From: Zooko O'Whielacronx zooko@zooko.com <zooko@zooko.com>
Date: Thu, 1 Feb 2007 06:03:25 +0000 (+0530)
Subject: pyfec: fix preconditions and typing, remove unused error-checking, tidy-up naming... 
X-Git-Url: https://git.rkrishnan.org/%5B/%5D%20/uri/flags/frontends/architecture.txt?a=commitdiff_plain;h=8252245977ddd1e925d9a3bff3b92841ae3bd9bb;p=tahoe-lafs%2Fzfec.git

pyfec: fix preconditions and typing, remove unused error-checking, tidy-up naming and documentation

darcs-hash:8c487c77471db12b73c52bb80a9cc71e8c5968da
---

diff --git a/pyfec/fec/_fecmodule.c b/pyfec/fec/_fecmodule.c
index 8bd6f46..97a935e 100644
--- a/pyfec/fec/_fecmodule.c
+++ b/pyfec/fec/_fecmodule.c
@@ -111,8 +111,8 @@ Encoder_init(Encoder *self, PyObject *args, PyObject *kwdict) {
         py_raise_fec_error("Precondition violation: second argument is required to be greater than or equal to 1, but it was %d", self->mm);
 	return -1;
     }
-    if (self->mm > 255) {
-        py_raise_fec_error("Precondition violation: second argument is required to be less than or equal to 255, but it was %d", self->mm);
+    if (self->mm > 256) {
+        py_raise_fec_error("Precondition violation: second argument is required to be less than or equal to 256, but it was %d", self->mm);
 	return -1;
     }
     if (self->kk > self->mm) {
@@ -142,14 +142,14 @@ Encoder_encode(Encoder *self, PyObject *args) {
 
     gf* check_shares_produced[self->mm - self->kk]; /* This is an upper bound -- we will actually use only num_check_shares_produced of these elements (see below). */
     PyObject* pystrs_produced[self->mm - self->kk]; /* This is an upper bound -- we will actually use only num_check_shares_produced of these elements (see below). */
-    unsigned char num_check_shares_produced = 0; /* The first num_check_shares_produced elements of the check_shares_produced array and of the pystrs_produced array will be used. */
+    unsigned num_check_shares_produced = 0; /* The first num_check_shares_produced elements of the check_shares_produced array and of the pystrs_produced array will be used. */
     const gf* incshares[self->kk];
-    unsigned char num_desired_shares;
+    unsigned num_desired_shares;
     PyObject* fast_desired_shares_ids = NULL;
     PyObject** fast_desired_shares_ids_items;
-    unsigned char c_desired_shares_ids[self->mm];
-    unsigned char c_desired_checkshares_ids[self->mm - self->kk];
-    unsigned char i;
+    unsigned c_desired_shares_ids[self->mm];
+    unsigned c_desired_checkshares_ids[self->mm - self->kk];
+    unsigned i;
     if (desired_shares_ids) {
         fast_desired_shares_ids = PySequence_Fast(desired_shares_ids, "Second argument (optional) was not a sequence.");
         num_desired_shares = PySequence_Fast_GET_SIZE(fast_desired_shares_ids);
@@ -360,8 +360,8 @@ Decoder_init(Encoder *self, PyObject *args, PyObject *kwdict) {
         py_raise_fec_error("Precondition violation: second argument is required to be greater than or equal to 1, but it was %d", self->mm);
 	return -1;
     }
-    if (self->mm > 255) {
-        py_raise_fec_error("Precondition violation: second argument is required to be less than or equal to 255, but it was %d", self->mm);
+    if (self->mm > 256) {
+        py_raise_fec_error("Precondition violation: second argument is required to be less than or equal to 256, but it was %d", self->mm);
 	return -1;
     }
     if (self->kk > self->mm) {
@@ -393,10 +393,10 @@ Decoder_decode(Decoder *self, PyObject *args) {
         return NULL;
 
     const gf*restrict cshares[self->kk];
-    unsigned char cshareids[self->kk];
+    unsigned cshareids[self->kk];
     gf*restrict recoveredcstrs[self->kk]; /* self->kk is actually an upper bound -- we probably won't need all of this space. */
     PyObject*restrict recoveredpystrs[self->kk]; /* self->kk is actually an upper bound -- we probably won't need all of this space. */
-    unsigned char i;
+    unsigned i;
     for (i=0; i<self->kk; i++)
         recoveredpystrs[i] = NULL;
     PyObject*restrict fastshares = PySequence_Fast(shares, "First argument was not a sequence.");
@@ -416,7 +416,7 @@ Decoder_decode(Decoder *self, PyObject *args) {
     }
 
     /* Construct a C array of gf*'s of the data and another of C ints of the shareids. */
-    unsigned char needtorecover=0;
+    unsigned needtorecover=0;
     PyObject** fastshareidsitems = PySequence_Fast_ITEMS(fastshareids);
     if (!fastshareidsitems)
         goto err;
@@ -428,11 +428,11 @@ Decoder_decode(Decoder *self, PyObject *args) {
         if (!PyInt_Check(fastshareidsitems[i]))
             goto err;
         long tmpl = PyInt_AsLong(fastshareidsitems[i]);
-        if (tmpl < 0 || tmpl >= UCHAR_MAX) {
+        if (tmpl < 0 || tmpl > 255) {
             py_raise_fec_error("Precondition violation: Share ids can't be less than zero or greater than 255.  %ld\n", tmpl);
             goto err;
         }
-        cshareids[i] = (unsigned char)tmpl;
+        cshareids[i] = (unsigned)tmpl;
         if (cshareids[i] >= self->kk)
             needtorecover+=1;
 
@@ -455,7 +455,7 @@ Decoder_decode(Decoder *self, PyObject *args) {
             i++;
         else {
             /* put pkt in the right position. */
-            unsigned char c = cshareids[i];
+            unsigned c = cshareids[i];
 
             SWAP (cshareids[i], cshareids[c], int);
             SWAP (cshares[i], cshares[c], const gf*);
@@ -477,7 +477,7 @@ Decoder_decode(Decoder *self, PyObject *args) {
     fec_decode(self->fec_matrix, cshares, recoveredcstrs, cshareids, sz);
 
     /* Wrap up both original primary shares and decoded shares into a Python list of Python strings. */
-    unsigned char nextrecoveredix=0;
+    unsigned nextrecoveredix=0;
     result = PyList_New(self->kk);
     if (result == NULL)
         goto err;
diff --git a/pyfec/fec/fec.c b/pyfec/fec/fec.c
index ba43da9..f563b86 100644
--- a/pyfec/fec/fec.c
+++ b/pyfec/fec/fec.c
@@ -128,7 +128,7 @@ modnn(int x) {
  * many numbers by the same constant. In this case the first call sets the
  * constant, and others perform the multiplications.  A value related to the
  * multiplication is held in a local variable declared with USE_GF_MULC . See
- * usage in addmul1().
+ * usage in _addmul1().
  */
 static gf gf_mul_table[256][256];
 
@@ -174,7 +174,7 @@ my_malloc (int sz, char *err_string) {
 }
 
 #define NEW_GF_MATRIX(rows, cols) \
-    (gf *)my_malloc(rows * cols * sizeof(gf), " ## __LINE__ ## " )
+    (gf*)my_malloc(rows * cols, " ## __LINE__ ## " )
 
 /*
  * initialize the data structures used for computations in GF.
@@ -252,15 +252,13 @@ generate_gf (void) {
  * calls are unfrequent in my typical apps so I did not bother.
  */
 #define addmul(dst, src, c, sz)                 \
-    if (c != 0) addmul1(dst, src, c, sz)
+    if (c != 0) _addmul1(dst, src, c, sz)
 
 #define UNROLL 16               /* 1, 4, 8, 16 */
 static void
-addmul1 (gf * dst1, const gf * src1, gf c, int sz) {
+_addmul1(register gf*restrict dst, const register gf*restrict src, gf c, size_t sz) {
     USE_GF_MULC;
-    register gf *dst = dst1;
-    register const gf *src = src1;
-    gf *lim = &dst[sz - UNROLL + 1];
+    const gf* lim = &dst[sz - UNROLL + 1];
 
     GF_MULC0 (c);
 
@@ -297,8 +295,8 @@ addmul1 (gf * dst1, const gf * src1, gf c, int sz) {
  * computes C = AB where A is n*k, B is k*m, C is n*m
  */
 static void
-matmul (gf * a, gf * b, gf * c, int n, int k, int m) {
-    int row, col, i;
+_matmul(gf * a, gf * b, gf * c, unsigned n, unsigned k, unsigned m) {
+    unsigned row, col, i;
 
     for (row = 0; row < n; row++) {
         for (col = 0; col < m; col++) {
@@ -313,20 +311,21 @@ matmul (gf * a, gf * b, gf * c, int n, int k, int m) {
 }
 
 /*
- * invert_mat() takes a matrix and produces its inverse
+ * _invert_mat() takes a matrix and produces its inverse
  * k is the size of the matrix.
  * (Gauss-Jordan, adapted from Numerical Recipes in C)
  * Return non-zero if singular.
  */
-static int
-invert_mat (gf * src, int k) {
+static void
+_invert_mat(gf* src, unsigned k) {
     gf c, *p;
-    int irow, icol, row, col, i, ix;
+    unsigned irow = 0;
+    unsigned icol = 0;
+    unsigned row, col, i, ix;
 
-    int error = -1;
-    int *indxc = (int *) my_malloc (k * sizeof (int), "indxc");
-    int *indxr = (int *) my_malloc (k * sizeof (int), "indxr");
-    int *ipiv = (int *) my_malloc (k * sizeof (int), "ipiv");
+    unsigned* indxc = (unsigned*) my_malloc (k * sizeof(unsigned), "indxc");
+    unsigned* indxr = (unsigned*) my_malloc (k * sizeof(unsigned), "indxr");
+    unsigned* ipiv = (unsigned*) my_malloc (k * sizeof(unsigned), "ipiv");
     gf *id_row = NEW_GF_MATRIX (1, k);
     gf *temp_row = NEW_GF_MATRIX (1, k);
 
@@ -343,7 +342,6 @@ invert_mat (gf * src, int k) {
          * Zeroing column 'col', look for a non-zero element.
          * First try on the diagonal, if it fails, look elsewhere.
          */
-        irow = icol = -1;
         if (ipiv[col] != 1 && src[col * k + col] != 0) {
             irow = col;
             icol = col;
@@ -365,10 +363,6 @@ invert_mat (gf * src, int k) {
                 }
             }
         }
-        if (icol == -1) {
-          ERR("Pivot not found!");
-          goto fail;
-        }
       found_piv:
         ++(ipiv[icol]);
         /*
@@ -416,26 +410,17 @@ invert_mat (gf * src, int k) {
         }
         id_row[icol] = 0;
     }                           /* done all columns */
-    for (col = k - 1; col >= 0; col--) {
-        if (indxr[col] < 0 || indxr[col] >= k) {
-            ERR("AARGH, indxr[col] %d\n", indxr[col]);
-            goto fail;
-        } else if (indxc[col] < 0 || indxc[col] >= k) {
-            ERR("AARGH, indxc[col] %d\n", indxc[col]);
-            goto fail;
-        } else if (indxr[col] != indxc[col]) {
+    for (col = k; col > 0; col--)
+        if (indxr[col-1] != indxc[col-1])
             for (row = 0; row < k; row++)
-                SWAP (src[row * k + indxr[col]], src[row * k + indxc[col]], gf);
-        }
-    }
-    error = 0;
+                SWAP (src[row * k + indxr[col-1]], src[row * k + indxc[col-1]], gf);
   fail:
     free (indxc);
     free (indxr);
     free (ipiv);
     free (id_row);
     free (temp_row);
-    return error;
+    return;
 }
 
 /*
@@ -449,14 +434,14 @@ invert_mat (gf * src, int k) {
  * p = coefficients of the matrix (p_i)
  * q = values of the polynomial (known)
  */
-int
-invert_vdm (gf * src, int k) {
-    int i, j, row, col;
+void
+_invert_vdm (gf* src, unsigned k) {
+    unsigned i, j, row, col;
     gf *b, *c, *p;
     gf t, xx;
 
     if (k == 1)                   /* degenerate case, matrix must be p^0 = 1 */
-        return 0;
+        return;
     /*
      * c holds the coefficient of P(x) = Prod (x - p_i), i=0..k-1
      * b holds the coefficient for the matrix inversion
@@ -491,9 +476,9 @@ invert_vdm (gf * src, int k) {
         xx = p[row];
         t = 1;
         b[k - 1] = 1;             /* this is in fact c[k] */
-        for (i = k - 2; i >= 0; i--) {
-            b[i] = c[i + 1] ^ gf_mul (xx, b[i + 1]);
-            t = gf_mul (xx, t) ^ b[i];
+        for (i = k - 1; i > 0; i--) {
+            b[i-1] = c[i] ^ gf_mul (xx, b[i]);
+            t = gf_mul (xx, t) ^ b[i-1];
         }
         for (col = 0; col < k; col++)
             src[col * k + row] = gf_mul (inverse[t], b[col]);
@@ -501,7 +486,7 @@ invert_vdm (gf * src, int k) {
     free (c);
     free (b);
     free (p);
-    return 0;
+    return;
 }
 
 static int fec_initialized = 0;
@@ -531,13 +516,9 @@ fec_free (fec_t *p) {
     free (p);
 }
 
-/*
- * create a new encoder, returning a descriptor. This contains k,n and
- * the encoding matrix.
- */
 fec_t *
-fec_new (unsigned char k, unsigned char n) {
-    unsigned char row, col;
+fec_new(unsigned k, unsigned n) {
+    unsigned row, col;
     gf *p, *tmp_m;
 
     fec_t *retval;
@@ -569,8 +550,8 @@ fec_new (unsigned char k, unsigned char n) {
      * k*k vandermonde matrix, multiply right the bottom n-k rows
      * by the inverse, and construct the identity matrix at the top.
      */
-    invert_vdm (tmp_m, k);        /* much faster than invert_mat */
-    matmul (tmp_m + k * k, tmp_m, retval->enc_matrix + k * k, n - k, k, k);
+    _invert_vdm (tmp_m, k);        /* much faster than _invert_mat */
+    _matmul(tmp_m + k * k, tmp_m, retval->enc_matrix + k * k, n - k, k, k);
     /*
      * the upper matrix is I so do not bother with a slow multiply
      */
@@ -583,9 +564,9 @@ fec_new (unsigned char k, unsigned char n) {
 }
 
 void
-fec_encode(const fec_t* code, const gf*restrict const*restrict const src, gf*restrict const*restrict const fecs, const unsigned char*restrict const share_ids, unsigned char num_share_ids, size_t sz) {
+fec_encode(const fec_t* code, const gf*restrict const*restrict const src, gf*restrict const*restrict const fecs, const unsigned*restrict const share_ids, size_t num_share_ids, size_t sz) {
     unsigned i, j;
-    unsigned char fecnum;
+    unsigned fecnum;
     gf* p;
 
     for (i=0; i<num_share_ids; i++) {
@@ -594,7 +575,7 @@ fec_encode(const fec_t* code, const gf*restrict const*restrict const src, gf*res
         memset(fecs[i], 0, sz);
         p = &(code->enc_matrix[fecnum * code->k]);
         for (j = 0; j < code->k; j++)
-            addmul (fecs[i], src[j], p[j], sz);
+            addmul(fecs[i], src[j], p[j], sz);
     }
 }
 
@@ -604,7 +585,7 @@ fec_encode(const fec_t* code, const gf*restrict const*restrict const src, gf*res
  * @param matrix a space allocated for a k by k matrix
  */
 void
-build_decode_matrix_into_space(const fec_t*restrict const code, const unsigned char*const restrict index, const unsigned char k, gf*restrict const matrix) {
+build_decode_matrix_into_space(const fec_t*restrict const code, const unsigned*const restrict index, const unsigned k, gf*restrict const matrix) {
     unsigned i;
     gf* p;
     for (i=0, p=matrix; i < k; i++, p += k) {
@@ -615,11 +596,11 @@ build_decode_matrix_into_space(const fec_t*restrict const code, const unsigned c
             memcpy(p, &(code->enc_matrix[index[i] * code->k]), k);
         }
     }
-    invert_mat (matrix, k);
+    _invert_mat (matrix, k);
 }
 
 void
-fec_decode(const fec_t* code, const gf*restrict const*restrict const inpkts, gf*restrict const*restrict const outpkts, const unsigned char*restrict const index, size_t sz) {
+fec_decode(const fec_t* code, const gf*restrict const*restrict const inpkts, gf*restrict const*restrict const outpkts, const unsigned*restrict const index, size_t sz) {
     gf m_dec[code->k * code->k];
     build_decode_matrix_into_space(code, index, code->k, m_dec);
 
diff --git a/pyfec/fec/fec.h b/pyfec/fec/fec.h
index 038b2c1..abce468 100644
--- a/pyfec/fec/fec.h
+++ b/pyfec/fec/fec.h
@@ -71,12 +71,16 @@ typedef unsigned char gf;
 
 typedef struct {
   unsigned long magic;
-  unsigned char k, n;                     /* parameters of the code */
+  unsigned k, n;                     /* parameters of the code */
   gf* enc_matrix;
 } fec_t;
 
-void fec_free (fec_t* p);
-fec_t* fec_new (unsigned char k, unsigned char n);
+/**
+ * param k the number of shares required to reconstruct
+ * param m the total number of share created
+ */
+fec_t* fec_new(unsigned k, unsigned m);
+void fec_free(fec_t* p);
 
 /**
  * @param inpkts the "primary shares" i.e. the chunks of the input data
@@ -84,7 +88,7 @@ fec_t* fec_new (unsigned char k, unsigned char n);
  * @param share_ids the numbers of the desired shares -- including both primary shares (the id < k) which fec_encode() ignores and check shares (the id >= k) which fec_encode() will produce and store into the buffers of the fecs parameter
  * @param num_share_ids the length of the share_ids array
  */
-void fec_encode(const fec_t* code, const gf*restrict const*restrict const src, gf*restrict const*restrict const fecs, const unsigned char*restrict const share_ids, unsigned char num_share_ids, size_t sz);
+void fec_encode(const fec_t* code, const gf*restrict const*restrict const src, gf*restrict const*restrict const fecs, const unsigned*restrict const share_ids, size_t num_share_ids, size_t sz);
 
 /**
  * @param inpkts an array of packets (size k)
@@ -92,6 +96,6 @@ void fec_encode(const fec_t* code, const gf*restrict const*restrict const src, g
  * @param index an array of the shareids of the packets in inpkts
  * @param sz size of a packet in bytes
  */
-void fec_decode(const fec_t* code, const gf*restrict const*restrict const inpkts, gf*restrict const*restrict const outpkts, const unsigned char*restrict const index, size_t sz);
+void fec_decode(const fec_t* code, const gf*restrict const*restrict const inpkts, gf*restrict const*restrict const outpkts, const unsigned*restrict const index, size_t sz);
 
 /* end of file */
diff --git a/pyfec/fec/test/test_pyfec.py b/pyfec/fec/test/test_pyfec.py
index 16579c8..fc5f8fd 100755
--- a/pyfec/fec/test/test_pyfec.py
+++ b/pyfec/fec/test/test_pyfec.py
@@ -30,6 +30,17 @@ import sys
 
 import fec
 
+from base64 import b32encode
+def ab(x): # debuggery
+    if len(x) >= 3:
+        return "%s:%s" % (len(x), b32encode(x[-3:]),)
+    elif len(x) == 2:
+        return "%s:%s" % (len(x), b32encode(x[-2:]),)
+    elif len(x) == 1:
+        return "%s:%s" % (len(x), b32encode(x[-1:]),)
+    elif len(x) == 0:
+        return "%s:%s" % (len(x), "--empty--",)
+
 def _h(k, m, ss):
     # sys.stdout.write("k: %s, m: %s,  len(ss): %r, len(ss[0]): %r" % (k, m, len(ss), len(ss[0]),)) ; sys.stdout.flush()
     encer = fec.Encoder(k, m)
@@ -47,7 +58,7 @@ def _h(k, m, ss):
     decoded = decer.decode(shares, nums)
     # sys.stdout.write("decoded.\n") ; sys.stdout.flush()
     assert len(decoded) == len(ss), (len(decoded), len(ss),)
-    assert tuple([str(s) for s in decoded]) == tuple([str(s) for s in ss]), (tuple([str(s) for s in decoded]), tuple([str(s) for s in ss]),)
+    assert tuple([str(s) for s in decoded]) == tuple([str(s) for s in ss]), (tuple([ab(str(s)) for s in decoded]), tuple([ab(str(s)) for s in ss]),)
 
 def randstr(n):
     return ''.join(map(chr, map(random.randrange, [0]*n, [256]*n)))
@@ -81,7 +92,7 @@ def _test_random():
     _h(k, m, ss)
 
 def test_random():
-    for i in range(2**5):
+    for i in range(2**7):
         # sys.stdout.write(",")
         _test_random()
         # sys.stdout.write(".")