/* Copyright (c) 2000, 2010 Oracle and/or its affiliates. All rights reserved. Copyright (C) 2011 Monty Program Ab. 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; version 2 of the License. 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., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1335 USA */ #include #ifdef HAVE_SPATIAL #include "gcalc_tools.h" #include "spatial.h" #define float_to_coord(d) ((double) d) /* Adds new shape to the relation. After that it can be used as an argument of an operation. */ gcalc_shape_info Gcalc_function::add_new_shape(uint32 shape_id, shape_type shape_kind) { shapes_buffer.q_append((uint32) shape_kind); return n_shapes++; } /* Adds new operation to the constructed relation. To construct the complex relation one has to specify operations in prefix style. */ void Gcalc_function::add_operation(uint operation, uint32 n_operands) { uint32 op_code= (uint32 ) operation + n_operands; function_buffer.q_append(op_code); } /* Sometimes the number of arguments is unknown at the moment the operation is added. That allows to specify it later. */ void Gcalc_function::add_operands_to_op(uint32 operation_pos, uint32 n_operands) { uint32 op_code= uint4korr(function_buffer.ptr() + operation_pos) + n_operands; function_buffer.write_at_position(operation_pos, op_code); } /* Just like the add_operation() but the result will be the inverted value of an operation. */ void Gcalc_function::add_not_operation(op_type operation, uint32 n_operands) { uint32 op_code= ((uint32) op_not | (uint32 ) operation) + n_operands; function_buffer.q_append(op_code); } int Gcalc_function::single_shape_op(shape_type shape_kind, gcalc_shape_info *si) { if (reserve_shape_buffer(1) || reserve_op_buffer(1)) return 1; *si= add_new_shape(0, shape_kind); add_operation(op_shape, *si); return 0; } int Gcalc_function::repeat_expression(uint32 exp_pos) { if (reserve_op_buffer(1)) return 1; add_operation(op_repeat, exp_pos); return 0; } /* Specify how many arguments we're going to have. */ int Gcalc_function::reserve_shape_buffer(uint n_shapes) { return shapes_buffer.reserve(n_shapes * 4, 512); } /* Specify how many operations we're going to have. */ int Gcalc_function::reserve_op_buffer(uint n_ops) { return function_buffer.reserve(n_ops * 4, 512); } int Gcalc_function::alloc_states() { if (function_buffer.reserve((n_shapes+1) * 2 * sizeof(int))) return 1; i_states= (int *) (function_buffer.ptr() + ALIGN_SIZE(function_buffer.length())); b_states= i_states + (n_shapes + 1); return 0; } int Gcalc_function::count_internal(const char *cur_func, uint set_type, const char **end) { uint c_op= uint4korr(cur_func); op_type next_func= (op_type) (c_op & op_any); int mask= (c_op & op_not) ? 1:0; uint n_ops= c_op & ~(op_any | op_not | v_mask); uint n_shape= c_op & ~(op_any | op_not | v_mask); /* same as n_ops */ value v_state= (value) (c_op & v_mask); int result= 0; const char *sav_cur_func= cur_func; // GCALC_DBUG_ENTER("Gcalc_function::count_internal"); cur_func+= 4; if (next_func == op_shape) { if (set_type == 0) result= i_states[n_shape] | b_states[n_shape]; /* the last call for the count_internal outside of all shapes. */ else if (set_type == 1) result= 0; else if (set_type == op_border) result= b_states[n_shape]; else if (set_type == op_internals) result= i_states[n_shape] && !b_states[n_shape]; goto exit; } if (next_func == op_false) { result= 0; goto exit; } if (next_func == op_border || next_func == op_internals) { result= count_internal(cur_func, (set_type == 1) ? set_type : next_func, &cur_func); goto exit; } if (next_func == op_repeat) { result= count_internal(function_buffer.ptr() + n_ops, set_type, 0); goto exit; } if (n_ops == 0) return mask; //GCALC_DBUG_RETURN(mask); result= count_internal(cur_func, set_type, &cur_func); while (--n_ops) { int next_res= count_internal(cur_func, set_type, &cur_func); switch (next_func) { case op_union: if (result == result_true || next_res == result_true) result= result_true; else if (result == result_unknown || next_res == result_unknown) result= result_unknown; else result= result_false; break; case op_intersection: if (result == result_false || next_res == result_false) result= result_false; else if (result == result_unknown || next_res == result_unknown) result= result_unknown; else result= result_true; break; case op_symdifference: if (result == result_unknown || next_res == result_unknown) result= result_unknown; else result= result ^ next_res; break; case op_difference: if (result == result_false || next_res == result_true) result= result_false; else if (result == result_unknown || next_res == result_unknown) result= result_unknown; else result= result_true; break; default: GCALC_DBUG_ASSERT(FALSE); }; } exit: if (result != result_unknown) result^= mask; if (v_state != v_empty) { switch (v_state) { case v_find_t: if (result == result_true) { c_op= (c_op & ~v_mask) | v_t_found; int4store(sav_cur_func, c_op); } else { if (set_type != 1) result= result_unknown; } break; case v_find_f: if (result == result_false) { c_op= (c_op & ~v_mask) | v_f_found; int4store(sav_cur_func, c_op); } else { if (set_type != 1) result= result_unknown; } break; case v_t_found: result= 1; break; case v_f_found: result= 0; break; default: GCALC_DBUG_ASSERT(0); }; } if (end) *end= cur_func; return result; //GCALC_DBUG_RETURN(result); } void Gcalc_function::clear_i_states() { for (uint i= 0; i < n_shapes; i++) i_states[i]= 0; } void Gcalc_function::clear_b_states() { for (uint i= 0; i < n_shapes; i++) b_states[i]= 0; } /* Clear the state of the object. */ void Gcalc_function::reset() { n_shapes= 0; shapes_buffer.length(0); function_buffer.length(0); } int Gcalc_function::check_function(Gcalc_scan_iterator &scan_it) { const Gcalc_scan_iterator::point *eq_start, *cur_eq; const Gcalc_scan_iterator::event_point *events; int result; GCALC_DBUG_ENTER("Gcalc_function::check_function"); while (scan_it.more_points()) { if (scan_it.step()) GCALC_DBUG_RETURN(-1); events= scan_it.get_events(); /* these kinds of events don't change the function */ Gcalc_point_iterator pit(&scan_it); clear_b_states(); clear_i_states(); /* Walk to the event, marking polygons we met */ for (; pit.point() != scan_it.get_event_position(); ++pit) { gcalc_shape_info si= pit.point()->get_shape(); if ((get_shape_kind(si) == Gcalc_function::shape_polygon)) invert_i_state(si); } if (events->simple_event()) { if (events->event == scev_end) set_b_state(events->get_shape()); if ((result= count()) != result_unknown) GCALC_DBUG_RETURN(result); clear_b_states(); continue; } /* Check the status of the event point */ for (; events; events= events->get_next()) { gcalc_shape_info si= events->get_shape(); if (events->event == scev_thread || events->event == scev_end || (get_shape_kind(si) == Gcalc_function::shape_polygon)) set_b_state(si); else if (events->event == scev_single_point || get_shape_kind(si) == Gcalc_function::shape_line) set_i_state(si); } if ((result= count()) != result_unknown) GCALC_DBUG_RETURN(result); /* Set back states changed in the loop above. */ for (events= scan_it.get_events(); events; events= events->get_next()) { gcalc_shape_info si= events->get_shape(); if (events->event == scev_thread || events->event == scev_end || get_shape_kind(si) == Gcalc_function::shape_polygon) clear_b_state(si); else if (events->event == scev_single_point || get_shape_kind(si) == Gcalc_function::shape_line) clear_i_state(si); } if (scan_it.get_event_position() == scan_it.get_event_end()) continue; /* Check the status after the event */ eq_start= pit.point(); do { ++pit; if (pit.point() != scan_it.get_event_end() && eq_start->cmp_dx_dy(pit.point()) == 0) continue; for (cur_eq= eq_start; cur_eq != pit.point(); cur_eq= cur_eq->get_next()) { gcalc_shape_info si= cur_eq->get_shape(); if (get_shape_kind(si) == Gcalc_function::shape_polygon) set_b_state(si); else invert_i_state(si); } if ((result= count()) != result_unknown) GCALC_DBUG_RETURN(result); for (cur_eq= eq_start; cur_eq != pit.point(); cur_eq= cur_eq->get_next()) { gcalc_shape_info si= cur_eq->get_shape(); if ((get_shape_kind(si) == Gcalc_function::shape_polygon)) { clear_b_state(si); invert_i_state(si); } else invert_i_state(cur_eq->get_shape()); } if ((result= count()) != result_unknown) GCALC_DBUG_RETURN(result); eq_start= pit.point(); } while (pit.point() != scan_it.get_event_end()); } GCALC_DBUG_RETURN(count_last()); } int Gcalc_operation_transporter::single_point(double x, double y) { gcalc_shape_info si; return m_fn->single_shape_op(Gcalc_function::shape_point, &si) || int_single_point(si, x, y); } int Gcalc_operation_transporter::start_line() { int_start_line(); return m_fn->single_shape_op(Gcalc_function::shape_line, &m_si); } int Gcalc_operation_transporter::complete_line() { int_complete_line(); return 0; } int Gcalc_operation_transporter::start_poly() { int_start_poly(); return m_fn->single_shape_op(Gcalc_function::shape_polygon, &m_si); } int Gcalc_operation_transporter::complete_poly() { int_complete_poly(); return 0; } int Gcalc_operation_transporter::start_ring() { int_start_ring(); return 0; } int Gcalc_operation_transporter::complete_ring() { int_complete_ring(); return 0; } int Gcalc_operation_transporter::add_point(double x, double y) { return int_add_point(m_si, x, y); } int Gcalc_operation_transporter::start_collection(int n_objects) { if (m_fn->reserve_shape_buffer(n_objects) || m_fn->reserve_op_buffer(1)) return 1; m_fn->add_operation(Gcalc_function::op_union, n_objects); return 0; } int Gcalc_operation_transporter::empty_shape() { if (m_fn->reserve_op_buffer(1)) return 1; m_fn->add_operation(Gcalc_function::op_false, 0); return 0; } int Gcalc_result_receiver::start_shape(Gcalc_function::shape_type shape) { GCALC_DBUG_ENTER("Gcalc_result_receiver::start_shape"); if (buffer.reserve(4*2, 512)) GCALC_DBUG_RETURN(1); cur_shape= shape; shape_pos= buffer.length(); buffer.length(shape_pos + ((shape == Gcalc_function::shape_point) ? 4:8)); n_points= 0; shape_area= 0.0; GCALC_DBUG_RETURN(0); } int Gcalc_result_receiver::add_point(double x, double y) { GCALC_DBUG_ENTER("Gcalc_result_receiver::add_point"); if (n_points && x == prev_x && y == prev_y) GCALC_DBUG_RETURN(0); if (!n_points++) { prev_x= first_x= x; prev_y= first_y= y; GCALC_DBUG_RETURN(0); } shape_area+= prev_x*y - prev_y*x; if (buffer.reserve(8*2, 512)) GCALC_DBUG_RETURN(1); buffer.q_append(prev_x); buffer.q_append(prev_y); prev_x= x; prev_y= y; GCALC_DBUG_RETURN(0); } int Gcalc_result_receiver::complete_shape() { GCALC_DBUG_ENTER("Gcalc_result_receiver::complete_shape"); if (n_points == 0) { buffer.length(shape_pos); GCALC_DBUG_RETURN(0); } if (n_points == 1) { if (cur_shape != Gcalc_function::shape_point) { if (cur_shape == Gcalc_function::shape_hole) { buffer.length(shape_pos); GCALC_DBUG_RETURN(0); } cur_shape= Gcalc_function::shape_point; buffer.length(buffer.length()-4); } } else { GCALC_DBUG_ASSERT(cur_shape != Gcalc_function::shape_point); if (cur_shape == Gcalc_function::shape_hole) { shape_area+= prev_x*first_y - prev_y*first_x; if (fabs(shape_area) < 1e-8) { buffer.length(shape_pos); GCALC_DBUG_RETURN(0); } } if ((cur_shape == Gcalc_function::shape_polygon || cur_shape == Gcalc_function::shape_hole) && prev_x == first_x && prev_y == first_y) { n_points--; buffer.write_at_position(shape_pos+4, n_points); goto do_complete; } buffer.write_at_position(shape_pos+4, n_points); } if (buffer.reserve(8*2, 512)) GCALC_DBUG_RETURN(1); buffer.q_append(prev_x); buffer.q_append(prev_y); do_complete: buffer.write_at_position(shape_pos, (uint32) cur_shape); if (!n_shapes++) { GCALC_DBUG_ASSERT(cur_shape != Gcalc_function::shape_hole); common_shapetype= cur_shape; } else if (cur_shape == Gcalc_function::shape_hole) { ++n_holes; } else if (!collection_result && (cur_shape != common_shapetype)) { collection_result= true; } GCALC_DBUG_RETURN(0); } int Gcalc_result_receiver::single_point(double x, double y) { return start_shape(Gcalc_function::shape_point) || add_point(x, y) || complete_shape(); } int Gcalc_result_receiver::done() { return 0; } void Gcalc_result_receiver::reset() { buffer.length(0); collection_result= FALSE; n_shapes= n_holes= 0; } int Gcalc_result_receiver::get_result_typeid() { if (!n_shapes || collection_result) return Geometry::wkb_geometrycollection; switch (common_shapetype) { case Gcalc_function::shape_polygon: return (n_shapes - n_holes == 1) ? Geometry::wkb_polygon : Geometry::wkb_multipolygon; case Gcalc_function::shape_point: return (n_shapes == 1) ? Geometry::wkb_point : Geometry::wkb_multipoint; case Gcalc_function::shape_line: return (n_shapes == 1) ? Geometry::wkb_linestring : Geometry::wkb_multilinestring; default: GCALC_DBUG_ASSERT(0); } return 0; } int Gcalc_result_receiver::move_hole(uint32 dest_position, uint32 source_position, uint32 *position_shift) { char *ptr; int source_len; GCALC_DBUG_ENTER("Gcalc_result_receiver::move_hole"); GCALC_DBUG_PRINT(("ps %d %d", dest_position, source_position)); *position_shift= source_len= buffer.length() - source_position; if (dest_position == source_position) GCALC_DBUG_RETURN(0); if (buffer.reserve(source_len, MY_ALIGN(source_len, 512))) GCALC_DBUG_RETURN(1); ptr= (char *) buffer.ptr(); memmove(ptr + dest_position + source_len, ptr + dest_position, buffer.length() - dest_position); memcpy(ptr + dest_position, ptr + buffer.length(), source_len); GCALC_DBUG_RETURN(0); } Gcalc_operation_reducer::Gcalc_operation_reducer(size_t blk_size) : Gcalc_dyn_list(blk_size, sizeof(res_point)), #ifndef GCALC_DBUG_OFF n_res_points(0), #endif /*GCALC_DBUG_OFF*/ m_res_hook((Gcalc_dyn_list::Item **)&m_result), m_first_active_thread(NULL) {} Gcalc_operation_reducer::Gcalc_operation_reducer( const Gcalc_operation_reducer &gor) : Gcalc_dyn_list(gor), #ifndef GCALC_DBUG_OFF n_res_points(0), #endif /*GCALC_DBUG_OFF*/ m_res_hook((Gcalc_dyn_list::Item **)&m_result), m_first_active_thread(NULL) {} void Gcalc_operation_reducer::init(Gcalc_function *fn, modes mode) { m_fn= fn; m_mode= mode; m_first_active_thread= NULL; m_lines= NULL; m_lines_hook= (Gcalc_dyn_list::Item **) &m_lines; m_poly_borders= NULL; m_poly_borders_hook= (Gcalc_dyn_list::Item **) &m_poly_borders; GCALC_SET_TERMINATED(killed, 0); } Gcalc_operation_reducer:: Gcalc_operation_reducer(Gcalc_function *fn, modes mode, size_t blk_size) : Gcalc_dyn_list(blk_size, sizeof(res_point)), m_res_hook((Gcalc_dyn_list::Item **)&m_result) { init(fn, mode); } void Gcalc_operation_reducer::res_point::set(const Gcalc_scan_iterator *si) { intersection_point= si->intersection_step(); pi= si->get_cur_pi(); } Gcalc_operation_reducer::res_point * Gcalc_operation_reducer::add_res_point(Gcalc_function::shape_type type) { GCALC_DBUG_ENTER("Gcalc_operation_reducer::add_res_point"); res_point *result= (res_point *)new_item(); *m_res_hook= result; result->prev_hook= m_res_hook; m_res_hook= &result->next; result->type= type; #ifndef GCALC_DBUG_OFF result->point_n= n_res_points++; #endif /*GCALC_DBUG_OFF*/ GCALC_DBUG_RETURN(result); } int Gcalc_operation_reducer::add_line(int incoming, active_thread *t, const Gcalc_scan_iterator::point *p) { line *l= new_line(); GCALC_DBUG_ENTER("Gcalc_operation_reducer::add_line"); if (!l) GCALC_DBUG_RETURN(1); l->incoming= incoming; l->t= t; l->p= p; *m_lines_hook= l; m_lines_hook= &l->next; GCALC_DBUG_RETURN(0); } int Gcalc_operation_reducer::add_poly_border(int incoming, active_thread *t, int prev_state, const Gcalc_scan_iterator::point *p) { poly_border *b= new_poly_border(); GCALC_DBUG_ENTER("Gcalc_operation_reducer::add_poly_border"); if (!b) GCALC_DBUG_RETURN(1); b->incoming= incoming; b->t= t; b->prev_state= prev_state; b->p= p; *m_poly_borders_hook= b; m_poly_borders_hook= &b->next; GCALC_DBUG_RETURN(0); } int Gcalc_operation_reducer::continue_range(active_thread *t, const Gcalc_heap::Info *p, const Gcalc_heap::Info *p_next) { res_point *rp= add_res_point(t->rp->type); GCALC_DBUG_ENTER("Gcalc_operation_reducer::continue_range"); if (!rp) GCALC_DBUG_RETURN(1); rp->glue= NULL; rp->down= t->rp; t->rp->up= rp; rp->intersection_point= false; rp->pi= p; t->rp= rp; t->p1= p; t->p2= p_next; GCALC_DBUG_RETURN(0); } inline int Gcalc_operation_reducer::continue_i_range(active_thread *t, const Gcalc_heap::Info *ii) { res_point *rp= add_res_point(t->rp->type); GCALC_DBUG_ENTER("Gcalc_operation_reducer::continue_i_range"); if (!rp) GCALC_DBUG_RETURN(1); rp->glue= NULL; rp->down= t->rp; t->rp->up= rp; rp->intersection_point= true; rp->pi= ii; t->rp= rp; GCALC_DBUG_RETURN(0); } int Gcalc_operation_reducer::end_couple(active_thread *t0, active_thread *t1, const Gcalc_heap::Info *p) { res_point *rp0, *rp1; GCALC_DBUG_ENTER("Gcalc_operation_reducer::end_couple"); GCALC_DBUG_ASSERT(t0->rp->type == t1->rp->type); if (!(rp0= add_res_point(t0->rp->type)) || !(rp1= add_res_point(t0->rp->type))) GCALC_DBUG_RETURN(1); rp0->down= t0->rp; rp1->down= t1->rp; rp1->glue= rp0; rp0->glue= rp1; rp0->up= rp1->up= NULL; t0->rp->up= rp0; t1->rp->up= rp1; rp0->intersection_point= rp1->intersection_point= false; rp0->pi= rp1->pi= p; GCALC_DBUG_RETURN(0); } int Gcalc_operation_reducer::count_slice(Gcalc_scan_iterator *si) { Gcalc_point_iterator pi(si); int prev_state= 0; int sav_prev_state; active_thread *prev_range= NULL; const Gcalc_scan_iterator::event_point *events; const Gcalc_scan_iterator::point *eq_start; active_thread **cur_t_hook= &m_first_active_thread; active_thread **starting_t_hook; active_thread *bottom_threads= NULL; active_thread *eq_thread, *point_thread;; GCALC_DBUG_ENTER("Gcalc_operation_reducer::count_slice"); m_fn->clear_i_states(); /* Walk to the event, remembering what is needed. */ for (; pi.point() != si->get_event_position(); ++pi, cur_t_hook= (active_thread **) &(*cur_t_hook)->next) { active_thread *cur_t= *cur_t_hook; if (cur_t->enabled() && cur_t->rp->type == Gcalc_function::shape_polygon) { prev_state^= 1; prev_range= prev_state ? cur_t : 0; } if (m_fn->get_shape_kind(pi.get_shape()) == Gcalc_function::shape_polygon) m_fn->invert_i_state(pi.get_shape()); } events= si->get_events(); if (events->simple_event()) { active_thread *cur_t= *cur_t_hook; switch (events->event) { case scev_point: { if (cur_t->enabled() && continue_range(cur_t, events->pi, events->next_pi)) GCALC_DBUG_RETURN(1); break; } case scev_end: { if (cur_t->enabled() && end_line(cur_t, si)) GCALC_DBUG_RETURN(1); *cur_t_hook= cur_t->get_next(); free_item(cur_t); break; } case scev_two_ends: { if (cur_t->enabled() && cur_t->get_next()->enabled()) { /* When two threads are ended here */ if (end_couple(cur_t, cur_t->get_next(), events->pi)) GCALC_DBUG_RETURN(1); } else if (cur_t->enabled() || cur_t->get_next()->enabled()) { /* Rare case when edges of a polygon coincide */ if (end_line(cur_t->enabled() ? cur_t : cur_t->get_next(), si)) GCALC_DBUG_RETURN(1); } *cur_t_hook= cur_t->get_next()->get_next(); free_item(cur_t->next); free_item(cur_t); break; } default: GCALC_DBUG_ASSERT(0); } GCALC_DBUG_RETURN(0); } starting_t_hook= cur_t_hook; sav_prev_state= prev_state; /* Walk through the event, collecting all the 'incoming' threads */ for (; events; events= events->get_next()) { active_thread *cur_t= *cur_t_hook; if (events->event == scev_single_point) continue; if (events->event == scev_thread || events->event == scev_two_threads) { active_thread *new_t= new_active_thread(); if (!new_t) GCALC_DBUG_RETURN(1); new_t->rp= NULL; /* Insert into the main thread list before the current */ new_t->next= cur_t; *cur_t_hook= new_t; cur_t_hook= (active_thread **) &new_t->next; } else { if (events->is_bottom()) { /* Move thread from the main list to the bottom_threads. */ *cur_t_hook= cur_t->get_next(); cur_t->next= bottom_threads; bottom_threads= cur_t; } if (cur_t->enabled()) { if (cur_t->rp->type == Gcalc_function::shape_line) { GCALC_DBUG_ASSERT(!prev_state); add_line(1, cur_t, events); } else { add_poly_border(1, cur_t, prev_state, events); prev_state^= 1; } if (!events->is_bottom()) { active_thread *new_t= new_active_thread(); if (!new_t) GCALC_DBUG_RETURN(1); new_t->rp= NULL; /* Replace the current thread with the new. */ new_t->next= cur_t->next; *cur_t_hook= new_t; cur_t_hook= (active_thread **) &new_t->next; /* And move old to the bottom list */ cur_t->next= bottom_threads; bottom_threads= cur_t; } } else if (!events->is_bottom()) cur_t_hook= (active_thread **) &cur_t->next; } } prev_state= sav_prev_state; cur_t_hook= starting_t_hook; eq_start= pi.point(); eq_thread= point_thread= *starting_t_hook; m_fn->clear_b_states(); while (eq_start != si->get_event_end()) { const Gcalc_scan_iterator::point *cur_eq; int in_state, after_state; ++pi; point_thread= point_thread->get_next(); if (pi.point() != si->get_event_end() && eq_start->cmp_dx_dy(pi.point()) == 0) continue; for (cur_eq= eq_start; cur_eq != pi.point(); cur_eq= cur_eq->get_next()) m_fn->set_b_state(cur_eq->get_shape()); in_state= m_fn->count(); m_fn->clear_b_states(); for (cur_eq= eq_start; cur_eq != pi.point(); cur_eq= cur_eq->get_next()) { gcalc_shape_info si= cur_eq->get_shape(); if ((m_fn->get_shape_kind(si) == Gcalc_function::shape_polygon)) m_fn->invert_i_state(si); } after_state= m_fn->count(); if (prev_state != after_state) { if (add_poly_border(0, eq_thread, prev_state, eq_start)) GCALC_DBUG_RETURN(1); } else if (!prev_state /* &&!after_state */ && in_state) { if (add_line(0, eq_thread, eq_start)) GCALC_DBUG_RETURN(1); } prev_state= after_state; eq_start= pi.point(); eq_thread= point_thread; } if (!sav_prev_state && !m_poly_borders && !m_lines) { /* Check if we need to add the event point itself */ m_fn->clear_i_states(); /* b_states supposed to be clean already */ for (pi.restart(si); pi.point() != si->get_event_position(); ++pi) { if (m_fn->get_shape_kind(pi.get_shape()) == Gcalc_function::shape_polygon) m_fn->invert_i_state(pi.get_shape()); } for (events= si->get_events(); events; events= events->get_next()) m_fn->set_b_state(events->get_shape()); GCALC_DBUG_RETURN(m_fn->count() ? add_single_point(si) : 0); } if (m_poly_borders) { *m_poly_borders_hook= NULL; while (m_poly_borders) { poly_border *pb1, *pb2; pb1= m_poly_borders; GCALC_DBUG_ASSERT(m_poly_borders->next); pb2= get_pair_border(pb1); /* Remove pb1 from the list. The pb2 already removed in get_pair_border. */ m_poly_borders= pb1->get_next(); if (connect_threads(pb1->incoming, pb2->incoming, pb1->t, pb2->t, pb1->p, pb2->p, prev_range, si, Gcalc_function::shape_polygon)) GCALC_DBUG_RETURN(1); free_item(pb1); free_item(pb2); } m_poly_borders_hook= (Gcalc_dyn_list::Item **) &m_poly_borders; m_poly_borders= NULL; } if (m_lines) { *m_lines_hook= NULL; if (m_lines->get_next() && !m_lines->get_next()->get_next()) { if (connect_threads(m_lines->incoming, m_lines->get_next()->incoming, m_lines->t, m_lines->get_next()->t, m_lines->p, m_lines->get_next()->p, NULL, si, Gcalc_function::shape_line)) GCALC_DBUG_RETURN(1); } else { for (line *cur_line= m_lines; cur_line; cur_line= cur_line->get_next()) { if (cur_line->incoming) { if (end_line(cur_line->t, si)) GCALC_DBUG_RETURN(1); } else start_line(cur_line->t, cur_line->p, si); } } free_list(m_lines); m_lines= NULL; m_lines_hook= (Gcalc_dyn_list::Item **) &m_lines; } if (bottom_threads) free_list(bottom_threads); GCALC_DBUG_RETURN(0); } int Gcalc_operation_reducer::add_single_point(const Gcalc_scan_iterator *si) { res_point *rp= add_res_point(Gcalc_function::shape_point); GCALC_DBUG_ENTER("Gcalc_operation_reducer::add_single_point"); if (!rp) GCALC_DBUG_RETURN(1); rp->glue= rp->up= rp->down= NULL; rp->set(si); GCALC_DBUG_RETURN(0); } Gcalc_operation_reducer::poly_border *Gcalc_operation_reducer::get_pair_border(poly_border *b1) { poly_border *prev_b= b1; poly_border *result= b1->get_next(); GCALC_DBUG_ENTER("Gcalc_operation_reducer::get_pair_border"); if (b1->prev_state) { if (b1->incoming) { /* Find the first outgoing, otherwise the last one. */ while (result->incoming && result->get_next()) { prev_b= result; result= result->get_next(); } } else { /* Get the last one */ while (result->get_next()) { prev_b= result; result= result->get_next(); } } } else /* !b1->prev_state */ { if (b1->incoming) { /* Get the next incoming, otherwise the last one. */ while (!result->incoming && result->get_next()) { prev_b= result; result= result->get_next(); } } else { /* Just pick the next one */ } } /* Delete the result from the list. */ prev_b->next= result->next; GCALC_DBUG_RETURN(result); } int Gcalc_operation_reducer::connect_threads( int incoming_a, int incoming_b, active_thread *ta, active_thread *tb, const Gcalc_scan_iterator::point *pa, const Gcalc_scan_iterator::point *pb, active_thread *prev_range, const Gcalc_scan_iterator *si, Gcalc_function::shape_type s_t) { GCALC_DBUG_ENTER("Gcalc_operation_reducer::connect_threads"); GCALC_DBUG_PRINT(("incoming %d %d", incoming_a, incoming_b)); if (incoming_a && incoming_b) { res_point *rpa, *rpb; GCALC_DBUG_ASSERT(ta->rp->type == tb->rp->type); if (!(rpa= add_res_point(ta->rp->type)) || !(rpb= add_res_point(ta->rp->type))) GCALC_DBUG_RETURN(1); rpa->down= ta->rp; rpb->down= tb->rp; rpb->glue= rpa; rpa->glue= rpb; rpa->up= rpb->up= NULL; ta->rp->up= rpa; tb->rp->up= rpb; rpa->set(si); rpb->set(si); ta->rp= tb->rp= NULL; GCALC_DBUG_RETURN(0); } if (!incoming_a) { GCALC_DBUG_ASSERT(!incoming_b); res_point *rp0, *rp1; if (!(rp0= add_res_point(s_t)) || !(rp1= add_res_point(s_t))) GCALC_DBUG_RETURN(1); rp0->glue= rp1; rp1->glue= rp0; rp0->set(si); rp1->set(si); rp0->down= rp1->down= NULL; ta->rp= rp0; tb->rp= rp1; ta->p1= pa->pi; ta->p2= pa->next_pi; tb->p1= pb->pi; tb->p2= pb->next_pi; if (prev_range) { rp0->outer_poly= prev_range->thread_start; tb->thread_start= prev_range->thread_start; /* Check if needed */ ta->thread_start= prev_range->thread_start; } else { rp0->outer_poly= 0; ta->thread_start= rp0; /* Check if needed */ tb->thread_start= rp0; } GCALC_DBUG_RETURN(0); } /* else, if only ta is incoming */ GCALC_DBUG_ASSERT(tb != ta); tb->rp= ta->rp; tb->thread_start= ta->thread_start; if (Gcalc_scan_iterator::point:: cmp_dx_dy(ta->p1, ta->p2, pb->pi, pb->next_pi) != 0) { if (si->intersection_step() ? continue_i_range(tb, si->get_cur_pi()) : continue_range(tb, si->get_cur_pi(), pb->next_pi)) GCALC_DBUG_RETURN(1); } tb->p1= pb->pi; tb->p2= pb->next_pi; GCALC_DBUG_RETURN(0); } int Gcalc_operation_reducer::start_line(active_thread *t, const Gcalc_scan_iterator::point *p, const Gcalc_scan_iterator *si) { res_point *rp= add_res_point(Gcalc_function::shape_line); GCALC_DBUG_ENTER("Gcalc_operation_reducer::start_line"); if (!rp) GCALC_DBUG_RETURN(1); rp->glue= rp->down= NULL; rp->set(si); t->rp= rp; t->p1= p->pi; t->p2= p->next_pi; GCALC_DBUG_RETURN(0); } int Gcalc_operation_reducer::end_line(active_thread *t, const Gcalc_scan_iterator *si) { GCALC_DBUG_ENTER("Gcalc_operation_reducer::end_line"); GCALC_DBUG_ASSERT(t->rp->type == Gcalc_function::shape_line); res_point *rp= add_res_point(Gcalc_function::shape_line); if (!rp) GCALC_DBUG_RETURN(1); rp->glue= rp->up= NULL; rp->down= t->rp; rp->set(si); t->rp->up= rp; t->rp= NULL; GCALC_DBUG_RETURN(0); } int Gcalc_operation_reducer::count_all(Gcalc_heap *hp) { Gcalc_scan_iterator si; GCALC_DBUG_ENTER("Gcalc_operation_reducer::count_all"); si.init(hp); GCALC_SET_TERMINATED(si.killed, killed); while (si.more_points()) { if (si.step()) GCALC_DBUG_RETURN(1); if (count_slice(&si)) GCALC_DBUG_RETURN(1); } GCALC_DBUG_RETURN(0); } inline void Gcalc_operation_reducer::free_result(res_point *res) { if ((*res->prev_hook= res->next)) { res->get_next()->prev_hook= res->prev_hook; } free_item(res); } inline int Gcalc_operation_reducer::get_single_result(res_point *res, Gcalc_result_receiver *storage) { GCALC_DBUG_ENTER("Gcalc_operation_reducer::get_single_result"); if (res->intersection_point) { double x, y; res->pi->calc_xy(&x, &y); if (storage->single_point(x,y)) GCALC_DBUG_RETURN(1); } else if (storage->single_point(res->pi->node.shape.x, res->pi->node.shape.y)) GCALC_DBUG_RETURN(1); free_result(res); GCALC_DBUG_RETURN(0); } int Gcalc_operation_reducer::get_result_thread(res_point *cur, Gcalc_result_receiver *storage, int move_upward, res_point *first_poly_node) { res_point *next; bool glue_step= false; double x, y; GCALC_DBUG_ENTER("Gcalc_operation_reducer::get_result_thread"); while (cur) { if (!glue_step) { if (cur->intersection_point) { cur->pi->calc_xy(&x, &y); } else { x= cur->pi->node.shape.x; y= cur->pi->node.shape.y; } if (storage->add_point(x, y)) GCALC_DBUG_RETURN(1); } next= move_upward ? cur->up : cur->down; if (!next && !glue_step) { next= cur->glue; move_upward^= 1; glue_step= true; if (next) next->glue= NULL; } else glue_step= false; cur->first_poly_node= first_poly_node; free_result(cur); cur= next; } GCALC_DBUG_RETURN(0); } int Gcalc_operation_reducer::get_polygon_result(res_point *cur, Gcalc_result_receiver *storage, res_point *first_poly_node) { GCALC_DBUG_ENTER("Gcalc_operation_reducer::get_polygon_result"); res_point *glue= cur->glue; glue->up->down= NULL; free_result(glue); GCALC_DBUG_RETURN(get_result_thread(cur, storage, 1, first_poly_node) || storage->complete_shape()); } int Gcalc_operation_reducer::get_line_result(res_point *cur, Gcalc_result_receiver *storage) { res_point *next; res_point *cur_orig= cur; int move_upward= 1; GCALC_DBUG_ENTER("Gcalc_operation_reducer::get_line_result"); if (cur->glue) { /* Here we have to find the beginning of the line */ next= cur->up; move_upward= 1; while (next) { cur= next; next= move_upward ? next->up : next->down; if (!next) { next= cur->glue; if (next == cur_orig) { /* It's the line loop */ cur= cur_orig; cur->glue->glue= NULL; move_upward= 1; break; } move_upward^= 1; } } } GCALC_DBUG_RETURN(get_result_thread(cur, storage, move_upward, 0) || storage->complete_shape()); } int Gcalc_operation_reducer::get_result(Gcalc_result_receiver *storage) { poly_instance *polygons= NULL; GCALC_DBUG_ENTER("Gcalc_operation_reducer::get_result"); *m_res_hook= NULL; /* This is to workaround an old gcc's bug */ if (m_res_hook == (Gcalc_dyn_list::Item **) &m_result) goto done; while (m_result) { Gcalc_function::shape_type shape= m_result->type; if (shape == Gcalc_function::shape_point) { if (get_single_result(m_result, storage)) GCALC_DBUG_RETURN(1); continue; } if (shape == Gcalc_function::shape_polygon) { if (m_result->outer_poly) { uint32 insert_position, hole_position, position_shift; poly_instance *cur_poly; insert_position= m_result->outer_poly->first_poly_node->poly_position; GCALC_DBUG_ASSERT(insert_position); hole_position= storage->position(); storage->start_shape(Gcalc_function::shape_hole); if (get_polygon_result(m_result, storage, m_result->outer_poly->first_poly_node) || storage->move_hole(insert_position, hole_position, &position_shift)) GCALC_DBUG_RETURN(1); for (cur_poly= polygons; cur_poly && *cur_poly->after_poly_position >= insert_position; cur_poly= cur_poly->get_next()) *cur_poly->after_poly_position+= position_shift; } else { uint32 *poly_position= &m_result->poly_position; poly_instance *p= new_poly(); p->after_poly_position= poly_position; p->next= polygons; polygons= p; storage->start_shape(Gcalc_function::shape_polygon); if (get_polygon_result(m_result, storage, m_result)) GCALC_DBUG_RETURN(1); *poly_position= storage->position(); } } else { storage->start_shape(shape); if (get_line_result(m_result, storage)) GCALC_DBUG_RETURN(1); } } done: m_res_hook= (Gcalc_dyn_list::Item **)&m_result; storage->done(); GCALC_DBUG_RETURN(0); } void Gcalc_operation_reducer::reset() { free_list((Gcalc_heap::Item **) &m_result, m_res_hook); m_res_hook= (Gcalc_dyn_list::Item **)&m_result; free_list(m_first_active_thread); } #endif /*HAVE_SPATIAL*/