MetzNet
/
dfhack
3
0
Fork 0
Code Issues Pull Requests Packages Projects Releases Wiki Activity

Merge branch 'master' of git://github.com/mizipzor/dfhack

develop
Petr Mrázek 2010-02-19 21:41:02 +01:00
parent c827cb6dfc 194bf2ddc1
commit 5cfb401d49
5 changed files with 1166 additions and 681 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

3
library/CMakeLists.txt
Unescape Escape View File

@ -19,7 +19,7 @@ md5/md5wrapper.h
tinyxml/tinystr.h
tinyxml/tinyxml.h
gopt/gopt.h
argstream/argstream.h
../shmserver/shms.h
)
@ -35,7 +35,6 @@ tinyxml/tinystr.cpp
tinyxml/tinyxml.cpp
tinyxml/tinyxmlerror.cpp
tinyxml/tinyxmlparser.cpp
gopt/gopt.c
)
SET(PROJECT_HDRS_LINUX

815
library/argstream/argstream.h
Unescape Escape View File

@ -0,0 +1,815 @@
/* Copyright (C) 2004 Xavier Décoret <Xavier.Decoret@imag.fr>
*
* argsteam 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 2 of the License, or
* (at your option) any later version.
*
* Foobar 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 Foobar; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
#ifndef ARGSTREAM_H
#define ARGSTREAM_H
#include <string>
#include <list>
#include <deque>
#include <map>
#include <stdexcept>
#include <sstream>
#include <iostream>
namespace
{
class argstream;
template<class T>
class ValueHolder;
template <typename T>
argstream& operator>> (argstream&, const ValueHolder<T>&);
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// Interface of ValueHolder<T>
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
template<class T>
class ValueHolder
{
public:
ValueHolder(char s,
const char* l,
T& b,
const char* desc,
bool mandatory);
ValueHolder(const char* l,
T& b,
const char* desc,
bool mandatory);
ValueHolder(char s,
T& b,
const char* desc,
bool mandatory);
friend argstream& operator>><>(argstream& s,const ValueHolder<T>& v);
std::string name() const;
std::string description() const;
private:
std::string shortName_;
std::string longName_;
T* value_;
T initialValue_;
std::string description_;
bool mandatory_;
};
template <class T>
inline ValueHolder<T>
parameter(char s,
const char* l,
T& b,
const char* desc="",
bool mandatory = true)
{
return ValueHolder<T>(s,l,b,desc,mandatory);
}
template <class T>
inline ValueHolder<T>
parameter(char s,
T& b,
const char* desc="",
bool mandatory = true)
{
return ValueHolder<T>(s,b,desc,mandatory);
}
template <class T>
inline ValueHolder<T>
parameter(const char* l,
T& b,
const char* desc="",
bool mandatory = true)
{
return ValueHolder<T>(l,b,desc,mandatory);
}
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// Interface of OptionHolder
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
class OptionHolder
{
public:
inline OptionHolder(char s,
const char* l,
bool& b,
const char* desc);
inline OptionHolder(const char* l,
bool& b,
const char* desc);
inline OptionHolder(char s,
bool& b,
const char* desc);
friend argstream& operator>>(argstream& s,const OptionHolder& v);
inline std::string name() const;
inline std::string description() const;
protected:
inline OptionHolder(char s,
const char* l,
const char* desc);
friend OptionHolder help(char s='h',
const char* l="help",
const char* desc="Display this help");
private:
std::string shortName_;
std::string longName_;
bool* value_;
std::string description_;
};
inline OptionHolder
option(char s,
const char* l,
bool& b,
const char* desc="")
{
return OptionHolder(s,l,b,desc);
}
inline OptionHolder
option(char s,
bool& b,
const char* desc="")
{
return OptionHolder(s,b,desc);
}
inline OptionHolder
option(const char* l,
bool& b,
const char* desc="")
{
return OptionHolder(l,b,desc);
}
inline OptionHolder
help(char s,
const char* l,
const char* desc)
{
return OptionHolder(s,l,desc);
}
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// Interface of ValuesHolder
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
template<class T,class O>
class ValuesHolder
{
public:
ValuesHolder(const O& o,
const char* desc,
int len);
friend argstream& operator>><>(argstream& s,const ValuesHolder<T,O>& v);
std::string name() const;
std::string description() const;
typedef T value_type;
private:
mutable O value_;
std::string description_;
int len_;
char letter_;
};
template<class T,class O>
inline ValuesHolder<T,O>
values(const O& o,
const char* desc="",
int len=-1)
{
return ValuesHolder<T,O>(o,desc,len);
}
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// Interface of ValueParser
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
template <class T>
class ValueParser
{
public:
inline T operator()(const std::string& s) const
{
std::istringstream is(s);
T t;
is>>t;
return t;
}
};
// We need to specialize for string otherwise parsing of a value that
// contains space (for example a string with space passed in quotes on the
// command line) would parse only the first element of the value!!!
template <>
class ValueParser<std::string>
{
public:
inline std::string operator()(const std::string& s) const
{
return s;
}
};
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// Interface of argstream
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
class argstream
{
public:
inline argstream(int argc,char** argv);
//inline argstream(const char* c);
template<class T>
friend argstream& operator>>(argstream& s,const ValueHolder<T>& v);
friend inline argstream& operator>>(argstream& s,const OptionHolder& v);
template<class T,class O>
friend argstream& operator>>(argstream& s,const ValuesHolder<T,O>& v);
inline bool helpRequested() const;
inline bool isOk() const;
inline std::string errorLog() const;
inline std::string usage() const;
inline void defaultErrorHandling(bool ignoreUnused=false) const;
static inline char uniqueLetter();
protected:
void parse(int argc,char** argv);
private:
typedef std::list<std::string>::iterator value_iterator;
typedef std::pair<std::string,std::string> help_entry;
std::string progName_;
std::map<std::string,value_iterator> options_;
std::list<std::string> values_;
bool minusActive_;
bool isOk_;
std::deque<help_entry> argHelps_;
std::string cmdLine_;
std::deque<std::string> errors_;
bool helpRequested_;
};
//************************************************************
// Implementation of ValueHolder<T>
//************************************************************
template<class T>
ValueHolder<T>::ValueHolder(char s,
const char* l,
T& v,
const char* desc,
bool mandatory)
: shortName_(1,s),
longName_(l),
value_(&v),
initialValue_(v),
description_(desc),
mandatory_(mandatory)
{
}
template<class T>
ValueHolder<T>::ValueHolder(const char* l,
T& v,
const char* desc,
bool mandatory)
: longName_(l),
value_(&v),
initialValue_(v),
description_(desc),
mandatory_(mandatory)
{
}
template<class T>
ValueHolder<T>::ValueHolder(char s,
T& v,
const char* desc,
bool mandatory)
: shortName_(1,s),
value_(&v),
initialValue_(v),
description_(desc),
mandatory_(mandatory)
{
}
template<class T>
std::string
ValueHolder<T>::name() const
{
std::ostringstream os;
if (!shortName_.empty()) os<<'-'<<shortName_;
if (!longName_.empty()) {
if (!shortName_.empty()) os<<'/';
os<<"--"<<longName_;
}
return os.str();
}
template<class T>
std::string
ValueHolder<T>::description() const
{
std::ostringstream os;
os<<description_;
if (mandatory_)
{
os<<"(mandatory)";
}
else
{
os<<"(default="<<initialValue_<<")";
}
return os.str();
}
//************************************************************
// Implementation of OptionHolder
//************************************************************
inline OptionHolder::OptionHolder(char s,
const char* l,
bool& b,
const char* desc)
: shortName_(1,s),
longName_(l),
value_(&b),
description_(desc)
{
}
inline OptionHolder::OptionHolder(const char* l,
bool& b,
const char* desc)
: longName_(l),
value_(&b),
description_(desc)
{
}
inline OptionHolder::OptionHolder(char s,
bool& b,
const char* desc)
: shortName_(1,s),
value_(&b),
description_(desc)
{
}
inline OptionHolder::OptionHolder(char s,
const char* l,
const char* desc)
: shortName_(1,s),
longName_(l),
value_(NULL),
description_(desc)
{
}
inline std::string
OptionHolder::name() const
{
std::ostringstream os;
if (!shortName_.empty()) os<<'-'<<shortName_;
if (!longName_.empty())
{
if (!shortName_.empty()) os<<'/';
os<<"--"<<longName_;
}
return os.str();
}
inline std::string
OptionHolder::description() const
{
return description_;
}
//************************************************************
// Implementation of ValuesHolder<T,O>
//************************************************************
template<class T,class O>
ValuesHolder<T,O>::ValuesHolder(const O& o,
const char* desc,
int len)
: value_(o),
description_(desc),
len_(len)
{
letter_ = argstream::uniqueLetter();
}
template <class T,class O>
std::string
ValuesHolder<T,O>::name() const
{
std::ostringstream os;
os<<letter_<<"i";
return os.str();
}
template <class T,class O>
std::string
ValuesHolder<T,O>::description() const
{
return description_;
}
//************************************************************
// Implementation of argstream
//************************************************************
inline
argstream::argstream(int argc,char** argv)
: progName_(argv[0]),
minusActive_(true),
isOk_(true)
{
parse(argc,argv);
}
//inline
// argstream::argstream(const char* c)
// : progName_(""),
// minusActive_(true),
// isOk_(true)
//{
// std::string s(c);
// // Build argc, argv from s. We must add a dummy first element for
// // progName because parse() expects it!!
// std::deque<std::string> args;
// args.push_back("");
// std::istringstream is(s);
// while (is.good())
// {
// std::string t;
// is>>t;
// args.push_back(t);
// }
// char* pargs[args.size()];
// char** p = pargs;
// for (std::deque<std::string>::const_iterator
// iter = args.begin();
// iter != args.end();++iter)
// {
// *p++ = const_cast<char*>(iter->c_str());
// }
// parse(args.size(),pargs);
//}
inline void
argstream::parse(int argc,char** argv)
{
// Run thru all arguments.
// * it has -- in front : it is a long name option, if remainder is empty,
// it is an error
// * it has - in front : it is a sequence of short name options, if
// remainder is empty, deactivates option (- will
// now be considered a char).
// * if any other char, or if option was deactivated
// : it is a value. Values are split in parameters
// (immediately follow an option) and pure values.
// Each time a value is parsed, if the previously parsed argument was an
// option, then the option is linked to the value in case of it is a
// option with parameter. The subtle point is that when several options
// are given with short names (ex: -abc equivalent to -a -b -c), the last
// parsed option is -c).
// Since we use map for option, any successive call overides the previous
// one: foo -a -b -a hello is equivalent to foo -b -a hello
// For values it is not true since we might have several times the same
// value.
value_iterator* lastOption = NULL;
for (char** a = argv,**astop=a+argc;++a!=astop;)
{
std::string s(*a);
if (minusActive_ && s[0] == '-')
{
if (s.size() > 1 && s[1] == '-')
{
if (s.size() == 2)
{
minusActive_ = false;
continue;
}
lastOption = &(options_[s.substr(2)] = values_.end());
}
else
{
if (s.size() > 1)
{
// Parse all chars, if it is a minus we have an error
for (std::string::const_iterator cter = s.begin();
++cter != s.end();)
{
if (*cter == '-')
{
isOk_ = false;
std::ostringstream os;
os<<"- in the middle of a switch "<<a;
errors_.push_back(os.str());
break;
}
lastOption = &(options_[std::string(1,*cter)] = values_.end());
}
}
else
{
isOk_ = false;
errors_.push_back("Invalid argument -");
break;
}
}
}
else
{
values_.push_back(s);
if (lastOption != NULL)
{
*lastOption = --values_.end();
}
lastOption = NULL;
}
}
#ifdef ARGSTREAM_DEBUG
for (std::map<std::string,value_iterator>::const_iterator
iter = options_.begin();iter != options_.end();++iter)
{
std::cout<<"DEBUG: option "<<iter->first;
if (iter->second != values_.end())
{
std::cout<<" -> "<<*(iter->second);
}
std::cout<<std::endl;
}
for (std::list<std::string>::const_iterator
iter = values_.begin();iter != values_.end();++iter)
{
std::cout<<"DEBUG: value "<<*iter<<std::endl;
}
#endif // ARGSTREAM_DEBUG
}
inline bool
argstream::isOk() const
{
return isOk_;
}
inline bool
argstream::helpRequested() const
{
return helpRequested_;
}
inline std::string
argstream::usage() const
{
std::ostringstream os;
os<<"usage: "<<progName_<<cmdLine_<<'\n';
unsigned int lmax = 0;
for (std::deque<help_entry>::const_iterator
iter = argHelps_.begin();iter != argHelps_.end();++iter)
{
if (lmax<iter->first.size()) lmax = iter->first.size();
}
for (std::deque<help_entry>::const_iterator
iter = argHelps_.begin();iter != argHelps_.end();++iter)
{
os<<'\t'<<iter->first<<std::string(lmax-iter->first.size(),' ')
<<" : "<<iter->second<<'\n';
}
return os.str();
}
inline std::string
argstream::errorLog() const
{
std::string s;
for(std::deque<std::string>::const_iterator iter = errors_.begin();
iter != errors_.end();++iter)
{
s += *iter;
s += '\n';
}
return s;
}
inline char
argstream::uniqueLetter()
{
static unsigned int c = 'a';
return c++;
}
template<class T>
argstream&
operator>>(argstream& s,const ValueHolder<T>& v)
{
// Search in the options if there is any such option defined either with a
// short name or a long name. If both are found, only the last one is
// used.
#ifdef ARGSTREAM_DEBUG
std::cout<<"DEBUG: searching "<<v.shortName_<<" "<<v.longName_<<std::endl;
#endif
s.argHelps_.push_back(argstream::help_entry(v.name(),v.description()));
if (v.mandatory_)
{
if (!v.shortName_.empty())
{
s.cmdLine_ += " -";
s.cmdLine_ += v.shortName_;
}
else
{
s.cmdLine_ += " --";
s.cmdLine_ += v.longName_;
}
s.cmdLine_ += " value";
}
else
{
if (!v.shortName_.empty())
{
s.cmdLine_ += " [-";
s.cmdLine_ += v.shortName_;
}
else
{
s.cmdLine_ += " [--";
s.cmdLine_ += v.longName_;
}
s.cmdLine_ += " value]";
}
std::map<std::string,argstream::value_iterator>::iterator iter =
s.options_.find(v.shortName_);
if (iter == s.options_.end())
{
iter = s.options_.find(v.longName_);
}
if (iter != s.options_.end())
{
// If we find counterpart for value holder on command line, either it
// has an associated value in which case we assign it, or it has not, in
// which case we have an error.
if (iter->second != s.values_.end())
{
#ifdef ARGSTREAM_DEBUG
std::cout<<"DEBUG: found value "<<*(iter->second)<<std::endl;
#endif
ValueParser<T> p;
*(v.value_) = p(*(iter->second));
// The option and its associated value are removed, the subtle thing
// is that someother options might have this associated value too,
// which we must invalidate.
s.values_.erase(iter->second);
// FIXME this loop seems to crash if a std::string is used as the value
//for (std::map<std::string,argstream::value_iterator>::iterator
// jter = s.options_.begin();jter != s.options_.end();++jter)
//{
// if (jter->second == iter->second)
// {
// jter->second = s.values_.end();
// }
//}
s.options_.erase(iter);
}
else
{
s.isOk_ = false;
std::ostringstream os;
os<<"No value following switch "<<iter->first
<<" on command line";
s.errors_.push_back(os.str());
}
}
else
{
if (v.mandatory_)
{
s.isOk_ = false;
std::ostringstream os;
os<<"Mandatory parameter ";
if (!v.shortName_.empty()) os<<'-'<<v.shortName_;
if (!v.longName_.empty())
{
if (!v.shortName_.empty()) os<<'/';
os<<"--"<<v.longName_;
}
os<<" missing";
s.errors_.push_back(os.str());
}
}
return s;
}
inline argstream&
operator>>(argstream& s,const OptionHolder& v)
{
// Search in the options if there is any such option defined either with a
// short name or a long name. If both are found, only the last one is
// used.
#ifdef ARGSTREAM_DEBUG
std::cout<<"DEBUG: searching "<<v.shortName_<<" "<<v.longName_<<std::endl;
#endif
s.argHelps_.push_back(argstream::help_entry(v.name(),v.description()));
{
std::string c;
if (!v.shortName_.empty())
{
c += " [-";
c += v.shortName_;
}
else
{
c += " [--";
c += v.longName_;
}
c += "]";
s.cmdLine_ = c+s.cmdLine_;
}
std::map<std::string,argstream::value_iterator>::iterator iter =
s.options_.find(v.shortName_);
if (iter == s.options_.end())
{
iter = s.options_.find(v.longName_);
}
if (iter != s.options_.end())
{
// If we find counterpart for value holder on command line then the
// option is true and if an associated value was found, it is ignored
if (v.value_ != NULL)
{
*(v.value_) = true;
}
else
{
s.helpRequested_ = true;
}
// The option only is removed
s.options_.erase(iter);
}
else
{
if (v.value_ != NULL)
{
*(v.value_) = false;
}
else
{
s.helpRequested_ = false;
}
}
return s;
}
template<class T,class O>
argstream&
operator>>(argstream& s,const ValuesHolder<T,O>& v)
{
s.argHelps_.push_back(argstream::help_entry(v.name(),v.description()));
{
std::ostringstream os;
os<<' '<<v.letter_<<'1';
switch (v.len_)
{
case -1:
os<<"...";
break;
case 1:
break;
default:
os<<"..."<<v.letter_<<v.len_;
break;
}
s.cmdLine_ += os.str();
}
std::list<std::string>::iterator first = s.values_.begin();
// We add to the iterator as much values as we can, limited to the length
// specified (if different of -1)
int n = v.len_ != -1?v.len_:s.values_.size();
while (first != s.values_.end() && n-->0)
{
// Read the value from the string *first
ValueParser<T> p;
*(v.value_++) = p(*first );
s.argHelps_.push_back(argstream::help_entry(v.name(),v.description()));
// The value we just removed was maybe "remembered" by an option so we
// remove it now.
for (std::map<std::string,argstream::value_iterator>::iterator
jter = s.options_.begin();jter != s.options_.end();++jter)
{
if (jter->second == first)
{
jter->second = s.values_.end();
}
}
++first;
}
// Check if we have enough values
if (n != 0)
{
s.isOk_ = false;
std::ostringstream os;
os<<"Expecting "<<v.len_<<" values";
s.errors_.push_back(os.str());
}
// Erase the values parsed
s.values_.erase(s.values_.begin(),first);
return s;
}
inline void
argstream::defaultErrorHandling(bool ignoreUnused) const
{
if (helpRequested_)
{
std::cout<<usage();
exit(1);
}
if (!isOk_)
{
std::cerr<<errorLog();
exit(1);
}
if (!ignoreUnused &&
(!values_.empty() || !options_.empty()))
{
std::cerr<<"Unused arguments"<<std::endl;
exit(1);
}
}
};
#endif // ARGSTREAM_H

265
library/gopt/gopt.c
Unescape Escape View File

@ -1,265 +0,0 @@
/* gopt.c version 8.1: tom.viza@gmail.com PUBLIC DOMAIN 2003-8 */
/*
I, Tom Vajzovic, am the author of this software and its documentation and
permanently abandon all copyright and other intellectual property rights in
them, including the right to be identified as the author.
I am fairly certain that this software does what the documentation says it
does, but I cannot guarantee that it does, or that it does what you think it
should, and I cannot guarantee that it will not have undesirable side effects.
You are free to use, modify and distribute this software as you please, but
you do so at your own risk. If you remove or hide this warning then you are
responsible for any problems encountered by people that you make the software
available to.
Before modifying or distributing this software I ask that you would please
read http://www.purposeful.co.uk/tfl/
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "gopt.h"
#ifdef USE_SYSEXITS
#include <sysexits.h>
#else
#define EX_OSERR EXIT_FAILURE
#define EX_USAGE EXIT_FAILURE
#endif
struct opt_spec_s {
int key;
int flags;
const char *shorts;
const char* const *longs;
};
typedef struct opt_spec_s opt_spec_t;
struct opt_s {
int key;
const char *arg;
};
typedef struct opt_s opt_t;
void *gopt_sort( int *argc, const char **argv, const void *opt_specs ){
void *opts;
{{{
const char* const *arg_p= argv + 1;
size_t opt_count= 1;
for( ; *arg_p; ++arg_p )
if( '-' == (*arg_p)[0] && (*arg_p)[1] )
if( '-' == (*arg_p)[1] )
if( (*arg_p)[2] )
++opt_count;
else
break;
else {
const opt_spec_t *opt_spec_p= (const opt_spec_t*)opt_specs;
for( ; opt_spec_p-> key; ++opt_spec_p )
if( strchr( opt_spec_p-> shorts, (*arg_p)[1] )){
opt_count+= opt_spec_p-> flags & GOPT_ARG ? 1 : strlen( (*arg_p) + 1 );
break;
}
}
opts= malloc( opt_count * sizeof(opt_t) );
}}}
{
const char **arg_p= argv + 1;
const char **next_operand= arg_p;
opt_t *next_option= (opt_t*)opts;
if( ! opts ){
perror( argv[0] );
exit( EX_OSERR );
}
for( ; *arg_p; ++arg_p )
if( '-' == (*arg_p)[0] && (*arg_p)[1] )
if( '-' == (*arg_p)[1] )
if( (*arg_p)[2] )
{{{
const opt_spec_t *opt_spec_p= (const opt_spec_t*)opt_specs;
const char* const *longs= opt_spec_p-> longs;
next_option-> key= 0;
while( *longs ){
const char *option_cp= (*arg_p) + 2;
const char *name_cp= *longs;
while( *option_cp && *option_cp == *name_cp ){
++option_cp;
++name_cp;
}
if( '=' == *option_cp || !*option_cp ){
if( *name_cp ){
if( next_option-> key ){
fprintf( stderr, "%s: --%.*s: abbreviated option is ambiguous\n", argv[0], (int)( option_cp -( (*arg_p) + 2 )), (*arg_p) + 2 );
free( opts );
exit( EX_USAGE );
}
next_option-> key= opt_spec_p-> key;
}
else {
next_option-> key= opt_spec_p-> key;
goto found_long;
}
}
if( !*++longs ){
++opt_spec_p;
if( opt_spec_p-> key )
longs= opt_spec_p-> longs;
}
}
if( ! next_option-> key ){
fprintf( stderr, "%s: --%.*s: unknown option\n", argv[0], (int)strcspn( (*arg_p) + 2, "=" ), (*arg_p) + 2 );
free( opts );
exit( EX_USAGE );
}
for( opt_spec_p= (const opt_spec_t*)opt_specs; opt_spec_p-> key != next_option-> key; ++opt_spec_p );
found_long:
if( !( opt_spec_p-> flags & GOPT_REPEAT )){
const opt_t *opt_p= (const opt_t*)opts;
for( ; opt_p != next_option; ++opt_p )
if( opt_p-> key == opt_spec_p-> key ){
fprintf( stderr, "%s: --%.*s: option may not be repeated (in any long or short form)\n", argv[0], (int)strcspn( (*arg_p) + 2, "=" ), (*arg_p) + 2 );
free( opts );
exit( EX_USAGE );
}
}
if( opt_spec_p-> flags & GOPT_ARG ){
next_option-> arg= strchr( (*arg_p) + 2, '=' ) + 1;
if( (char*)0 + 1 == next_option-> arg ){
++arg_p;
if( !*arg_p || '-' == (*arg_p)[0] && (*arg_p)[1] ){
fprintf( stderr, "%s: --%s: option requires an option argument\n", argv[0], (*(arg_p-1)) + 2 );
free( opts );
exit( EX_USAGE );
}
next_option-> arg= *arg_p;
}
}
else {
if( strchr( (*arg_p) + 2, '=' )){
fprintf( stderr, "%s: --%.*s: option may not take an option argument\n", argv[0], (int)strcspn( (*arg_p) + 2, "=" ), (*arg_p) + 2 );
free( opts );
exit( EX_USAGE );
}
next_option-> arg= NULL;
}
++next_option;
}}}
else {
for( ++arg_p; *arg_p; ++arg_p )
*next_operand++= *arg_p;
break;
}
else
{{{
const char *short_opt= (*arg_p) + 1;
for( ;*short_opt; ++short_opt ){
const opt_spec_t *opt_spec_p= (const opt_spec_t*)opt_specs;
for( ; opt_spec_p-> key; ++opt_spec_p )
if( strchr( opt_spec_p-> shorts, *short_opt )){
if( !( opt_spec_p-> flags & GOPT_REPEAT )){
const opt_t *opt_p= (const opt_t*)opts;
for( ; opt_p != next_option; ++opt_p )
if( opt_p-> key == opt_spec_p-> key ){
fprintf( stderr, "%s: -%c: option may not be repeated (in any long or short form)\n", argv[0], *short_opt );
free( opts );
exit( EX_USAGE );
}
}
next_option-> key= opt_spec_p-> key;
if( opt_spec_p-> flags & GOPT_ARG ){
if( short_opt[1] )
next_option-> arg= short_opt + 1;
else {
++arg_p;
if( !*arg_p || '-' == (*arg_p)[0] && (*arg_p)[1] ){
fprintf( stderr, "%s: -%c: option requires an option argument\n", argv[0], *short_opt );
free( opts );
exit( EX_USAGE );
}
next_option-> arg= *arg_p;
}
++next_option;
goto break_2;
}
next_option-> arg= NULL;
++next_option;
goto continue_2;
}
fprintf( stderr, "%s: -%c: unknown option\n", argv[0], *short_opt );
free( opts );
exit( EX_USAGE );
continue_2: 0;
}
break_2: 0;
}}}
else
*next_operand++= *arg_p;
next_option-> key= 0;
*next_operand= NULL;
*argc= next_operand - argv;
}
return opts;
}
size_t gopt( const void *vptr_opts, int key ){
const opt_t *opts= (const opt_t*)vptr_opts;
size_t count= 0;
for( ; opts-> key; ++opts )
count+= opts-> key == key;
return count;
}
size_t gopt_arg( const void *vptr_opts, int key, const char **arg ){
const opt_t *opts= (const opt_t*)vptr_opts;
size_t count= 0;
for( ; opts-> key; ++opts )
if( opts-> key == key ){
if( ! count )
*arg= opts-> arg;
++count;
}
return count;
}
const char *gopt_arg_i( const void *vptr_opts, int key, size_t i ){
const opt_t *opts= (const opt_t*)vptr_opts;
for( ; opts-> key; ++opts )
if( opts-> key == key ){
if( ! i )
return opts-> arg;
--i;
}
return NULL;
}
size_t gopt_args( const void *vptr_opts, int key, const char **args, size_t args_len ){
const char **args_stop= args + args_len;
const char **args_ptr= args;
const opt_t *opts= (const opt_t*)vptr_opts;
for( ; opts-> key; ++opts )
if( opts-> key == key ){
if( args_stop == args_ptr )
return args_len + gopt( opts, key );
*args_ptr++= opts-> arg;
}
if( args_stop != args_ptr )
*args_ptr= NULL;
return args_ptr - args;
}
void gopt_free( void *vptr_opts ){
free( vptr_opts );
}

60
library/gopt/gopt.h
Unescape Escape View File

@ -1,60 +0,0 @@
/* gopt.h version 8.1: tom.viza@gmail.com PUBLIC DOMAIN 2003-8 */
/*
I, Tom Vajzovic, am the author of this software and its documentation and
permanently abandon all copyright and other intellectual property rights in
them, including the right to be identified as the author.
I am fairly certain that this software does what the documentation says it
does, but I cannot guarantee that it does, or that it does what you think it
should, and I cannot guarantee that it will not have undesirable side effects.
You are free to use, modify and distribute this software as you please, but
you do so at your own risk. If you remove or hide this warning then you are
responsible for any problems encountered by people that you make the software
available to.
Before modifying or distributing this software I ask that you would please
read http://www.purposeful.co.uk/tfl/
*/
#ifndef GOPT_H_INCLUDED
#define GOPT_H_INCLUDED
#define GOPT_ONCE 0
#define GOPT_REPEAT 1
#define GOPT_NOARG 0
#define GOPT_ARG 2
#define gopt_start(...) (const void*)( const struct { int k; int f; const char *s; const char*const*l; }[]){ __VA_ARGS__, {0}}
#define gopt_option(k,f,s,l) { k, f, s, l }
#define gopt_shorts( ... ) (const char*)(const char[]){ __VA_ARGS__, 0 }
#define gopt_longs( ... ) (const char**)(const char*[]){ __VA_ARGS__, NULL }
void *gopt_sort( int *argc, const char **argv, const void *opt_specs );
/* returns a pointer for use in the following calls
* prints to stderr and call exit() on error
*/
size_t gopt( const void *opts, int key );
/* returns the number of times the option was specified
* which will be 0 or 1 unless GOPT_REPEAT was used
*/
size_t gopt_arg( const void *opts, int key, const char **arg );
/* returns the number of times the option was specified
* writes a pointer to the option argument from the first (or only) occurance to *arg
*/
const char *gopt_arg_i( const void *opts, int key, size_t i );
/* returns a pointer to the ith (starting at zero) occurance
* of the option, or NULL if it was not specified that many times
*/
size_t gopt_args( const void *opts, int key, const char **args, size_t args_len );
/* returns the number of times the option was specified
* writes pointers to the option arguments in the order of occurance to args[].
* writes at most args_len pointers
* if the return value is less than args_len, also writes a null pointer
*/
void gopt_free( void *opts );
/* releases memory allocated in the corresponding call to gopt_sort()
* opts can no longer be used
*/
#endif /* GOPT_H_INCLUDED */

704
tools/digger.cpp
Unescape Escape View File

@ -1,354 +1,350 @@
// digger.cpp
// Usage: Call with a list of TileClass ids separated by a space,
// every (visible) tile on the map with that id will be designated for digging.
// NOTE currently only works with trees
// TODO add a sort of "sub-target" to dig() to make it able to designate stone as well
// TODO add proper cli
// TODO add interactive text based menu
// TODO add ability to mark num closest to cursor
#include <iostream>
#include <integers.h>
#include <vector>
#include <list>
#include <cstdlib>
#include <algorithm>
#include <assert.h>
using namespace std;
#include <DFTypes.h>
#include <DFTileTypes.h>
#include <DFHackAPI.h>
int vec_count(vector<uint16_t>& vec, uint16_t t)
{
int count = 0;
for (uint32_t i = 0; i < vec.size(); ++i)
{
if (vec[i] == t)
++count;
}
return count;
}
//// manhattan distance
//int source_distance(int sx, int sy, int sz,
// int x, int y, int z, int i)
//{
// // TODO changing x and y seems to be optimized away (?)
// cout << x << " " << i << " " << i%16 << " " << x+(i%16) << endl;
//
// // handle the fact that x,y,z refers to a 16x16 grid
// //x += i%16;
// //y += i/16;
// int dx = i%16;
// int dy = i/16;
// //x *= 16;
// //y *= 16;
// //x += dx;
// //y += dy;
// return abs(sx-(x+(i%16)))+abs(sy-(y+(i/16)))+abs(sz-z);
//}
int manhattan_distance(int x, int y, int z, int xx, int yy, int zz)
{
return abs(x-xx)+abs(y-yy)+abs(z-zz);
}
struct DigTarget
{
//public:
DigTarget() :
source_distance(0),
grid_x(0), grid_y(0),
local_x(0), local_y(0),
real_x(0), real_y(0), z(0)
{
}
DigTarget(
int realx, int realy, int _z,
int sourcex, int sourcey, int sourcez) :
//grid_x(realx/16), grid_y(realy/16),
//local_x(realx%16), local_y(realy%16),
real_x(realx), real_y(realy), z(_z)
{
grid_x = realx/16;
grid_y = realy/16;
local_x = realx%16;
local_y = realy%16;
source_distance = manhattan_distance(
real_x, real_y, z,
sourcex, sourcey, sourcez);
}
DigTarget(
int gridx, int gridy, int _z,
int localx, int localy,
int sourcex, int sourcey, int sourcez) :
//source_distance(manhattan_distance(
// realx, realy, realz,
// sourcex, sourcey, sourcez)),
grid_x(gridx), grid_y(gridy),
local_x(localx), local_y(localy),
z(_z)
//real_x(realx), real_y(realy), real_z(realz)
{
real_x = (grid_x*16)+local_x;
real_y = (grid_y*16)+local_y;
source_distance = manhattan_distance(
real_x, real_y, z,
sourcex, sourcey, sourcez);
}
int source_distance; // the distance to the source coords, used for sorting
//int source_distance() const { return _source_distance; }
int grid_x, grid_y;
int local_x, local_y;
int real_x, real_y;
int z;
//int index;
//const bool valid;
bool operator<(const DigTarget& o) const { return source_distance < o.source_distance; }
//private:
// int source_x, source_y, source_z;
// int _source_distance;
};
int dig(DFHack::API& DF,
vector<uint16_t>& targets,
int num = -1,
const int x_source = 0,
const int y_source = 0,
const int z_source = 0)
{
if (num == 0)
return 0; // max limit of 0, nothing to do
uint32_t x_max,y_max,z_max;
DFHack::t_designation designations[16][16];
uint16_t tiles[16][16];
//uint32_t count = 0;
DF.getSize(x_max,y_max,z_max);
// every tile found, will later be sorted by distance to source
vector<DigTarget> candidates;
cout << "============================" << endl;
cout << "source is " << x_source << " " << y_source << " " << z_source << endl;
//int debugmaxx = 0;
//int debugmaxy = 0;
// walk the map
for(uint32_t x = 0; x < x_max; x++)
{
for(uint32_t y = 0; y < y_max; y++)
{
for(uint32_t z = 0; z < z_max; z++)
{
if (z != z_source)
continue; // hack to cut down on targets
if(DF.isValidBlock(x,y,z))
{
// read block designations and tiletype
DF.ReadDesignations(x,y,z, (uint32_t *) designations);
DF.ReadTileTypes(x,y,z, (uint16_t *) tiles);
// search all tiles for dig targets:
// visible, not yet marked for dig and matching tile type
for(uint32_t lx = 0; lx < 16; lx++)
{
for(uint32_t ly = 0; ly < 16; ly++)
{
if (designations[lx][ly].bits.hidden == 0 &&
designations[lx][ly].bits.dig == 0 &&
vec_count(targets, DFHack::tileTypeTable[tiles[lx][ly]].c) > 0)
{
//cout << "target found at: ";
//cout << x << "," << y << "," << z << "," << i << endl;
//designations[i].bits.dig = DFHack::designation_default;
//++count;
//int realx = (x*16)+lx;
//int realy = (y*16)+ly;
candidates.push_back(DigTarget(
x, y, z,
lx, ly,
x_source, y_source, z_source));
//cout << "target found at " << world_x << " " << world_y << " " << z;
//cout << ", " << dt->source_distance << " tiles to source" << endl;
//if (world_x > debugmaxx)
// debugmaxx = world_x;
//if (world_y > debugmaxy)
// debugmaxy = world_y;
}
} // local y
} // local x
}
}
}
}
// TODO the following routine doesnt check if the tile is already marked for digging
// if we found more tiles than was requested, sort them by distance to source,
// keep the front 'num' elements and drop the rest
if (num != -1 && candidates.size() > (unsigned int)num)
{
sort(candidates.begin(), candidates.end());
candidates.resize(num);
}
num = candidates.size();
cout << "============================" << endl;
cout << "source is " << x_source << " " << y_source << " " << z_source << endl;
// mark the tiles for actual digging
for (vector<DigTarget>::const_iterator i = candidates.begin(); i != candidates.end(); ++i)
{
//int grid_x = (*i).x/16;
//int grid_y = (*i).y/16;
//int z = (*i).z;
//int local_x = (*i).x%grid_x;
//int local_y = (*i).y%grid_y;
cout << "designating at " << (*i).real_x << " " << (*i).real_y << " " << (*i).z;
cout << ", " << (*i).source_distance << " tiles to source" << endl;
// TODO this could probably be made much better, theres a big chance the trees are on the same grid
// TODO move into function in DigTarget
DF.ReadDesignations((*i).grid_x, (*i).grid_y, (*i).z, (uint32_t *) designations);
designations[(*i).local_x][(*i).local_y].bits.dig = DFHack::designation_default;
DF.WriteDesignations((*i).grid_x, (*i).grid_y, (*i).z, (uint32_t *) designations);
}
//cout << debugmaxx << " " << debugmaxy << endl;
return num;
}
void test()
{
{
DigTarget dt;
//assert(!dt.valid);
}
{
DigTarget dt(
20, 35, 16,
10, 12, 14);
assert(dt.grid_x == 1);
assert(dt.grid_y == 2);
assert(dt.local_x == 4);
assert(dt.local_y == 3);
assert(dt.real_x == 20);
assert(dt.real_y == 35);
assert(dt.z == 16);
assert(dt.source_distance == 35);
//assert(dt.valid);
}
{
DigTarget dt(
2, 4, 16,
5, 10,
10, 12, 14);
assert(dt.grid_x == 2);
assert(dt.grid_y == 4);
assert(dt.local_x == 5);
assert(dt.local_y == 10);
assert(dt.real_x == 37);
assert(dt.real_y == 74);
assert(dt.z == 16);
assert(dt.source_distance == 91);
//assert(dt.valid);
}
//{ // sorting
// DigTarget a(
// 20, 35, 16,
// 10, 12, 14);
// DigTarget b(
// 2, 4, 16,
// 5, 10,
// 10, 12, 14);
// vector<DigTarget> v;
// v.push_back(b);
// v.push_back(a);
// sort(v.begin(), v.end());
// assert(*(v.begin()) == a);
//}
}
int main (int argc, const char* argv[])
{
test();
vector<uint16_t> targets;
for (int i = 1; i < argc; ++i)
{
targets.push_back(atoi(argv[i]));
}
if (targets.size() == 0)
{
cout << "Usage: Call with a list of TileClass ids separated by a space,\n";
cout << "every (visible) tile on the map with that id will be designated for digging.\n\n";
}
else
{
DFHack::API DF("Memory.xml");
if(!DF.Attach())
{
cerr << "DF not found" << endl;
return 1;
}
DF.InitMap();
// TODO hack until we have a proper cli to specify origin
int x_source = 134, y_source = 134, z_source = 16; // my wagon starts here; cut trees close to wagon
//DF.InitViewAndCursor();
//if (!DF.getViewCoords(x_source, y_source, z_source))
//{
// cerr << "Enable cursor" << endl;
// return 1;
//}
int count = dig(DF, targets, 10, x_source, y_source, z_source); // <-- important part
cout << count << " targets designated" << endl;
DF.Detach();
}
#ifndef LINUX_BUILD
cout << "Done. Press any key to continue" << endl;
cin.ignore();
#endif
return 0;
}
// digger.cpp
// Usage: Call with a list of TileClass ids separated by a space,
// every (visible) tile on the map with that id will be designated for digging.
// NOTE currently only works with trees
// TODO add a sort of "sub-target" to dig() to make it able to designate stone as well
// TODO add proper cli
// TODO add interactive text based menu
// TODO add ability to mark num closest to cursor
#include <iostream>
#include <integers.h>
#include <vector>
#include <list>
#include <cstdlib>
#include <algorithm>
#include <assert.h>
using namespace std;
#include <DFTypes.h>
#include <DFTileTypes.h>
#include <DFHackAPI.h>
#include <argstream/argstream.h>
// counts the occurances of a certain element in a vector
int vec_count(vector<uint16_t>& vec, uint16_t t)
{
int count = 0;
for (uint32_t i = 0; i < vec.size(); ++i)
{
if (vec[i] == t)
++count;
}
return count;
}
// splits a string on a certain char
//
// src is the string to split
// delim is the delimiter to split the string around
// tokens is filled with every occurance between delims
void string_split(vector<string>& tokens, const std::string& src, const std::string& delim)
{
std::string::size_type start = 0;
std::string::size_type end;
while (true)
{
end = src.find(delim, start);
tokens.push_back(src.substr(start, end - start));
if (end == std::string::npos) // last token handled
break;
start = end + delim.size(); // skip next delim
}
}
void parse_int_csv(vector<uint16_t>& targets, const std::string& src)
{
std::string::size_type start = 0;
std::string::size_type end;
while (true)
{
end = src.find(",", start);
targets.push_back(atoi(src.substr(start, end - start).c_str()));
if (end == std::string::npos) // last token handled
break;
start = end + 1; // skip next delim
}
}
// calculates the manhattan distance between two coords
int manhattan_distance(int x, int y, int z, int xx, int yy, int zz)
{
return abs(x-xx)+abs(y-yy)+abs(z-zz);
}
struct DigTarget
{
DigTarget() :
source_distance(0),
grid_x(0), grid_y(0),
local_x(0), local_y(0),
real_x(0), real_y(0), z(0)
{
}
DigTarget(
int realx, int realy, int _z,
int sourcex, int sourcey, int sourcez) :
real_x(realx), real_y(realy), z(_z)
{
grid_x = realx/16;
grid_y = realy/16;
local_x = realx%16;
local_y = realy%16;
source_distance = manhattan_distance(
real_x, real_y, z,
sourcex, sourcey, sourcez);
}
DigTarget(
int gridx, int gridy, int _z,
int localx, int localy,
int sourcex, int sourcey, int sourcez) :
grid_x(gridx), grid_y(gridy),
local_x(localx), local_y(localy),
z(_z)
{
real_x = (grid_x*16)+local_x;
real_y = (grid_y*16)+local_y;
source_distance = manhattan_distance(
real_x, real_y, z,
sourcex, sourcey, sourcez);
}
int source_distance; // the distance to the source coords, used for sorting
int grid_x, grid_y;
int local_x, local_y;
int real_x, real_y;
int z;
bool operator<(const DigTarget& o) const { return source_distance < o.source_distance; }
};
int dig(DFHack::API& DF,
vector<uint16_t>& targets,
int num = -1,
const int x_source = 0,
const int y_source = 0,
const int z_source = 0)
{
if (num == 0)
return 0; // max limit of 0, nothing to do
uint32_t x_max,y_max,z_max;
DFHack::t_designation designations[16][16];
uint16_t tiles[16][16];
DF.getSize(x_max,y_max,z_max);
// every tile found, will later be sorted by distance to source
vector<DigTarget> candidates;
//cout << "============================" << endl;
//cout << "source is " << x_source << " " << y_source << " " << z_source << endl;
// walk the map
for(uint32_t x = 0; x < x_max; x++)
{
for(uint32_t y = 0; y < y_max; y++)
{
for(uint32_t z = 0; z < z_max; z++)
{
if(DF.isValidBlock(x,y,z))
{
// read block designations and tiletype
DF.ReadDesignations(x,y,z, (uint32_t *) designations);
DF.ReadTileTypes(x,y,z, (uint16_t *) tiles);
// search all tiles for dig targets:
// visible, not yet marked for dig and matching tile type
for(uint32_t lx = 0; lx < 16; lx++)
{
for(uint32_t ly = 0; ly < 16; ly++)
{
if (designations[lx][ly].bits.hidden == 0 &&
designations[lx][ly].bits.dig == 0 &&
vec_count(targets, DFHack::tileTypeTable[tiles[lx][ly]].c) > 0)
{
candidates.push_back(DigTarget(
x, y, z,
lx, ly,
x_source, y_source, z_source));
//cout << "target found at " << world_x << " " << world_y << " " << z;
//cout << ", " << dt->source_distance << " tiles to source" << endl;
}
} // local y
} // local x
}
}
}
}
// if we found more tiles than was requested, sort them by distance to source,
// keep the front 'num' elements and drop the rest
if (num != -1 && candidates.size() > (unsigned int)num)
{
sort(candidates.begin(), candidates.end());
candidates.resize(num);
}
num = candidates.size();
//cout << "============================" << endl;
//cout << "source is " << x_source << " " << y_source << " " << z_source << endl;
// mark the tiles for actual digging
for (vector<DigTarget>::const_iterator i = candidates.begin(); i != candidates.end(); ++i)
{
//cout << "designating at " << (*i).real_x << " " << (*i).real_y << " " << (*i).z;
//cout << ", " << (*i).source_distance << " tiles to source" << endl;
// TODO this could probably be made much better, theres a big chance the trees are on the same grid
// TODO move into function in DigTarget
DF.ReadDesignations((*i).grid_x, (*i).grid_y, (*i).z, (uint32_t *) designations);
designations[(*i).local_x][(*i).local_y].bits.dig = DFHack::designation_default;
DF.WriteDesignations((*i).grid_x, (*i).grid_y, (*i).z, (uint32_t *) designations);
}
return num;
}
void test()
{
//////////////////////////
// DigTarget
{
DigTarget dt(
20, 35, 16,
10, 12, 14);
assert(dt.grid_x == 1);
assert(dt.grid_y == 2);
assert(dt.local_x == 4);
assert(dt.local_y == 3);
assert(dt.real_x == 20);
assert(dt.real_y == 35);
assert(dt.z == 16);
assert(dt.source_distance == 35);
}
{
DigTarget dt(
2, 4, 16,
5, 10,
10, 12, 14);
assert(dt.grid_x == 2);
assert(dt.grid_y == 4);
assert(dt.local_x == 5);
assert(dt.local_y == 10);
assert(dt.real_x == 37);
assert(dt.real_y == 74);
assert(dt.z == 16);
assert(dt.source_distance == 91);
}
//////////////////////////
// string splitter
{
vector<string> tokens;
string src = "10,9,11";
string delim = ",";
string_split(tokens, src, delim);
assert(tokens.size() == 3);
assert(tokens[0] == "10");
assert(tokens[1] == "9");
assert(tokens[2] == "11");
}
{
vector<string> tokens;
string src = "10";
string delim = ",";
string_split(tokens, src, delim);
assert(tokens.size() == 1);
assert(tokens[0] == "10");
}
{
vector<uint16_t> targets;
parse_int_csv(targets, "9,10");
assert(targets[0] == 9);
assert(targets[1] == 10);
}
}
int main (int argc, char** argv)
{
test();
// Command line options
string s_targets;
string s_origin = "0,0,0";
bool verbose;
int max;
argstream as(argc,argv);
as >>option('v',"verbose",verbose,"Active verbose mode") // TODO handle verbose
>>parameter('o',"origin",s_origin,"Close to where we should designate targets, format: x,y,z")
>>parameter('t',"targets",s_targets,"What kinds of tile we should designate, format: type1,type2")
>>parameter('m',"max",max,"The maximum limit of designated targets")
>>help();
// handle some commands
vector<uint16_t> targets;
parse_int_csv(targets, s_targets);
vector<uint16_t> origin;
parse_int_csv(origin, s_origin);
// sane check
if (!as.isOk())
{
cout << as.errorLog();
}
else if (targets.size() == 0 || origin.size() != 3)
{
//cout << "Usage: Call with a list of TileClass ids separated by a space,\n";
//cout << "every (visible) tile on the map with that id will be designated for digging.\n\n";
cout << as.usage();
}
else
{
DFHack::API DF("Memory.xml");
if(!DF.Attach())
{
cerr << "DF not found" << endl;
return 1;
}
DF.InitMap();
// TODO hack until we have a proper cli to specify origin
int x_source = 134, y_source = 134, z_source = 16; // my wagon starts here; cut trees close to wagon
//DF.InitViewAndCursor();
//if (!DF.getViewCoords(x_source, y_source, z_source))
//{
// cerr << "Enable cursor" << endl;
// return 1;
//}
int count = dig(DF, targets, 10, origin[0],origin[1],origin[2]); // <-- important part
cout << count << " targets designated" << endl;
DF.Detach();
}
#ifndef LINUX_BUILD
cout << "Done. Press any key to continue" << endl;
cin.ignore();
#endif
return 0;
}