reflex2q3/ReflexToQ3/includes/oopless-parser.cpp
2017-05-06 17:54:48 -07:00

215 lines
7.2 KiB
C++

#define KEYWORD_ENTITY "entity"
#define KEYWORD_BRUSH "brush"
#define KEYWORD_VERTICES "vertices"
#define KEYWORD_FACES "faces"
#define KEYWORD_GLOBAL "global"
#define KEYWORD_PREFAB "prefab"
#include "oopless-parser.hpp"
#include "brushdef.hpp"
#include <sstream>
#include <iostream>
using namespace std;
// place holding functions to test proper control flow.
bool write(const struct TBrush &geometry,
ofstream &fout,
void (*b) (stringstream &, const vector<TPlanePoints> &)) {
bool ok = true;
if (geometry.m_Vertices.size() < 1) {
cerr << "error: geometry has no vertices" << endl;
ok = false;
}
if (geometry.m_Faces.size() < 1) {
cerr << "error: geometry has no faces"<< endl;
ok = false;
}
if (ok) {
fout << GetBrushString(geometry, b);
}
return ok;
}
void write(const vector<string> &entity, ofstream &fo) {
;
}
// entities will vary widely depending on their type and available flags.
// for now, acquire entity data, and handle their conversion in the write methods.
vector<string> get_entity(ifstream &f) {
vector<string> output;
string line;
unsigned int pos = f.tellg();
while (getline(f, line)) {
if (line.find(KEYWORD_ENTITY) != string::npos ||
line.find(KEYWORD_BRUSH) != string::npos ||
line.find(KEYWORD_PREFAB) != string::npos) {
f.seekg(pos);
return output;
} else {
output.push_back(line);
}
pos = f.tellg();
}
}
vector<Eigen::Vector3f> parse_vertices(ifstream &f) {
#define FIRSTCH(x) x[0]
vector<Eigen::Vector3f> output;
string line;
unsigned int pos = f.tellg();
while(getline(f, line)) {
if (line.find(KEYWORD_FACES) != string::npos ||
line.find(KEYWORD_BRUSH) != string::npos ||
line.find(KEYWORD_ENTITY) != string::npos ||
line.find(KEYWORD_PREFAB) != string::npos) {
f.seekg(pos);
return output;
} else {
Eigen::Vector3f v;
stringstream ss(line);
string vdata;
unsigned int i = 0;
while (ss >> vdata) {
if (isdigit(FIRSTCH(vdata)) || FIRSTCH(vdata) == '-') {
double dvalue = stod(vdata);
v[i] = (float)dvalue;
}
// note: this prevents the index growing out of vector capacity
// alternatively can throw an exception when that happens instead
// to make it clear that an illegal line has been hit.
i = (i + 1) % 3;
}
output.push_back(v);
}
pos = f.tellg();
}
return output;
}
vector<struct TFace> parse_face(ifstream &f) {
#define FIRSTCH(x) x[0]
#define SECONDCH(x) x[1]
// it is possible for the next line to be unrelated to faces
// so it is needed to reset the stream prior to reading
// the new label, e.g '\tbrush'.
vector<struct TFace> output;
string line;
unsigned int pos = f.tellg();
while(getline(f, line)) {
if (line.find(KEYWORD_VERTICES) != string::npos ||
line.find(KEYWORD_BRUSH) != string::npos ||
line.find(KEYWORD_ENTITY) != string::npos ||
line.find(KEYWORD_PREFAB) != string::npos ||
line.find(KEYWORD_GLOBAL) != string::npos) {
f.seekg(pos);
return output;
} else {
struct TFace x;
float *f = &x.m_fXOffset;;
stringstream ss(line);
string fdata;
bool hex = false;
unsigned int i = 0;
while (ss >> fdata) {
if (i < 5) {
if (isdigit(FIRSTCH(fdata)) || FIRSTCH(fdata) == '-') {
double dvalue = stod(fdata);
*f = (float)dvalue;
f++;
}
// note: if there is a non-digit in the first 5 fields
// then it qualifies as an illegal line.
} else if (4 < i && i < 8) {
x.m_Indices.push_back(stoi(fdata));
} else if (8 <= i) {
if (!hex && fdata.length() > 1) {
if (SECONDCH(fdata) == 'x') {
// this is the unidentified hex digit.
// out of range for stoi
x.hex = strtoul(fdata.c_str(), NULL, 16);
hex = true;
}
} else if (!hex) {
x.m_Indices.push_back(stoi(fdata));
} else if (hex) {
x.m_Material = fdata;
} else {
;
}
}
i++;
} // end, per field iteration
output.push_back(x);
} // end else case, if line did not contain other keywords
pos = f.tellg();
} // end, per line iteration
// the odd case when the map file ends with a face indent.
return output;
}
struct TBrush parse_brush(ifstream &f) {
struct TBrush output;
string l;
getline(f, l);
// wip: note must return the entire brush, adjust control flow
if (l.find(KEYWORD_VERTICES) != string::npos) {
output.m_Vertices = parse_vertices(f);
}
getline(f, l);
if (l.find(KEYWORD_FACES) != string::npos) {
output.m_Faces = parse_face(f);
}
return output;
}
void parse_prefab(ifstream &f,
ofstream &out,
void (*b) (stringstream &, const vector<TPlanePoints> &)) {
string l;
getline(f, l);
if (l.find(KEYWORD_BRUSH) != string::npos) {
write(parse_brush(f), out, b);
} else if (l.find(KEYWORD_ENTITY) != string::npos) {
write(get_entity(f), out);
}
}
// note: can't use a single function pointer for variadic overloaded write function?
bool convertmap(const char * const infile,
const char * const outfile,
void (*brushdef) (stringstream &, const vector<TPlanePoints> &)) {
ifstream fin;
fin.open(infile);
if (!fin.good()){
cerr << "error: failed to open input file" << endl;
return false;
}
ofstream fout;
fout.open(outfile);
if (!fout.good()) {
cerr << "error: failed to open output file" << endl;
return false;
}
fout << "{\n"
<< "\"classname\" \"worldspawn\"" << endl;
string line;
while (getline(fin, line)) {
if (line.find(KEYWORD_PREFAB) != string::npos ||
line.find(KEYWORD_GLOBAL) != string::npos) {
parse_prefab(fin, fout, brushdef);
} else if (line.find(KEYWORD_ENTITY) != string::npos) {
write(get_entity(fin), fout);
} else if (line.find(KEYWORD_BRUSH) != string::npos) {
write(parse_brush(fin), fout, brushdef);
}
}
fout << "}" << endl;
fin.close();
fout.close();
return true;
}