@ -47,6 +47,11 @@ constant float4 overshoot_color_2 = { 0.00f, 0.00f, 0.00f, 0.00f };
// =========================================================================
// =========================================================================
# define setting ( name ) settings_buffer[name]
// =========================================================================
// ========================= HELPER FUNCTIONS ==============================
@ -120,7 +125,7 @@ bool get_oct_vox(
struct TraversalState ts ;
// push the root node to the parent stack
ts.current_descriptor_index = *settings_buffer ;
ts.current_descriptor_index = setting( OCTREE_ROOT_INDEX ) ;
ts.current_descriptor = octree_descriptor_buffer[ts.current_descriptor_index] ;
ts.scale = 0 ;
ts.found = false ;
@ -315,146 +320,6 @@ __kernel void raycaster(
intersection_t += delta_t * fabs ( convert_float3 ( face_mask.xyz ) ) ;
voxel.xyz += voxel_step.xyz * face_mask.xyz ;
// =======================================================================================================================================
// =======================================================================================================================================
// =======================================================================================================================================
// uchar prev_val = traversal_state.idx_stack[traversal_state.scale] ;
// uint8_t this_face_mask = 0 ;
//
// // Check the voxel face that we traversed
// // and increment the idx in the idx stack
// if ( face_mask.x ) {
// this_face_mask = Octree::idx_set_x_mask ;
// }
// else if ( face_mask.y ) {
// this_face_mask = Octree::idx_set_y_mask ;
// }
// else if ( face_mask.z ) {
// this_face_mask = Octree::idx_set_z_mask ;
// }
//
// traversal_state.idx_stack[traversal_state.scale] ^= this_face_mask ;
//
// // Mask index is the 1D index 'd value of the idx for interaction with the valid / leaf masks
// int mask_index = traversal_state.idx_stack[traversal_state.scale] ;
//
// // Whether or not the next oct we want to enter in the current CD 's valid mask is 1 or 0
// bool is_valid = false ;
//
// // TODO: Rework this logic so we don 't have this bodgy if
// if ( mask_index > prev_val )
// is_valid = ( traversal_state.parent_stack[traversal_state.parent_stack_position] >> 16 ) & mask_8[mask_index] ;
//
// // Check to see if the idx increased or decreased
// // If it decreased
// // Pop up the stack until the oct that the idx flip is valid and we landed on a valid oct
// while ( mask_index < prev_val | | !is_valid ) {
//
// jump_power *= 2 ;
//
// // Keep track of the 0th edge of out current oct
// traversal_state.oct_pos.x = floor ( voxel.x / 2 ) * jump_power ;
// traversal_state.oct_pos.y = floor ( voxel.y / 2 ) * jump_power ;
// traversal_state.oct_pos.z = floor ( voxel.z / 2 ) * jump_power ;
//
// // Clear and pop the idx stack
// traversal_state.idx_stack[traversal_state.scale] = 0 ;
//
// // Scale is now set to the oct above. Be wary of this
// traversal_state.scale-- ;
//
// // Update the prev_val for our new idx
// prev_val = traversal_state.idx_stack[traversal_state.scale] ;
//
// // Clear and pop the parent stack, maybe off by one error?
// traversal_state.parent_stack_index[traversal_state.parent_stack_position] = 0 ;
// traversal_state.parent_stack[traversal_state.parent_stack_position] = 0 ;
// traversal_state.parent_stack_position-- ;
//
// // Set the current CD to the one on top of the stack
// traversal_state.current_descriptor =
// traversal_state.parent_stack[traversal_state.parent_stack_position] ;
//
// // Apply the face mask to the new idx for the while check
// traversal_state.idx_stack[traversal_state.scale] ^= this_face_mask ;
//
// // Get the mask index of the new idx and check the valid status
// mask_index = traversal_state.idx_stack[traversal_state.scale] ;
// is_valid = ( traversal_state.parent_stack[traversal_state.parent_stack_position] >> 16 ) & mask_8[mask_index] ;
// }
//
// // At this point parent_stack[position] is at the CD of an oct with a valid oct at the leaf indicated by the current
// // idx in the idx stack scale
//
// // While we haven 't bottomed out and the oct we 're looking at is valid
// while ( jump_power > 1 && is_valid ) {
//
// // If all went well and we found a valid non-leaf oct then we will traverse further down the hierarchy
// traversal_state.scale++ ;
// jump_power /= 2 ;
//
// // Count the number of valid octs that come before and add it to the index to get the position
// // Negate it by one as it counts itself
// int count = count_bits ( ( uint8_t ) ( traversal_state.parent_stack[traversal_state.parent_stack_position] >> 16 ) & count_mask_8[mask_index] ) - 1 ;
//
// // If this CD had the far bit set
// if ( far_bit_mask & descriptor_buffer[traversal_state.parent_stack_index[traversal_state.parent_stack_position]] ) {
//
// // access the far point at which the head points too. Determine it 's value, and add
// // the count of the valid bits in the current CD to the index
// uint64_t far_pointer_index =
// traversal_state.parent_stack_index[traversal_state.parent_stack_position] + // current index +
// ( traversal_state.parent_stack[traversal_state.parent_stack_position] & child_pointer_mask ) ; // the relative prt to the far ptr
//
// // Get the absolute ptr from the far ptr and add the count to get the CD that we want
// traversal_state.parent_stack_index[traversal_state.parent_stack_position + 1] = descriptor_buffer[far_pointer_index] + count ;
// }
// // If this CD doesn 't have the far bit set, access the element at which head points to
// // and then add the specified number of indices to get to the correct child descriptor
// else {
// traversal_state.parent_stack_index[traversal_state.parent_stack_position + 1] =
// traversal_state.parent_stack_index[traversal_state.parent_stack_position] + // The current index to this CD
// ( traversal_state.parent_stack[traversal_state.parent_stack_position] & child_pointer_mask ) + count ; // The relative dist + the number of bits that were valid
// }
//
// // Now that we have the index set we can increase our parent stack position to the next level and
// // retrieve the value of its CD
// traversal_state.parent_stack_position++ ;
// traversal_state.parent_stack[traversal_state.parent_stack_position] = descriptor_buffer[traversal_state.parent_stack_index[traversal_state.parent_stack_position]] ;
//
// // Unlike the single shot DFS, it makes a bit more sense to have this at the tail of the while loop
// // Do the logic steps to find which sub oct we step down into
// if ( voxel.x >= ( jump_power / 2 ) + traversal_state.oct_pos.x ) {
//
// // Set our voxel position to the ( 0 , 0 ) of the correct oct
// traversal_state.oct_pos.x += ( jump_power / 2 ) ;
//
// // Set the idx to represent the move
// traversal_state.idx_stack[traversal_state.scale] | = idx_set_x_mask ;
//
// }
// if ( voxel.y >= ( jump_power / 2 ) + traversal_state.oct_pos.y ) {
//
// traversal_state.oct_pos.y += ( jump_power / 2 ) ;
// traversal_state.idx_stack[traversal_state.scale] | = idx_set_y_mask ;
// }
// if ( voxel.z >= ( jump_power / 2 ) + traversal_state.oct_pos.z ) {
//
// traversal_state.oct_pos.z += ( jump_power / 2 ) ;
// traversal_state.idx_stack[traversal_state.scale] | = idx_set_z_mask ;
// }
//
// // Update the mask index with the new voxel we walked down to, and then check it 's valid status
// mask_index = traversal_state.idx_stack[traversal_state.scale] ;
// is_valid = ( traversal_state.parent_stack[traversal_state.parent_stack_position] >> 16 ) & mask_8[mask_index] ;
//
// }
// =======================================================================================================================================
// =======================================================================================================================================
// =======================================================================================================================================
// Test for out of bounds contions, add fog
if ( any ( voxel >= *map_dim ) | | any ( voxel < 0 ) ) {
voxel.xyz -= voxel_step.xyz * face_mask.xyz ;
@ -462,11 +327,11 @@ __kernel void raycaster(
color_accumulator.w *= 4 ;
break ;
}
int vox_dim = setting ( OCTDIM ) ;
int vox_dim = OCTDIM ;
// If we hit a voxel
// If we hit a voxel
// if ( voxel.x < ( *map_dim ) . x && voxel.y < ( *map_dim ) . x && voxel.z < ( *map_dim ) . x ) {
if ( voxel.x < ( *map_dim ) . x && voxel.y < ( *map_dim ) . x && voxel.z < ( *map_dim ) . x ) {
// if ( get_oct_vox (
// voxel,
// octree_descriptor_buffer,
@ -480,7 +345,7 @@ __kernel void raycaster(
// }
// } else {
voxel_data = map[voxel.x + ( *map_dim ) . x * ( voxel.y + ( *map_dim ) . z * ( voxel.z ) ) ] ;
// }
