/* Copyright (C) 1996-1997 Id Software, Inc. This program 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. This program 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 this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA See file, 'COPYING', for details. */ #pragma once #include #include #include #include #include #include #include #include #include "qvec.hh" constexpr int32_t MBSPIDENT = -1; constexpr size_t MAX_MAP_HULLS_H2 = 8; struct dmodelh2_t { qvec3f mins; qvec3f maxs; qvec3f origin; std::array headnode; /* hexen2 only uses 6 */ int32_t visleafs; /* not including the solid leaf 0 */ int32_t firstface; int32_t numfaces; // serialize for streams void stream_write(std::ostream &s) const; void stream_read(std::istream &s); }; enum vistype_t { VIS_PVS, VIS_PHS }; // the visibility lump consists of a header with a count, then // byte offsets for the PVS and PHS of each cluster, then the raw // compressed bit vectors. struct mvis_t { std::vector> bit_offsets; std::vector bits; size_t header_offset() const; // set a bit offset of the specified cluster/vistype *relative to the start of the bits array* // (after the header) void set_bit_offset(vistype_t type, size_t cluster, size_t offset); // fetch the bit offset of the specified cluster/vistype // relative to the start of the bits array int32_t get_bit_offset(vistype_t type, size_t cluster) const; void resize(size_t numclusters); void stream_read(std::istream &stream, const lump_t &lump); void stream_write(std::ostream &stream) const; }; // structured data from BSP. this is the header of the miptex used // in Quake-like formats. constexpr size_t MIPLEVELS = 4; struct dmiptex_t { std::array name; uint32_t width, height; std::array offsets; /* four mip maps stored */ // serialize for streams void stream_write(std::ostream &s) const; void stream_read(std::istream &s); }; // semi-structured miptex data; we don't directly care about // the contents of the miptex beyond the header. we store // some of the data from the miptex (name, width, height) but // the full, raw miptex is also stored in `data`. struct miptex_t { std::string name; uint32_t width, height; std::vector data; /** * set at read time if the offset is -1 */ bool null_texture = false; /** * exposed for testing -notex */ std::array offsets; size_t stream_size() const; void stream_read(std::istream &stream, size_t len); void stream_write(std::ostream &stream) const; }; // structured miptex container lump struct dmiptexlump_t { std::vector textures; void stream_read(std::istream &stream, const lump_t &lump); void stream_write(std::ostream &stream) const; size_t stream_size() const; }; // 0-2 are axial planes // 3-5 are non-axial planes snapped to the nearest enum class plane_type_t { PLANE_INVALID = -1, PLANE_X = 0, PLANE_Y = 1, PLANE_Z = 2, PLANE_ANYX = 3, PLANE_ANYY = 4, PLANE_ANYZ = 5, }; template inline plane_type_t calculate_plane_type(const qplane3 &p) { for (size_t i = 0; i < 3; i++) { if (p.normal[i] == 1.0 || p.normal[i] == -1.0) { return (i == 0 ? plane_type_t::PLANE_X : i == 1 ? plane_type_t::PLANE_Y : plane_type_t::PLANE_Z); } } double ax = fabs(p.normal[0]); double ay = fabs(p.normal[1]); double az = fabs(p.normal[2]); if (ax >= ay && ax >= az) { return plane_type_t::PLANE_ANYX; } else if (ay >= ax && ay >= az) { return plane_type_t::PLANE_ANYY; } else { return plane_type_t::PLANE_ANYZ; } } // Fmt support template<> struct fmt::formatter { constexpr auto parse(format_parse_context &ctx) -> decltype(ctx.begin()) { return ctx.end(); } template auto format(plane_type_t t, FormatContext &ctx) { string_view name = "unknown"; switch (t) { case plane_type_t::PLANE_INVALID: name = "PLANE_INVALID"; break; case plane_type_t::PLANE_X: name = "PLANE_X"; break; case plane_type_t::PLANE_Y: name = "PLANE_Y"; break; case plane_type_t::PLANE_Z: name = "PLANE_Z"; break; case plane_type_t::PLANE_ANYX: name = "PLANE_ANYX"; break; case plane_type_t::PLANE_ANYY: name = "PLANE_ANYY"; break; case plane_type_t::PLANE_ANYZ: name = "PLANE_ANYZ"; break; } return format_to(ctx.out(), "{}", name); } }; struct dplane_t : qplane3f { int32_t type; [[nodiscard]] constexpr dplane_t operator-() const { return {qplane3f::operator-(), type}; } // serialize for streams void stream_write(std::ostream &s) const; void stream_read(std::istream &s); // optimized case template inline T distance_to_fast(const qvec &point) const { switch (static_cast(type)) { case plane_type_t::PLANE_X: return point[0] - dist; case plane_type_t::PLANE_Y: return point[1] - dist; case plane_type_t::PLANE_Z: return point[2] - dist; default: { return qplane3f::distance_to(point); } } } }; struct bsp2_dnode_t { int32_t planenum; std::array children; /* negative numbers are -(leafs+1), not nodes */ qvec3f mins; /* for sphere culling */ qvec3f maxs; uint32_t firstface; uint32_t numfaces; /* counting both sides */ // serialize for streams void stream_write(std::ostream &s) const; void stream_read(std::istream &s); }; struct mtexinfo_t { texvecf vecs; // [s/t][xyz offset] surfflags_t flags; // native miptex flags + extended flags // q1 only int32_t miptex; // q2 only int32_t value; // light emission, etc std::array texture; // texture name (textures/*.wal) int32_t nexttexinfo = -1; // for animations, -1 = end of chain }; constexpr size_t MAXLIGHTMAPS = 4; constexpr uint16_t INVALID_LIGHTSTYLE_OLD = 0xffu; struct mface_t { int64_t planenum; int32_t side; // if true, the face is on the back side of the plane int32_t firstedge; /* we must support > 64k edges */ int32_t numedges; int32_t texinfo; /* lighting info */ std::array styles; int32_t lightofs; /* start of [numstyles*surfsize] samples */ // serialize for streams void stream_write(std::ostream &s) const; void stream_read(std::istream &s); }; /* * Note that children are interpreted as unsigned values now, so that we can * handle > 32k clipnodes. Values > 0xFFF0 can be assumed to be CONTENTS * values and can be read as the signed value to be compatible with the above * (i.e. simply subtract 65536). */ struct bsp2_dclipnode_t { int32_t planenum; std::array children; /* negative numbers are contents */ // serialize for streams void stream_write(std::ostream &s) const; void stream_read(std::istream &s); }; using bsp2_dedge_t = std::array; /* vertex numbers */ /* * leaf 0 is the generic CONTENTS_SOLID leaf, used for all solid areas (except Q2) * all other leafs need visibility info */ /* Ambient Sounds */ enum ambient_type_t : uint8_t { AMBIENT_WATER, AMBIENT_SKY, AMBIENT_SLIME, AMBIENT_LAVA, NUM_AMBIENTS = 4 }; constexpr int32_t CLUSTER_INVALID = -1; constexpr int32_t AREA_INVALID = 0; struct mleaf_t { // bsp2_dleaf_t int32_t contents; int32_t visofs; /* -1 = no visibility info; Q1 only! */ qvec3f mins; /* for frustum culling */ qvec3f maxs; uint32_t firstmarksurface; uint32_t nummarksurfaces; std::array ambient_level; // q2 extras int32_t cluster; int32_t area; uint32_t firstleafbrush; uint32_t numleafbrushes; // comparison operator for tests bool operator==(const mleaf_t &other) const; }; struct darea_t { int32_t numareaportals; int32_t firstareaportal; // serialize for streams void stream_write(std::ostream &s) const; void stream_read(std::istream &s); // comparison operator for tests bool operator==(const darea_t &other) const; }; // each area has a list of portals that lead into other areas // when portals are closed, other areas may not be visible or // hearable even if the vis info says that it should be struct dareaportal_t { int32_t portalnum; int32_t otherarea; // serialize for streams void stream_write(std::ostream &s) const; void stream_read(std::istream &s); // comparison operator for tests bool operator==(const dareaportal_t &other) const; }; struct dbrush_t { int32_t firstside; int32_t numsides; int32_t contents; // serialize for streams void stream_write(std::ostream &s) const; void stream_read(std::istream &s); }; struct q2_dbrushside_qbism_t { uint32_t planenum; // facing out of the leaf int32_t texinfo; // serialize for streams void stream_write(std::ostream &s) const; void stream_read(std::istream &s); }; struct bspversion_t; // "generic" bsp - superset of all other supported types struct mbsp_t { // the BSP version that we came from, if any const bspversion_t *loadversion; // the BSP we were converted from, if any fs::path file; std::vector dmodels; mvis_t dvis; std::vector dlightdata; dmiptexlump_t dtex; std::string dentdata; std::vector dleafs; std::vector dplanes; std::vector dvertexes; std::vector dnodes; std::vector texinfo; std::vector dfaces; std::vector dclipnodes; std::vector dedges; std::vector dleaffaces; std::vector dleafbrushes; std::vector dsurfedges; std::vector dareas; std::vector dareaportals; std::vector dbrushes; std::vector dbrushsides; }; extern const bspversion_t bspver_generic; const std::initializer_list &gamedef_list();