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esl_huffman.c
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esl_huffman.c
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/* Huffman coding, especially for digitized alphabets.
*
* Contents:
* 1. The ESL_HUFFMAN object
* 2. Huffman encoding
* 3. Huffman decoding
* 4. Debugging, development
* 5. Internal function, components of creating huffman codes
* 6. Example driver
*
* Useful emacs gdb tricks for displaying bit field v:
* p /t v (no leading zeros, beware!)
* x &v
*/
#include <esl_config.h>
#include <stdio.h>
#include "easel.h"
#include "esl_quicksort.h"
#include "esl_huffman.h"
/* Declarations of stuff in internal functions/structures section */
struct hufftree_s {
float val; // Sum of frequencies of all leaves under this node
int depth; // Depth of node
int left; // index of left child in array of tree nodes (0..N-2; 0 is the root)
int right; // "" for right child
};
static int sort_floats_decreasing(const void *data, int e1, int e2);
static int sort_canonical (const void *data, int e1, int e2);
static int huffman_tree (ESL_HUFFMAN *hc, struct hufftree_s *htree, const float *fq);
static int huffman_codelengths (ESL_HUFFMAN *hc, struct hufftree_s *htree, const float *fq);
static int huffman_canonize (ESL_HUFFMAN *hc);
static int huffman_decoding_table(ESL_HUFFMAN *hc);
static void dump_uint32(FILE *fp, uint32_t v, int L);
static void huffman_pack(uint32_t *X, int *ip, int *ap, uint32_t code, int L);
static void huffman_unpack(const ESL_HUFFMAN *hc, uint32_t *vp, const uint32_t *X, int n, int *ip, int *ap, char *ret_x, int *ret_L);
/*****************************************************************
* 1. The ESL_HUFFMAN object
*****************************************************************/
/* Function: esl_huffman_Build()
* Synopsis: Build a new Huffman code.
* Incept: SRE, Thu Nov 12 11:08:09 2015
*
* Purpose: Build a canonical Huffman code for observed symbol
* frequencies <fq[0..K]> for <K> possible symbols.
* Frequencies can be counts, or normalized probabilities;
* all that matters is their relative magnitude (and that
* they're $\geq 0$).
*
* If you're encoding an Easel digital alphabet, you want
* <K = abc->Kp>, inclusive of ambiguity codes, gaps,
* missing data, and rare digital codes.
*
* If you're encoding 7-bit ASCII text, you want K=128, and
* the symbols codes are ASCII codes.
*
* If you're encoding MTF-encoded ASCII text, again you
* want K=128 and the "symbol" codes are 0..127 offsets in
* the move-to-front encoding.
*
* If you're encoding an arbitrary symbol table -- a table
* of gap lengths, perhaps? -- <K> can be anything.
*
* Unobserved symbols (with <fq[] = 0>) will not be encoded;
* they get a code length of 0, and a code of 0.
*
* Args: fq - symbol frequencies 0..K-1; sum to 1
* K - size of fq (encoded alphabet size)
* ret_hc - RETURN: new huffman code object
*
* Returns: <eslOK> on success, and <*ret_hc> points to the new
* <ESL_HUFFMAN> object.
*
* Throws: <eslEMEM> on allocation error.
*
* <eslERANGE> if the encoding requires a code length
* that exceeds <eslHUFFMAN_MAXCODE>, and won't fit in
* a <uint32_t>.
*/
int
esl_huffman_Build(const float *fq, int K, ESL_HUFFMAN **ret_hc)
{
ESL_HUFFMAN *hc = NULL;
struct hufftree_s *htree = NULL; // only need tree temporarily, during code construction.
int i,r;
int status;
ESL_DASSERT1(( fq ));
ESL_DASSERT1(( K > 0 ));
ESL_ALLOC(hc, sizeof(ESL_HUFFMAN));
hc->len = NULL;
hc->code = NULL;
hc->sorted_at = NULL;
hc->dt_len = NULL;
hc->dt_lcode = NULL;
hc->dt_rank = NULL;
hc->K = K;
hc->Ku = 0;
hc->D = 0;
hc->Lmax = 0;
ESL_ALLOC(hc->len, sizeof(int) * hc->K);
ESL_ALLOC(hc->code, sizeof(uint32_t) * hc->K);
ESL_ALLOC(hc->sorted_at, sizeof(int) * hc->K);
for (i = 0; i < hc->K; i++) hc->len[i] = 0;
for (i = 0; i < hc->K; i++) hc->code[i] = 0;
/* Sort the symbol frequencies, largest to smallest */
esl_quicksort(fq, hc->K, sort_floats_decreasing, hc->sorted_at);
/* Figure out how many are nonzero: that's hc->Ku */
for (r = hc->K-1; r >= 0; r--)
if (fq[hc->sorted_at[r]] > 0.) break;
hc->Ku = r+1;
ESL_ALLOC(htree, sizeof(struct hufftree_s) * (ESL_MAX(1, hc->Ku-1))); // Ku=1 is ok; avoid zero malloc.
if ( (status = huffman_tree (hc, htree, fq)) != eslOK) goto ERROR;
if ( (status = huffman_codelengths(hc, htree, fq)) != eslOK) goto ERROR; // can fail eslERANGE on maxlen > 32
if ( (status = huffman_canonize (hc)) != eslOK) goto ERROR;
ESL_ALLOC(hc->dt_len, sizeof(int) * hc->D);
ESL_ALLOC(hc->dt_lcode, sizeof(uint32_t) * hc->D);
ESL_ALLOC(hc->dt_rank, sizeof(int) * hc->D);
if ( (status = huffman_decoding_table(hc)) != eslOK) goto ERROR;
free(htree);
*ret_hc = hc;
return eslOK;
ERROR:
free(htree);
esl_huffman_Destroy(hc);
*ret_hc = NULL;
return status;
}
/* Function: esl_huffman_Destroy()
* Synopsis: Free an <ESL_HUFFMAN> code.
* Incept: SRE, Thu Nov 12 11:07:39 2015
*/
void
esl_huffman_Destroy(ESL_HUFFMAN *hc)
{
if (hc) {
free(hc->len);
free(hc->code);
free(hc->sorted_at);
free(hc->dt_len);
free(hc->dt_lcode);
free(hc->dt_rank);
free(hc);
}
}
/*****************************************************************
* 2. Encoding
*****************************************************************/
/* Function: esl_huffman_Encode()
* Synopsis: Encode a string.
* Incept: SRE, Thu Jun 2 09:27:43 2016 [Hamilton]
*
* Purpose: Use Huffman code <hc> to encode the plaintext input <T> of
* length <n>. The encoded result <X> consists of <nb> bits,
* stored in an array of <nX> <uint32_t>'s; this result is
* returned through the pointers <*ret_X>, <*ret_nX>, and
* <*ret_nb>.
*
* The encoded array <X> is allocated here, and must be
* free'd by the caller.
*
* Args: hc - Huffman code to use for encoding
* T - plaintext input to encode, [0..n-1]; does not need to be NUL-terminated.
* n - length of T
* ret_X - RETURN: encoded bit array
* ret_nb - RETURN: length of X in bits (nX = nb / 32, rounded up)
*
* Returns: <eslOK> on success.
*
* Throws: <eslEMEM> on allocation failure. Now <*ret_X = NULL> and <*ret_nb = 0>.
*/
int
esl_huffman_Encode(const ESL_HUFFMAN *hc, const char *T, int n, uint32_t **ret_X, int *ret_nb)
{
uint32_t *X = NULL;
int xalloc = ESL_MAX(16, (n+15)/16); // current allocation for X, in uint32_t's
int pos = 0; // current position in X's uint32_t array
int nb;
int i;
int status;
ESL_DASSERT1(( hc != NULL ));
ESL_DASSERT1(( T != NULL ));
ESL_DASSERT1(( n > 0 ));
ESL_ALLOC(X, sizeof(uint32_t) * xalloc);
X[0] = 0;
nb = 0;
for (i = 0; i < n; i++)
{
huffman_pack(X, &pos, &nb, hc->code[(int) T[i]], hc->len[(int) T[i]]);
if (pos+1 == xalloc) {
xalloc *= 2;
ESL_REALLOC(X, sizeof(uint32_t) * xalloc);
}
}
*ret_X = X; // X consists of <pos+1> uint32_t's
*ret_nb = 32*pos + nb; // ... we return exact # of bits.
return eslOK;
ERROR:
*ret_X = NULL;
*ret_nb = 0;
return status;
}
/*****************************************************************
* 3. Decoding
*****************************************************************/
/* Function: esl_huffman_Decode()
* Synopsis: Decode a bit stream.
* Incept: SRE, Thu Jun 2 09:52:46 2016 [Hamilton, Act I]
*
* Purpose: Use Huffman code <hc> to decode a bit stream <X> of length
* <n> integers and <nb> bits. The result is a plaintext
* string <T> of length <nT> characters. Return this result
* through <*ret_T> and <*ret_nT>.
*
* The decoded plaintext <T> is allocated here, and must be
* free'd by the caller.
*
* <T> is NUL-terminated, just in case that's useful --
* though the caller isn't necessarily going to treat <T>
* as a string. (It could be using "symbols" 0..127, which
* would include <\0> as a valid symbol.)
*
* Args: hc - Huffman code to use to decode <X>
* X - bit stream to decode
* nb - length of <X> in BITS (nX = nb/32, rounded up)
* ret_T - RETURN: decoded plaintext string, \0-terminated
* ret_n - RETURN: length of <T> in chars
*
* Returns: <eslOK> on success; <*ret_T> and <*ret_nT> hold the result.
*
* Throws: <eslEMEM> on allocation failure. Now <*ret_T> is <NULL> and
* <*ret_nT> is 0.
*
* Xref:
*/
int
esl_huffman_Decode(const ESL_HUFFMAN *hc, const uint32_t *X, int nb, char **ret_T, int *ret_n)
{
char *T = NULL;
int allocT; // current allocation for T
uint32_t v = X[0]; // current (full) 32 bits we're going to decode in this step
int i = 1; // index of X[i] we will first pull *new* bits from, after decoding v
int nX = (nb+31)/32; // length of X in uint32_t's: nb/32 rounded up.
int a = (nX > 1 ? 32 : 0);
int pos = 0;
int L; // length of code we just decoded, in bits
int status;
allocT = nX * 4; // an initial guess: 4 bytes per X, maybe 4x compression
ESL_ALLOC(T, sizeof(char) * allocT);
while (nb > 0)
{
huffman_unpack(hc, &v, X, nX, &i, &a, &(T[pos]), &L);
nb -= L;
if (++pos == allocT) {
allocT *= 2;
ESL_REALLOC(T, sizeof(char) * allocT);
}
}
/* We know we have space for the \0, from how we reallocated. */
T[pos] = '\0';
*ret_T = T;
*ret_n = pos;
return eslOK;
ERROR:
*ret_T = NULL;
*ret_n = 0;
return status;
}
/*****************************************************************
* 4. Debugging, development
*****************************************************************/
/* Function: esl_huffman_Dump()
* Synopsis: Dump info on a huffman code structure.
* Incept: SRE, Sat Jun 4 07:38:15 2016
*
* Purpose: Dump the internals of object <hc> to output stream <fp>.
*/
int
esl_huffman_Dump(FILE *fp, ESL_HUFFMAN *hc)
{
int r,x;
int d,L;
/* Encoding table: <letter index> <code length> <binary encoding> */
fprintf(fp, "Encoding table:\n");
for (r = 0; r < hc->Ku; r++)
{
x = hc->sorted_at[r];
fprintf(fp, "%3d %2d ", x, hc->len[x]);
dump_uint32(fp, hc->code[x], hc->len[x]);
fprintf(fp, "\n");
}
fputc('\n', fp);
/* Decoding table (if set) */
if (hc->dt_len)
{
fprintf(fp, "Decoding table:\n");
for (d = 0; d < hc->D; d++)
{
L = hc->dt_len[d];
fprintf(fp, "L=%2d r=%3d (%3d) ", L, hc->dt_rank[d], hc->sorted_at[hc->dt_rank[d]]);
dump_uint32(fp, hc->dt_lcode[d], eslHUFFMAN_MAXCODE);
fputc('\n', fp);
}
}
return eslOK;
}
/*****************************************************************
* 5. Internal functions and structures
*****************************************************************/
/* sort_floats_decreasing()
* Sorting function for esl_quicksort(), putting
* symbol frequencies in decreasing order.
*/
static int
sort_floats_decreasing(const void *data, int e1, int e2)
{
float *fq = (float *) data;
if (fq[e1] > fq[e2]) return -1;
if (fq[e1] < fq[e2]) return 1;
return 0;
}
/* sort_canonical()
* Sorting function for esl_quicksort(), putting symbols into
* canonical Huffman order: primarily by ascending code length,
* secondarily by ascending symbol code.
*/
static int
sort_canonical(const void *data, int e1, int e2)
{
ESL_HUFFMAN *hc = (ESL_HUFFMAN *) data;
int L1 = hc->len[e1];
int L2 = hc->len[e2];
if (L2 == 0) return -1; // len=0 means symbol isn't encoded at all, doesn't occur
else if (L1 == 0) return 1;
else if (L1 < L2) return -1;
else if (L1 > L2) return 1;
else if (e1 < e2) return -1;
else if (e1 > e2) return 1;
else return 0;
}
/* Build the Huffman tree, joining nodes/leaves of smallest frequency.
* This takes advantage of having the fq[] array sorted, and the fact
* that the internal node values also come out sorted... i.e. we don't
* have to re-sort, we can always find the smallest leaves/nodes by
* looking at the last ones.
*
* For the Ku=1 edge case, there's no tree, and this no-ops.
*
* Input:
* hc->sorted_at[] lists symbol indices from largest to smallest freq.
* hc->Ku is the number of syms w/ nonzero freq; tree has Ku-1 nodes
* htree blank, allocated for at least Ku-1 nodes
*
* Output:
* htree's left, right, val fields are filled.
*
* Returns:
* <eslOK> on success.
*/
static int
huffman_tree(ESL_HUFFMAN *hc, struct hufftree_s *htree, const float *fq)
{
int r = hc->Ku-1; // r = smallest leaf symbol that hasn't been included in tree yet; r+1 = # of leaves left
int k = hc->Ku-2; // k = smallest internal node not used as a child yet; k-j = # nodes not used as child yet
int j;
for (j = hc->Ku-2; j >= 0; j--) // j = index of next node we add; we add one per iteration
{
/* Should we join two leaves?
* If we have no internal nodes yet (because we're just starting),
* or the two smallest frequencies are <= the smallest unjoined node's value
*/
if ( (j == hc->Ku-2) || (r >= 1 && fq[hc->sorted_at[r]] <= htree[k].val))
{
htree[j].right = -hc->sorted_at[r]; // leaves are signified by negative indices in tree
htree[j].left = -hc->sorted_at[r-1];
htree[j].val = fq[hc->sorted_at[r]] + fq[hc->sorted_at[r-1]];
r -= 2;
}
/* Or should we join two nodes?
* If we have no leaves left,
* or (we do have two nodes) and both are smaller than smallest unjoined leaf's value
*/
else if (r == -1 || (k-j >= 2 && htree[k-1].val < fq[hc->sorted_at[r]]))
{
htree[j].right = k;
htree[j].left = k-1;
htree[j].val = htree[k].val + htree[k-1].val;
k -= 2;
}
/* Otherwise, we join smallest node and smallest leaf. */
else
{
htree[j].right = -hc->sorted_at[r];
htree[j].left = k;
htree[j].val = fq[hc->sorted_at[r]] + htree[k].val;
r--;
k--;
}
}
return eslOK;
}
/* Calculate code lengths, equal to the depth of each node.
* Traverse the tree, calculating depth of each node, starting with
* depth 0 for root 0. We don't need a stack for this traversal,
* tree is already indexed in traversal order.
*
* For the Ku=1 edge case, there's no tree; for a single encoded
* symbol we set hc->len[0] = 1, hc->Lmax = 1
*
* Input:
* hc->Ku is the number of syms w/ nonzero freqs; tree has Ku-1 nodes.
* htree[0..Ku-2] is the constructed Huffman tree, with right/left/val set.
* htree[].len has been initialized to 0 for all symbols 0..K
*
* Output:
* htree's depth field is set.
* hc->len is set for all encoded symbols (left at 0 for unused symbols)
* hc->Lmax is set
*
* Return:
* <eslOK> on success
* <eslERANGE> if max code length > eslHUFFMAN_MAXCODE and won't fit in uint32_t
*/
static int
huffman_codelengths(ESL_HUFFMAN *hc, struct hufftree_s *htree, const float *fq)
{
int i;
if (hc->Ku == 1)
{
hc->len[ hc->sorted_at[0] ] = 1;
hc->Lmax = 1;
return eslOK;
}
htree[0].depth = 0;
for (i = 0; i < hc->Ku-1; i++)
{
if (htree[i].right <= 0) hc->len[-htree[i].right] = htree[i].depth + 1;
else htree[htree[i].right].depth = htree[i].depth + 1;
if (htree[i].left <= 0) hc->len[-htree[i].left] = htree[i].depth + 1;
else htree[htree[i].left].depth = htree[i].depth + 1;
}
hc->Lmax = 0;
for (i = 0; i < hc->K; i++)
hc->Lmax = ESL_MAX(hc->len[i], hc->Lmax);
return (hc->Lmax > eslHUFFMAN_MAXCODE ? eslERANGE : eslOK);
}
/* huffman_canonize()
* Given code lengths, now we calculate the canonical Huffman encoding.
*
* Input:
* hc->len[] code lengths are set for all K (0 for unused symbols)
* hc->code[] have been initialized to 0 for all K
*
* Output:
* hc->code[] have been set for all used symbols.
* hc->D number of different code lengths is set
*
* Returns:
* <eslOK> on success.
*/
static int
huffman_canonize(ESL_HUFFMAN *hc)
{
int r;
/* Sort symbols according to 1) code length; 2) order in digital alphabet (i.e. symbol code itself)
* Reuse/reset <sorted_at>.
* You can't just sort the encoded Ku; you have to sort all K, because
* quicksort expects indices to be contiguous (0..K-1).
*/
esl_quicksort(hc, hc->K, sort_canonical, hc->sorted_at);
/* Assign codes. (All K have been initialized to zero already.) */
for (r = 1; r < hc->Ku; r++)
hc->code[hc->sorted_at[r]] =
(hc->code[hc->sorted_at[r-1]] + 1) << (hc->len[hc->sorted_at[r]] - hc->len[hc->sorted_at[r-1]]);
/* Set D, the number of different code lengths */
hc->D = 1;
for (r = 1; r < hc->Ku; r++)
if (hc->len[hc->sorted_at[r]] > hc->len[hc->sorted_at[r-1]]) hc->D++;
return eslOK;
}
/* huffman_decoding_table()
* Given a canonical Huffman code; build the table that lets us
* efficiently decode it.
*
* Input:
* hc->K is set: total # of symbols (inclusive of unused ones)
* hc->Ku is set: total # of encoded/used symbols
* hc->code is set: canonical Huffman codes for symbols 0..K-1
* hc->len is set: code lengths for symbols 0..K-1
* hc->sorted_at is set: canonical Huffman sort order
* hc->Lmax is set: maximum code length
* hc->D is set: # of different code lengths
*
* hc->dt_len is allocated for hc->D, but otherwise uninitialized
* hc->dt_lcode is allocated for hc->D, but otherwise uninitialized
* hc->dt_rank is allocated for hc->D, but otherwise uninitialized
*
* Output:
* hc->dt_len is set: lengths of each used code length 0..D-1
* hc->dt_lcode is set: left-flushed first code for each code length [d]
* hc->dt_rank is set: rank r for 1st code for each used code length [d]
*/
static int
huffman_decoding_table(ESL_HUFFMAN *hc)
{
int r;
int D = 0;
hc->dt_len[0] = hc->len[hc->sorted_at[0]];
hc->dt_lcode[0] = hc->code[hc->sorted_at[0]] << (eslHUFFMAN_MAXCODE - hc->len[hc->sorted_at[0]]);
hc->dt_rank[0] = 0;
for (r = 1; r < hc->Ku; r++)
if (hc->len[hc->sorted_at[r]] > hc->len[hc->sorted_at[r-1]])
{
D++;
hc->dt_len[D] = hc->len[hc->sorted_at[r]];
hc->dt_lcode[D] = hc->code[hc->sorted_at[r]] << (eslHUFFMAN_MAXCODE - hc->len[hc->sorted_at[r]]);
hc->dt_rank[D] = r;
}
ESL_DASSERT1(( hc->D == D+1 ));
return eslOK;
}
static void
dump_uint32(FILE *fp, uint32_t v, int L)
{
uint32_t mask;
int i;
for (mask = 1 << (L-1), i = L; i >= 1; i--, mask = mask >> 1)
putc( ((v & mask) ? '1' : '0'), fp);
}
/* huffman_pack()
*
* <X[i]> is the current uint32_t unit in the encoded buffer <X>. It
* has <a> bits in it so far, maximally left-shifted; therefore (32-a)
* bits are available.
*
* <code> is the next Huffman code to pack into the buffer, of length
* <L>, and it's right flush.
*
* a=10 used (32-a)=20 free
* |xxxxxxxxxx|......................| X[i]
* |........................|yyyyyyyy| code, L=8
* |----- w -----|
* w = 32-(a+L)
*
* If L < 32-a, then we just shift by w and pack it into X[i]. Else,
* we shift the other way (by -w), pack what we can into X[i], and
* leave the remainder in X[i+1].
*
* We update <i> and <a> for <X> accordingly... so we pass them by
* reference in <ip> and <ap>.
*/
static void
huffman_pack(uint32_t *X, int *ip, int *ap, uint32_t code, int L)
{
int w = 32 - (*ap+L);
if (w > 0) // code can pack into X[i]'s available space.
{
X[*ip] = X[*ip] | (code << w);
*ap += L;
}
else if (w < 0) // code packs partly in X[i], remainder in X[i+1].
{
X[*ip] = X[*ip] | (code >> (-w));
(*ip)++;
X[*ip] = code << (32+w);
(*ap) = -w;
}
else // code packs exactly; w=0, no leftshift needed, OR it as is.
{
X[*ip] = X[*ip] | code;
*ip += 1;
*ap = 0;
X[*ip] = 0; // don't forget to initialize X[i+1]!
}
}
/* huffman_unpack()
* *vp : ptr to v; v = next 32 bits
* *X : encoded input
* n : length of input (in uint32_t)
* *ip : current position in <X>
* *ap : number of bits left in X[*ip]
*
* If we have to buffer X (say, if we're reading it from
* a long input) we'll have to redesign. Right now we assume
* it's just an array.
*/
static void
huffman_unpack(const ESL_HUFFMAN *hc, uint32_t *vp, const uint32_t *X, int n, int *ip, int *ap, char *ret_x, int *ret_L)
{
int L,D;
int idx;
uint32_t w;
for (D = 0; D < hc->D-1; D++)
if ((*vp) < hc->dt_lcode[D+1]) break;
L = hc->dt_len[D];
/* L is now the next code's length (prefix of v) */
/* Decode, by taking advantage of lexicographic sort/numerical order of canonical code, within each L */
idx = hc->dt_rank[D] + ( ((*vp) - hc->dt_lcode[D]) >> (eslHUFFMAN_MAXCODE-L) );
/* Now refill v, as much as we can, from bits in X[i] and X[i+1], and update i, a */
*vp = ( (*vp) << L); // Remove L bits from *vp by leftshifting it.
if (*ip < n) { // Take either L or all *ap bits from X[i], if it exists.
w = X[*ip] << (32-(*ap)); // Shift off the bits we already used in X[i]. w is now X[i], left-flushed.
*vp |= (w >> (32-L)); // Right-shift w into position, leaving it with leading 0's where *vp already has bits.
*ap -= L; // We used up to L bits from X[i]
// if *ap is still >0, we have bits left to use in X[i]. Otherwise:
if (*ap == 0) // If we exactly finished off X[i]:
{
(*ip)++; // then advance in X[].
*ap = 32;
}
else if (*ap < 0) // If we finished off X[i] but still need some bits
{
(*ip)++; // then go on to X[i+1] and 32 fresh bits.
if (*ip < n) // If it exists...
{ // (...no, I don't like all these branches either...)
*ap += 32; // then we're going to leave it w/ <*ap> bits
*vp |= (X[*ip] >> *ap); // after taking the bits we need to fill v
}
else
{
*ap = 0; // If X[i+1] doesn't exist, leave *ip = n and *ap = 0; out of data in X (though not necessarily in v)
}
}
}
*ret_x = (char) hc->sorted_at[idx];
*ret_L = L;
}
/*****************************************************************
* 6. Unit tests
*****************************************************************/
#ifdef eslHUFFMAN_TESTDRIVE
#include "esl_random.h"
#include "esl_randomseq.h"
#include "esl_vectorops.h"
#include <string.h>
static void
utest_kryptos(ESL_RANDOMNESS *rng)
{
char msg[] = "kryptos utest failed";
ESL_HUFFMAN *hc = NULL;
char T[] = "BETWEEN SUBTLE SHADING AND THE ABSENCE OF LIGHT LIES THE NUANCE OF IQLUSION";
int n = strlen(T);
uint32_t *X = NULL;
int nb;
char *T2 = NULL;
int n2;
float fq[128];
int K = 128;
int i;
int status;
/* Any half-assed frequency distribution will do for this, over [ A-Z] */
for (i = 0; i < 128; i++) fq[i] = 0.;
for (i = 'A'; i <= 'Z'; i++) fq[i] = esl_random(rng);
fq[' '] = esl_random(rng);
esl_vec_FNorm(fq, 128);
if (( status = esl_huffman_Build (fq, K, &hc) ) != eslOK) esl_fatal(msg);
if (( status = esl_huffman_Encode(hc, T, n, &X, &nb)) != eslOK) esl_fatal(msg);
if (( status = esl_huffman_Decode(hc, X, nb, &T2, &n2)) != eslOK) esl_fatal(msg);
//esl_huffman_Dump(stdout, hc);
//printf("%s\n", T);
//printf("%s\n", T2);
if (n2 != n) esl_fatal(msg);
if (strcmp(T, T2) != 0) esl_fatal(msg);
free(X);
free(T2);
esl_huffman_Destroy(hc);
}
/* utest_uniletter()
* Tests an edge case of a text consisting of a single letter, Ku=1.
* (Ku=1 cases get tested occasionally by utest_backandforth() too.)
*/
static void
utest_uniletter(void)
{
char msg[] = "uniletter utest failed";
char T[] = "AAAAAAAAAA";
int n = strlen(T);
int K = 128;
float fq[128];
ESL_HUFFMAN *hc = NULL;
uint32_t *X = NULL;
int nb;
char *T2 = NULL;
int n2;
int i;
int status;
for (i = 0; i < 128; i++) fq[i] = 0.;
fq['A'] = (float) n;
if (( status = esl_huffman_Build (fq, K, &hc) ) != eslOK) esl_fatal(msg);
if (( status = esl_huffman_Encode(hc, T, n, &X, &nb)) != eslOK) esl_fatal(msg);
if (( status = esl_huffman_Decode(hc, X, nb, &T2, &n2)) != eslOK) esl_fatal(msg);
if (n2 != n) esl_fatal(msg);
if (strcmp(T, T2) != 0) esl_fatal(msg);
free(X);
free(T2);
esl_huffman_Destroy(hc);
}
/* utest_backandforth()
* Encode and decode a random text string, and test
* that it decodes to the original.
*/
static void
utest_backandforth(ESL_RANDOMNESS *rng)
{
char msg[] = "back and forth utest failed";
ESL_HUFFMAN *hc = NULL;
double *fq0 = NULL;
float *fq = NULL;
int K; // alphabet size: randomly chosen from 1..128
char *T = NULL; // random plaintext
int n; // randomly chosen length of plaintext T
uint32_t *X = NULL; // Huffman-coded bit stream
int nb; // length of X in bits
char *T2 = NULL; // decoded plaintext
int n2; // length of T2 in chars
int i;
int status;
/* Sample a zero-peppered frequency distribution <fq> for a randomly
* selected alphabet size <K>.
*/
K = 1 + esl_rnd_Roll(rng, 128); // Choose a random alphabet size from 1 to 128
if (( fq0 = malloc(sizeof(double) * K)) == NULL) esl_fatal(msg); // esl_random works in doubles
if (( fq = malloc(sizeof(float) * K)) == NULL) esl_fatal(msg); // esl_huffman works in floats
esl_rnd_Dirichlet(rng, NULL, K, fq0); // Sample a uniform random probability vector
for (i = 0; i < K; i++) // Pepper it with exact 0's while converting to float
fq[i] = ( esl_rnd_Roll(rng, 4) == 0 ? 0. : (float) fq0[i] );
esl_vec_FNorm(fq, K); // and renormalize. (edge case: if fq was all 0, now it's uniform.)
/* Sample a random plaintext array <T>, of randomly selected length <n>.
* We're using codes 0..K-1 -- T is not a string, it's an array -- don't \0 it.
*/
n = 1 + esl_rnd_Roll(rng, 10);
if (( T = malloc(sizeof(char) * (n+1))) == NULL) esl_fatal(msg);
for (i = 0; i < n; i++) T[i] = esl_rnd_FChoose(rng,fq,K);
if (( status = esl_huffman_Build (fq, K, &hc) ) != eslOK) esl_fatal(msg);
if (( status = esl_huffman_Encode(hc, T, n, &X, &nb)) != eslOK) esl_fatal(msg);
if (( status = esl_huffman_Decode(hc, X, nb, &T2, &n2)) != eslOK) esl_fatal(msg);
//esl_huffman_Dump(stdout, hc);
if ( n2 != n) esl_fatal(msg);
if ( memcmp(T, T2, n) != 0) esl_fatal(msg);
free(T2);
free(X);
free(fq0);
free(fq);
free(T);
esl_huffman_Destroy(hc);
}
#endif /*eslHUFFMAN_TESTDRIVE*/
/*****************************************************************
* 7. Test driver
*****************************************************************/
#ifdef eslHUFFMAN_TESTDRIVE
#include <esl_config.h>
#include <stdio.h>
#include "easel.h"
#include "esl_getopts.h"
#include "esl_huffman.h"
#include "esl_random.h"
static ESL_OPTIONS options[] = {
/* name type default env range togs reqs incomp help docgrp */
{"-h", eslARG_NONE, FALSE, NULL, NULL, NULL, NULL, NULL, "show help and usage", 0},
{"-s", eslARG_INT, "0", NULL, NULL, NULL, NULL, NULL, "set random number seed to <n>", 0},
{ 0,0,0,0,0,0,0,0,0,0},
};
static char usage[] = "[-options]";
static char banner[] = "test driver for huffman module";
int
main(int argc, char **argv)
{
ESL_GETOPTS *go = esl_getopts_CreateDefaultApp(options, 0, argc, argv, banner, usage);
ESL_RANDOMNESS *rng = esl_randomness_Create(esl_opt_GetInteger(go, "-s"));
fprintf(stderr, "## %s\n", argv[0]);
fprintf(stderr, "# rng seed = %" PRIu32 "\n", esl_randomness_GetSeed(rng));
utest_kryptos (rng);
utest_uniletter ( );
utest_backandforth(rng);
fprintf(stderr, "# status = ok\n");
esl_getopts_Destroy(go);
esl_randomness_Destroy(rng);
return eslOK;
}
#endif /*eslHUFFMAN_TESTDRIVE*/
/*****************************************************************
* 8. Examples
*****************************************************************/
#ifdef eslHUFFMAN_EXAMPLE2
/* esl_huffman_example2 <fqfile>
*
* The input <fqfile> consists of N lines with
* two whitespace-delimited fields:
* <label> <frequency>
*
* Huffman code the frequency distribution, and output the resulting
* encoding.
*/
#include "easel.h"
#include "esl_buffer.h"
#include "esl_huffman.h"
#include "esl_mem.h"
#include "esl_vectorops.h"
int
main(int argc, char **argv)
{
ESL_HUFFMAN *hc = NULL;
ESL_BUFFER *bf = NULL;
esl_pos_t n;
char *p;
char *tok;
esl_pos_t toklen;
int kalloc = 16;
char **label = malloc(sizeof(char *) * kalloc);
float *fq = malloc(sizeof(float) * kalloc);
int K = 0;
float meanL = 0.;
int i;
int status;
status = esl_buffer_Open(argv[1], NULL, &bf);
if (status == eslENOTFOUND) esl_fatal("open failed: %s", bf->errmsg);
else if (status == eslFAIL) esl_fatal("gzip -dc failed: %s", bf->errmsg);
else if (status != eslOK) esl_fatal("open failed with error code %d", status);
while (( status = esl_buffer_GetLine(bf, &p, &n)) == eslOK)
{
if ( esl_memtok(&p, &n, " \t\n", &tok, &toklen) != eslOK) continue;
if ( esl_memstrdup(tok, toklen, &(label[K])) != eslOK) continue;
if ( esl_mem_strtof(p, n, NULL, &(fq[K])) != eslOK) continue;
if (++K == kalloc) {
kalloc *= 2;
label = realloc(label, sizeof(char *) * kalloc);
fq = realloc(fq, sizeof(float) * kalloc);
}
}
esl_vec_FNorm(fq, K);
if (( status = esl_huffman_Build(fq, K, &hc)) != eslOK) esl_fatal("failed to build huffman code");
for (i = 0; i < K; i++)
{
printf("%-10s %2d ", label[i], hc->len[i]);
dump_uint32(stdout, hc->code[i], hc->len[i]);
printf("\n");
}
for (i = 0; i < K; i++)
meanL += (float) hc->len[i] * fq[i];
printf("\nMean code length = %.2f bits\n", meanL);
for (i = 0; i < K; i++) free(label[i]);
free(label);
free(fq);
esl_huffman_Destroy(hc);
esl_buffer_Close(bf);
return 0;
}
#endif /*eslHUFFMAN_EXAMPLE2*/