#include #include "common/tifffile.h" #include "pcs.h" #include "geotiff.h" #define ModelPixelScaleTag 33550 #define ModelTiepointTag 33922 #define ModelTransformationTag 34264 #define GeoKeyDirectoryTag 34735 #define GeoDoubleParamsTag 34736 #define GTModelTypeGeoKey 1024 #define GTRasterTypeGeoKey 1025 #define GeographicTypeGeoKey 2048 #define GeogGeodeticDatumGeoKey 2050 #define GeogPrimeMeridianGeoKey 2051 #define GeogAngularUnitsGeoKey 2054 #define GeogEllipsoidGeoKey 2056 #define GeogAzimuthUnitsGeoKey 2060 #define ProjectedCSTypeGeoKey 3072 #define ProjectionGeoKey 3074 #define ProjCoordTransGeoKey 3075 #define ProjLinearUnitsGeoKey 3076 #define ProjStdParallel1GeoKey 3078 #define ProjStdParallel2GeoKey 3079 #define ProjNatOriginLongGeoKey 3080 #define ProjNatOriginLatGeoKey 3081 #define ProjFalseEastingGeoKey 3082 #define ProjFalseNorthingGeoKey 3083 #define ProjFalseOriginLongGeoKey 3084 #define ProjFalseOriginLatGeoKey 3085 #define ProjFalseOriginEastingGeoKey 3086 #define ProjFalseOriginNorthingGeoKey 3087 #define ProjCenterLongGeoKey 3088 #define ProjCenterLatGeoKey 3089 #define ProjCenterEastingGeoKey 3090 #define ProjCenterNorthingGeoKey 3091 #define ProjScaleAtNatOriginGeoKey 3092 #define ProjScaleAtCenterGeoKey 3093 #define ProjAzimuthAngleGeoKey 3094 #define ProjStraightVertPoleLongGeoKey 3095 #define ProjRectifiedGridAngleGeoKey 3096 #define ModelTypeProjected 1 #define ModelTypeGeographic 2 #define ModelTypeGeocentric 3 #define CT_TransverseMercator 1 #define CT_ObliqueMercator 3 #define CT_Mercator 7 #define CT_LambertConfConic_2SP 8 #define CT_LambertConfConic_1SP 9 #define CT_LambertAzimEqualArea 10 #define CT_AlbersEqualArea 11 #define CT_PolarStereographic 15 #define CT_ObliqueStereographic 16 #define IS_SET(map, key) \ ((map).contains(key) && (map).value(key).SHORT != 32767) typedef struct { quint16 KeyDirectoryVersion; quint16 KeyRevision; quint16 MinorRevision; quint16 NumberOfKeys; } Header; typedef struct { quint16 KeyID; quint16 TIFFTagLocation; quint16 Count; quint16 ValueOffset; } KeyEntry; bool GeoTIFF::readEntry(TIFFFile &file, Ctx &ctx) const { quint16 tag; quint16 type; quint32 count, offset; if (!file.readValue(tag)) return false; if (!file.readValue(type)) return false; if (!file.readValue(count)) return false; if (!file.readValue(offset)) return false; switch (tag) { case ModelPixelScaleTag: if (type != TIFF_DOUBLE || count != 3) return false; ctx.scale = offset; break; case ModelTiepointTag: if (type != TIFF_DOUBLE || count < 6 || count % 6) return false; ctx.tiepoints = offset; ctx.tiepointCount = count / 6; break; case GeoKeyDirectoryTag: if (type != TIFF_SHORT) return false; ctx.keys = offset; break; case GeoDoubleParamsTag: if (type != TIFF_DOUBLE) return false; ctx.values = offset; break; case ModelTransformationTag: if (type != TIFF_DOUBLE || count != 16) return false; ctx.matrix = offset; break; } return true; } bool GeoTIFF::readIFD(TIFFFile &file, quint32 offset, Ctx &ctx) const { quint16 count; if (!file.seek(offset)) return false; if (!file.readValue(count)) return false; for (quint16 i = 0; i < count; i++) if (!readEntry(file, ctx)) return false; return true; } bool GeoTIFF::readScale(TIFFFile &file, quint32 offset, PointD &scale) const { if (!file.seek(offset)) return false; if (!file.readValue(scale.rx())) return false; if (!file.readValue(scale.ry())) return false; return true; } bool GeoTIFF::readTiepoints(TIFFFile &file, quint32 offset, quint32 count, QList &points) const { double z, pz; PointD xy, pp; if (!file.seek(offset)) return false; for (quint32 i = 0; i < count; i++) { if (!file.readValue(xy.rx())) return false; if (!file.readValue(xy.ry())) return false; if (!file.readValue(z)) return false; if (!file.readValue(pp.rx())) return false; if (!file.readValue(pp.ry())) return false; if (!file.readValue(pz)) return false; points.append(ReferencePoint(xy, pp)); } return true; } bool GeoTIFF::readMatrix(TIFFFile &file, quint32 offset, double matrix[16]) const { if (!file.seek(offset)) return false; for (int i = 0; i < 16; i++) if (!file.readValue(matrix[i])) return false; return true; } bool GeoTIFF::readKeys(TIFFFile &file, Ctx &ctx, QMap &kv) const { Header header; KeyEntry entry; Value value; if (!file.seek(ctx.keys)) return false; if (!file.readValue(header.KeyDirectoryVersion)) return false; if (!file.readValue(header.KeyRevision)) return false; if (!file.readValue(header.MinorRevision)) return false; if (!file.readValue(header.NumberOfKeys)) return false; for (int i = 0; i < header.NumberOfKeys; i++) { if (!file.readValue(entry.KeyID)) return false; if (!file.readValue(entry.TIFFTagLocation)) return false; if (!file.readValue(entry.Count)) return false; if (!file.readValue(entry.ValueOffset)) return false; switch (entry.KeyID) { case GTModelTypeGeoKey: case GTRasterTypeGeoKey: case GeographicTypeGeoKey: case GeogGeodeticDatumGeoKey: case GeogPrimeMeridianGeoKey: case GeogAngularUnitsGeoKey: case GeogAzimuthUnitsGeoKey: case ProjectedCSTypeGeoKey: case ProjectionGeoKey: case ProjCoordTransGeoKey: case ProjLinearUnitsGeoKey: case GeogEllipsoidGeoKey: if (entry.TIFFTagLocation != 0 || entry.Count != 1) return false; value.SHORT = entry.ValueOffset; kv.insert(entry.KeyID, value); break; case ProjScaleAtNatOriginGeoKey: case ProjNatOriginLongGeoKey: case ProjNatOriginLatGeoKey: case ProjFalseEastingGeoKey: case ProjFalseNorthingGeoKey: case ProjStdParallel1GeoKey: case ProjStdParallel2GeoKey: case ProjCenterLongGeoKey: case ProjCenterLatGeoKey: case ProjScaleAtCenterGeoKey: case ProjAzimuthAngleGeoKey: case ProjRectifiedGridAngleGeoKey: case ProjFalseOriginLongGeoKey: case ProjFalseOriginLatGeoKey: case ProjCenterEastingGeoKey: case ProjCenterNorthingGeoKey: case ProjFalseOriginEastingGeoKey: case ProjFalseOriginNorthingGeoKey: case ProjStraightVertPoleLongGeoKey: if (!readGeoValue(file, ctx.values, entry.ValueOffset, value.DOUBLE)) return false; kv.insert(entry.KeyID, value); break; default: break; } } return true; } bool GeoTIFF::readGeoValue(TIFFFile &file, quint32 offset, quint16 index, double &val) const { qint64 pos = file.pos(); if (!file.seek(offset + index * sizeof(double))) return false; if (!file.readValue(val)) return false; if (!file.seek(pos)) return false; return true; } const GCS *GeoTIFF::gcs(QMap &kv) { const GCS *gcs = 0; if (IS_SET(kv, GeographicTypeGeoKey)) { if (!(gcs = GCS::gcs(kv.value(GeographicTypeGeoKey).SHORT))) _errorString = QString("%1: unknown GCS") .arg(kv.value(GeographicTypeGeoKey).SHORT); } else if (IS_SET(kv, GeogGeodeticDatumGeoKey) || kv.value(GeogEllipsoidGeoKey).SHORT == 7019 || kv.value(GeogEllipsoidGeoKey).SHORT == 7030) { int pm = IS_SET(kv, GeogPrimeMeridianGeoKey) ? kv.value(GeogPrimeMeridianGeoKey).SHORT : 8901; int au = IS_SET(kv, GeogAngularUnitsGeoKey) ? kv.value(GeogAngularUnitsGeoKey).SHORT : 9102; // If only the ellipsoid is defined and it is GRS80 or WGS84, handle // such definition as a WGS84 geodetic datum. int gd = IS_SET(kv, GeogGeodeticDatumGeoKey) ? kv.value(GeogGeodeticDatumGeoKey).SHORT : 6326; if (!(gcs = GCS::gcs(gd, pm, au))) _errorString = QString("%1+%2: unknown geodetic datum + prime" " meridian combination").arg(gd).arg(pm); } else _errorString = "Can not determine GCS"; return gcs; } Projection::Method GeoTIFF::method(QMap &kv) { if (!IS_SET(kv, ProjCoordTransGeoKey)) { _errorString = "Missing coordinate transformation method"; return Projection::Method(); } switch (kv.value(ProjCoordTransGeoKey).SHORT) { case CT_TransverseMercator: return Projection::Method(9807); case CT_ObliqueMercator: return Projection::Method(9815); case CT_Mercator: return Projection::Method(9804); case CT_LambertConfConic_2SP: return Projection::Method(9802); case CT_LambertConfConic_1SP: return Projection::Method(9801); case CT_LambertAzimEqualArea: return Projection::Method(9820); case CT_AlbersEqualArea: return Projection::Method(9822); case CT_PolarStereographic: return Projection::Method(9829); case CT_ObliqueStereographic: return Projection::Method(9809); default: _errorString = QString("%1: unknown coordinate transformation method") .arg(kv.value(ProjCoordTransGeoKey).SHORT); return Projection::Method(); } } bool GeoTIFF::projectedModel(QMap &kv) { if (IS_SET(kv, ProjectedCSTypeGeoKey)) { const PCS *pcs; if (!(pcs = PCS::pcs(kv.value(ProjectedCSTypeGeoKey).SHORT))) { _errorString = QString("%1: unknown PCS") .arg(kv.value(ProjectedCSTypeGeoKey).SHORT); return false; } _projection = Projection(pcs); } else if (IS_SET(kv, ProjectionGeoKey)) { const GCS *g = gcs(kv); if (!g) return false; const PCS *pcs = PCS::pcs(g, kv.value(ProjectionGeoKey).SHORT); if (!pcs) { _errorString = QString("%1: unknown projection code") .arg(kv.value(GeographicTypeGeoKey).SHORT) .arg(kv.value(ProjectionGeoKey).SHORT); return false; } _projection = Projection(pcs); } else { double lat0, lon0, scale, fe, fn, sp1, sp2; const GCS *g = gcs(kv); if (!g) return false; Projection::Method m(method(kv)); if (m.isNull()) return false; AngularUnits au(IS_SET(kv, GeogAngularUnitsGeoKey) ? kv.value(GeogAngularUnitsGeoKey).SHORT : 9102); AngularUnits zu(IS_SET(kv, GeogAzimuthUnitsGeoKey) ? kv.value(GeogAzimuthUnitsGeoKey).SHORT : 9102); LinearUnits lu(IS_SET(kv, ProjLinearUnitsGeoKey) ? kv.value(ProjLinearUnitsGeoKey).SHORT : 9001); if (lu.isNull()) { _errorString = QString("%1: unknown projection linear units code") .arg(kv.value(ProjLinearUnitsGeoKey).SHORT); return false; } if (kv.contains(ProjNatOriginLatGeoKey)) lat0 = au.toDegrees(kv.value(ProjNatOriginLatGeoKey).DOUBLE); else if (kv.contains(ProjCenterLatGeoKey)) lat0 = au.toDegrees(kv.value(ProjCenterLatGeoKey).DOUBLE); else if (kv.contains(ProjFalseOriginLatGeoKey)) lat0 = au.toDegrees(kv.value(ProjFalseOriginLatGeoKey).DOUBLE); else lat0 = NAN; if (kv.contains(ProjNatOriginLongGeoKey)) lon0 = au.toDegrees(kv.value(ProjNatOriginLongGeoKey).DOUBLE); else if (kv.contains(ProjCenterLongGeoKey)) lon0 = au.toDegrees(kv.value(ProjCenterLongGeoKey).DOUBLE); else if (kv.contains(ProjFalseOriginLongGeoKey)) lon0 = au.toDegrees(kv.value(ProjFalseOriginLongGeoKey).DOUBLE); else if (kv.contains(ProjStraightVertPoleLongGeoKey)) lon0 = au.toDegrees(kv.value(ProjStraightVertPoleLongGeoKey).DOUBLE); else lon0 = NAN; if (kv.contains(ProjScaleAtNatOriginGeoKey)) scale = kv.value(ProjScaleAtNatOriginGeoKey).DOUBLE; else if (kv.contains(ProjScaleAtCenterGeoKey)) scale = kv.value(ProjScaleAtCenterGeoKey).DOUBLE; else scale = NAN; if (kv.contains(ProjStdParallel1GeoKey)) sp1 = au.toDegrees(kv.value(ProjStdParallel1GeoKey).DOUBLE); else if (kv.contains(ProjAzimuthAngleGeoKey)) sp1 = zu.toDegrees(kv.value(ProjAzimuthAngleGeoKey).DOUBLE); else sp1 = NAN; if (kv.contains(ProjStdParallel2GeoKey)) sp2 = au.toDegrees(kv.value(ProjStdParallel2GeoKey).DOUBLE); else if (kv.contains(ProjRectifiedGridAngleGeoKey)) sp2 = au.toDegrees(kv.value(ProjRectifiedGridAngleGeoKey).DOUBLE); else sp2 = NAN; if (kv.contains(ProjFalseNorthingGeoKey)) fn = lu.toMeters(kv.value(ProjFalseNorthingGeoKey).DOUBLE); else if (kv.contains(ProjCenterNorthingGeoKey)) fn = lu.toMeters(kv.value(ProjCenterNorthingGeoKey).DOUBLE); else if (kv.contains(ProjFalseOriginNorthingGeoKey)) fn = lu.toMeters(kv.value(ProjFalseOriginNorthingGeoKey).DOUBLE); else fn = NAN; if (kv.contains(ProjFalseEastingGeoKey)) fe = lu.toMeters(kv.value(ProjFalseEastingGeoKey).DOUBLE); else if (kv.contains(ProjCenterEastingGeoKey)) fe = lu.toMeters(kv.value(ProjCenterEastingGeoKey).DOUBLE); else if (kv.contains(ProjFalseOriginEastingGeoKey)) fe = lu.toMeters(kv.value(ProjFalseOriginEastingGeoKey).DOUBLE); else fe = NAN; Projection::Setup setup(lat0, lon0, scale, fe, fn, sp1, sp2); PCS pcs(g, m, setup, lu, CoordinateSystem()); _projection = Projection(&pcs); } return true; } bool GeoTIFF::geographicModel(QMap &kv) { const GCS *g = gcs(kv); if (!g) return false; _projection = Projection(g); return true; } GeoTIFF::GeoTIFF(const QString &path) { QList points; PointD scale; QMap kv; Ctx ctx; QFile file(path); if (!file.open(QIODevice::ReadOnly)) { _errorString = file.errorString(); return; } TIFFFile tiff(&file); if (!tiff.isValid()) { _errorString = "Not a TIFF file"; return; } for (quint32 ifd = tiff.ifd(); ifd; ) { if (!readIFD(tiff, ifd, ctx) || !tiff.readValue(ifd)) { _errorString = "Invalid IFD"; return; } } if (!ctx.keys) { _errorString = "Not a GeoTIFF file"; return; } if (ctx.scale) { if (!readScale(tiff, ctx.scale, scale)) { _errorString = "Error reading model pixel scale"; return; } } if (ctx.tiepoints) { if (!readTiepoints(tiff, ctx.tiepoints, ctx.tiepointCount, points)) { _errorString = "Error reading raster->model tiepoint pairs"; return; } } if (!readKeys(tiff, ctx, kv)) { _errorString = "Error reading Geo key/value"; return; } switch (kv.value(GTModelTypeGeoKey).SHORT) { case ModelTypeProjected: if (!projectedModel(kv)) return; break; case ModelTypeGeographic: if (!geographicModel(kv)) return; break; case ModelTypeGeocentric: _errorString = "Geocentric models are not supported"; return; default: _errorString = "Unknown/missing model type"; return; } if (ctx.scale && ctx.tiepoints) _transform = Transform(points.first(), scale); else if (ctx.tiepointCount > 1) _transform = Transform(points); else if (ctx.matrix) { double matrix[16]; if (!readMatrix(tiff, ctx.matrix, matrix)) { _errorString = "Error reading transformation matrix"; return; } _transform = Transform(matrix); } else { _errorString = "Incomplete/missing model transformation info"; return; } if (!_transform.isValid()) _errorString = _transform.errorString(); }