Saving before breaking changes

master
MitchellHansen 8 years ago
parent ce862feb0b
commit c7bde50e0d

@ -24,16 +24,16 @@ public:
Map(uint32_t dimensions); Map(uint32_t dimensions);
void generate_octree(); void dump_logs();
void setVoxel(sf::Vector3i position, int val); void setVoxel(sf::Vector3i position, int val);
bool getVoxelFromOctree(sf::Vector3i position); bool getVoxelFromOctree(sf::Vector3i position);
bool getVoxel(sf::Vector3i pos); bool getVoxel(sf::Vector3i pos);
Octree a; Octree octree;
void test_map(); bool test();
private: private:
@ -42,6 +42,9 @@ private:
std::stringstream output_stream; std::stringstream output_stream;
// ========================= // =========================
void generate_octree(unsigned int dimensions);
// Generate children is the main recursive function
uint64_t generate_children(sf::Vector3i pos, int dim); uint64_t generate_children(sf::Vector3i pos, int dim);
char* voxel_data; char* voxel_data;

@ -10,13 +10,16 @@ public:
Octree(); Octree();
~Octree() {}; ~Octree() {};
uint64_t *blob = new uint64_t[100000]; uint64_t *trunk_buffer = new uint64_t[10000];
uint64_t *descriptor_buffer = new uint64_t[100000];
uint32_t *attachment_lookup = new uint32_t[100000];
uint64_t *attachment_buffer = new uint64_t[100000];
uint64_t root_index = 0; uint64_t root_index = 0;
uint64_t stack_pos = 0x8000; uint64_t stack_pos = 0x8000;
uint64_t global_pos = 0; uint64_t global_pos = 0;
uint64_t copy_to_stack(std::vector<uint64_t> children); uint64_t copy_to_stack(std::vector<uint64_t> children, unsigned int voxel_scale);
// With a position and the head of the stack. Traverse down the voxel hierarchy to find // With a position and the head of the stack. Traverse down the voxel hierarchy to find
// the IDX and stack position of the highest resolution (maybe set resolution?) oct // the IDX and stack position of the highest resolution (maybe set resolution?) oct
@ -26,22 +29,28 @@ public:
private: private:
std::vector<uint64_t> anchor_stack;
unsigned int octree_voxel_dimension = 32;
// (X, Y, Z) mask for the idx // (X, Y, Z) mask for the idx
const uint8_t idx_set_x_mask = 0x1; const uint8_t idx_set_x_mask = 0x1;
const uint8_t idx_set_y_mask = 0x2; const uint8_t idx_set_y_mask = 0x2;
const uint8_t idx_set_z_mask = 0x4; const uint8_t idx_set_z_mask = 0x4;
// Mask for // Mask for checking if valid or leaf
const uint8_t mask_8[8] = { const uint8_t mask_8[8] = {
0x1, 0x2, 0x4, 0x8, 0x1, 0x2, 0x4, 0x8,
0x10, 0x20, 0x40, 0x80 0x10, 0x20, 0x40, 0x80
}; };
// Mask for counting the previous valid bits
const uint8_t count_mask_8[8]{ const uint8_t count_mask_8[8]{
0x1, 0x3, 0x7, 0xF, 0x1, 0x3, 0x7, 0xF,
0x1F, 0x3F, 0x7F, 0xFF 0x1F, 0x3F, 0x7F, 0xFF
}; };
// uint64_t manipulation masks
const uint64_t child_pointer_mask = 0x0000000000007fff; const uint64_t child_pointer_mask = 0x0000000000007fff;
const uint64_t far_bit_mask = 0x8000; const uint64_t far_bit_mask = 0x8000;
const uint64_t valid_mask = 0xFF0000; const uint64_t valid_mask = 0xFF0000;

@ -385,6 +385,6 @@ __kernel void raycaster(
} while (++dist < 700.0f); } while (++dist < 700.0f);
write_imagef(image, pixel, white_light(mix(fog_color, (float4)(0.40, 0.00, 0.40, 0.2), 1.0 - max(dist / 700.0f, (float)0)), (float3)(lights[7], lights[8], lights[9]), face_mask)); //write_imagef(image, pixel, white_light(mix(fog_color, (float4)(0.40, 0.00, 0.40, 0.2), 1.0 - max(dist / 700.0f, (float)0)), (float3)(lights[7], lights[8], lights[9]), face_mask));
return; return;
} }

@ -92,9 +92,8 @@ int main() {
// ============================= // =============================
Map _map(32); Map _map(32);
_map.generate_octree(); _map.test();
_map.a.print_block(0); _map.dump_logs();
_map.test_map();
//std::cin.get(); //std::cin.get();
//return 0; //return 0;
// ============================= // =============================
@ -102,7 +101,7 @@ int main() {
sf::RenderWindow window(sf::VideoMode(WINDOW_X, WINDOW_Y), "SFML"); sf::RenderWindow window(sf::VideoMode(WINDOW_X, WINDOW_Y), "SFML");
window.setMouseCursorVisible(false); window.setMouseCursorVisible(false);
window.setKeyRepeatEnabled(false); window.setKeyRepeatEnabled(false);
window.setFramerateLimit(120); //window.setFramerateLimit(120);
window.setVerticalSyncEnabled(false); window.setVerticalSyncEnabled(false);
ImGui::SFML::Init(window); ImGui::SFML::Init(window);

@ -11,8 +11,16 @@ Map::Map(uint32_t dimensions) {
if (rand() % 25 < 2) if (rand() % 25 < 2)
voxel_data[i] = 1; voxel_data[i] = 1;
else else
voxel_data[i] = 1; voxel_data[i] = 0;
}
generate_octree(dimensions);
} }
void Map::dump_logs() {
octree.print_block(0);
} }
uint64_t Map::generate_children(sf::Vector3i pos, int voxel_scale) { uint64_t Map::generate_children(sf::Vector3i pos, int voxel_scale) {
@ -36,7 +44,6 @@ uint64_t Map::generate_children(sf::Vector3i pos, int voxel_scale) {
// want to do chunking / loading of raw data I can edit the voxel access // want to do chunking / loading of raw data I can edit the voxel access
if (voxel_scale == 1) { if (voxel_scale == 1) {
//
uint64_t child_descriptor = 0; uint64_t child_descriptor = 0;
// Setting the individual valid mask bits // Setting the individual valid mask bits
@ -49,8 +56,8 @@ uint64_t Map::generate_children(sf::Vector3i pos, int voxel_scale) {
// We are querying leafs, so we need to fill the leaf mask // We are querying leafs, so we need to fill the leaf mask
child_descriptor |= 0xFF000000; child_descriptor |= 0xFF000000;
// This is where contours // The CP will be left blank, contour mask and ptr will need to
// The CP will be left blank, contours will be added maybe // be added here later
return child_descriptor; return child_descriptor;
} }
@ -92,7 +99,7 @@ uint64_t Map::generate_children(sf::Vector3i pos, int voxel_scale) {
// interlace them and allow the memory handler to work correctly. // interlace them and allow the memory handler to work correctly.
// Copy the children to the stack and set the child_descriptors pointer to the correct value // Copy the children to the stack and set the child_descriptors pointer to the correct value
child_descriptor |= a.copy_to_stack(descriptor_array); child_descriptor |= octree.copy_to_stack(descriptor_array, voxel_scale);
// Free space may also be allocated here as well // Free space may also be allocated here as well
@ -100,19 +107,18 @@ uint64_t Map::generate_children(sf::Vector3i pos, int voxel_scale) {
return child_descriptor; return child_descriptor;
} }
void Map::generate_octree() { void Map::generate_octree(unsigned int dimensions) {
// Launch the recursive generator at (0,0,0) as the first point // Launch the recursive generator at (0,0,0) as the first point
// and the octree dimension as the initial block size // and the octree dimension as the initial block size
uint64_t root_node = generate_children(sf::Vector3i(0, 0, 0), OCT_DIM/2); uint64_t root_node = generate_children(sf::Vector3i(0, 0, 0), OCT_DIM/2);
uint64_t tmp = 0;
// ========= DEBUG ============== // ========= DEBUG ==============
PrettyPrintUINT64(root_node, &output_stream); PrettyPrintUINT64(root_node, &output_stream);
output_stream << " " << OCT_DIM << " " << counter++ << std::endl; output_stream << " " << OCT_DIM << " " << counter++ << std::endl;
// ============================== // ==============================
a.root_index = a.copy_to_stack(std::vector<uint64_t>{root_node}); octree.root_index = octree.copy_to_stack(std::vector<uint64_t>{root_node}, OCT_DIM);
// Dump the debug log // Dump the debug log
DumpLog(&output_stream, "raw_output.txt"); DumpLog(&output_stream, "raw_output.txt");
@ -125,7 +131,7 @@ void Map::setVoxel(sf::Vector3i world_position, int val) {
bool Map::getVoxelFromOctree(sf::Vector3i position) bool Map::getVoxelFromOctree(sf::Vector3i position)
{ {
return a.get_voxel(position); return octree.get_voxel(position);
} }
bool Map::getVoxel(sf::Vector3i pos){ bool Map::getVoxel(sf::Vector3i pos){
@ -137,7 +143,7 @@ bool Map::getVoxel(sf::Vector3i pos){
} }
} }
void Map::test_map() { bool Map::test() {
std::cout << "Validating map..." << std::endl; std::cout << "Validating map..." << std::endl;
@ -192,5 +198,7 @@ void Map::test_map() {
std::cout << "Octree linear xyz access : "; std::cout << "Octree linear xyz access : ";
std::cout << timer.restart().asMicroseconds() << " microseconds" << std::endl; std::cout << timer.restart().asMicroseconds() << " microseconds" << std::endl;
return true;
} }

@ -5,24 +5,38 @@ Octree::Octree() {
// initialize the first stack block // initialize the first stack block
for (int i = 0; i < 0x8000; i++) { for (int i = 0; i < 0x8000; i++) {
blob[i] = 0; descriptor_buffer[i] = 0;
} }
} }
uint64_t Octree::copy_to_stack(std::vector<uint64_t> children) {
// Check for the 15 bit boundry // Copy to stack enables the hybrid depth-breadth first tree by taking
if (stack_pos - children.size() > stack_pos) { // a list of valid non-leaf child descriptors contained under a common parent.
global_pos = stack_pos;
stack_pos = 0x8000; uint64_t Octree::copy_to_stack(std::vector<uint64_t> children, unsigned int voxel_scale) {
}
else { //// Check for the 15 bit boundry
stack_pos -= children.size(); //if (stack_pos - children.size() > stack_pos) {
} // global_pos = stack_pos;
// stack_pos = 0x8000;
//}
//else {
// stack_pos -= children.size();
//}
// Check for the far bit // Copy to stack needs to keep track of an "anchor_stack" which will hopefully facilitate
// relative pointer generation for items being copied to the stack
memcpy(&blob[stack_pos + global_pos], children.data(), children.size() * sizeof(uint64_t)); // We need to return the relative pointer to the child node list
// 16 bits, one far bit, one sign bit? 14 bits == +- 16384
// Worth halving the ptr reach to enable backwards ptrs?
// could increase packability allowing far ptrs and attachments to come before or after
stack_pos -= children.size();
memcpy(&descriptor_buffer[stack_pos + global_pos], children.data(), children.size() * sizeof(uint64_t));
// Return the bitmask encoding the index of that value // Return the bitmask encoding the index of that value
// If we tripped the far bit, allocate a far index to the stack and place // If we tripped the far bit, allocate a far index to the stack and place
@ -39,7 +53,7 @@ bool Octree::get_voxel(sf::Vector3i position) {
oct_state state; oct_state state;
// push the root node to the parent stack // push the root node to the parent stack
uint64_t head = blob[root_index]; uint64_t head = descriptor_buffer[root_index];
state.parent_stack[state.parent_stack_position] = head; state.parent_stack[state.parent_stack_position] = head;
// Set our initial dimension and the position at the corner of the oct to keep track of our position // Set our initial dimension and the position at the corner of the oct to keep track of our position
@ -116,7 +130,7 @@ bool Octree::get_voxel(sf::Vector3i position) {
// access the element at which head points to and then add the specified number of indices // access the element at which head points to and then add the specified number of indices
// to get to the correct child descriptor // to get to the correct child descriptor
head = blob[(head & child_pointer_mask) + count]; head = descriptor_buffer[(head & child_pointer_mask) + count];
// Increment the parent stack position and put the new oct node as the parent // Increment the parent stack position and put the new oct node as the parent
state.parent_stack_position++; state.parent_stack_position++;
@ -142,7 +156,7 @@ void Octree::print_block(int block_pos) {
std::stringstream sss; std::stringstream sss;
for (int i = block_pos; i < (int)pow(2, 15); i++) { for (int i = block_pos; i < (int)pow(2, 15); i++) {
PrettyPrintUINT64(blob[i], &sss); PrettyPrintUINT64(descriptor_buffer[i], &sss);
sss << "\n"; sss << "\n";
} }
DumpLog(&sss, "raw_data.txt"); DumpLog(&sss, "raw_data.txt");

@ -613,7 +613,7 @@ int Hardware_Caster::compile_kernel(std::string kernel_source, bool is_path, std
// Try and build the program // Try and build the program
// "-cl-finite-math-only -cl-fast-relaxed-math -cl-unsafe-math-optimizations" // "-cl-finite-math-only -cl-fast-relaxed-math -cl-unsafe-math-optimizations"
error = clBuildProgram(program, 1, &device_id, NULL, NULL, NULL); error = clBuildProgram(program, 1, &device_id, "-cl-finite-math-only -cl-fast-relaxed-math -cl-unsafe-math-optimizations", NULL, NULL);
// Check to see if it errored out // Check to see if it errored out
if (vr_assert(error, "clBuildProgram")) { if (vr_assert(error, "clBuildProgram")) {

Loading…
Cancel
Save