/*********************************************************** (C) Copyright 2003 A.M. Kuchling. All Rights Reserved (C) Copyright 2004 A.M. Kuchling, Ralph Heinkel All Rights Reserved Permission to use, copy, modify, and distribute this software and its documentation for any purpose and without fee is hereby granted, provided that the above copyright notice appear in all copies and that both that copyright notice and this permission notice appear in supporting documentation, and that the name of A.M. Kuchling and Ralph Heinkel not be used in advertising or publicity pertaining to distribution of the software without specific, written prior permission. A.M. KUCHLING, R.H. HEINKEL DISCLAIM ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. ******************************************************************/ /* SaneDev objects */ #include "Python.h" #include "Imaging.h" #include #include static PyObject *ErrorObject; typedef struct { PyObject_HEAD SANE_Handle h; } SaneDevObject; #ifdef WITH_THREAD PyThreadState *_save; #endif /* Raise a SANE exception */ PyObject * PySane_Error(SANE_Status st) { const char *string; if (st==SANE_STATUS_GOOD) {Py_INCREF(Py_None); return (Py_None);} string=sane_strstatus(st); PyErr_SetString(ErrorObject, string); return NULL; } staticforward PyTypeObject SaneDev_Type; #define SaneDevObject_Check(v) ((v)->ob_type == &SaneDev_Type) static SaneDevObject * newSaneDevObject(void) { SaneDevObject *self; self = PyObject_NEW(SaneDevObject, &SaneDev_Type); if (self == NULL) return NULL; self->h=NULL; return self; } /* SaneDev methods */ static void SaneDev_dealloc(SaneDevObject *self) { if (self->h) sane_close(self->h); self->h=NULL; PyObject_DEL(self); } static PyObject * SaneDev_close(SaneDevObject *self, PyObject *args) { if (!PyArg_ParseTuple(args, "")) return NULL; if (self->h) sane_close(self->h); self->h=NULL; Py_INCREF(Py_None); return (Py_None); } static PyObject * SaneDev_get_parameters(SaneDevObject *self, PyObject *args) { SANE_Status st; SANE_Parameters p; char *format="unknown format"; if (!PyArg_ParseTuple(args, "")) return NULL; if (self->h==NULL) { PyErr_SetString(ErrorObject, "SaneDev object is closed"); return NULL; } Py_BEGIN_ALLOW_THREADS st=sane_get_parameters(self->h, &p); Py_END_ALLOW_THREADS if (st) return PySane_Error(st); switch (p.format) { case(SANE_FRAME_GRAY): format="gray"; break; case(SANE_FRAME_RGB): format="color"; break; case(SANE_FRAME_RED): format="red"; break; case(SANE_FRAME_GREEN): format="green"; break; case(SANE_FRAME_BLUE): format="blue"; break; } return Py_BuildValue("si(ii)ii", format, p.last_frame, p.pixels_per_line, p.lines, p.depth, p.bytes_per_line); } static PyObject * SaneDev_fileno(SaneDevObject *self, PyObject *args) { SANE_Status st; SANE_Int fd; if (!PyArg_ParseTuple(args, "")) return NULL; if (self->h==NULL) { PyErr_SetString(ErrorObject, "SaneDev object is closed"); return NULL; } st=sane_get_select_fd(self->h, &fd); if (st) return PySane_Error(st); return PyInt_FromLong(fd); } static PyObject * SaneDev_start(SaneDevObject *self, PyObject *args) { SANE_Status st; if (!PyArg_ParseTuple(args, "")) return NULL; if (self->h==NULL) { PyErr_SetString(ErrorObject, "SaneDev object is closed"); return NULL; } /* sane_start can take several seconds, if the user initiates a new scan, while the scan head of a flatbed scanner moves back to the start position after finishing a previous scan. Hence it is worth to allow threads here. */ Py_BEGIN_ALLOW_THREADS st=sane_start(self->h); Py_END_ALLOW_THREADS if (st) return PySane_Error(st); Py_INCREF(Py_None); return Py_None; } static PyObject * SaneDev_cancel(SaneDevObject *self, PyObject *args) { if (!PyArg_ParseTuple(args, "")) return NULL; if (self->h==NULL) { PyErr_SetString(ErrorObject, "SaneDev object is closed"); return NULL; } sane_cancel(self->h); Py_INCREF(Py_None); return Py_None; } static PyObject * SaneDev_get_options(SaneDevObject *self, PyObject *args) { const SANE_Option_Descriptor *d; PyObject *list, *value; int i=1; if (!PyArg_ParseTuple(args, "")) return NULL; if (self->h==NULL) { PyErr_SetString(ErrorObject, "SaneDev object is closed"); return NULL; } if (!(list = PyList_New(0))) return NULL; do { d=sane_get_option_descriptor(self->h, i); if (d!=NULL) { PyObject *constraint=NULL; int j; switch (d->constraint_type) { case(SANE_CONSTRAINT_NONE): Py_INCREF(Py_None); constraint=Py_None; break; case(SANE_CONSTRAINT_RANGE): if (d->type == SANE_TYPE_INT) constraint=Py_BuildValue("iii", d->constraint.range->min, d->constraint.range->max, d->constraint.range->quant); else constraint=Py_BuildValue("ddd", SANE_UNFIX(d->constraint.range->min), SANE_UNFIX(d->constraint.range->max), SANE_UNFIX(d->constraint.range->quant)); break; case(SANE_CONSTRAINT_WORD_LIST): constraint=PyList_New(d->constraint.word_list[0]); if (d->type == SANE_TYPE_INT) for (j=1; j<=d->constraint.word_list[0]; j++) PyList_SetItem(constraint, j-1, PyInt_FromLong(d->constraint.word_list[j])); else for (j=1; j<=d->constraint.word_list[0]; j++) PyList_SetItem(constraint, j-1, PyFloat_FromDouble(SANE_UNFIX(d->constraint.word_list[j]))); break; case(SANE_CONSTRAINT_STRING_LIST): constraint=PyList_New(0); for(j=0; d->constraint.string_list[j]!=NULL; j++) PyList_Append(constraint, PyString_FromString(d->constraint.string_list[j])); break; } value=Py_BuildValue("isssiiiiO", i, d->name, d->title, d->desc, d->type, d->unit, d->size, d->cap, constraint); PyList_Append(list, value); } i++; } while (d!=NULL); return list; } static PyObject * SaneDev_get_option(SaneDevObject *self, PyObject *args) { SANE_Status st; const SANE_Option_Descriptor *d; PyObject *value=NULL; int n; void *v; if (!PyArg_ParseTuple(args, "i", &n)) { return NULL; } if (self->h==NULL) { PyErr_SetString(ErrorObject, "SaneDev object is closed"); return NULL; } d=sane_get_option_descriptor(self->h, n); v=malloc(d->size+1); st=sane_control_option(self->h, n, SANE_ACTION_GET_VALUE, v, NULL); if (st) { free(v); return PySane_Error(st); } switch(d->type) { case(SANE_TYPE_BOOL): case(SANE_TYPE_INT): value=Py_BuildValue("i", *( (SANE_Int*)v) ); break; case(SANE_TYPE_FIXED): value=Py_BuildValue("d", SANE_UNFIX((*((SANE_Fixed*)v))) ); break; case(SANE_TYPE_STRING): value=Py_BuildValue("s", v); break; case(SANE_TYPE_BUTTON): case(SANE_TYPE_GROUP): value=Py_BuildValue("O", Py_None); break; } free(v); return value; } static PyObject * SaneDev_set_option(SaneDevObject *self, PyObject *args) { SANE_Status st; const SANE_Option_Descriptor *d; SANE_Int i; PyObject *value; int n; void *v; if (!PyArg_ParseTuple(args, "iO", &n, &value)) return NULL; if (self->h==NULL) { PyErr_SetString(ErrorObject, "SaneDev object is closed"); return NULL; } d=sane_get_option_descriptor(self->h, n); v=malloc(d->size+1); switch(d->type) { case(SANE_TYPE_BOOL): if (!PyInt_Check(value)) { PyErr_SetString(PyExc_TypeError, "SANE_BOOL requires an integer"); free(v); return NULL; } /* fall through */ case(SANE_TYPE_INT): if (!PyInt_Check(value)) { PyErr_SetString(PyExc_TypeError, "SANE_INT requires an integer"); free(v); return NULL; } *( (SANE_Int*)v) = PyInt_AsLong(value); break; case(SANE_TYPE_FIXED): if (!PyFloat_Check(value)) { PyErr_SetString(PyExc_TypeError, "SANE_FIXED requires a floating point number"); free(v); return NULL; } *( (SANE_Fixed*)v) = SANE_FIX(PyFloat_AsDouble(value)); break; case(SANE_TYPE_STRING): if (!PyString_Check(value)) { PyErr_SetString(PyExc_TypeError, "SANE_STRING requires a string"); free(v); return NULL; } strncpy(v, PyString_AsString(value), d->size-1); ((char*)v)[d->size-1] = 0; break; case(SANE_TYPE_BUTTON): case(SANE_TYPE_GROUP): break; } st=sane_control_option(self->h, n, SANE_ACTION_SET_VALUE, v, &i); if (st) {free(v); return PySane_Error(st);} free(v); return Py_BuildValue("i", i); } static PyObject * SaneDev_set_auto_option(SaneDevObject *self, PyObject *args) { SANE_Status st; const SANE_Option_Descriptor *d; SANE_Int i; int n; if (!PyArg_ParseTuple(args, "i", &n)) return NULL; if (self->h==NULL) { PyErr_SetString(ErrorObject, "SaneDev object is closed"); return NULL; } d=sane_get_option_descriptor(self->h, n); st=sane_control_option(self->h, n, SANE_ACTION_SET_AUTO, NULL, &i); if (st) {return PySane_Error(st);} return Py_BuildValue("i", i); } #define READSIZE 32768 static PyObject * SaneDev_snap(SaneDevObject *self, PyObject *args) { SANE_Status st; /* The buffer should be a multiple of 3 in size, so each sane_read operation will return an integral number of RGB triples. */ SANE_Byte buffer[READSIZE]; /* XXX how big should the buffer be? */ SANE_Int len, lastlen; Imaging im; SANE_Parameters p; int px, py, remain, cplen, bufpos, padbytes; long L; char errmsg[80]; union { char c[2]; INT16 i16; } endian; PyObject *pyNoCancel = NULL; int noCancel = 0; endian.i16 = 1; if (!PyArg_ParseTuple(args, "l|O", &L, &pyNoCancel)) return NULL; if (self->h==NULL) { PyErr_SetString(ErrorObject, "SaneDev object is closed"); return NULL; } im=(Imaging)L; if (pyNoCancel) noCancel = PyObject_IsTrue(pyNoCancel); st=SANE_STATUS_GOOD; px=py=0; /* xxx not yet implemented - handscanner support (i.e., unknown image length during start) - generally: move the functionality from method snap in sane.py down here -- I don't like this cross-dependency. we need to call sane_get_parameters here, and we can create the result Image object here. */ Py_UNBLOCK_THREADS sane_get_parameters(self->h, &p); if (p.format == SANE_FRAME_GRAY) { switch (p.depth) { case 1: remain = p.bytes_per_line * im->ysize; padbytes = p.bytes_per_line - (im->xsize+7)/8; bufpos = 0; lastlen = len = 0; while (st!=SANE_STATUS_EOF && py < im->ysize) { while (len > 0 && py < im->ysize) { int i, j, k; j = buffer[bufpos++]; k = 0x80; for (i = 0; i < 8 && px < im->xsize; i++) { im->image8[py][px++] = (k&j) ? 0 : 0xFF; k = k >> 1; } len--; if (px >= im->xsize) { bufpos += padbytes; len -= padbytes; py++; px = 0; } } st=sane_read(self->h, buffer, remainh); Py_BLOCK_THREADS return PySane_Error(st); } bufpos -= lastlen; lastlen = len; remain -= len; /* skip possible pad bytes at the start of the buffer */ len -= bufpos; } break; case 8: remain = p.bytes_per_line * im->ysize; padbytes = p.bytes_per_line - im->xsize; bufpos = 0; len = 0; while (st!=SANE_STATUS_EOF && py < im->ysize) { while (len > 0 && py < im->ysize) { cplen = len; if (px + cplen >= im->xsize) cplen = im->xsize - px; memcpy(&im->image8[py][px], &buffer[bufpos], cplen); len -= cplen; bufpos += cplen; px += cplen; if (px >= im->xsize) { px = 0; py++; bufpos += padbytes; len -= padbytes; } } bufpos = -len; st=sane_read(self->h, buffer, remainh); Py_BLOCK_THREADS return PySane_Error(st); } remain -= len; len -= bufpos; } break; case 16: remain = p.bytes_per_line * im->ysize; padbytes = p.bytes_per_line - 2 * im->xsize; bufpos = endian.c[0]; lastlen = len = 0; while (st!=SANE_STATUS_EOF && py < im->ysize) { while (len > 0 && py < im->ysize) { im->image8[py][px++] = buffer[bufpos]; bufpos += 2; len -= 2; if (px >= im->xsize) { bufpos += padbytes; len -= padbytes; py++; px = 0; } } st=sane_read(self->h, buffer, remainh); Py_BLOCK_THREADS return PySane_Error(st); } remain -= len; bufpos -= lastlen; lastlen = len; len -= bufpos; } break; default: /* other depths are not formally "illegal" according to the Sane API, but it's agreed by Sane developers that other depths than 1, 8, 16 should not be used */ sane_cancel(self->h); Py_BLOCK_THREADS snprintf(errmsg, 80, "unsupported pixel depth: %i", p.depth); PyErr_SetString(ErrorObject, errmsg); return NULL; } } else if (p.format == SANE_FRAME_RGB) { int incr, color, pxs, pxmax, bit, val, mask; switch (p.depth) { case 1: remain = p.bytes_per_line * im->ysize; padbytes = p.bytes_per_line - ((im->xsize+7)/8) * 3; bufpos = 0; len = 0; lastlen = 0; pxmax = 4 * im->xsize; while (st!=SANE_STATUS_EOF && py < im->ysize) { pxs = px; for (color = 0; color < 3; color++) { while (len <= 0 && st == SANE_STATUS_GOOD) { st=sane_read(self->h, buffer, remainh); Py_BLOCK_THREADS return PySane_Error(st); } bufpos -= lastlen; remain -= len; lastlen = len; /* skip possible pad bytes at the start of the buffer */ len -= bufpos; } if (st == SANE_STATUS_EOF) break; pxs = px; val = buffer[bufpos++]; len--; mask = 0x80; for (bit = 0; (bit < 8) && (px < pxmax); bit++) { ((UINT8**)(im->image32))[py][px] = (val&mask) ? 0xFF : 0; mask = mask >> 1; px += 4; } pxs++; px = pxs; } if (st == SANE_STATUS_EOF) break; for (bit = 0; bit < 8 && px < pxmax; bit++) { ((UINT8**)(im->image32))[py][px] = 0; px += 4; } px -= 3; if (px >= pxmax) { bufpos += padbytes; len -= padbytes; py++; px = 0; } } break; case 8: case 16: if (p.depth == 8) { padbytes = p.bytes_per_line - 3 * im->xsize; bufpos = 0; incr = 1; } else { padbytes = p.bytes_per_line - 6 * im->xsize; bufpos = endian.c[0]; incr = 2; } remain = p.bytes_per_line * im->ysize; len = 0; lastlen = 0; pxmax = 4 * im->xsize; /* probably not very efficient. But we have to deal with these possible conditions: - we may have padding bytes at the end of a scan line - the number of bytes read with sane_read may be smaller than the number of pad bytes - the buffer may become empty after setting any of the red/green/blue pixel values */ while (st != SANE_STATUS_EOF && py < im->ysize) { for (color = 0; color < 3; color++) { while (len <= 0 && st == SANE_STATUS_GOOD) { bufpos -= lastlen; if (remain == 0) { sane_cancel(self->h); Py_BLOCK_THREADS PyErr_SetString(ErrorObject, "internal _sane error: premature end of scan"); return NULL; } st = sane_read(self->h, buffer, remain<(READSIZE) ? remain : (READSIZE), &len); if (st && (st!=SANE_STATUS_EOF)) { sane_cancel(self->h); Py_BLOCK_THREADS return PySane_Error(st); } lastlen = len; remain -= len; len -= bufpos; } if (st == SANE_STATUS_EOF) break; ((UINT8**)(im->image32))[py][px++] = buffer[bufpos]; bufpos += incr; len -= incr; } if (st == SANE_STATUS_EOF) break; ((UINT8**)(im->image32))[py][px++] = 0; if (px >= pxmax) { px = 0; py++; bufpos += padbytes; len -= padbytes; } } break; default: Py_BLOCK_THREADS sane_cancel(self->h); snprintf(errmsg, 80, "unsupported pixel depth: %i", p.depth); PyErr_SetString(ErrorObject, errmsg); return NULL; } } else /* should be SANE_FRAME_RED, GREEN or BLUE */ { int lastlen, pxa, pxmax, offset, incr, frame_count = 0; /* at least the Sane test backend behaves a bit weird, if it returns "premature EOF" for sane_read, i.e., if the option "return value of sane_read" is set to SANE_STATUS_EOF. In this case, the test backend does not advance to the next frame, so p.last_frame will never be set... So let's count the number of frames we try to acquire */ while (!p.last_frame && frame_count < 4) { frame_count++; st = sane_get_parameters(self->h, &p); if (st) { sane_cancel(self->h); Py_BLOCK_THREADS return PySane_Error(st); } remain = p.bytes_per_line * im->ysize; bufpos = 0; len = 0; lastlen = 0; py = 0; switch (p.format) { case SANE_FRAME_RED: offset = 0; break; case SANE_FRAME_GREEN: offset = 1; break; case SANE_FRAME_BLUE: offset = 2; break; default: sane_cancel(self->h); Py_BLOCK_THREADS snprintf(errmsg, 80, "unknown/invalid frame format: %i", p.format); PyErr_SetString(ErrorObject, errmsg); return NULL; } px = offset; pxa = 3; pxmax = im->xsize * 4; switch (p.depth) { case 1: padbytes = p.bytes_per_line - (im->xsize+7)/8; st = SANE_STATUS_GOOD; while (st != SANE_STATUS_EOF && py < im->ysize) { while (len > 0) { int bit, mask, val; val = buffer[bufpos++]; len--; mask = 0x80; for (bit = 0; bit < 8 && px < pxmax; bit++) { ((UINT8**)(im->image32))[py][px] = val&mask ? 0xFF : 0; ((UINT8**)(im->image32))[py][pxa] = 0; px += 4; pxa += 4; mask = mask >> 1; } if (px >= pxmax) { px = offset; pxa = 3; py++; bufpos += padbytes; len -= padbytes; } } while (len <= 0 && st == SANE_STATUS_GOOD && remain > 0) { bufpos -= lastlen; st = sane_read(self->h, buffer, remain<(READSIZE) ? remain : (READSIZE), &len); if (st && (st!=SANE_STATUS_EOF)) { sane_cancel(self->h); Py_BLOCK_THREADS return PySane_Error(st); } remain -= len; lastlen = len; len -= bufpos; } } break; case 8: case 16: if (p.depth == 8) { padbytes = p.bytes_per_line - im->xsize; incr = 1; } else { padbytes = p.bytes_per_line - 2 * im->xsize; incr = 2; bufpos = endian.c[0]; } st = SANE_STATUS_GOOD; while (st != SANE_STATUS_EOF && py < im->ysize) { while (len <= 0) { bufpos -= lastlen; if (remain == 0) { sane_cancel(self->h); Py_BLOCK_THREADS PyErr_SetString(ErrorObject, "internal _sane error: premature end of scan"); return NULL; } st = sane_read(self->h, buffer, remain<(READSIZE) ? remain : (READSIZE), &len); if (st && (st!=SANE_STATUS_EOF)) { sane_cancel(self->h); Py_BLOCK_THREADS return PySane_Error(st); } if (st == SANE_STATUS_EOF) break; lastlen = len; remain -= len; if (bufpos >= len) len = 0; else len -= bufpos; } if (st == SANE_STATUS_EOF) break; ((UINT8**)(im->image32))[py][px] = buffer[bufpos]; ((UINT8**)(im->image32))[py][pxa] = 0; bufpos += incr; len -= incr; px += 4; pxa += 4; if (px >= pxmax) { px = offset; pxa = 3; py++; bufpos += padbytes; len -= padbytes; } } break; default: sane_cancel(self->h); Py_BLOCK_THREADS snprintf(errmsg, 80, "unsupported pixel depth: %i", p.depth); PyErr_SetString(ErrorObject, errmsg); return NULL; } if (!p.last_frame) { /* all sane_read calls in the above loop may return SANE_STATUS_GOOD, but the backend may need another sane_read call which returns SANE_STATUS_EOF in order to start a new frame. */ do { st = sane_read(self->h, buffer, READSIZE, &len); } while (st == SANE_STATUS_GOOD); if (st != SANE_STATUS_EOF) { Py_BLOCK_THREADS sane_cancel(self->h); return PySane_Error(st); } st = sane_start(self->h); if (st) { Py_BLOCK_THREADS return PySane_Error(st); } } } } /* enforce SANE_STATUS_EOF. Can be necessary for ADF scans for some backends */ do { st = sane_read(self->h, buffer, READSIZE, &len); } while (st == SANE_STATUS_GOOD); if (st != SANE_STATUS_EOF) { sane_cancel(self->h); Py_BLOCK_THREADS return PySane_Error(st); } if (!noCancel) sane_cancel(self->h); Py_BLOCK_THREADS Py_INCREF(Py_None); return Py_None; } #ifdef WITH_NUMARRAY #include "numarray/libnumarray.h" /* this global variable is set to 1 in 'init_sane()' after successfully importing the numarray module. */ int NUMARRAY_IMPORTED = 0; static PyObject * SaneDev_arr_snap(SaneDevObject *self, PyObject *args) { SANE_Status st; SANE_Byte buffer[READSIZE]; SANE_Int len; SANE_Parameters p; PyArrayObject *pyArr = NULL; NumarrayType arrType; int line, line_index, buffer_index, remain_bytes_line, num_pad_bytes; int cp_num_bytes, total_remain, bpp, arr_bytes_per_line; int pixels_per_line = -1; char errmsg[80]; if (!NUMARRAY_IMPORTED) { PyErr_SetString(ErrorObject, "numarray package not available"); return NULL; } if (!PyArg_ParseTuple(args, "|i", &pixels_per_line)) return NULL; if (self->h==NULL) { PyErr_SetString(ErrorObject, "SaneDev object is closed"); return NULL; } sane_get_parameters(self->h, &p); if (p.format != SANE_FRAME_GRAY) { sane_cancel(self->h); snprintf(errmsg, 80, "numarray only supports gray-scale images"); PyErr_SetString(ErrorObject, errmsg); return NULL; } if (p.depth == 8) { bpp=1; /* bytes-per-pixel */ arrType = tUInt8; } else if (p.depth == 16) { bpp=2; /* bytes-per-pixel */ arrType = tUInt16; } else { sane_cancel(self->h); snprintf(errmsg, 80, "arrsnap: unsupported pixel depth: %i", p.depth); PyErr_SetString(ErrorObject, errmsg); return NULL; } if (pixels_per_line < 1) /* The user can choose a smaller result array than the actual scan */ pixels_per_line = p.pixels_per_line; else if (pixels_per_line > p.pixels_per_line) { PyErr_SetString(ErrorObject,"given pixels_per_line too big"); return NULL; } /* important: NumArray have indices like (y, x) !! */ if (!(pyArr = NA_NewArray(NULL, arrType, 2, p.lines, pixels_per_line))) { PyErr_SetString(ErrorObject, "failed to create NumArray object"); return NULL; } arr_bytes_per_line = pixels_per_line * bpp; st=SANE_STATUS_GOOD; #ifdef WRITE_PGM FILE *fp; fp = fopen("sane_p5.pgm", "w"); fprintf(fp, "P5\n%d %d\n%d\n", p.pixels_per_line, p.lines, (int) pow(2.0, (double) p.depth)-1); #endif line_index = line = 0; remain_bytes_line = arr_bytes_per_line; total_remain = p.bytes_per_line * p.lines; num_pad_bytes = p.bytes_per_line - arr_bytes_per_line; while (st!=SANE_STATUS_EOF) { Py_BEGIN_ALLOW_THREADS st = sane_read(self->h, buffer, READSIZE < total_remain ? READSIZE : total_remain, &len); Py_END_ALLOW_THREADS #ifdef WRITE_PGM printf("p5_write: read %d of %d\n", len, READSIZE); fwrite(buffer, 1, len, fp); #endif buffer_index = 0; total_remain -= len; while (len > 0) { /* copy at most the number of bytes that fit into (the rest of) one line: */ cp_num_bytes = (len > remain_bytes_line ? remain_bytes_line : len); remain_bytes_line -= cp_num_bytes; len -= cp_num_bytes; #ifdef DEBUG printf("copying %d bytes from b_idx %d to d_idx %d\n", cp_num_bytes, buffer_index, line * arr_bytes_per_line + line_index); printf("len is now %d\n", len); #endif memcpy(pyArr->data + line * arr_bytes_per_line + line_index, buffer + buffer_index, cp_num_bytes); buffer_index += cp_num_bytes; if (remain_bytes_line ==0) { /* The line has been completed, so reinitialize remain_bytes_line increase the line counter, and reset line_index */ #ifdef DEBUG printf("line %d full, skipping %d bytes\n",line,num_pad_bytes); #endif remain_bytes_line = arr_bytes_per_line; line++; line_index = 0; /* Skip the number of bytes in the input stream which are not used: */ len -= num_pad_bytes; buffer_index += num_pad_bytes; } else line_index += cp_num_bytes; } } #ifdef WRITE_PGM fclose(fp); printf("p5_write finished\n"); #endif sane_cancel(self->h); return (PyObject*) pyArr; } #endif /* WITH_NUMARRAY */ static PyMethodDef SaneDev_methods[] = { {"get_parameters", (PyCFunction)SaneDev_get_parameters, 1}, {"get_options", (PyCFunction)SaneDev_get_options, 1}, {"get_option", (PyCFunction)SaneDev_get_option, 1}, {"set_option", (PyCFunction)SaneDev_set_option, 1}, {"set_auto_option", (PyCFunction)SaneDev_set_auto_option, 1}, {"start", (PyCFunction)SaneDev_start, 1}, {"cancel", (PyCFunction)SaneDev_cancel, 1}, {"snap", (PyCFunction)SaneDev_snap, 1}, #ifdef WITH_NUMARRAY {"arr_snap", (PyCFunction)SaneDev_arr_snap, 1}, #endif /* WITH_NUMARRAY */ {"fileno", (PyCFunction)SaneDev_fileno, 1}, {"close", (PyCFunction)SaneDev_close, 1}, {NULL, NULL} /* sentinel */ }; static PyObject * SaneDev_getattr(SaneDevObject *self, char *name) { return Py_FindMethod(SaneDev_methods, (PyObject *)self, name); } staticforward PyTypeObject SaneDev_Type = { PyObject_HEAD_INIT(&PyType_Type) 0, /*ob_size*/ "SaneDev", /*tp_name*/ sizeof(SaneDevObject), /*tp_basicsize*/ 0, /*tp_itemsize*/ /* methods */ (destructor)SaneDev_dealloc, /*tp_dealloc*/ 0, /*tp_print*/ (getattrfunc)SaneDev_getattr, /*tp_getattr*/ 0, /*tp_setattr*/ 0, /*tp_compare*/ 0, /*tp_repr*/ 0, /*tp_as_number*/ 0, /*tp_as_sequence*/ 0, /*tp_as_mapping*/ 0, /*tp_hash*/ }; /* --------------------------------------------------------------------- */ static PyObject * PySane_init(PyObject *self, PyObject *args) { SANE_Status st; SANE_Int version; if (!PyArg_ParseTuple(args, "")) return NULL; /* XXX Authorization is not yet supported */ st=sane_init(&version, NULL); if (st) return PySane_Error(st); return Py_BuildValue("iiii", version, SANE_VERSION_MAJOR(version), SANE_VERSION_MINOR(version), SANE_VERSION_BUILD(version)); } static PyObject * PySane_exit(PyObject *self, PyObject *args) { if (!PyArg_ParseTuple(args, "")) return NULL; sane_exit(); Py_INCREF(Py_None); return Py_None; } static PyObject * PySane_get_devices(PyObject *self, PyObject *args) { SANE_Device **devlist; SANE_Device *dev; SANE_Status st; PyObject *list; int local_only, i; if (!PyArg_ParseTuple(args, "|i", &local_only)) { return NULL; } st=sane_get_devices(&devlist, local_only); if (st) return PySane_Error(st); if (!(list = PyList_New(0))) return NULL; for(i=0; devlist[i]!=NULL; i++) { dev=devlist[i]; PyList_Append(list, Py_BuildValue("ssss", dev->name, dev->vendor, dev->model, dev->type)); } return list; } /* Function returning new SaneDev object */ static PyObject * PySane_open(PyObject *self, PyObject *args) { SaneDevObject *rv; SANE_Status st; char *name; if (!PyArg_ParseTuple(args, "s", &name)) return NULL; rv = newSaneDevObject(); if ( rv == NULL ) return NULL; st = sane_open(name, &(rv->h)); if (st) { Py_DECREF(rv); return PySane_Error(st); } return (PyObject *)rv; } static PyObject * PySane_OPTION_IS_ACTIVE(PyObject *self, PyObject *args) { SANE_Int cap; long lg; if (!PyArg_ParseTuple(args, "l", &lg)) return NULL; cap=lg; return PyInt_FromLong( SANE_OPTION_IS_ACTIVE(cap)); } static PyObject * PySane_OPTION_IS_SETTABLE(PyObject *self, PyObject *args) { SANE_Int cap; long lg; if (!PyArg_ParseTuple(args, "l", &lg)) return NULL; cap=lg; return PyInt_FromLong( SANE_OPTION_IS_SETTABLE(cap)); } /* List of functions defined in the module */ static PyMethodDef PySane_methods[] = { {"init", PySane_init, 1}, {"exit", PySane_exit, 1}, {"get_devices", PySane_get_devices, 1}, {"_open", PySane_open, 1}, {"OPTION_IS_ACTIVE", PySane_OPTION_IS_ACTIVE, 1}, {"OPTION_IS_SETTABLE", PySane_OPTION_IS_SETTABLE, 1}, {NULL, NULL} /* sentinel */ }; static void insint(PyObject *d, char *name, int value) { PyObject *v = PyInt_FromLong((long) value); if (!v || PyDict_SetItemString(d, name, v)) Py_FatalError("can't initialize sane module"); Py_DECREF(v); } void init_sane(void) { PyObject *m, *d; /* Create the module and add the functions */ m = Py_InitModule("_sane", PySane_methods); /* Add some symbolic constants to the module */ d = PyModule_GetDict(m); ErrorObject = PyString_FromString("_sane.error"); PyDict_SetItemString(d, "error", ErrorObject); insint(d, "INFO_INEXACT", SANE_INFO_INEXACT); insint(d, "INFO_RELOAD_OPTIONS", SANE_INFO_RELOAD_OPTIONS); insint(d, "RELOAD_PARAMS", SANE_INFO_RELOAD_PARAMS); insint(d, "FRAME_GRAY", SANE_FRAME_GRAY); insint(d, "FRAME_RGB", SANE_FRAME_RGB); insint(d, "FRAME_RED", SANE_FRAME_RED); insint(d, "FRAME_GREEN", SANE_FRAME_GREEN); insint(d, "FRAME_BLUE", SANE_FRAME_BLUE); insint(d, "CONSTRAINT_NONE", SANE_CONSTRAINT_NONE); insint(d, "CONSTRAINT_RANGE", SANE_CONSTRAINT_RANGE); insint(d, "CONSTRAINT_WORD_LIST", SANE_CONSTRAINT_WORD_LIST); insint(d, "CONSTRAINT_STRING_LIST", SANE_CONSTRAINT_STRING_LIST); insint(d, "TYPE_BOOL", SANE_TYPE_BOOL); insint(d, "TYPE_INT", SANE_TYPE_INT); insint(d, "TYPE_FIXED", SANE_TYPE_FIXED); insint(d, "TYPE_STRING", SANE_TYPE_STRING); insint(d, "TYPE_BUTTON", SANE_TYPE_BUTTON); insint(d, "TYPE_GROUP", SANE_TYPE_GROUP); insint(d, "UNIT_NONE", SANE_UNIT_NONE); insint(d, "UNIT_PIXEL", SANE_UNIT_PIXEL); insint(d, "UNIT_BIT", SANE_UNIT_BIT); insint(d, "UNIT_MM", SANE_UNIT_MM); insint(d, "UNIT_DPI", SANE_UNIT_DPI); insint(d, "UNIT_PERCENT", SANE_UNIT_PERCENT); insint(d, "UNIT_MICROSECOND", SANE_UNIT_MICROSECOND); insint(d, "CAP_SOFT_SELECT", SANE_CAP_SOFT_SELECT); insint(d, "CAP_HARD_SELECT", SANE_CAP_HARD_SELECT); insint(d, "CAP_SOFT_DETECT", SANE_CAP_SOFT_DETECT); insint(d, "CAP_EMULATED", SANE_CAP_EMULATED); insint(d, "CAP_AUTOMATIC", SANE_CAP_AUTOMATIC); insint(d, "CAP_INACTIVE", SANE_CAP_INACTIVE); insint(d, "CAP_ADVANCED", SANE_CAP_ADVANCED); /* handy for checking array lengths: */ insint(d, "SANE_WORD_SIZE", sizeof(SANE_Word)); /* possible return values of set_option() */ insint(d, "INFO_INEXACT", SANE_INFO_INEXACT); insint(d, "INFO_RELOAD_OPTIONS", SANE_INFO_RELOAD_OPTIONS); insint(d, "INFO_RELOAD_PARAMS", SANE_INFO_RELOAD_PARAMS); /* Check for errors */ if (PyErr_Occurred()) Py_FatalError("can't initialize module _sane"); #ifdef WITH_NUMARRAY import_libnumarray(); if (PyErr_Occurred()) PyErr_Clear(); else /* this global variable is declared just in front of the arr_snap() function and should be set to 1 after successfully importing the numarray module. */ NUMARRAY_IMPORTED = 1; #endif /* WITH_NUMARRAY */ }