lyx_mirror/src/BiblioInfo.cpp
2017-03-19 16:15:03 +01:00

1577 lines
46 KiB
C++

/**
* \file BiblioInfo.cpp
* This file is part of LyX, the document processor.
* Licence details can be found in the file COPYING.
*
* \author Angus Leeming
* \author Herbert Voß
* \author Richard Heck
* \author Julien Rioux
* \author Jürgen Spitzmüller
*
* Full author contact details are available in file CREDITS.
*/
#include <config.h>
#include "BiblioInfo.h"
#include "Buffer.h"
#include "BufferParams.h"
#include "buffer_funcs.h"
#include "Citation.h"
#include "Encoding.h"
#include "InsetIterator.h"
#include "Language.h"
#include "output_xhtml.h"
#include "Paragraph.h"
#include "TextClass.h"
#include "TocBackend.h"
#include "support/convert.h"
#include "support/debug.h"
#include "support/docstream.h"
#include "support/gettext.h"
#include "support/lassert.h"
#include "support/lstrings.h"
#include "support/regex.h"
#include "support/textutils.h"
#include <map>
#include <set>
using namespace std;
using namespace lyx::support;
namespace lyx {
namespace {
// Remove placeholders from names
docstring renormalize(docstring const & input)
{
docstring res = subst(input, from_ascii("$$space!"), from_ascii(" "));
return subst(res, from_ascii("$$comma!"), from_ascii(","));
}
// Split the surname into prefix ("von-part") and family name
pair<docstring, docstring> parseSurname(docstring const & sname)
{
// Split the surname into its tokens
vector<docstring> pieces = getVectorFromString(sname, from_ascii(" "));
if (pieces.size() < 2)
return make_pair(docstring(), sname);
// Now we look for pieces that begin with a lower case letter.
// All except for the very last token constitute the "von-part".
docstring prefix;
vector<docstring>::const_iterator it = pieces.begin();
vector<docstring>::const_iterator const en = pieces.end();
bool first = true;
for (; it != en; ++it) {
if ((*it).empty())
continue;
// If this is the last piece, then what we now have is
// the family name, notwithstanding the casing.
if (it + 1 == en)
break;
char_type const c = (*it)[0];
// If the piece starts with a upper case char, we assume
// this is part of the surname.
if (!isLower(c))
break;
// Nothing of the former, so add this piece to the prename
if (!first)
prefix += " ";
else
first = false;
prefix += *it;
}
// Reconstruct the family name.
// Note that if we left the loop with because it + 1 == en,
// then this will still do the right thing, i.e., make surname
// just be the last piece.
docstring surname;
first = true;
for (; it != en; ++it) {
if (!first)
surname += " ";
else
first = false;
surname += *it;
}
return make_pair(prefix, surname);
}
struct name_parts {
docstring surname;
docstring prename;
docstring suffix;
docstring prefix;
};
// gets the name parts (prename, surname, prefix, suffix) from an author-type string
name_parts nameParts(docstring const & iname)
{
name_parts res;
if (iname.empty())
return res;
// First we check for goupings (via {...}) and replace blanks and
// commas inside groups with temporary placeholders
docstring name;
int gl = 0;
docstring::const_iterator p = iname.begin();
while (p != iname.end()) {
// count grouping level
if (*p == '{')
++gl;
else if (*p == '}')
--gl;
// generate string with probable placeholders
if (*p == ' ' && gl > 0)
name += from_ascii("$$space!");
else if (*p == ',' && gl > 0)
name += from_ascii("$$comma!");
else
name += *p;
++p;
}
// Now we look for a comma, and take the last name to be everything
// preceding the right-most one, so that we also get the name suffix
// (aka "jr" part).
vector<docstring> pieces = getVectorFromString(name);
if (pieces.size() > 1) {
// Whether we have a name suffix or not, the prename is
// always last item
res.prename = renormalize(pieces.back());
// The family name, conversely, is always the first item.
// However, it might contain a prefix (aka "von" part)
docstring const sname = pieces.front();
res.prefix = renormalize(parseSurname(sname).first);
res.surname = renormalize(parseSurname(sname).second);
// If we have three pieces (the maximum allowed by BibTeX),
// the second one is the name suffix.
if (pieces.size() > 2)
res.suffix = renormalize(pieces.at(1));
return res;
}
// OK, so now we want to look for the last name.
// Split on spaces, to get various tokens.
pieces = getVectorFromString(name, from_ascii(" "));
// No space: Only a family name given
if (pieces.size() < 2) {
res.surname = renormalize(pieces.back());
return res;
}
// If we get two pieces, assume "prename surname"
if (pieces.size() == 2) {
res.prename = renormalize(pieces.front());
res.surname = renormalize(pieces.back());
return res;
}
// More than 3 pieces: A name prefix (aka "von" part) might be included.
// We look for the first piece that begins with a lower case letter
// (which is the name prefix, if it is not the last token) or the last token.
docstring prename;
vector<docstring>::const_iterator it = pieces.begin();
vector<docstring>::const_iterator const en = pieces.end();
bool first = true;
for (; it != en; ++it) {
if ((*it).empty())
continue;
char_type const c = (*it)[0];
// If the piece starts with a lower case char, we assume
// this is the name prefix and thus prename is complete.
if (isLower(c))
break;
// Same if this is the last piece, which is always the surname.
if (it + 1 == en)
break;
// Nothing of the former, so add this piece to the prename
if (!first)
prename += " ";
else
first = false;
prename += *it;
}
// Now reconstruct the family name and strip the prefix.
// Note that if we left the loop because it + 1 == en,
// then this will still do the right thing, i.e., make surname
// just be the last piece.
docstring surname;
first = true;
for (; it != en; ++it) {
if (!first)
surname += " ";
else
first = false;
surname += *it;
}
res.prename = renormalize(prename);
res.prefix = renormalize(parseSurname(surname).first);
res.surname = renormalize(parseSurname(surname).second);
return res;
}
docstring constructName(docstring const & name, string const scheme)
{
// re-constructs a name from name parts according
// to a given scheme
docstring const prename = nameParts(name).prename;
docstring const surname = nameParts(name).surname;
docstring const prefix = nameParts(name).prefix;
docstring const suffix = nameParts(name).suffix;
string res = scheme;
static regex const reg1("(.*)(\\{%prename%\\[\\[)([^\\]]+)(\\]\\]\\})(.*)");
static regex const reg2("(.*)(\\{%suffix%\\[\\[)([^\\]]+)(\\]\\]\\})(.*)");
static regex const reg3("(.*)(\\{%prefix%\\[\\[)([^\\]]+)(\\]\\]\\})(.*)");
smatch sub;
if (regex_match(scheme, sub, reg1)) {
res = sub.str(1);
if (!prename.empty())
res += sub.str(3);
res += sub.str(5);
}
if (regex_match(res, sub, reg2)) {
res = sub.str(1);
if (!suffix.empty())
res += sub.str(3);
res += sub.str(5);
}
if (regex_match(res, sub, reg3)) {
res = sub.str(1);
if (!prefix.empty())
res += sub.str(3);
res += sub.str(5);
}
docstring result = from_ascii(res);
result = subst(result, from_ascii("%prename%"), prename);
result = subst(result, from_ascii("%surname%"), surname);
result = subst(result, from_ascii("%prefix%"), prefix);
result = subst(result, from_ascii("%suffix%"), suffix);
return result;
}
vector<docstring> const getAuthors(docstring const & author)
{
// We check for goupings (via {...}) and only consider " and "
// outside groups as author separator. This is to account
// for cases such as {{Barnes and Noble, Inc.}}, which
// need to be treated as one single family name.
// We use temporary placeholders in order to differentiate the
// diverse " and " cases.
// First, we temporarily replace all ampersands. It is rather unusual
// in author names, but can happen (consider cases such as "C \& A Corp.").
docstring iname = subst(author, from_ascii("&"), from_ascii("$$amp!"));
// Then, we temporarily make all " and " strings to ampersands in order
// to handle them later on a per-char level.
iname = subst(iname, from_ascii(" and "), from_ascii(" & "));
// Now we traverse through the string and replace the "&" by the proper
// output in- and outside groups
docstring name;
int gl = 0;
docstring::const_iterator p = iname.begin();
while (p != iname.end()) {
// count grouping level
if (*p == '{')
++gl;
else if (*p == '}')
--gl;
// generate string with probable placeholders
if (*p == '&') {
if (gl > 0)
// Inside groups, we output "and"
name += from_ascii("and");
else
// Outside groups, we output a separator
name += from_ascii("$$namesep!");
}
else
name += *p;
++p;
}
// re-insert the literal ampersands
name = subst(name, from_ascii("$$amp!"), from_ascii("&"));
// Now construct the actual vector
return getVectorFromString(name, from_ascii(" $$namesep! "));
}
bool multipleAuthors(docstring const author)
{
return getAuthors(author).size() > 1;
}
// converts a string containing LaTeX commands into unicode
// for display.
docstring convertLaTeXCommands(docstring const & str)
{
docstring val = str;
docstring ret;
bool scanning_cmd = false;
bool scanning_math = false;
bool escaped = false; // used to catch \$, etc.
while (!val.empty()) {
char_type const ch = val[0];
// if we're scanning math, we output everything until we
// find an unescaped $, at which point we break out.
if (scanning_math) {
if (escaped)
escaped = false;
else if (ch == '\\')
escaped = true;
else if (ch == '$')
scanning_math = false;
ret += ch;
val = val.substr(1);
continue;
}
// if we're scanning a command name, then we just
// discard characters until we hit something that
// isn't alpha.
if (scanning_cmd) {
if (isAlphaASCII(ch)) {
val = val.substr(1);
escaped = false;
continue;
}
// so we're done with this command.
// now we fall through and check this character.
scanning_cmd = false;
}
// was the last character a \? If so, then this is something like:
// \\ or \$, so we'll just output it. That's probably not always right...
if (escaped) {
// exception: output \, as THIN SPACE
if (ch == ',')
ret.push_back(0x2009);
else
ret += ch;
val = val.substr(1);
escaped = false;
continue;
}
if (ch == '$') {
ret += ch;
val = val.substr(1);
scanning_math = true;
continue;
}
// Change text mode accents in the form
// {\v a} to \v{a} (see #9340).
// FIXME: This is a sort of mini-tex2lyx.
// Use the real tex2lyx instead!
static lyx::regex const tma_reg("^\\{\\\\[bcCdfGhHkrtuUv]\\s\\w\\}");
if (lyx::regex_search(to_utf8(val), tma_reg)) {
val = val.substr(1);
val.replace(2, 1, from_ascii("{"));
continue;
}
// Apart from the above, we just ignore braces
if (ch == '{' || ch == '}') {
val = val.substr(1);
continue;
}
// we're going to check things that look like commands, so if
// this doesn't, just output it.
if (ch != '\\') {
ret += ch;
val = val.substr(1);
continue;
}
// ok, could be a command of some sort
// let's see if it corresponds to some unicode
// unicodesymbols has things in the form: \"{u},
// whereas we may see things like: \"u. So we'll
// look for that and change it, if necessary.
// FIXME: This is a sort of mini-tex2lyx.
// Use the real tex2lyx instead!
static lyx::regex const reg("^\\\\\\W\\w");
if (lyx::regex_search(to_utf8(val), reg)) {
val.insert(3, from_ascii("}"));
val.insert(2, from_ascii("{"));
}
bool termination;
docstring rem;
docstring const cnvtd = Encodings::fromLaTeXCommand(val,
Encodings::TEXT_CMD, termination, rem);
if (!cnvtd.empty()) {
// it did, so we'll take that bit and proceed with what's left
ret += cnvtd;
val = rem;
continue;
}
// it's a command of some sort
scanning_cmd = true;
escaped = true;
val = val.substr(1);
}
return ret;
}
// Escape '<' and '>' and remove richtext markers (e.g. {!this is richtext!}) from a string.
docstring processRichtext(docstring const & str, bool richtext)
{
docstring val = str;
docstring ret;
bool scanning_rich = false;
while (!val.empty()) {
char_type const ch = val[0];
if (ch == '{' && val.size() > 1 && val[1] == '!') {
// beginning of rich text
scanning_rich = true;
val = val.substr(2);
continue;
}
if (scanning_rich && ch == '!' && val.size() > 1 && val[1] == '}') {
// end of rich text
scanning_rich = false;
val = val.substr(2);
continue;
}
if (richtext) {
if (scanning_rich)
ret += ch;
else {
// we need to escape '<' and '>'
if (ch == '<')
ret += "&lt;";
else if (ch == '>')
ret += "&gt;";
else
ret += ch;
}
} else if (!scanning_rich /* && !richtext */)
ret += ch;
// else the character is discarded, which will happen only if
// richtext == false and we are scanning rich text
val = val.substr(1);
}
return ret;
}
} // anon namespace
//////////////////////////////////////////////////////////////////////
//
// BibTeXInfo
//
//////////////////////////////////////////////////////////////////////
BibTeXInfo::BibTeXInfo(docstring const & key, docstring const & type)
: is_bibtex_(true), bib_key_(key), entry_type_(type), info_(),
modifier_(0)
{}
docstring const BibTeXInfo::getAuthorOrEditorList(Buffer const * buf,
bool full, bool forceshort) const
{
docstring author = operator[]("author");
if (author.empty())
author = operator[]("editor");
return getAuthorList(buf, author, full, forceshort);
}
docstring const BibTeXInfo::getAuthorList(Buffer const * buf,
docstring const & author, bool const full, bool const forceshort,
bool const allnames, bool const beginning) const
{
// Maxnames treshold depend on engine
size_t maxnames = buf ?
buf->params().documentClass().max_citenames() : 2;
if (!is_bibtex_) {
docstring const opt = label();
if (opt.empty())
return docstring();
docstring authors;
docstring const remainder = trim(split(opt, authors, '('));
if (remainder.empty())
// in this case, we didn't find a "(",
// so we don't have author (year)
return docstring();
return authors;
}
if (author.empty())
return author;
// OK, we've got some names. Let's format them.
// Try to split the author list
vector<docstring> const authors = getAuthors(author);
docstring retval;
CiteEngineType const engine_type = buf ? buf->params().citeEngineType()
: ENGINE_TYPE_DEFAULT;
// These are defined in the styles
string const etal =
buf ? buf->params().documentClass().getCiteMacro(engine_type, "_etal")
: " et al.";
string const namesep =
buf ? buf->params().documentClass().getCiteMacro(engine_type, "_namesep")
: ", ";
string const lastnamesep =
buf ? buf->params().documentClass().getCiteMacro(engine_type, "_lastnamesep")
: ", and ";
string const pairnamesep =
buf ? buf->params().documentClass().getCiteMacro(engine_type, "_pairnamesep")
: " and ";
string firstnameform =
buf ? buf->params().documentClass().getCiteMacro(engine_type, "!firstnameform")
: "{%prefix%[[%prefix% ]]}%surname%{%suffix%[[, %suffix%]]}{%prename%[[, %prename%]]}";
if (!beginning)
firstnameform = buf ? buf->params().documentClass().getCiteMacro(engine_type, "!firstbynameform")
: "%prename% {%prefix%[[%prefix% ]]}%surname%{%suffix%[[, %suffix%]]}";
string othernameform = buf ? buf->params().documentClass().getCiteMacro(engine_type, "!othernameform")
: "{%prefix%[[%prefix% ]]}%surname%{%suffix%[[, %suffix%]]}{%prename%[[, %prename%]]}";
if (!beginning)
othernameform = buf ? buf->params().documentClass().getCiteMacro(engine_type, "!otherbynameform")
: "%prename% {%prefix%[[%prefix% ]]}%surname%{%suffix%[[, %suffix%]]}";
string citenameform = buf ? buf->params().documentClass().getCiteMacro(engine_type, "!citenameform")
: "{%prefix%[[%prefix% ]]}%surname%";
// Shorten the list (with et al.) if forceshort is set
// and the list can actually be shortened, else if maxcitenames
// is passed and full is not set.
bool shorten = forceshort && authors.size() > 1;
vector<docstring>::const_iterator it = authors.begin();
vector<docstring>::const_iterator en = authors.end();
for (size_t i = 0; it != en; ++it, ++i) {
if (i >= maxnames && !full) {
shorten = true;
break;
}
if (*it == "others") {
retval += buf ? buf->B_(etal) : from_ascii(etal);
break;
}
if (i > 0 && i == authors.size() - 1) {
if (authors.size() == 2)
retval += buf ? buf->B_(pairnamesep) : from_ascii(pairnamesep);
else
retval += buf ? buf->B_(lastnamesep) : from_ascii(lastnamesep);
} else if (i > 0)
retval += buf ? buf->B_(namesep) : from_ascii(namesep);
if (allnames)
retval += (i == 0) ? constructName(*it, firstnameform)
: constructName(*it, othernameform);
else
retval += constructName(*it, citenameform);
}
if (shorten) {
if (allnames)
retval = constructName(authors[0], firstnameform) + (buf ? buf->B_(etal) : from_ascii(etal));
else
retval = constructName(authors[0], citenameform) + (buf ? buf->B_(etal) : from_ascii(etal));
}
return convertLaTeXCommands(retval);
}
docstring const BibTeXInfo::getYear() const
{
if (is_bibtex_) {
// first try legacy year field
docstring year = operator[]("year");
if (!year.empty())
return year;
// now try biblatex's date field
year = operator[]("date");
// Format is [-]YYYY-MM-DD*/[-]YYYY-MM-DD*
// We only want the years.
static regex const yreg("[-]?([\\d]{4}).*");
static regex const ereg(".*/[-]?([\\d]{4}).*");
smatch sm;
string const date = to_utf8(year);
if (!regex_match(date, sm, yreg))
// cannot parse year.
return docstring();
year = from_ascii(sm[1]);
// check for an endyear
if (regex_match(date, sm, ereg))
year += char_type(0x2013) + from_ascii(sm[1]);
return year;
}
docstring const opt = label();
if (opt.empty())
return docstring();
docstring authors;
docstring tmp = split(opt, authors, '(');
if (tmp.empty())
// we don't have author (year)
return docstring();
docstring year;
tmp = split(tmp, year, ')');
return year;
}
namespace {
docstring parseOptions(docstring const & format, string & optkey,
docstring & ifpart, docstring & elsepart);
// Calls parseOptions to deal with an embedded option, such as:
// {%number%[[, no.~%number%]]}
// which must appear at the start of format. ifelsepart gets the
// whole of the option, and we return what's left after the option.
// we return format if there is an error.
docstring parseEmbeddedOption(docstring const & format, docstring & ifelsepart)
{
LASSERT(format[0] == '{' && format[1] == '%', return format);
string optkey;
docstring ifpart;
docstring elsepart;
docstring const rest = parseOptions(format, optkey, ifpart, elsepart);
if (format == rest) { // parse error
LYXERR0("ERROR! Couldn't parse `" << format <<"'.");
return format;
}
LASSERT(rest.size() <= format.size(),
{ ifelsepart = docstring(); return format; });
ifelsepart = format.substr(0, format.size() - rest.size());
return rest;
}
// Gets a "clause" from a format string, where the clause is
// delimited by '[[' and ']]'. Returns what is left after the
// clause is removed, and returns format if there is an error.
docstring getClause(docstring const & format, docstring & clause)
{
docstring fmt = format;
// remove '[['
fmt = fmt.substr(2);
// we'll remove characters from the front of fmt as we
// deal with them
while (!fmt.empty()) {
if (fmt[0] == ']' && fmt.size() > 1 && fmt[1] == ']') {
// that's the end
fmt = fmt.substr(2);
break;
}
// check for an embedded option
if (fmt[0] == '{' && fmt.size() > 1 && fmt[1] == '%') {
docstring part;
docstring const rest = parseEmbeddedOption(fmt, part);
if (fmt == rest) {
LYXERR0("ERROR! Couldn't parse embedded option in `" << format <<"'.");
return format;
}
clause += part;
fmt = rest;
} else { // it's just a normal character
clause += fmt[0];
fmt = fmt.substr(1);
}
}
return fmt;
}
// parse an options string, which must appear at the start of the
// format parameter. puts the parsed bits in optkey, ifpart, and
// elsepart and returns what's left after the option is removed.
// if there's an error, it returns format itself.
docstring parseOptions(docstring const & format, string & optkey,
docstring & ifpart, docstring & elsepart)
{
LASSERT(format[0] == '{' && format[1] == '%', return format);
// strip '{%'
docstring fmt = format.substr(2);
size_t pos = fmt.find('%'); // end of key
if (pos == string::npos) {
LYXERR0("Error parsing `" << format <<"'. Can't find end of key.");
return format;
}
optkey = to_utf8(fmt.substr(0, pos));
fmt = fmt.substr(pos + 1);
// [[format]] should be next
if (fmt[0] != '[' || fmt[1] != '[') {
LYXERR0("Error parsing `" << format <<"'. Can't find '[[' after key.");
return format;
}
docstring curfmt = fmt;
fmt = getClause(curfmt, ifpart);
if (fmt == curfmt) {
LYXERR0("Error parsing `" << format <<"'. Couldn't get if clause.");
return format;
}
if (fmt[0] == '}') // we're done, no else clause
return fmt.substr(1);
// else part should follow
if (fmt[0] != '[' || fmt[1] != '[') {
LYXERR0("Error parsing `" << format <<"'. Can't find else clause.");
return format;
}
curfmt = fmt;
fmt = getClause(curfmt, elsepart);
// we should be done
if (fmt == curfmt || fmt[0] != '}') {
LYXERR0("Error parsing `" << format <<"'. Can't find end of option.");
return format;
}
return fmt.substr(1);
}
} // anon namespace
/* FIXME
Bug #9131 revealed an oddity in how we are generating citation information
when more than one key is given. We end up building a longer and longer format
string as we go, which we then have to re-parse, over and over and over again,
rather than generating the information for the individual keys and then putting
all of that together. We do that to deal with the way separators work, from what
I can tell, but it still feels like a hack. Fixing this would require quite a
bit of work, however.
*/
docstring BibTeXInfo::expandFormat(docstring const & format,
BibTeXInfoList const xrefs, int & counter, Buffer const & buf,
CiteItem const & ci, bool next, bool second) const
{
// incorrect use of macros could put us in an infinite loop
static int const max_passes = 5000;
// the use of overly large keys can lead to performance problems, due
// to eventual attempts to convert LaTeX macros to unicode. See bug
// #8944. By default, the size is limited to 128 (in CiteItem), but
// for specific purposes (such as XHTML export), it needs to be enlarged
// This is perhaps not the best solution, but it will have to do for now.
size_t const max_keysize = ci.max_key_size;
odocstringstream ret; // return value
string key;
bool scanning_key = false;
bool scanning_rich = false;
CiteEngineType const engine_type = buf.params().citeEngineType();
docstring fmt = format;
// we'll remove characters from the front of fmt as we
// deal with them
while (!fmt.empty()) {
if (counter > max_passes) {
LYXERR0("Recursion limit reached while parsing `"
<< format << "'.");
return _("ERROR!");
}
char_type thischar = fmt[0];
if (thischar == '%') {
// beginning or end of key
if (scanning_key) {
// end of key
scanning_key = false;
// so we replace the key with its value, which may be empty
if (key[0] == '!') {
// macro
string const val =
buf.params().documentClass().getCiteMacro(engine_type, key);
fmt = from_utf8(val) + fmt.substr(1);
counter += 1;
continue;
} else if (key[0] == '_') {
// a translatable bit
string const val =
buf.params().documentClass().getCiteMacro(engine_type, key);
docstring const trans =
translateIfPossible(from_utf8(val), buf.params().language->code());
ret << trans;
} else {
docstring const val =
getValueForKey(key, buf, ci, xrefs, max_keysize);
if (!scanning_rich)
ret << from_ascii("{!<span class=\"bib-" + key + "\">!}");
ret << val;
if (!scanning_rich)
ret << from_ascii("{!</span>!}");
}
} else {
// beginning of key
key.clear();
scanning_key = true;
}
}
else if (thischar == '{') {
// beginning of option?
if (scanning_key) {
LYXERR0("ERROR: Found `{' when scanning key in `" << format << "'.");
return _("ERROR!");
}
if (fmt.size() > 1) {
if (fmt[1] == '%') {
// it is the beginning of an optional format
string optkey;
docstring ifpart;
docstring elsepart;
docstring const newfmt =
parseOptions(fmt, optkey, ifpart, elsepart);
if (newfmt == fmt) // parse error
return _("ERROR!");
fmt = newfmt;
docstring const val =
getValueForKey(optkey, buf, ci, xrefs);
if (optkey == "next" && next)
ret << ifpart; // without expansion
else if (optkey == "second" && second) {
int newcounter = 0;
ret << expandFormat(ifpart, xrefs, newcounter, buf,
ci, next);
} else if (!val.empty()) {
int newcounter = 0;
ret << expandFormat(ifpart, xrefs, newcounter, buf,
ci, next);
} else if (!elsepart.empty()) {
int newcounter = 0;
ret << expandFormat(elsepart, xrefs, newcounter, buf,
ci, next);
}
// fmt will have been shortened for us already
continue;
}
if (fmt[1] == '!') {
// beginning of rich text
scanning_rich = true;
fmt = fmt.substr(2);
ret << from_ascii("{!");
continue;
}
}
// we are here if '{' was not followed by % or !.
// So it's just a character.
ret << thischar;
}
else if (scanning_rich && thischar == '!'
&& fmt.size() > 1 && fmt[1] == '}') {
// end of rich text
scanning_rich = false;
fmt = fmt.substr(2);
ret << from_ascii("!}");
continue;
}
else if (scanning_key)
key += char(thischar);
else {
try {
ret.put(thischar);
} catch (EncodingException & /* e */) {
LYXERR0("Uncodable character '" << docstring(1, thischar) << " in citation label!");
}
}
fmt = fmt.substr(1);
} // for loop
if (scanning_key) {
LYXERR0("Never found end of key in `" << format << "'!");
return _("ERROR!");
}
if (scanning_rich) {
LYXERR0("Never found end of rich text in `" << format << "'!");
return _("ERROR!");
}
return ret.str();
}
docstring const & BibTeXInfo::getInfo(BibTeXInfoList const xrefs,
Buffer const & buf, CiteItem const & ci) const
{
bool const richtext = ci.richtext;
if (!richtext && !info_.empty())
return info_;
if (richtext && !info_richtext_.empty())
return info_richtext_;
if (!is_bibtex_) {
BibTeXInfo::const_iterator it = find(from_ascii("ref"));
info_ = it->second;
return info_;
}
CiteEngineType const engine_type = buf.params().citeEngineType();
DocumentClass const & dc = buf.params().documentClass();
docstring const & format =
from_utf8(dc.getCiteFormat(engine_type, to_utf8(entry_type_)));
int counter = 0;
info_ = expandFormat(format, xrefs, counter, buf,
ci, false, false);
if (info_.empty()) {
// this probably shouldn't happen
return info_;
}
if (richtext) {
info_richtext_ = convertLaTeXCommands(processRichtext(info_, true));
return info_richtext_;
}
info_ = convertLaTeXCommands(processRichtext(info_, false));
return info_;
}
docstring const BibTeXInfo::getLabel(BibTeXInfoList const xrefs,
Buffer const & buf, docstring const & format,
CiteItem const & ci, bool next, bool second) const
{
docstring loclabel;
int counter = 0;
loclabel = expandFormat(format, xrefs, counter, buf, ci, next, second);
if (!loclabel.empty() && !next) {
loclabel = processRichtext(loclabel, ci.richtext);
loclabel = convertLaTeXCommands(loclabel);
}
return loclabel;
}
docstring const & BibTeXInfo::operator[](docstring const & field) const
{
BibTeXInfo::const_iterator it = find(field);
if (it != end())
return it->second;
static docstring const empty_value = docstring();
return empty_value;
}
docstring const & BibTeXInfo::operator[](string const & field) const
{
return operator[](from_ascii(field));
}
docstring BibTeXInfo::getValueForKey(string const & oldkey, Buffer const & buf,
CiteItem const & ci, BibTeXInfoList const xrefs, size_t maxsize) const
{
// anything less is pointless
LASSERT(maxsize >= 16, maxsize = 16);
string key = oldkey;
bool cleanit = false;
if (prefixIs(oldkey, "clean:")) {
key = oldkey.substr(6);
cleanit = true;
}
docstring ret = operator[](key);
if (ret.empty() && !xrefs.empty()) {
vector<BibTeXInfo const *>::const_iterator it = xrefs.begin();
vector<BibTeXInfo const *>::const_iterator en = xrefs.end();
for (; it != en; ++it) {
if (*it && !(**it)[key].empty()) {
ret = (**it)[key];
break;
}
}
}
if (ret.empty()) {
// some special keys
// FIXME: dialog, textbefore and textafter have nothing to do with this
if (key == "dialog" && ci.context == CiteItem::Dialog)
ret = from_ascii("x"); // any non-empty string will do
else if (key == "export" && ci.context == CiteItem::Export)
ret = from_ascii("x"); // any non-empty string will do
else if (key == "ifstar" && ci.Starred)
ret = from_ascii("x"); // any non-empty string will do
else if (key == "ifqualified" && ci.isQualified)
ret = from_ascii("x"); // any non-empty string will do
else if (key == "entrytype")
ret = entry_type_;
else if (prefixIs(key, "ifentrytype:")
&& from_ascii(key.substr(12)) == entry_type_)
ret = from_ascii("x"); // any non-empty string will do
else if (key == "key")
ret = bib_key_;
else if (key == "label")
ret = label_;
else if (key == "modifier" && modifier_ != 0)
ret = modifier_;
else if (key == "numericallabel")
ret = cite_number_;
else if (prefixIs(key, "ifmultiple:")) {
// Return whether we have multiple authors
docstring const kind = operator[](from_ascii(key.substr(11)));
if (multipleAuthors(kind))
ret = from_ascii("x"); // any non-empty string will do
}
else if (prefixIs(key, "abbrvnames:")) {
// Special key to provide abbreviated name list,
// with respect to maxcitenames. Suitable for Bibliography
// beginnings.
docstring const kind = operator[](from_ascii(key.substr(11)));
ret = getAuthorList(&buf, kind, false, false, true);
if (ci.forceUpperCase && isLowerCase(ret[0]))
ret[0] = uppercase(ret[0]);
} else if (prefixIs(key, "fullnames:")) {
// Return a full name list. Suitable for Bibliography
// beginnings.
docstring const kind = operator[](from_ascii(key.substr(10)));
ret = getAuthorList(&buf, kind, true, false, true);
if (ci.forceUpperCase && isLowerCase(ret[0]))
ret[0] = uppercase(ret[0]);
} else if (prefixIs(key, "forceabbrvnames:")) {
// Special key to provide abbreviated name lists,
// irrespective of maxcitenames. Suitable for Bibliography
// beginnings.
docstring const kind = operator[](from_ascii(key.substr(15)));
ret = getAuthorList(&buf, kind, false, true, true);
if (ci.forceUpperCase && isLowerCase(ret[0]))
ret[0] = uppercase(ret[0]);
} else if (prefixIs(key, "abbrvbynames:")) {
// Special key to provide abbreviated name list,
// with respect to maxcitenames. Suitable for further names inside a
// bibliography item // (such as "ed. by ...")
docstring const kind = operator[](from_ascii(key.substr(11)));
ret = getAuthorList(&buf, kind, false, false, true, false);
if (ci.forceUpperCase && isLowerCase(ret[0]))
ret[0] = uppercase(ret[0]);
} else if (prefixIs(key, "fullbynames:")) {
// Return a full name list. Suitable for further names inside a
// bibliography item // (such as "ed. by ...")
docstring const kind = operator[](from_ascii(key.substr(10)));
ret = getAuthorList(&buf, kind, true, false, true, false);
if (ci.forceUpperCase && isLowerCase(ret[0]))
ret[0] = uppercase(ret[0]);
} else if (prefixIs(key, "forceabbrvbynames:")) {
// Special key to provide abbreviated name lists,
// irrespective of maxcitenames. Suitable for further names inside a
// bibliography item // (such as "ed. by ...")
docstring const kind = operator[](from_ascii(key.substr(15)));
ret = getAuthorList(&buf, kind, false, true, true, false);
if (ci.forceUpperCase && isLowerCase(ret[0]))
ret[0] = uppercase(ret[0]);
} else if (key == "abbrvciteauthor") {
// Special key to provide abbreviated author or
// editor names (suitable for citation labels),
// with respect to maxcitenames.
ret = getAuthorOrEditorList(&buf, false, false);
if (ci.forceUpperCase && isLowerCase(ret[0]))
ret[0] = uppercase(ret[0]);
} else if (key == "fullciteauthor") {
// Return a full author or editor list (for citation labels)
ret = getAuthorOrEditorList(&buf, true, false);
if (ci.forceUpperCase && isLowerCase(ret[0]))
ret[0] = uppercase(ret[0]);
} else if (key == "forceabbrvciteauthor") {
// Special key to provide abbreviated author or
// editor names (suitable for citation labels),
// irrespective of maxcitenames.
ret = getAuthorOrEditorList(&buf, false, true);
if (ci.forceUpperCase && isLowerCase(ret[0]))
ret[0] = uppercase(ret[0]);
} else if (key == "bibentry") {
// Special key to provide the full bibliography entry: see getInfo()
CiteEngineType const engine_type = buf.params().citeEngineType();
DocumentClass const & dc = buf.params().documentClass();
docstring const & format =
from_utf8(dc.getCiteFormat(engine_type, to_utf8(entry_type_), false));
int counter = 0;
ret = expandFormat(format, xrefs, counter, buf, ci, false, false);
} else if (key == "textbefore")
ret = ci.textBefore;
else if (key == "textafter")
ret = ci.textAfter;
else if (key == "curpretext")
ret = ci.getPretexts()[bib_key_];
else if (key == "curposttext")
ret = ci.getPosttexts()[bib_key_];
else if (key == "year")
ret = getYear();
}
if (cleanit)
ret = html::cleanAttr(ret);
// make sure it is not too big
support::truncateWithEllipsis(ret, maxsize);
return ret;
}
//////////////////////////////////////////////////////////////////////
//
// BiblioInfo
//
//////////////////////////////////////////////////////////////////////
namespace {
// A functor for use with sort, leading to case insensitive sorting
class compareNoCase: public binary_function<docstring, docstring, bool>
{
public:
bool operator()(docstring const & s1, docstring const & s2) const {
return compare_no_case(s1, s2) < 0;
}
};
} // namespace anon
vector<docstring> const BiblioInfo::getXRefs(BibTeXInfo const & data, bool const nested) const
{
vector<docstring> result;
if (!data.isBibTeX())
return result;
// Legacy crossref field. This is not nestable.
if (!nested && !data["crossref"].empty()) {
docstring const xrefkey = data["crossref"];
result.push_back(xrefkey);
// However, check for nested xdatas
BiblioInfo::const_iterator it = find(xrefkey);
if (it != end()) {
BibTeXInfo const & xref = it->second;
vector<docstring> const nxdata = getXRefs(xref, true);
if (!nxdata.empty())
result.insert(result.end(), nxdata.begin(), nxdata.end());
}
}
// Biblatex's xdata field. Infinitely nestable.
// XData field can consist of a comma-separated list of keys
vector<docstring> const xdatakeys = getVectorFromString(data["xdata"]);
if (!xdatakeys.empty()) {
vector<docstring>::const_iterator xit = xdatakeys.begin();
vector<docstring>::const_iterator xen = xdatakeys.end();
for (; xit != xen; ++xit) {
docstring const xdatakey = *xit;
result.push_back(xdatakey);
BiblioInfo::const_iterator it = find(xdatakey);
if (it != end()) {
BibTeXInfo const & xdata = it->second;
vector<docstring> const nxdata = getXRefs(xdata, true);
if (!nxdata.empty())
result.insert(result.end(), nxdata.begin(), nxdata.end());
}
}
}
return result;
}
vector<docstring> const BiblioInfo::getKeys() const
{
vector<docstring> bibkeys;
BiblioInfo::const_iterator it = begin();
for (; it != end(); ++it)
bibkeys.push_back(it->first);
sort(bibkeys.begin(), bibkeys.end(), compareNoCase());
return bibkeys;
}
vector<docstring> const BiblioInfo::getFields() const
{
vector<docstring> bibfields;
set<docstring>::const_iterator it = field_names_.begin();
set<docstring>::const_iterator end = field_names_.end();
for (; it != end; ++it)
bibfields.push_back(*it);
sort(bibfields.begin(), bibfields.end());
return bibfields;
}
vector<docstring> const BiblioInfo::getEntries() const
{
vector<docstring> bibentries;
set<docstring>::const_iterator it = entry_types_.begin();
set<docstring>::const_iterator end = entry_types_.end();
for (; it != end; ++it)
bibentries.push_back(*it);
sort(bibentries.begin(), bibentries.end());
return bibentries;
}
docstring const BiblioInfo::getAuthorOrEditorList(docstring const & key, Buffer const & buf) const
{
BiblioInfo::const_iterator it = find(key);
if (it == end())
return docstring();
BibTeXInfo const & data = it->second;
return data.getAuthorOrEditorList(&buf, false);
}
docstring const BiblioInfo::getCiteNumber(docstring const & key) const
{
BiblioInfo::const_iterator it = find(key);
if (it == end())
return docstring();
BibTeXInfo const & data = it->second;
return data.citeNumber();
}
docstring const BiblioInfo::getYear(docstring const & key, bool use_modifier) const
{
BiblioInfo::const_iterator it = find(key);
if (it == end())
return docstring();
BibTeXInfo const & data = it->second;
docstring year = data.getYear();
if (year.empty()) {
// let's try the crossrefs
vector<docstring> const xrefs = getXRefs(data);
if (xrefs.empty())
// no luck
return docstring();
vector<docstring>::const_iterator it = xrefs.begin();
vector<docstring>::const_iterator en = xrefs.end();
for (; it != en; ++it) {
BiblioInfo::const_iterator const xrefit = find(*it);
if (xrefit == end())
continue;
BibTeXInfo const & xref_data = xrefit->second;
year = xref_data.getYear();
if (!year.empty())
// success!
break;
}
}
if (use_modifier && data.modifier() != 0)
year += data.modifier();
return year;
}
docstring const BiblioInfo::getYear(docstring const & key, Buffer const & buf, bool use_modifier) const
{
docstring const year = getYear(key, use_modifier);
if (year.empty())
return buf.B_("No year");
return year;
}
docstring const BiblioInfo::getInfo(docstring const & key,
Buffer const & buf, CiteItem const & ci) const
{
BiblioInfo::const_iterator it = find(key);
if (it == end())
return docstring(_("Bibliography entry not found!"));
BibTeXInfo const & data = it->second;
BibTeXInfoList xrefptrs;
vector<docstring> const xrefs = getXRefs(data);
if (!xrefs.empty()) {
vector<docstring>::const_iterator it = xrefs.begin();
vector<docstring>::const_iterator en = xrefs.end();
for (; it != en; ++it) {
BiblioInfo::const_iterator const xrefit = find(*it);
if (xrefit != end())
xrefptrs.push_back(&(xrefit->second));
}
}
return data.getInfo(xrefptrs, buf, ci);
}
docstring const BiblioInfo::getLabel(vector<docstring> keys,
Buffer const & buf, string const & style, CiteItem const & ci) const
{
size_t max_size = ci.max_size;
// shorter makes no sense
LASSERT(max_size >= 16, max_size = 16);
// we can't display more than 10 of these, anyway
bool const too_many_keys = keys.size() > 10;
if (too_many_keys)
keys.resize(10);
CiteEngineType const engine_type = buf.params().citeEngineType();
DocumentClass const & dc = buf.params().documentClass();
docstring const & format = from_utf8(dc.getCiteFormat(engine_type, style, false, "cite"));
docstring ret = format;
vector<docstring>::const_iterator key = keys.begin();
vector<docstring>::const_iterator ken = keys.end();
for (int i = 0; key != ken; ++key, ++i) {
BiblioInfo::const_iterator it = find(*key);
BibTeXInfo empty_data;
empty_data.key(*key);
BibTeXInfo & data = empty_data;
vector<BibTeXInfo const *> xrefptrs;
if (it != end()) {
data = it->second;
vector<docstring> const xrefs = getXRefs(data);
if (!xrefs.empty()) {
vector<docstring>::const_iterator it = xrefs.begin();
vector<docstring>::const_iterator en = xrefs.end();
for (; it != en; ++it) {
BiblioInfo::const_iterator const xrefit = find(*it);
if (xrefit != end())
xrefptrs.push_back(&(xrefit->second));
}
}
}
ret = data.getLabel(xrefptrs, buf, ret, ci, key + 1 != ken, i == 1);
}
if (too_many_keys)
ret.push_back(0x2026);//HORIZONTAL ELLIPSIS
support::truncateWithEllipsis(ret, max_size);
return ret;
}
bool BiblioInfo::isBibtex(docstring const & key) const
{
docstring key1;
split(key, key1, ',');
BiblioInfo::const_iterator it = find(key1);
if (it == end())
return false;
return it->second.isBibTeX();
}
vector<docstring> const BiblioInfo::getCiteStrings(
vector<docstring> const & keys, vector<CitationStyle> const & styles,
Buffer const & buf, CiteItem const & ci) const
{
if (empty())
return vector<docstring>();
string style;
vector<docstring> vec(styles.size());
for (size_t i = 0; i != vec.size(); ++i) {
style = styles[i].name;
vec[i] = getLabel(keys, buf, style, ci);
}
return vec;
}
void BiblioInfo::mergeBiblioInfo(BiblioInfo const & info)
{
bimap_.insert(info.begin(), info.end());
field_names_.insert(info.field_names_.begin(), info.field_names_.end());
entry_types_.insert(info.entry_types_.begin(), info.entry_types_.end());
}
namespace {
// used in xhtml to sort a list of BibTeXInfo objects
bool lSorter(BibTeXInfo const * lhs, BibTeXInfo const * rhs)
{
docstring const lauth = lhs->getAuthorOrEditorList();
docstring const rauth = rhs->getAuthorOrEditorList();
docstring const lyear = lhs->getYear();
docstring const ryear = rhs->getYear();
docstring const ltitl = lhs->operator[]("title");
docstring const rtitl = rhs->operator[]("title");
return (lauth < rauth)
|| (lauth == rauth && lyear < ryear)
|| (lauth == rauth && lyear == ryear && ltitl < rtitl);
}
}
void BiblioInfo::collectCitedEntries(Buffer const & buf)
{
cited_entries_.clear();
// We are going to collect all the citation keys used in the document,
// getting them from the TOC.
// FIXME We may want to collect these differently, in the first case,
// so that we might have them in order of appearance.
set<docstring> citekeys;
shared_ptr<Toc const> toc = buf.tocBackend().toc("citation");
Toc::const_iterator it = toc->begin();
Toc::const_iterator const en = toc->end();
for (; it != en; ++it) {
if (it->str().empty())
continue;
vector<docstring> const keys = getVectorFromString(it->str());
citekeys.insert(keys.begin(), keys.end());
}
if (citekeys.empty())
return;
// We have a set of the keys used in this document.
// We will now convert it to a list of the BibTeXInfo objects used in
// this document...
vector<BibTeXInfo const *> bi;
set<docstring>::const_iterator cit = citekeys.begin();
set<docstring>::const_iterator const cen = citekeys.end();
for (; cit != cen; ++cit) {
BiblioInfo::const_iterator const bt = find(*cit);
if (bt == end() || !bt->second.isBibTeX())
continue;
bi.push_back(&(bt->second));
}
// ...and sort it.
sort(bi.begin(), bi.end(), lSorter);
// Now we can write the sorted keys
vector<BibTeXInfo const *>::const_iterator bit = bi.begin();
vector<BibTeXInfo const *>::const_iterator ben = bi.end();
for (; bit != ben; ++bit)
cited_entries_.push_back((*bit)->key());
}
void BiblioInfo::makeCitationLabels(Buffer const & buf)
{
collectCitedEntries(buf);
CiteEngineType const engine_type = buf.params().citeEngineType();
bool const numbers = (engine_type & ENGINE_TYPE_NUMERICAL);
int keynumber = 0;
char modifier = 0;
// used to remember the last one we saw
// we'll be comparing entries to see if we need to add
// modifiers, like "1984a"
map<docstring, BibTeXInfo>::iterator last = bimap_.end();
vector<docstring>::const_iterator it = cited_entries_.begin();
vector<docstring>::const_iterator const en = cited_entries_.end();
for (; it != en; ++it) {
map<docstring, BibTeXInfo>::iterator const biit = bimap_.find(*it);
// this shouldn't happen, but...
if (biit == bimap_.end())
// ...fail gracefully, anyway.
continue;
BibTeXInfo & entry = biit->second;
if (numbers) {
docstring const num = convert<docstring>(++keynumber);
entry.setCiteNumber(num);
} else {
// The first test here is checking whether this is the first
// time through the loop. If so, then we do not have anything
// with which to compare.
if (last != bimap_.end()
&& entry.getAuthorOrEditorList() == last->second.getAuthorOrEditorList()
// we access the year via getYear() so as to get it from the xref,
// if we need to do so
&& getYear(entry.key()) == getYear(last->second.key())) {
if (modifier == 0) {
// so the last one should have been 'a'
last->second.setModifier('a');
modifier = 'b';
} else if (modifier == 'z')
modifier = 'A';
else
modifier++;
} else {
modifier = 0;
}
entry.setModifier(modifier);
// remember the last one
last = biit;
}
}
// Set the labels
it = cited_entries_.begin();
for (; it != en; ++it) {
map<docstring, BibTeXInfo>::iterator const biit = bimap_.find(*it);
// this shouldn't happen, but...
if (biit == bimap_.end())
// ...fail gracefully, anyway.
continue;
BibTeXInfo & entry = biit->second;
if (numbers) {
entry.label(entry.citeNumber());
} else {
docstring const auth = entry.getAuthorOrEditorList(&buf, false);
// we do it this way so as to access the xref, if necessary
// note that this also gives us the modifier
docstring const year = getYear(*it, buf, true);
if (!auth.empty() && !year.empty())
entry.label(auth + ' ' + year);
else
entry.label(entry.key());
}
}
}
//////////////////////////////////////////////////////////////////////
//
// CitationStyle
//
//////////////////////////////////////////////////////////////////////
CitationStyle citationStyleFromString(string const & command,
BufferParams const & params)
{
CitationStyle cs;
if (command.empty())
return cs;
string const alias = params.getCiteAlias(command);
string cmd = alias.empty() ? command : alias;
if (isUpperCase(command[0])) {
cs.forceUpperCase = true;
cmd[0] = lowercase(cmd[0]);
}
size_t const n = command.size() - 1;
if (command[n] == '*') {
cs.hasStarredVersion = true;
if (suffixIs(cmd, '*'))
cmd = cmd.substr(0, cmd.size() - 1);
}
cs.name = cmd;
return cs;
}
string citationStyleToString(const CitationStyle & cs, bool const latex)
{
string cmd = latex ? cs.cmd : cs.name;
if (cs.forceUpperCase)
cmd[0] = uppercase(cmd[0]);
if (cs.hasStarredVersion)
cmd += '*';
return cmd;
}
} // namespace lyx