for (i = 0; i < entries; i++) {
				if (lengthlist[i] == 0)
					break;
			}

			if (i == entries) {
				opb.write(0, 1); // no unused entries
				for (i = 0; i < entries; i++) {
					opb.write(lengthlist[i] - 1, 5);
				}
			} else {
				opb.write(1, 1); // we have unused entries; thus we tag
				for (i = 0; i < entries; i++) {
					if (lengthlist[i] == 0) {
						opb.write(0, 1);
					} else {
						opb.write(1, 1);
						opb.write(lengthlist[i] - 1, 5);
					}
				}
			}
		}

		// is the entry number the desired return value, or do we have a
		// mapping? If we have a mapping, what type?
		opb.write(maptype, 4);
		switch (maptype) {
		case 0:
			// no mapping
			break;
		case 1:
		case 2:
			// implicitly populated value mapping
			// explicitly populated value mapping
			if (quantlist == null) {
				// no quantlist? error
				return (-1);
			}

			// values that define the dequantization
			opb.write(q_min, 32);
			opb.write(q_delta, 32);
			opb.write(q_quant - 1, 4);
			opb.write(q_sequencep, 1);

		{
			int quantvals = 0;
			switch (maptype) {
			case 1:
				// a single column of (c->entries/c->dim) quantized values for
				// building a full value list algorithmically (square lattice)
				quantvals = maptype1_quantvals();
				break;
			case 2:
				// every value (c->entries*c->dim total) specified explicitly
				quantvals = entries * dim;
				break;
			}

			// quantized values
			for (i = 0; i < quantvals; i++) {
				opb.write(Math.abs(quantlist[i]), q_quant);
			}
		}
			break;
		default:
			// error case; we don't have any other map types now
			return (-1);
		}
		return (0);
	}

	// unpacks a codebook from the packet buffer into the codebook struct,
	// readies the codebook auxiliary structures for decode
	int unpack(Buffer opb) {
		int i;
		// memset(s,0,sizeof(static_codebook));

		// make sure alignment is correct
		if (opb.read(24) != 0x564342) {
			// goto _eofout;
			clear();
			return (-1);
		}

		// first the basic parameters
		dim = opb.read(16);
		entries = opb.read(24);
		if (entries == -1) {
			// goto _eofout;
			clear();
			return (-1);
		}

		// codeword ordering.... length ordered or unordered?
		switch (opb.read(1)) {
		case 0:
			// unordered
			lengthlist = new int[entries];

			// allocated but unused entries?
			if (opb.read(1) != 0) {
				// yes, unused entries

				for (i = 0; i < entries; i++) {
					if (opb.read(1) != 0) {
						int num = opb.read(5);
						if (num == -1) {
							// goto _eofout;
							clear();
							return (-1);
						}
						lengthlist[i] = num + 1;
					} else {
						lengthlist[i] = 0;
					}
				}
			} else {
				// all entries used; no tagging
				for (i = 0; i < entries; i++) {
					int num = opb.read(5);
					if (num == -1) {
						// goto _eofout;
						clear();
						return (-1);
					}
					lengthlist[i] = num + 1;
				}
			}
			break;
		case 1:
		// ordered
		{
			int length = opb.read(5) + 1;
			lengthlist = new int[entries];

			for (i = 0; i < entries;) {
				int num = opb.read(Util.ilog(entries - i));
				if (num == -1) {
					// goto _eofout;
					clear();
					return (-1);
				}
				for (int j = 0; j < num; j++, i++) {
					lengthlist[i] = length;
				}
				length++;
			}
		}
			break;
		default:
			// EOF
			return (-1);
		}

		// Do we have a mapping to unpack?
		switch ((maptype = opb.read(4))) {
		case 0:
			// no mapping
			break;
		case 1:
		case 2:
			// implicitly populated value mapping
			// explicitly populated value mapping
			q_min = opb.read(32);
			q_delta = opb.read(32);
			q_quant = opb.read(4) + 1;
			q_sequencep = opb.read(1);

		{
			int quantvals = 0;
			switch (maptype) {
			case 1:
				quantvals = maptype1_quantvals();
				break;
			case 2:
				quantvals = entries * dim;
				break;
			}

			// quantized values
			quantlist = new int[quantvals];
			for (i = 0; i < quantvals; i++) {
				quantlist[i] = opb.read(q_quant);
			}
			if (quantlist[quantvals - 1] == -1) {
				// goto _eofout;
				clear();
				return (-1);
			}
		}
			break;
		default:
			// goto _eofout;
			clear();
			return (-1);
		}
		// all set
		return (0);
		// _errout:
		// _eofout:
		// vorbis_staticbook_clear(s);
		// return(-1);
	}

	// there might be a straightforward one-line way to do the below
	// that's portable and totally safe against roundoff, but I haven't
	// thought of it. Therefore, we opt on the side of caution
	private int maptype1_quantvals() {
		int vals = (int) (Math.floor(Math.pow(entries, 1. / dim)));

		// the above *should* be reliable, but we'll not assume that FP is
		// ever reliable when bitstream sync is at stake; verify via integer
		// means that vals really is the greatest value of dim for which
		// vals^b->bim <= b->entries
		// treat the above as an initial guess
		while (true) {
			int acc = 1;
			int acc1 = 1;
			for (int i = 0; i < dim; i++) {
				acc *= vals;
				acc1 *= vals + 1;
			}
			if (acc <= entries && acc1 > entries) {
				return (vals);
			} else {
				if (acc > entries) {
					vals--;
				} else {
					vals++;
				}
			}
		}
	}

	void clear() {
	}

	// unpack the quantized list of values for encode/decode
	// we need to deal with two map types: in map type 1, the values are
	// generated algorithmically (each column of the vector counts through
	// the values in the quant vector). in map type 2, all the values came
	// in in an explicit list. Both value lists must be unpacked
	float[] unquantize() {

		if (maptype == 1 || maptype == 2) {
			int quantvals;
			float mindel = float32_unpack(q_min);
			float delta = float32_unpack(q_delta);
			float[] r = new float[entries * dim];

			// maptype 1 and 2 both use a quantized value vector, but
			// different sizes
			switch (maptype) {
			case 1:
				// most of the time, entries%dimensions == 0, but we need to be
				// well defined. We define that the possible vales at each
				// scalar is values == entries/dim. If entries%dim != 0, we'll
				// have 'too few' values (values*dim<entries), which means that
				// we'll have 'left over' entries; left over entries use zeroed
				// values (and are wasted). So don't generate codebooks like that
				quantvals = maptype1_quantvals();
				for (int j = 0; j < entries; j++) {
					float last = 0.f;
					int indexdiv = 1;
					for (int k = 0; k < dim; k++) {
						int index = (j / indexdiv) % quantvals;
						float val = quantlist[index];
						val = Math.abs(val) * delta + mindel + last;
						if (q_sequencep != 0)
							last = val;
						r[j * dim + k] = val;
						indexdiv *= quantvals;
					}
				}
				break;
			case 2:
				for (int j = 0; j < entries; j++) {
					float last = 0.f;
					for (int k = 0; k < dim; k++) {
						float val = quantlist[j * dim + k];
						// if((j*dim+k)==0){System.err.println(" | 0 -> "+val+" | ");}
						val = Math.abs(val) * delta + mindel + last;
						if (q_sequencep != 0)
							last = val;
						r[j * dim + k] = val;
						// if((j*dim+k)==0){System.err.println(" $ r[0] -> "+r[0]+" | ");}
					}
				}
				// System.err.println("\nr[0]="+r[0]);
			}
			return (r);
		}
		return (null);
	}

	// 32 bit float (not IEEE; nonnormalized mantissa +
	// biased exponent) : neeeeeee eeemmmmm mmmmmmmm mmmmmmmm
	// Why not IEEE? It's just not that important here.

	static final int VQ_FEXP = 10;
	static final int VQ_FMAN = 21;
	static final int VQ_FEXP_BIAS = 768; // bias toward values smaller than 1.

	// doesn't currently guard under/overflow
	static long float32_pack(float val) {
		int sign = 0;
		int exp;
		int mant;
		if (val < 0) {
			sign = 0x80000000;
			val = -val;
		}
		exp = (int) Math.floor(Math.log(val) / Math.log(2));
		mant = (int) Math.rint(Math.pow(val, (VQ_FMAN - 1) - exp));
		exp = (exp + VQ_FEXP_BIAS) << VQ_FMAN;
		return (sign | exp | mant);
	}

	static float float32_unpack(int val) {
		float mant = val & 0x1fffff;
		float exp = (val & 0x7fe00000) >>> VQ_FMAN;
		if ((val & 0x80000000) != 0)
			mant = -mant;
		return (ldexp(mant, ((int) exp) - (VQ_FMAN - 1) - VQ_FEXP_BIAS));
	}

	static float ldexp(float foo, int e) {
		return (float) (foo * Math.pow(2, e));
	}
}