Mercurial > hg > octave-lyh
view libinterp/corefcn/lookup.cc @ 17280:8ce6cdd272eb
Support TeX elements in FreeType renderer.
* libinterp/corefcn/txt-eng.cc: New file. Contains mapping from symbol
name to character code, in Unicode and MS symbol.
* libinterp/corefcn/modules.mk (COREFCN_SRC): Add txt-eng.cc.
* libinterp/corefcn/oct-tex-lexer.ll: Add "\n" to rules applicable to
".", as
the latter does not include new line characters.
* libinterp/corefcn/oct-tex-parser.yy: Remove debug statements.
* libinterp/corefcn/txt-eng.ft.cc (gripe_missing_glyph,
gripe_glyph_render): Change signature from char to FT_ULong.
(ft_render::ft_render): Adapt to new/removed members.
(ft_render::~ft_render): Remove use of fonts member.
(ft_render::set_font): Likewise. Use font instead.
(ft_render::push_new_line): Likewise. Change meaning of yoffset and
initialize line_yoffset.
(ft_render::update_line_bbox): New method.
(ft_render::set_mode): Change meaning of yoffset and initialize
line_yoffset.
(ft_render::process_character): New method.
(ft_render::visit(text_element_string)): Use it.
(ft_render::visit(text_element_list),
ft_render::visit(text_element_subscript),
ft_render::visit(text_element_superscript),
ft_render::visit(text_element_color),
ft_render::visit(text_element_fontsize),
ft_render::visit(text_element_fontname),
ft_render::visit(text_element_fontstyle),
ft_render::visit(text_element_symbol)): New methods.
(ft_render::set_color): Use color member instead of red/green/blue.
* libinterp/corefcn/txt-eng-ft.h (ft_render::visit(text_element_list),
ft_render::visit(text_element_subscript),
ft_render::visit(text_element_superscript),
ft_render::visit(text_element_color),
ft_render::visit(text_element_fontsize),
ft_render::visit(text_element_fontname),
ft_render::visit(text_element_fontstyle),
ft_render::visit(text_element_symbol)): New methods.
(ft_render::update_line_bbox, ft_render::process_character): New
methods.
(ft_render::current_face): Removed method.i
(ft_render::font): New member, replaces obsolete ft_render::fonts.
(ft_render::line_yoffset): New member.
(ft_render::color): New member, replaces obsolete red, green and blue.
(ft_render::ft_font::ft_font()): Implement default constructor.
(ft_render::ft_font::operator=): Fix incorrect use of FT_Reference_Face
return value.
(ft_render::ft_font::is_valid): New method.
* libinterp/corefcn/txt-eng.h (class text_element_symbol, class
text_element_fontname, class text_element_fontsize, class
text_element_fontname, class text_element_fontstyle, class
text_element_color): Add forward definition.
(text_element_symbol::invalid_code): New enum.
(text_element_symbol::code): New member.
(text_element_symbol::text_element_symbol): Initialize it.
(text_element_symbol::get_symbol_code): New method.
(text_element_fontstyle::get_fontstyle): New method.
(text_element_fontname::get_fontname): Renamed from fontname.
(text_element_fontsize::get_fontsize): Renamed from fontsize.
| author | Michael Goffioul <michael.goffioul@gmail.com> |
|---|---|
| date | Sun, 18 Aug 2013 16:36:46 -0400 |
| parents | 2fc554ffbc28 |
| children |
line wrap: on
line source
/* Copyright (C) 2008-2012 VZLU Prague a.s., Czech Republic This file is part of Octave. Octave is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. Octave 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 General Public License for more details. You should have received a copy of the GNU General Public License along with Octave; see the file COPYING. If not, see <http://www.gnu.org/licenses/>. */ // Author: Jaroslav Hajek <highegg@gmail.com> #ifdef HAVE_CONFIG_H #include <config.h> #endif #include <cctype> #include <functional> #include <algorithm> #include "dNDArray.h" #include "CNDArray.h" #include "Cell.h" #include "defun.h" #include "error.h" #include "gripes.h" #include "oct-obj.h" #include "ov.h" static bool contains_char (const std::string& str, char c) { return (str.find (c) != std::string::npos || str.find (std::toupper (c)) != std::string::npos); } // case-insensitive character comparison functors struct icmp_char_lt : public std::binary_function<char, char, bool> { bool operator () (char x, char y) const { return std::toupper (x) < std::toupper (y); } }; struct icmp_char_gt : public std::binary_function<char, char, bool> { bool operator () (char x, char y) const { return std::toupper (x) > std::toupper (y); } }; // FIXME -- maybe these should go elsewhere? // FIXME -- are they even needed now? // case-insensitive ascending comparator #if 0 static bool stri_comp_lt (const std::string& a, const std::string& b) { return std::lexicographical_compare (a.begin (), a.end (), b.begin (), b.end (), icmp_char_lt ()); } // case-insensitive descending comparator static bool stri_comp_gt (const std::string& a, const std::string& b) { return std::lexicographical_compare (a.begin (), a.end (), b.begin (), b.end (), icmp_char_gt ()); } #endif template <class T> inline sortmode get_sort_mode (const Array<T>& array, typename octave_sort<T>::compare_fcn_type desc_comp = octave_sort<T>::descending_compare) { octave_idx_type n = array.numel (); if (n > 1 && desc_comp (array (0), array (n-1))) return DESCENDING; else return ASCENDING; } // FIXME: perhaps there should be octave_value::lookup? // The question is, how should it behave w.r.t. the second argument's type. // We'd need a dispatch on two arguments. Hmmm... #define INT_ARRAY_LOOKUP(TYPE) \ (table.is_ ## TYPE ## _type () && y.is_ ## TYPE ## _type ()) \ retval = do_numeric_lookup (table.TYPE ## _array_value (), \ y.TYPE ## _array_value (), \ left_inf, right_inf, \ match_idx, match_bool); template <class ArrayT> static octave_value do_numeric_lookup (const ArrayT& array, const ArrayT& values, bool left_inf, bool right_inf, bool match_idx, bool match_bool) { octave_value retval; Array<octave_idx_type> idx = array.lookup (values); octave_idx_type n = array.numel (), nval = values.numel (); // Post-process. if (match_bool) { boolNDArray match (idx.dims ()); for (octave_idx_type i = 0; i < nval; i++) { octave_idx_type j = idx.xelem (i); match.xelem (i) = j != 0 && values(i) == array(j-1); } retval = match; } else if (match_idx || left_inf || right_inf) { if (match_idx) { NDArray ridx (idx.dims ()); for (octave_idx_type i = 0; i < nval; i++) { octave_idx_type j = idx.xelem (i); ridx.xelem (i) = (j != 0 && values(i) == array(j-1)) ? j : 0; } retval = ridx; } else if (left_inf && right_inf) { // Results in valid indices. Optimize using lazy index. octave_idx_type zero = 0; for (octave_idx_type i = 0; i < nval; i++) { octave_idx_type j = idx.xelem (i) - 1; idx.xelem (i) = std::max (zero, std::min (j, n-2)); } retval = idx_vector (idx); } else if (left_inf) { // Results in valid indices. Optimize using lazy index. octave_idx_type zero = 0; for (octave_idx_type i = 0; i < nval; i++) { octave_idx_type j = idx.xelem (i) - 1; idx.xelem (i) = std::max (zero, j); } retval = idx_vector (idx); } else if (right_inf) { NDArray ridx (idx.dims ()); for (octave_idx_type i = 0; i < nval; i++) { octave_idx_type j = idx.xelem (i); ridx.xelem (i) = std::min (j, n-1); } retval = ridx; } } else retval = idx; return retval; } DEFUN (lookup, args, , "-*- texinfo -*-\n\ @deftypefn {Built-in Function} {@var{idx} =} lookup (@var{table}, @var{y})\n\ @deftypefnx {Built-in Function} {@var{idx} =} lookup (@var{table}, @var{y}, @var{opt})\n\ Lookup values in a sorted table. Usually used as a prelude to\n\ interpolation.\n\ \n\ If table is increasing and @code{idx = lookup (table, y)}, then\n\ @code{table(idx(i)) <= y(i) < table(idx(i+1))} for all @code{y(i)}\n\ within the table. If @code{y(i) < table(1)} then\n\ @code{idx(i)} is 0. If @code{y(i) >= table(end)} or @code{isnan (y(i))} then\n\ @code{idx(i)} is @code{n}.\n\ \n\ If the table is decreasing, then the tests are reversed.\n\ For non-strictly monotonic tables, empty intervals are always skipped.\n\ The result is undefined if @var{table} is not monotonic, or if\n\ @var{table} contains a NaN.\n\ \n\ The complexity of the lookup is O(M*log(N)) where N is the size of\n\ @var{table} and M is the size of @var{y}. In the special case when @var{y}\n\ is also sorted, the complexity is O(min(M*log(N),M+N)).\n\ \n\ @var{table} and @var{y} can also be cell arrays of strings\n\ (or @var{y} can be a single string). In this case, string lookup\n\ is performed using lexicographical comparison.\n\ \n\ If @var{opts} is specified, it must be a string with letters indicating\n\ additional options.\n\ \n\ @table @code\n\ @item m\n\ @code{table(idx(i)) == val(i)} if @code{val(i)}\n\ occurs in table; otherwise, @code{idx(i)} is zero.\n\ \n\ @item b\n\ @code{idx(i)} is a logical 1 or 0, indicating whether\n\ @code{val(i)} is contained in table or not.\n\ \n\ @item l\n\ For numeric lookups\n\ the leftmost subinterval shall be extended to infinity (i.e., all indices\n\ at least 1)\n\ \n\ @item r\n\ For numeric lookups\n\ the rightmost subinterval shall be extended to infinity (i.e., all indices\n\ at most n-1).\n\ @end table\n\ @end deftypefn") { octave_value retval; int nargin = args.length (); if (nargin < 2 || nargin > 3 || (nargin == 3 && ! args(2).is_string ())) { print_usage (); return retval; } octave_value table = args(0), y = args(1); if (table.ndims () > 2 || (table.columns () > 1 && table.rows () > 1)) warning ("lookup: table is not a vector"); bool num_case = ((table.is_numeric_type () && y.is_numeric_type ()) || (table.is_char_matrix () && y.is_char_matrix ())); bool str_case = table.is_cellstr () && (y.is_string () || y.is_cellstr ()); bool left_inf = false; bool right_inf = false; bool match_idx = false; bool match_bool = false; if (nargin == 3) { std::string opt = args(2).string_value (); left_inf = contains_char (opt, 'l'); right_inf = contains_char (opt, 'r'); match_idx = contains_char (opt, 'm'); match_bool = contains_char (opt, 'b'); if (opt.find_first_not_of ("lrmb") != std::string::npos) { error ("lookup: unrecognized option: %c", opt[opt.find_first_not_of ("lrmb")]); return retval; } } if ((match_idx || match_bool) && (left_inf || right_inf)) error ("lookup: m, b cannot be specified with l or r"); else if (match_idx && match_bool) error ("lookup: only one of m or b can be specified"); else if (str_case && (left_inf || right_inf)) error ("lookup: l, r are not recognized for string lookups"); if (error_state) return retval; if (num_case) { // In the case of a complex array, absolute values will be used for compatibility // (though it's not too meaningful). if (table.is_complex_type ()) table = table.abs (); if (y.is_complex_type ()) y = y.abs (); Array<octave_idx_type> idx; // PS: I learned this from data.cc if INT_ARRAY_LOOKUP (int8) else if INT_ARRAY_LOOKUP (int16) else if INT_ARRAY_LOOKUP (int32) else if INT_ARRAY_LOOKUP (int64) else if INT_ARRAY_LOOKUP (uint8) else if INT_ARRAY_LOOKUP (uint16) else if INT_ARRAY_LOOKUP (uint32) else if INT_ARRAY_LOOKUP (uint64) else if (table.is_char_matrix () && y.is_char_matrix ()) retval = do_numeric_lookup (table.char_array_value (), y.char_array_value (), left_inf, right_inf, match_idx, match_bool); else if (table.is_single_type () || y.is_single_type ()) retval = do_numeric_lookup (table.float_array_value (), y.float_array_value (), left_inf, right_inf, match_idx, match_bool); else retval = do_numeric_lookup (table.array_value (), y.array_value (), left_inf, right_inf, match_idx, match_bool); } else if (str_case) { Array<std::string> str_table = table.cellstr_value (); Array<std::string> str_y (dim_vector (1, 1)); if (y.is_cellstr ()) str_y = y.cellstr_value (); else str_y(0) = y.string_value (); Array<octave_idx_type> idx = str_table.lookup (str_y); octave_idx_type nval = str_y.numel (); // Post-process. if (match_bool) { boolNDArray match (idx.dims ()); for (octave_idx_type i = 0; i < nval; i++) { octave_idx_type j = idx.xelem (i); match.xelem (i) = j != 0 && str_y(i) == str_table(j-1); } retval = match; } else if (match_idx) { NDArray ridx (idx.dims ()); if (match_idx) { for (octave_idx_type i = 0; i < nval; i++) { octave_idx_type j = idx.xelem (i); ridx.xelem (i) = (j != 0 && str_y(i) == str_table(j-1)) ? j : 0; } } retval = ridx; } else retval = idx; } else print_usage (); return retval; } /* %!assert (lookup (1:3, 0.5), 0) # value before table %!assert (lookup (1:3, 3.5), 3) # value after table error %!assert (lookup (1:3, 1.5), 1) # value within table error %!assert (lookup (1:3, [3,2,1]), [3,2,1]) %!assert (lookup ([1:4]', [1.2, 3.5]'), [1, 3]') %!assert (lookup ([1:4], [1.2, 3.5]'), [1, 3]') %!assert (lookup ([1:4]', [1.2, 3.5]), [1, 3]) %!assert (lookup ([1:4], [1.2, 3.5]), [1, 3]) %!assert (lookup (1:3, [3, 2, 1]), [3, 2, 1]) %!assert (lookup ([3:-1:1], [3.5, 3, 1.2, 2.5, 2.5]), [0, 1, 2, 1, 1]) %!assert (isempty (lookup ([1:3], []))) %!assert (isempty (lookup ([1:3]', []))) %!assert (lookup (1:3, [1, 2; 3, 0.5]), [1, 2; 3, 0]) %!assert (lookup (1:4, [1, 1.2; 3, 2.5], "m"), [1, 0; 3, 0]) %!assert (lookup (4:-1:1, [1, 1.2; 3, 2.5], "m"), [4, 0; 2, 0]) %!assert (lookup (1:4, [1, 1.2; 3, 2.5], "b"), logical ([1, 0; 3, 0])) %!assert (lookup (4:-1:1, [1, 1.2; 3, 2.5], "b"), logical ([4, 0; 2, 0])) %! %!assert (lookup ({"apple","lemon","orange"}, {"banana","kiwi"; "ananas","mango"}), [1,1;0,2]) %!assert (lookup ({"apple","lemon","orange"}, "potato"), 3) %!assert (lookup ({"orange","lemon","apple"}, "potato"), 0) */