dfhack/library/modules/Materials.cpp

/*
www.sourceforge.net/projects/dfhack
Copyright (c) 2009 Petr Mrázek (peterix), Kenneth Ferland (Impaler[WrG]), dorf

This software is provided 'as-is', without any express or implied
warranty. In no event will the authors be held liable for any
damages arising from the use of this software.

Permission is granted to anyone to use this software for any
purpose, including commercial applications, and to alter it and
redistribute it freely, subject to the following restrictions:

1. The origin of this software must not be misrepresented; you must
not claim that you wrote the original software. If you use this
software in a product, an acknowledgment in the product documentation
would be appreciated but is not required.

2. Altered source versions must be plainly marked as such, and
must not be misrepresented as being the original software.

3. This notice may not be removed or altered from any source
distribution.
*/

#include "Internal.h"
#include "ContextShared.h"
#include "dfhack/DFTypes.h"
#include "dfhack/modules/Materials.h"
#include "dfhack/VersionInfo.h"
#include "dfhack/DFProcess.h"
#include "dfhack/DFVector.h"
#include <dfhack/DFError.h>
#include "ModuleFactory.h"

using namespace DFHack;

Module* DFHack::createMaterials(DFContextShared * d)
{
    return new Materials(d);
}

class Materials::Private
{
    public:
    DFContextShared *d;
    Process * owner;
    OffsetGroup * OG_Materials;
    uint32_t vector_inorganic;
    uint32_t vector_organic_all;
    uint32_t vector_organic_plants;
    uint32_t vector_organic_trees;
    uint32_t vector_races;
    uint32_t vector_other;
    /*
    bool Inited;
    bool Started;
    */
};

Materials::Materials(DFContextShared * d_)
{
    d = new Private;
    d->d = d_;
    d->owner = d_->p;
    OffsetGroup *OG_Materials = d->OG_Materials = d->owner->getDescriptor()->getGroup("Materials");
    {
        d->vector_inorganic = OG_Materials->getAddress("inorganics");
        d->vector_organic_all = OG_Materials->getAddress ("organics_all");
        d->vector_organic_plants = OG_Materials->getAddress ("organics_plants");
        d->vector_organic_trees = OG_Materials->getAddress ("organics_trees");
        d->vector_races = OG_Materials->getAddress("creature_type_vector");
    }
}
Materials::~Materials()
{
    delete d;
}

bool Materials::Finish()
{
    /*
    inorganic.clear();
    organic.clear();
    tree.clear();
    plant.clear();
    race.clear();
    raceEx.clear();
    color.clear();
    other.clear();
    alldesc.clear();
    */
    return true;
}

/*
    {
LABEL_53:
      if ( a1
        || (signed int)a2 < 0
        || a2 >= (inorg_end - inorg_start) >> 2
        || (v13 = *(_DWORD *)(inorg_start + 4 * a2), !v13) )
      {
        switch ( a1 )
        {
          case 1:
            sub_40FDD0("AMBER");
            break;
          case 2:
            sub_40FDD0("CORAL");
            break;
          case 3:
            sub_40FDD0("GLASS_GREEN");
            break;
          case 4:
            sub_40FDD0("GLASS_CLEAR");
            break;
          case 5:
            sub_40FDD0("GLASS_CRYSTAL");
            break;
          case 6:
            sub_40FDD0("WATER");
            break;
          case 7:
            sub_40FDD0("COAL");
            break;
          case 8:
            sub_40FDD0("POTASH");
            break;
          case 9:
            sub_40FDD0("ASH");
            break;
          case 10:
            sub_40FDD0("PEARLASH");
            break;
          case 11:
            sub_40FDD0("LYE");
            break;
          case 12:
            sub_40FDD0("MUD");
            break;
          case 13:
            sub_40FDD0("VOMIT");
            break;
          case 14:
            sub_40FDD0("SALT");
            break;
          case 15:
            sub_40FDD0("FILTH_B");
            break;
          case 16:
            sub_40FDD0("FILTH_Y");
            break;
          case 17:
            sub_40FDD0("UNKNOWN_SUBSTANCE");
            break;
          case 18:
            sub_40FDD0("GRIME");
            break;
          default:
            sub_40A070("NONE", 4u);
            break;
        }
        result = sub_40A070("NONE", 4u);
        if ( a1 == 7 )
        {
          result = a2;
          if ( a2 )
          {
            if ( a2 == 1 )
              result = sub_40A070("CHARCOAL", 8u);
          }
          else
          {
            result = sub_40A070("COKE", 4u);
          }
        }
      }
      else
      {
        sub_40A070("INORGANIC", 9u);
        result = sub_409CA0(v13, 0, -1);
      }
    }

*/

/*
bool API::ReadInorganicMaterials (vector<t_matgloss> & inorganic)
{
    Process *p = d->owner;
    memory_info * minfo = p->getDescriptor();
    int matgloss_address = minfo->getAddress ("mat_inorganics");
    int matgloss_colors = minfo->getOffset ("material_color");
    int matgloss_stone_name_offset = minfo->getOffset("matgloss_stone_name");

    DfVector <uint32_t> p_matgloss (p, matgloss_address);

    uint32_t size = p_matgloss.getSize();
    inorganic.resize (0);
    inorganic.reserve (size);
    for (uint32_t i = 0; i < size;i++)
    {
        // read the matgloss pointer from the vector into temp
        uint32_t temp = p_matgloss[i];
        // read the string pointed at by
        t_matgloss mat;
        //cout << temp << endl;
        //fill_char_buf(mat.id, d->p->readSTLString(temp)); // reads a C string given an address
        p->readSTLString (temp, mat.id, 128);

        p->readSTLString (temp+matgloss_stone_name_offset, mat.name, 128);
        mat.fore = (uint8_t) p->readWord (temp + matgloss_colors);
        mat.back = (uint8_t) p->readWord (temp + matgloss_colors + 2);
        mat.bright = (uint8_t) p->readWord (temp + matgloss_colors + 4);

        inorganic.push_back (mat);
    }
    return true;
}
*/



// good for now
inline bool ReadNamesOnly(Process* p, uint32_t address, vector<t_matgloss> & names)
{
    DfVector <uint32_t> p_matgloss (p, address);
    uint32_t size = p_matgloss.size();
    names.clear();
    names.reserve (size);
    for (uint32_t i = 0; i < size;i++)
    {
        t_matgloss mat;
        p->readSTLString (p_matgloss[i], mat.id, 128);
        names.push_back(mat);
    }
    return true;
}

bool Materials::ReadInorganicMaterials (void)
{
    Process * p = d->owner;
    DfVector <uint32_t> p_matgloss (p, d->vector_inorganic);
    uint32_t size = p_matgloss.size();
    inorganic.clear();
    inorganic.reserve (size);
    for (uint32_t i = 0; i < size;i++)
    {
        t_matgloss mat;

        p->readSTLString (p_matgloss[i], mat.id, 128);
        //p->readSTLString (p_matgloss[i] + mat_name, mat.name, 128);
        mat.name[0] = 0;
        mat.fore = 0;
        mat.back = 0;
        mat.bright = 0;
        inorganic.push_back(mat);
    }
    return true;
}

bool Materials::ReadOrganicMaterials (void)
{
    return ReadNamesOnly(d->owner, d->vector_organic_all, organic );
}

bool Materials::ReadWoodMaterials (void)
{
    return ReadNamesOnly(d->owner, d->vector_organic_trees, tree );
}

bool Materials::ReadPlantMaterials (void)
{
    return ReadNamesOnly(d->owner, d->vector_organic_plants, plant );
}

bool Materials::ReadCreatureTypes (void)
{
    return ReadNamesOnly(d->owner, d->vector_races, race );
    return true;
}

bool Materials::ReadOthers(void)
{
    Process * p = d->owner;
    uint32_t matBase = d->OG_Materials->getAddress ("other");
    uint32_t i = 0;
    uint32_t ptr;

    other.clear();

    while(1)
    {
        t_matglossOther mat;
        ptr = p->readDWord(matBase + i*4);
        if(ptr==0)
            break;
        p->readSTLString(ptr, mat.rawname, sizeof(mat.rawname));
        other.push_back(mat);
        i++;
    }
    return true;
}

bool Materials::ReadDescriptorColors (void)
{
    Process * p = d->owner;
    OffsetGroup * OG_Descriptors = p->getDescriptor()->getGroup("Materials")->getGroup("descriptors");
    DfVector <uint32_t> p_colors (p, OG_Descriptors->getAddress ("colors_vector"));
    uint32_t size = p_colors.size();

    color.clear();
    if(size == 0)
        return false;
    color.reserve(size);
    for (uint32_t i = 0; i < size;i++)
    {
        t_descriptor_color col;
        p->readSTLString (p_colors[i] + OG_Descriptors->getOffset ("rawname"), col.id, 128);
        p->readSTLString (p_colors[i] + OG_Descriptors->getOffset ("name"), col.name, 128);
        col.r = p->readFloat( p_colors[i] + OG_Descriptors->getOffset ("color_r") );
        col.v = p->readFloat( p_colors[i] + OG_Descriptors->getOffset ("color_v") );
        col.b = p->readFloat( p_colors[i] + OG_Descriptors->getOffset ("color_b") );
        color.push_back(col);
    }
    return ReadNamesOnly(d->owner, OG_Descriptors->getAddress ("all_colors_vector"), alldesc );
    return true;
}

bool Materials::ReadCreatureTypesEx (void)
{
    Process *p = d->owner;
    VersionInfo *mem = p->getDescriptor();
    OffsetGroup * OG_string = mem->getGroup("string");
    uint32_t sizeof_string = OG_string->getHexValue ("sizeof");

    OffsetGroup * OG_Mats = mem->getGroup("Materials");
    DfVector <uint32_t> p_races (p, OG_Mats->getAddress ("creature_type_vector"));

    OffsetGroup * OG_Creature = OG_Mats->getGroup("creature");
        uint32_t castes_vector_offset = OG_Creature->getOffset ("caste_vector");
        uint32_t extract_vector_offset = OG_Creature->getOffset ("extract_vector");
        uint32_t tile_offset = OG_Creature->getOffset ("tile");
        uint32_t tile_color_offset = OG_Creature->getOffset ("tile_color");

    bool have_advanced = false;
    uint32_t caste_colormod_offset;
    uint32_t caste_attributes_offset;
    uint32_t caste_bodypart_offset;
    uint32_t bodypart_id_offset;
    uint32_t bodypart_category_offset;
    uint32_t bodypart_layers_offset;
    uint32_t bodypart_singular_offset;
    uint32_t bodypart_plural_offset;
    uint32_t color_modifier_part_offset;
    uint32_t color_modifier_startdate_offset;
    uint32_t color_modifier_enddate_offset;
    try
    {
        OffsetGroup * OG_Caste = OG_Creature->getGroup("caste");
            caste_colormod_offset = OG_Caste->getOffset ("color_modifiers");
            caste_attributes_offset = OG_Caste->getOffset ("attributes");
            caste_bodypart_offset = OG_Caste->getOffset ("bodypart_vector");
        OffsetGroup * OG_CasteBodyparts = OG_Creature->getGroup("caste_bodyparts");
            bodypart_id_offset = OG_CasteBodyparts->getOffset ("id");
            bodypart_category_offset = OG_CasteBodyparts->getOffset ("category");
            bodypart_layers_offset = OG_CasteBodyparts->getOffset ("layers_vector"); // unused
            bodypart_singular_offset = OG_CasteBodyparts->getOffset ("singular_vector"); // unused
            bodypart_plural_offset = OG_CasteBodyparts->getOffset ("plural_vector"); // unused
        OffsetGroup * OG_CasteColorMods = OG_Creature->getGroup("caste_color_mods");
            color_modifier_part_offset = OG_CasteColorMods->getOffset ("part");
            color_modifier_startdate_offset = OG_CasteColorMods->getOffset ("startdate");
            color_modifier_enddate_offset = OG_CasteColorMods->getOffset ("enddate");
        have_advanced = true;
    }
    catch (Error::All &){};

    uint32_t size = p_races.size();
    uint32_t sizecas = 0;
    uint32_t sizecolormod;
    uint32_t sizecolorlist;
    uint32_t sizebp;
    raceEx.clear();
    raceEx.reserve (size);
    for (uint32_t i = 0; i < size;i++)
    {
        t_creaturetype mat;
        // FROM race READ
        // std::string rawname AT 0,
        // char tile_character AT tile_offset,
        // word tilecolor.fore : tile_color_offset,
        // word tilecolor.back : tile_color_offset + 2,
        // word tilecolor.bright : tile_color_offset + 4
        p->readSTLString (p_races[i], mat.rawname, sizeof(mat.rawname));
        mat.tile_character = p->readByte( p_races[i] + tile_offset );
        mat.tilecolor.fore = p->readWord( p_races[i] + tile_color_offset );
        mat.tilecolor.back = p->readWord( p_races[i] + tile_color_offset + 2 );
        mat.tilecolor.bright = p->readWord( p_races[i] + tile_color_offset + 4 );

        DfVector <uint32_t> p_castes(p, p_races[i] + castes_vector_offset);
        sizecas = p_castes.size();
        for (uint32_t j = 0; j < sizecas;j++)
        {
            /* caste name */
            t_creaturecaste caste;
            uint32_t caste_start = p_castes[j];
            p->readSTLString (caste_start, caste.rawname, sizeof(caste.rawname));
            p->readSTLString (caste_start + sizeof_string, caste.singular, sizeof(caste.singular));
            p->readSTLString (caste_start + 2 * sizeof_string, caste.plural, sizeof(caste.plural));
            p->readSTLString (caste_start + 3 * sizeof_string, caste.adjective, sizeof(caste.adjective));
            //cout << "Caste " << caste.rawname << " " << caste.singular << ": 0x" << hex << caste_start << endl;
            if(have_advanced)
            {
                /* color mod reading */
                // Caste + offset > color mod vector
                DfVector <uint32_t> p_colormod(p, caste_start + caste_colormod_offset);
                sizecolormod = p_colormod.size();
                caste.ColorModifier.resize(sizecolormod);
                for(uint32_t k = 0; k < sizecolormod;k++)
                {
                    // color mod [0] -> color list
                    DfVector <uint32_t> p_colorlist(p, p_colormod[k]);
                    sizecolorlist = p_colorlist.size();
                    caste.ColorModifier[k].colorlist.resize(sizecolorlist);
                    for(uint32_t l = 0; l < sizecolorlist; l++)
                        caste.ColorModifier[k].colorlist[l] = p_colorlist[l];
                    // color mod [color_modifier_part_offset] = string part
                    p->readSTLString( p_colormod[k] + color_modifier_part_offset, caste.ColorModifier[k].part, sizeof(caste.ColorModifier[k].part));
                    caste.ColorModifier[k].startdate = p->readDWord( p_colormod[k] + color_modifier_startdate_offset );
                    caste.ColorModifier[k].enddate = p->readDWord( p_colormod[k] + color_modifier_enddate_offset );
                }
                /* body parts */
                DfVector <uint32_t> p_bodypart(p, caste_start + caste_bodypart_offset);
                caste.bodypart.empty();
                sizebp = p_bodypart.size();
                for(uint32_t k = 0; k < sizebp; k++)
                {
                    t_bodypart part;
                    p->readSTLString (p_bodypart[k] + bodypart_id_offset, part.id, sizeof(part.id));
                    p->readSTLString (p_bodypart[k] + bodypart_category_offset, part.category, sizeof(part.category));
                    caste.bodypart.push_back(part);
                }
                p->read(caste_start + caste_attributes_offset, sizeof(t_attrib) * (6+11), (uint8_t *)&caste.strength);
            }
            mat.castes.push_back(caste);
        }
        DfVector <uint32_t> p_extract(p, p_races[i] + extract_vector_offset);
        for(uint32_t j = 0; j < p_extract.size(); j++)
        {
            t_creatureextract extract;
            p->readSTLString( p_extract[j], extract.rawname, sizeof(extract.rawname));
            mat.extract.push_back(extract);
        }
        raceEx.push_back(mat);
    }
    return true;
}

void Materials::ReadAllMaterials(void)
{
    this->ReadInorganicMaterials();
    this->ReadOrganicMaterials();
    this->ReadWoodMaterials();
    this->ReadPlantMaterials();
    this->ReadCreatureTypes();
    this->ReadCreatureTypesEx();
    this->ReadDescriptorColors();
    this->ReadOthers();
}

std::string Materials::getDescription(t_material & mat)
{
    std::string out;
    int32_t typeC;

    if ( (mat.subIndex<419) || (mat.subIndex>618) )
    {
        if ( (mat.subIndex<19) || (mat.subIndex>218) )
        {
            if (mat.subIndex)
                if (mat.subIndex>0x292)
                    return "?";
                else
                {
                    if (mat.subIndex>=this->other.size())
                    {
                        if (mat.itemType == 0) {
                            if(mat.subIndex<0)
                                return "any inorganic";
                            else
                                return this->inorganic[mat.subIndex].id;
                        }
                        if(mat.subIndex<0)
                            return "any";
                        if(mat.subIndex>=this->raceEx.size())
                            return "stuff";
                        return this->raceEx[mat.subIndex].rawname;
                    }
                    else
                    {
                        if (mat.index==-1)
                            return std::string(this->other[mat.subIndex].rawname);
                        else
                            return std::string(this->other[mat.subIndex].rawname) + " derivate";
                    }
                }
            else
                if(mat.index<0)
                    return "any inorganic";
                else
                    return this->inorganic[mat.index].id;
        }
        else
        {
            if (mat.index>=this->raceEx.size())
                return "unknown race";
            typeC = mat.subIndex;
            typeC -=19;
            if ((typeC<0) || (typeC>=this->raceEx[mat.index].extract.size()))
            {
                return string(this->raceEx[mat.index].rawname).append(" extract");
            }
            return std::string(this->raceEx[mat.index].rawname).append(" ").append(this->raceEx[mat.index].extract[typeC].rawname);
        }
    }
    else
    {
        return this->organic[mat.index].id;
    }
    return out;
}

//type of material only so we know which vector to retrieve
std::string Materials::getType(t_material & mat)
{
	if((mat.subIndex<419) || (mat.subIndex>618))
	{
		if((mat.subIndex<19) || (mat.subIndex>218))
		{
			if(mat.subIndex)
			{
				if(mat.subIndex>0x292)
				{
					return "unknown";
				}
				else
				{
					if(mat.subIndex>=this->other.size())
					{
						if(mat.subIndex<0)
							return "any";

						if(mat.subIndex>=this->raceEx.size())
							return "unknown";

						return "racex";
					}
					else
					{
						if (mat.index==-1)
							return "other";
						else
							return "other derivate";
					}
				}
			}
			else
				return "inorganic";
		}
		else
		{
			if (mat.index>=this->raceEx.size())
				return "unknown";

			return "racex extract";
		}
	}
	else
	{
		return "organic";
	}
}