clean up DeviceRRGSB internal data and member functions

This commit is contained in:
tangxifan 2019-06-07 14:45:56 -06:00
parent c9f810ceb6
commit 24d53390d8
6 changed files with 255 additions and 275 deletions

View File

@ -1273,7 +1273,7 @@ DeviceRRGSB build_device_rr_gsb(boolean output_sb_xml, char* sb_xml_dir,
LL_rr_node_indices,
num_segments, LL_rr_indexed_data);
DeviceCoordinator sb_coordinator = rr_sb.get_sb_coordinator();
LL_drive_rr_gsb.add_rr_switch_block(sb_coordinator, rr_sb);
LL_drive_rr_gsb.add_rr_gsb(sb_coordinator, rr_sb);
}
}
/* Report number of unique mirrors */
@ -1281,10 +1281,6 @@ DeviceRRGSB build_device_rr_gsb(boolean output_sb_xml, char* sb_xml_dir,
"Backannotated %d switch blocks.\n",
(nx + 1) * (ny + 1) );
LL_drive_rr_gsb.build_segment_ids();
vpr_printf(TIO_MESSAGE_INFO,
"Detect %lu routing segments used by switch blocks.\n",
LL_drive_rr_gsb.get_num_segments());
if (TRUE == output_sb_xml) {
write_device_rr_gsb_to_xml(sb_xml_dir, LL_drive_rr_gsb);
@ -1297,15 +1293,18 @@ DeviceRRGSB build_device_rr_gsb(boolean output_sb_xml, char* sb_xml_dir,
}
/* Build a list of unique modules for each Switch Block */
LL_drive_rr_gsb.build_unique_mirror();
/* Build a list of unique modules for each side of each Switch Block */
LL_drive_rr_gsb.build_sb_unique_module();
/* Report number of unique mirrors */
vpr_printf(TIO_MESSAGE_INFO,
"Detect %d independent switch blocks from %d switch blocks.\n",
LL_drive_rr_gsb.get_num_unique_mirror(), (nx + 1) * (ny + 1) );
"Detect %lu routing segments used by switch blocks.\n",
LL_drive_rr_gsb.get_num_segments());
vpr_printf(TIO_MESSAGE_INFO,
"Detect %d independent switch blocks from %d switch blocks.\n",
LL_drive_rr_gsb.get_num_sb_unique_module(), (nx + 1) * (ny + 1) );
/* Build a list of unique modules for each side of each Switch Block */
LL_drive_rr_gsb.build_unique_module();
/* Report number of unique mirrors */
for (size_t side = 0; side < LL_drive_rr_gsb.get_max_num_sides(); ++side) {
Side side_manager(side);
@ -1314,7 +1313,7 @@ DeviceRRGSB build_device_rr_gsb(boolean output_sb_xml, char* sb_xml_dir,
vpr_printf(TIO_MESSAGE_INFO,
"For side %s, segment id %lu: Detect %d independent switch blocks from %d switch blocks.\n",
side_manager.to_string(), LL_drive_rr_gsb.get_segment_id(iseg),
LL_drive_rr_gsb.get_num_unique_module(side_manager.get_side(), iseg),
LL_drive_rr_gsb.get_num_sb_unique_submodule(side_manager.get_side(), iseg),
(nx + 1) * (ny + 1) );
}
}
@ -1328,9 +1327,6 @@ DeviceRRGSB build_device_rr_gsb(boolean output_sb_xml, char* sb_xml_dir,
for (size_t iy = 0; iy <= sb_range.get_y(); ++iy) {
RRGSB rr_sb = LL_drive_rr_gsb.get_gsb(ix, iy);
RRGSB rotated_rr_sb = rotate_rr_switch_block_for_mirror(sb_range, rr_sb);
DeviceCoordinator sb_coordinator = rr_sb.get_sb_coordinator();
LL_drive_rr_gsb.add_rotatable_mirror(sb_coordinator, rotated_rr_sb);
if (TRUE == output_sb_xml) {
std::string fname_prefix(sb_xml_dir);
/* Add slash if needed */
@ -1343,11 +1339,6 @@ DeviceRRGSB build_device_rr_gsb(boolean output_sb_xml, char* sb_xml_dir,
}
}
/* Skip rotating mirror searching */
vpr_printf(TIO_MESSAGE_INFO,
"Detect %d rotatable unique switch blocks from %d switch blocks.\n",
LL_drive_rr_gsb.get_num_rotatable_mirror(), (nx + 1) * (ny + 1) );
return LL_drive_rr_gsb;
}

View File

@ -1949,26 +1949,18 @@ bool RRGSB::validate_cb_type(t_rr_type cb_type) const {
DeviceCoordinator DeviceRRGSB::get_gsb_range() const {
size_t max_y = 0;
/* Get the largest size of sub-arrays */
for (size_t x = 0; x < rr_gsb.size(); ++x) {
max_y = std::max(max_y, rr_gsb[x].size());
for (size_t x = 0; x < rr_gsb_.size(); ++x) {
max_y = std::max(max_y, rr_gsb_[x].size());
}
DeviceCoordinator coordinator(rr_gsb.size(), max_y);
DeviceCoordinator coordinator(rr_gsb_.size(), max_y);
return coordinator;
}
/* Get a rr switch block in the array with a coordinator */
RRGSB DeviceRRGSB::get_gsb(DeviceCoordinator& coordinator) const {
assert(validate_coordinator(coordinator));
return rr_gsb[coordinator.get_x()][coordinator.get_y()];
}
/* get the number of unique side modules of switch blocks */
size_t DeviceRRGSB::get_num_unique_module(enum e_side side, size_t seg_index) const {
Side side_manager(side);
assert(validate_side(side));
assert(validate_segment_index(seg_index));
return unique_module_[side_manager.to_size_t()][seg_index].size();
return rr_gsb_[coordinator.get_x()][coordinator.get_y()];
}
/* Get a rr switch block in the array with a coordinator */
@ -1977,53 +1969,78 @@ RRGSB DeviceRRGSB::get_gsb(size_t x, size_t y) const {
return get_gsb(coordinator);
}
/* get the number of unique mirrors of switch blocks */
size_t DeviceRRGSB::get_num_unique_mirror() const {
return unique_mirror_.size();
/* get the number of unique side modules of switch blocks */
size_t DeviceRRGSB::get_num_sb_unique_submodule(enum e_side side, size_t seg_index) const {
Side side_manager(side);
assert(validate_side(side));
assert(validate_segment_index(seg_index));
return sb_unique_submodule_[side_manager.to_size_t()][seg_index].size();
}
/* get the number of rotatable mirrors of switch blocks */
size_t DeviceRRGSB::get_num_rotatable_mirror() const {
return rotatable_mirror_.size();
/* get the number of unique mirrors of switch blocks */
size_t DeviceRRGSB::get_num_sb_unique_module() const {
return sb_unique_module_.size();
}
/* Get the submodule id of a SB */
size_t DeviceRRGSB::get_sb_unique_submodule_id(DeviceCoordinator& coordinator, enum e_side side, size_t seg_id) const {
assert (validate_coordinator(coordinator));
Side side_manager(side);
assert (validate_side(side));
assert (validate_segment_index(seg_id));
size_t x = coordinator.get_x();
size_t y = coordinator.get_y();
return sb_unique_submodule_id_[x][y][side][seg_id];
}
/* Get a rr switch block which is a unique module of a side of SB */
RRGSB DeviceRRGSB::get_unique_side_module(size_t index, enum e_side side, size_t seg_id) const {
assert (validate_unique_module_index(index, side, seg_id));
RRGSB DeviceRRGSB::get_sb_unique_submodule(size_t index, enum e_side side, size_t seg_id) const {
assert (validate_sb_unique_submodule_index(index, side, seg_id));
Side side_manager(side);
assert (validate_side(side));
return rr_gsb[unique_module_[side_manager.to_size_t()][seg_id][index].get_x()][unique_module_[side_manager.to_size_t()][seg_id][index].get_y()];
size_t x = sb_unique_submodule_[side_manager.to_size_t()][seg_id][index].get_x();
size_t y = sb_unique_submodule_[side_manager.to_size_t()][seg_id][index].get_y();
return rr_gsb_[x][y];
}
/* Get a rr switch block which a unique mirror */
RRGSB DeviceRRGSB::get_unique_mirror(size_t index) const {
assert (validate_unique_mirror_index(index));
/* Get a rr switch block which is a unique module of a side of SB */
RRGSB DeviceRRGSB::get_sb_unique_submodule(DeviceCoordinator& coordinator, enum e_side side, size_t seg_id) const {
assert (validate_coordinator(coordinator));
return rr_gsb[unique_mirror_[index].get_x()][unique_mirror_[index].get_y()];
Side side_manager(side);
assert (validate_side(side));
size_t module_id = get_sb_unique_submodule_id(coordinator, side, seg_id);
return get_sb_unique_submodule(module_id, side, seg_id);
}
/* Get a rr switch block which a unique mirror */
RRGSB DeviceRRGSB::get_sb_unique_module(size_t index) const {
assert (validate_sb_unique_module_index(index));
return rr_gsb_[sb_unique_module_[index].get_x()][sb_unique_module_[index].get_y()];
}
/* Give a coordinator of a rr switch block, and return its unique mirror */
RRGSB DeviceRRGSB::get_unique_mirror(DeviceCoordinator& coordinator) const {
RRGSB DeviceRRGSB::get_sb_unique_module(DeviceCoordinator& coordinator) const {
assert(validate_coordinator(coordinator));
size_t unique_mirror_id = rr_gsbmirror_id_[coordinator.get_x()][coordinator.get_y()];
return get_unique_mirror(unique_mirror_id);
}
/* Get a rr switch block which a unique mirror */
RRGSB DeviceRRGSB::get_rotatable_mirror(size_t index) const {
assert (validate_rotatable_mirror_index(index));
return rr_gsb[rotatable_mirror_[index].get_x()][rotatable_mirror_[index].get_y()];
size_t sb_unique_module_id = sb_unique_module_id_[coordinator.get_x()][coordinator.get_y()];
return get_sb_unique_module(sb_unique_module_id);
}
/* Get the maximum number of sides across the switch blocks */
size_t DeviceRRGSB::get_max_num_sides() const {
size_t max_num_sides = 0;
for (size_t ix = 0; ix < rr_gsb.size(); ++ix) {
for (size_t iy = 0; iy < rr_gsb[ix].size(); ++iy) {
max_num_sides = std::max(max_num_sides, rr_gsb[ix][iy].get_num_sides());
for (size_t ix = 0; ix < rr_gsb_.size(); ++ix) {
for (size_t iy = 0; iy < rr_gsb_[ix].size(); ++iy) {
max_num_sides = std::max(max_num_sides, rr_gsb_[ix][iy].get_num_sides());
}
}
return max_num_sides;
@ -2040,56 +2057,73 @@ size_t DeviceRRGSB::get_segment_id(size_t index) const {
return segment_ids_[index];
}
/* Evaluate if the Switch Blocks of two GSBs share exactly the same submodule */
bool DeviceRRGSB::is_two_sb_share_same_submodules(DeviceCoordinator& src, DeviceCoordinator& des) const {
/* check the numbers of sides */
if (get_gsb(src).get_num_sides() != get_gsb(des).get_num_sides()) {
return false;
}
/* check the numbers/directionality of channel rr_nodes */
for (size_t side = 0; side < get_gsb(src).get_num_sides(); ++side) {
Side side_manager(side);
for (size_t iseg = 0; iseg < get_num_segments(); ++iseg) {
if ( get_sb_unique_submodule_id(src, side_manager.get_side(), iseg)
!= get_sb_unique_submodule_id(des, side_manager.get_side(), iseg)) {
return false;
}
}
}
return true;
}
/* Public Mutators */
/* TODO: TOBE DEPRECATED!!! conf_bits should be initialized when creating a switch block!!! */
void DeviceRRGSB::set_sb_num_reserved_conf_bits(DeviceCoordinator& coordinator, size_t num_reserved_conf_bits) {
assert(validate_coordinator(coordinator));
rr_gsb[coordinator.get_x()][coordinator.get_y()].set_sb_num_reserved_conf_bits(num_reserved_conf_bits);
rr_gsb_[coordinator.get_x()][coordinator.get_y()].set_sb_num_reserved_conf_bits(num_reserved_conf_bits);
return;
}
/* TODO: TOBE DEPRECATED!!! conf_bits should be initialized when creating a switch block!!! */
void DeviceRRGSB::set_sb_conf_bits_lsb(DeviceCoordinator& coordinator, size_t conf_bits_lsb) {
assert(validate_coordinator(coordinator));
rr_gsb[coordinator.get_x()][coordinator.get_y()].set_sb_conf_bits_lsb(conf_bits_lsb);
rr_gsb_[coordinator.get_x()][coordinator.get_y()].set_sb_conf_bits_lsb(conf_bits_lsb);
return;
}
/* TODO: TOBE DEPRECATED!!! conf_bits should be initialized when creating a switch block!!! */
void DeviceRRGSB::set_sb_conf_bits_msb(DeviceCoordinator& coordinator, size_t conf_bits_msb) {
assert(validate_coordinator(coordinator));
rr_gsb[coordinator.get_x()][coordinator.get_y()].set_sb_conf_bits_msb(conf_bits_msb);
rr_gsb_[coordinator.get_x()][coordinator.get_y()].set_sb_conf_bits_msb(conf_bits_msb);
return;
}
/* Pre-allocate the rr_switch_block array that the device requires */
void DeviceRRGSB::reserve(DeviceCoordinator& coordinator) {
rr_gsb.resize(coordinator.get_x());
rr_sb_unique_module_id_.resize(coordinator.get_x());
rr_gsbmirror_id_.resize(coordinator.get_x());
rr_gsbrotatable_mirror_id_.resize(coordinator.get_x());
rr_gsb_.resize(coordinator.get_x());
sb_unique_submodule_id_.resize(coordinator.get_x());
sb_unique_module_id_.resize(coordinator.get_x());
for (size_t x = 0; x < coordinator.get_x(); ++x) {
rr_gsb[x].resize(coordinator.get_y());
rr_sb_unique_module_id_[x].resize(coordinator.get_y());
rr_gsbmirror_id_[x].resize(coordinator.get_y());
rr_gsbrotatable_mirror_id_[x].resize(coordinator.get_y());
rr_gsb_[x].resize(coordinator.get_y());
sb_unique_submodule_id_[x].resize(coordinator.get_y());
sb_unique_module_id_[x].resize(coordinator.get_y());
}
return;
}
/* Pre-allocate the rr_sb_unique_module_id matrix that the device requires */
void DeviceRRGSB::reserve_unique_module_id(DeviceCoordinator& coordinator) {
void DeviceRRGSB::reserve_sb_unique_submodule_id(DeviceCoordinator& coordinator) {
RRGSB rr_sb = get_gsb(coordinator);
rr_sb_unique_module_id_[coordinator.get_x()][coordinator.get_y()].resize(rr_sb.get_num_sides());
sb_unique_submodule_id_[coordinator.get_x()][coordinator.get_y()].resize(rr_sb.get_num_sides());
for (size_t side = 0; side < rr_sb.get_num_sides(); ++side) {
Side side_manager(side);
rr_sb_unique_module_id_[coordinator.get_x()][coordinator.get_y()][side_manager.to_size_t()].resize(segment_ids_.size());
sb_unique_submodule_id_[coordinator.get_x()][coordinator.get_y()][side_manager.to_size_t()].resize(segment_ids_.size());
}
return;
@ -2097,69 +2131,75 @@ void DeviceRRGSB::reserve_unique_module_id(DeviceCoordinator& coordinator) {
/* Resize rr_switch_block array is needed*/
void DeviceRRGSB::resize_upon_need(DeviceCoordinator& coordinator) {
if (coordinator.get_x() + 1 > rr_gsb.size()) {
rr_gsb.resize(coordinator.get_x() + 1);
rr_sb_unique_module_id_.resize(coordinator.get_x() + 1);
rr_gsbmirror_id_.resize(coordinator.get_x() + 1);
rr_gsbrotatable_mirror_id_.resize(coordinator.get_x() + 1);
if (coordinator.get_x() + 1 > rr_gsb_.size()) {
rr_gsb_.resize(coordinator.get_x() + 1);
sb_unique_submodule_id_.resize(coordinator.get_x() + 1);
sb_unique_module_id_.resize(coordinator.get_x() + 1);
}
if (coordinator.get_y() + 1 > rr_gsb[coordinator.get_x()].size()) {
rr_gsb[coordinator.get_x()].resize(coordinator.get_y() + 1);
rr_sb_unique_module_id_[coordinator.get_x()].resize(coordinator.get_y() + 1);
rr_gsbmirror_id_[coordinator.get_x()].resize(coordinator.get_y() + 1);
rr_gsbrotatable_mirror_id_[coordinator.get_x()].resize(coordinator.get_y() + 1);
if (coordinator.get_y() + 1 > rr_gsb_[coordinator.get_x()].size()) {
rr_gsb_[coordinator.get_x()].resize(coordinator.get_y() + 1);
sb_unique_submodule_id_[coordinator.get_x()].resize(coordinator.get_y() + 1);
sb_unique_module_id_[coordinator.get_x()].resize(coordinator.get_y() + 1);
}
return;
}
/* Add a switch block to the array, which will automatically identify and update the lists of unique mirrors and rotatable mirrors */
void DeviceRRGSB::add_rr_switch_block(DeviceCoordinator& coordinator,
RRGSB& rr_sb) {
void DeviceRRGSB::add_rr_gsb(DeviceCoordinator& coordinator,
RRGSB& rr_gsb) {
/* Resize upon needs*/
resize_upon_need(coordinator);
/* Add the switch block into array */
rr_gsb[coordinator.get_x()][coordinator.get_y()] = rr_sb;
rr_gsb_[coordinator.get_x()][coordinator.get_y()] = rr_gsb;
return;
}
/* Add a switch block to the array, which will automatically identify and update the lists of unique mirrors and rotatable mirrors */
void DeviceRRGSB::build_unique_mirror() {
void DeviceRRGSB::build_sb_unique_module() {
/* Make sure a clean start */
clear_mirror();
clear_sb_unique_module();
for (size_t ix = 0; ix < rr_gsb.size(); ++ix) {
for (size_t iy = 0; iy < rr_gsb[ix].size(); ++iy) {
bool is_unique_mirror = true;
RRGSB* rr_sb = &(rr_gsb[ix][iy]);
/* build segment id look-up*/
build_segment_ids();
/* Build the unique submodule */
build_sb_unique_submodule();
for (size_t ix = 0; ix < rr_gsb_.size(); ++ix) {
for (size_t iy = 0; iy < rr_gsb_[ix].size(); ++iy) {
bool is_unique_module = true;
DeviceCoordinator sb_coordinator(ix, iy);
/* Traverse the unique_mirror list and check it is an mirror of another */
for (size_t mirror_id = 0; mirror_id < get_num_unique_mirror(); ++mirror_id) {
for (size_t id = 0; id < get_num_sb_unique_module(); ++id) {
/* If we have the same coordinator, this is already not unique_mirror */
if ( (ix == unique_mirror_[mirror_id].get_x())
&& (iy == unique_mirror_[mirror_id].get_y()) ) {
is_unique_mirror = false;
if ( (ix == sb_unique_module_[id].get_x())
&& (iy == sb_unique_module_[id].get_y()) ) {
is_unique_module = false;
break;
}
if (true == get_gsb(unique_mirror_[mirror_id]).is_sb_mirror(*rr_sb)) {
/* Check if the two modules have the same submodules,
* if so, these two modules are the same, indicating the sb is not unique.
* else the sb is unique
*/
if (true == is_two_sb_share_same_submodules(sb_unique_module_[id], sb_coordinator)) {
/* This is a mirror, raise the flag and we finish */
is_unique_mirror = false;
is_unique_module = false;
/* Record the id of unique mirror */
rr_gsbmirror_id_[ix][iy] = mirror_id;
sb_unique_module_id_[ix][iy] = id;
break;
}
}
/* Add to list if this is a unique mirror*/
if (true == is_unique_mirror) {
if (true == is_unique_module) {
DeviceCoordinator coordinator(ix, iy);
unique_mirror_.push_back(coordinator);
sb_unique_module_.push_back(coordinator);
/* Record the id of unique mirror */
rr_gsbmirror_id_[ix][iy] = unique_mirror_.size() - 1;
sb_unique_module_id_[ix][iy] = sb_unique_module_.size() - 1;
}
}
}
@ -2167,68 +2207,35 @@ void DeviceRRGSB::build_unique_mirror() {
}
/* Add a switch block to the array, which will automatically identify and update the lists of unique mirrors and rotatable mirrors */
void DeviceRRGSB::build_unique_module() {
void DeviceRRGSB::build_sb_unique_submodule() {
/* Make sure a clean start */
clear_unique_module();
clear_sb_unique_submodule();
/* Allocate the unique_side_module_ */
unique_module_.resize(get_max_num_sides());
for (size_t side = 0; side < unique_module_.size(); ++side) {
unique_module_[side].resize(segment_ids_.size());
sb_unique_submodule_.resize(get_max_num_sides());
for (size_t side = 0; side < sb_unique_submodule_.size(); ++side) {
sb_unique_submodule_[side].resize(segment_ids_.size());
}
for (size_t ix = 0; ix < rr_gsb.size(); ++ix) {
for (size_t iy = 0; iy < rr_gsb[ix].size(); ++iy) {
for (size_t ix = 0; ix < rr_gsb_.size(); ++ix) {
for (size_t iy = 0; iy < rr_gsb_[ix].size(); ++iy) {
DeviceCoordinator coordinator(ix, iy);
RRGSB rr_sb = rr_gsb[ix][iy];
RRGSB rr_sb = rr_gsb_[ix][iy];
/* reserve the rr_sb_unique_module_id */
reserve_unique_module_id(coordinator);
reserve_sb_unique_submodule_id(coordinator);
for (size_t side = 0; side < rr_sb.get_num_sides(); ++side) {
Side side_manager(side);
/* Try to add it to the list */
add_unique_side_module(coordinator, rr_sb, side_manager.get_side());
add_sb_unique_side_submodule(coordinator, rr_sb, side_manager.get_side());
}
}
}
return;
}
void DeviceRRGSB::add_rotatable_mirror(DeviceCoordinator& coordinator,
RRGSB& rotated_rr_sb) {
bool is_rotatable_mirror = true;
/* add rotatable mirror support */
for (size_t mirror_id = 0; mirror_id < get_num_rotatable_mirror(); ++mirror_id) {
/* Skip if these may never match as a mirror (violation in basic requirements */
if (false == get_gsb(rotatable_mirror_[mirror_id]).is_sb_mirrorable(rotated_rr_sb)) {
continue;
}
if (true == get_gsb(rotatable_mirror_[mirror_id]).is_sb_mirror(rotated_rr_sb)) {
/* This is a mirror, raise the flag and we finish */
is_rotatable_mirror = false;
/* Record the id of unique mirror */
rr_gsbrotatable_mirror_id_[coordinator.get_x()][coordinator.get_y()] = mirror_id;
break;
}
}
/* Add to list if this is a unique mirror*/
if (true == is_rotatable_mirror) {
rotatable_mirror_.push_back(coordinator);
/* Record the id of unique mirror */
rr_gsbrotatable_mirror_id_[coordinator.get_x()][coordinator.get_y()] = rotatable_mirror_.size() - 1;
/*
printf("Detect a rotatable mirror: SB[%lu][%lu]\n", coordinator.get_x(), coordinator.get_y());
*/
}
return;
}
void DeviceRRGSB::add_unique_side_segment_module(DeviceCoordinator& coordinator,
void DeviceRRGSB::add_sb_unique_side_segment_submodule(DeviceCoordinator& coordinator,
RRGSB& rr_sb,
enum e_side side,
size_t seg_id) {
@ -2236,22 +2243,22 @@ void DeviceRRGSB::add_unique_side_segment_module(DeviceCoordinator& coordinator,
Side side_manager(side);
/* add rotatable mirror support */
for (size_t id = 0; id < get_num_unique_module(side, seg_id); ++id) {
for (size_t id = 0; id < get_num_sb_unique_submodule(side, seg_id); ++id) {
/* Skip if these may never match as a mirror (violation in basic requirements */
if (true == get_gsb(unique_module_[side_manager.to_size_t()][seg_id][id]).is_sb_side_segment_mirror(rr_sb, side, segment_ids_[seg_id])) {
if (true == get_gsb(sb_unique_submodule_[side_manager.to_size_t()][seg_id][id]).is_sb_side_segment_mirror(rr_sb, side, segment_ids_[seg_id])) {
/* This is a mirror, raise the flag and we finish */
is_unique_side_module = false;
/* Record the id of unique mirror */
rr_sb_unique_module_id_[coordinator.get_x()][coordinator.get_y()][side_manager.to_size_t()][seg_id] = id;
sb_unique_submodule_id_[coordinator.get_x()][coordinator.get_y()][side_manager.to_size_t()][seg_id] = id;
break;
}
}
/* Add to list if this is a unique mirror*/
if (true == is_unique_side_module) {
unique_module_[side_manager.to_size_t()][seg_id].push_back(coordinator);
sb_unique_submodule_[side_manager.to_size_t()][seg_id].push_back(coordinator);
/* Record the id of unique mirror */
rr_sb_unique_module_id_[coordinator.get_x()][coordinator.get_y()][side_manager.to_size_t()][seg_id] = unique_module_[side_manager.to_size_t()][seg_id].size() - 1;
sb_unique_submodule_id_[coordinator.get_x()][coordinator.get_y()][side_manager.to_size_t()][seg_id] = sb_unique_submodule_[side_manager.to_size_t()][seg_id].size() - 1;
/*
printf("Detect a rotatable mirror: SB[%lu][%lu]\n", coordinator.get_x(), coordinator.get_y());
*/
@ -2265,13 +2272,13 @@ void DeviceRRGSB::add_unique_side_segment_module(DeviceCoordinator& coordinator,
* If it is similar to any module[side][i] in the list, we build a link from the rr_sb to the unique_module
* Otherwise, we add the module to the unique_module list
*/
void DeviceRRGSB::add_unique_side_module(DeviceCoordinator& coordinator,
void DeviceRRGSB::add_sb_unique_side_submodule(DeviceCoordinator& coordinator,
RRGSB& rr_sb,
enum e_side side) {
Side side_manager(side);
for (size_t iseg = 0; iseg < segment_ids_.size(); ++iseg) {
add_unique_side_segment_module(coordinator, rr_sb, side, iseg);
add_sb_unique_side_segment_submodule(coordinator, rr_sb, side, iseg);
}
return;
@ -2279,10 +2286,14 @@ void DeviceRRGSB::add_unique_side_module(DeviceCoordinator& coordinator,
/* build a map of segment_ids */
void DeviceRRGSB::build_segment_ids() {
/* Make sure a clean start */
clear_segment_ids();
/* go through each rr_sb, each side and find the segment_ids */
for (size_t ix = 0; ix < rr_gsb.size(); ++ix) {
for (size_t iy = 0; iy < rr_gsb[ix].size(); ++iy) {
RRGSB* rr_sb = &(rr_gsb[ix][iy]);
for (size_t ix = 0; ix < rr_gsb_.size(); ++ix) {
for (size_t iy = 0; iy < rr_gsb_[ix].size(); ++iy) {
RRGSB* rr_sb = &(rr_gsb_[ix][iy]);
for (size_t side = 0 ; side < rr_sb->get_num_sides(); ++side) {
Side side_manager(side);
/* get a list of segment_ids in this side */
@ -2306,65 +2317,71 @@ void DeviceRRGSB::build_segment_ids() {
/* clean the content */
void DeviceRRGSB::clear() {
clear_gsb();
/* clean unique module lists */
clear_sb_unique_module();
clear_sb_unique_module_id();
clear_sb_unique_submodule();
clear_sb_unique_submodule_id();
return;
}
void DeviceRRGSB::clear_gsb() {
/* clean gsb array */
for (size_t x = 0; x < rr_gsb_.size(); ++x) {
rr_gsb_[x].clear();
}
rr_gsb_.clear();
return;
}
void DeviceRRGSB::clear_sb_unique_module_id() {
/* clean rr_switch_block array */
for (size_t x = 0; x < rr_gsb.size(); ++x) {
rr_gsb[x].clear();
rr_gsbmirror_id_[x].clear();
rr_gsbrotatable_mirror_id_[x].clear();
for (size_t x = 0; x < rr_gsb_.size(); ++x) {
sb_unique_module_id_[x].clear();
}
rr_gsb.clear();
rr_gsbmirror_id_.clear();
rr_gsbrotatable_mirror_id_.clear();
return;
}
void DeviceRRGSB::clear_sb_unique_submodule_id() {
/* clean rr_sb_unique_side_module_id */
for (size_t x = 0; x < rr_sb_unique_module_id_.size(); ++x) {
for (size_t y = 0; y < rr_sb_unique_module_id_[x].size(); ++y) {
rr_sb_unique_module_id_[x][y].clear();
for (size_t x = 0; x < sb_unique_submodule_id_.size(); ++x) {
for (size_t y = 0; y < sb_unique_submodule_id_[x].size(); ++y) {
for (size_t side = 0; side < sb_unique_submodule_.size(); ++side) {
sb_unique_submodule_id_[x][y][side].clear();
}
rr_sb_unique_module_id_[x].clear();
sb_unique_submodule_id_[x][y].clear();
}
rr_sb_unique_module_id_.clear();
/* clean unique side module */
clear_unique_module();
/* clean unique mirror */
clear_mirror();
/* clean unique mirror */
clear_rotatable_mirror();
sb_unique_submodule_id_[x].clear();
}
sb_unique_submodule_id_.clear();
return;
}
/* clean the content related to unique_mirrors */
void DeviceRRGSB::clear_unique_module() {
void DeviceRRGSB::clear_sb_unique_submodule() {
/* clean unique_side_module_ */
for (size_t side = 0; side < unique_module_.size(); ++side) {
unique_module_[side].clear();
for (size_t side = 0; side < sb_unique_submodule_.size(); ++side) {
for (size_t iseg = 0; iseg < segment_ids_.size(); ++iseg) {
sb_unique_submodule_[side][iseg].clear();
}
sb_unique_submodule_[side].clear();
}
return;
}
/* clean the content related to unique_mirrors */
void DeviceRRGSB::clear_mirror() {
void DeviceRRGSB::clear_sb_unique_module() {
/* clean unique mirror */
unique_mirror_.clear();
sb_unique_module_.clear();
return;
}
/* clean the content related to rotatable_mirrors */
void DeviceRRGSB::clear_rotatable_mirror() {
/* clean unique mirror */
rotatable_mirror_.clear();
return;
}
/* clean the content related to segment_ids */
void DeviceRRGSB::clear_segment_ids() {
/* clean segment_ids_ */
@ -2376,10 +2393,10 @@ void DeviceRRGSB::clear_segment_ids() {
/* Validate if the (x,y) is the range of this device */
bool DeviceRRGSB::validate_coordinator(DeviceCoordinator& coordinator) const {
if (coordinator.get_x() >= rr_gsb.capacity()) {
if (coordinator.get_x() >= rr_gsb_.capacity()) {
return false;
}
if (coordinator.get_y() >= rr_gsb[coordinator.get_x()].capacity()) {
if (coordinator.get_y() >= rr_gsb_[coordinator.get_x()].capacity()) {
return false;
}
return true;
@ -2388,35 +2405,27 @@ bool DeviceRRGSB::validate_coordinator(DeviceCoordinator& coordinator) const {
/* Validate if the index in the range of unique_mirror vector*/
bool DeviceRRGSB::validate_side(enum e_side side) const {
Side side_manager(side);
if (side_manager.to_size_t() >= unique_module_.size()) {
if (side_manager.to_size_t() >= sb_unique_submodule_.size()) {
return false;
}
return true;
}
/* Validate if the index in the range of unique_mirror vector*/
bool DeviceRRGSB::validate_unique_mirror_index(size_t index) const {
if (index >= unique_mirror_.size()) {
bool DeviceRRGSB::validate_sb_unique_module_index(size_t index) const {
if (index >= sb_unique_module_.size()) {
return false;
}
return true;
}
/* Validate if the index in the range of unique_mirror vector*/
bool DeviceRRGSB::validate_rotatable_mirror_index(size_t index) const {
if (index >= rotatable_mirror_.size()) {
return false;
}
return true;
}
/* Validate if the index in the range of unique_mirror vector*/
bool DeviceRRGSB::validate_unique_module_index(size_t index, enum e_side side, size_t seg_index) const {
bool DeviceRRGSB::validate_sb_unique_submodule_index(size_t index, enum e_side side, size_t seg_index) const {
assert( validate_side(side));
assert( validate_segment_index(seg_index));
Side side_manager(side);
if (index >= unique_module_[side_manager.get_side()][seg_index].size()) {
if (index >= sb_unique_submodule_[side_manager.get_side()][seg_index].size()) {
return false;
}
return true;

View File

@ -276,52 +276,53 @@ class DeviceRRGSB {
DeviceCoordinator get_gsb_range() const; /* get the max coordinator of the switch block array */
RRGSB get_gsb(DeviceCoordinator& coordinator) const; /* Get a rr switch block in the array with a coordinator */
RRGSB get_gsb(size_t x, size_t y) const; /* Get a rr switch block in the array with a coordinator */
size_t get_num_unique_module(enum e_side side, size_t seg_index) const; /* get the number of unique mirrors of switch blocks */
size_t get_num_unique_mirror() const; /* get the number of unique mirrors of switch blocks */
size_t get_num_rotatable_mirror() const; /* get the number of rotatable mirrors of switch blocks */
RRGSB get_unique_side_module(size_t index, enum e_side side, size_t seg_id) const; /* Get a rr switch block which a unique mirror */
RRGSB get_unique_mirror(size_t index) const; /* Get a rr switch block which a unique mirror */
RRGSB get_unique_mirror(DeviceCoordinator& coordinator) const; /* Get a rr switch block which a unique mirror */
RRGSB get_rotatable_mirror(size_t index) const; /* Get a rr switch block which a unique mirror */
size_t get_num_sb_unique_submodule(enum e_side side, size_t seg_index) const; /* get the number of unique mirrors of switch blocks */
size_t get_num_sb_unique_module() const; /* get the number of unique mirrors of switch blocks */
size_t get_sb_unique_submodule_id(DeviceCoordinator& coordinator, enum e_side side, size_t seg_id) const;
RRGSB get_sb_unique_submodule(size_t index, enum e_side side, size_t seg_id) const; /* Get a rr switch block which a unique mirror */
RRGSB get_sb_unique_submodule(DeviceCoordinator& coordinator, enum e_side side, size_t seg_id) const; /* Get a rr switch block which a unique mirror */
RRGSB get_sb_unique_module(size_t index) const; /* Get a rr switch block which a unique mirror */
RRGSB get_sb_unique_module(DeviceCoordinator& coordinator) const; /* Get a rr switch block which a unique mirror */
size_t get_max_num_sides() const; /* Get the maximum number of sides across the switch blocks */
size_t get_num_segments() const; /* Get the size of segment_ids */
size_t get_segment_id(size_t index) const; /* Get a segment id */
bool is_two_sb_share_same_submodules(DeviceCoordinator& src, DeviceCoordinator& des) const;
public: /* Mutators */
void set_sb_num_reserved_conf_bits(DeviceCoordinator& coordinator, size_t num_reserved_conf_bits); /* TODO: TOBE DEPRECATED!!! conf_bits should be initialized when creating a switch block!!! */
void set_sb_conf_bits_lsb(DeviceCoordinator& coordinator, size_t conf_bits_lsb); /* TODO: TOBE DEPRECATED!!! conf_bits should be initialized when creating a switch block!!! */
void set_sb_conf_bits_msb(DeviceCoordinator& coordinator, size_t conf_bits_msb); /* TODO: TOBE DEPRECATED!!! conf_bits should be initialized when creating a switch block!!! */
void reserve(DeviceCoordinator& coordinator); /* Pre-allocate the rr_switch_block array that the device requires */
void reserve_unique_module_id(DeviceCoordinator& coordinator); /* Pre-allocate the rr_sb_unique_module_id matrix that the device requires */
void reserve_sb_unique_submodule_id(DeviceCoordinator& coordinator); /* Pre-allocate the rr_sb_unique_module_id matrix that the device requires */
void resize_upon_need(DeviceCoordinator& coordinator); /* Resize the rr_switch_block array if needed */
void add_rr_switch_block(DeviceCoordinator& coordinator, RRGSB& rr_sb); /* Add a switch block to the array, which will automatically identify and update the lists of unique mirrors and rotatable mirrors */
void build_unique_mirror(); /* Add a switch block to the array, which will automatically identify and update the lists of unique mirrors and rotatable mirrors */
void build_unique_module(); /* Add a switch block to the array, which will automatically identify and update the lists of unique side module */
void add_rotatable_mirror(DeviceCoordinator& coordinator, RRGSB& rr_sb); /* Add a switch block to the array, which will automatically identify and update the lists of unique mirrors and rotatable mirrors */
void add_unique_side_segment_module(DeviceCoordinator& coordinator, RRGSB& rr_sb, enum e_side side, size_t seg_id);
void add_unique_side_module(DeviceCoordinator& coordinator, RRGSB& rr_sb, enum e_side side);
void build_segment_ids(); /* build a map of segment_ids */
void add_rr_gsb(DeviceCoordinator& coordinator, RRGSB& rr_gsb); /* Add a switch block to the array, which will automatically identify and update the lists of unique mirrors and rotatable mirrors */
void build_sb_unique_module(); /* Add a switch block to the array, which will automatically identify and update the lists of unique mirrors and rotatable mirrors */
void clear(); /* clean the content */
void clear_unique_module(); /* clean the content */
void clear_mirror(); /* clean the content */
void clear_rotatable_mirror(); /* clean the content */
private: /* Internal cleaners */
void clear_gsb(); /* clean the content */
void clear_sb_unique_module(); /* clean the content */
void clear_sb_unique_module_id(); /* clean the content */
void clear_sb_unique_submodule(); /* clean the content */
void clear_sb_unique_submodule_id(); /* clean the content */
void clear_segment_ids();
private: /* Validators */
bool validate_coordinator(DeviceCoordinator& coordinator) const; /* Validate if the (x,y) is the range of this device */
bool validate_side(enum e_side side) const; /* validate if side is in the range of unique_side_module_ */
bool validate_unique_mirror_index(size_t index) const; /* Validate if the index in the range of unique_mirror vector*/
bool validate_rotatable_mirror_index(size_t index) const; /* Validate if the index in the range of unique_mirror vector*/
bool validate_unique_module_index(size_t index, enum e_side side, size_t seg_index) const; /* Validate if the index in the range of unique_module vector */
bool validate_sb_unique_module_index(size_t index) const; /* Validate if the index in the range of unique_mirror vector*/
bool validate_sb_unique_submodule_index(size_t index, enum e_side side, size_t seg_index) const; /* Validate if the index in the range of unique_module vector */
bool validate_segment_index(size_t index) const;
private: /* Internal builders */
void build_segment_ids(); /* build a map of segment_ids */
void add_sb_unique_side_submodule(DeviceCoordinator& coordinator, RRGSB& rr_sb, enum e_side side);
void add_sb_unique_side_segment_submodule(DeviceCoordinator& coordinator, RRGSB& rr_sb, enum e_side side, size_t seg_id);
void build_sb_unique_submodule(); /* Add a switch block to the array, which will automatically identify and update the lists of unique side module */
private: /* Internal Data */
std::vector< std::vector<RRGSB> > rr_gsb;
std::vector< std::vector<RRGSB> > rr_gsb_;
std::vector< std::vector< std::vector< std::vector<size_t> > > > rr_sb_unique_module_id_; /* A map from rr_switch_block to its unique_side_module [0..x][0..y][0..num_sides][num_seg-1]*/
std::vector< std::vector <std::vector<DeviceCoordinator> > > unique_module_; /* For each side of switch block, we identify a list of unique modules based on its connection. This is a matrix [0..num_sides-1][0..num_seg-1][0..num_module], num_sides will the max number of sides of all the rr_switch_blocks */
std::vector< std::vector<size_t> > sb_unique_module_id_; /* A map from rr_gsb to its unique mirror */
std::vector<DeviceCoordinator> sb_unique_module_;
std::vector< std::vector<size_t> > rr_gsbmirror_id_; /* A map from rr_switch_block to its unique mirror */
std::vector<DeviceCoordinator> unique_mirror_;
std::vector< std::vector<size_t> > rr_gsbrotatable_mirror_id_; /* A map from rr_switch_block to its unique mirror */
std::vector<DeviceCoordinator> rotatable_mirror_;
std::vector< std::vector< std::vector< std::vector<size_t> > > > sb_unique_submodule_id_; /* A map from rr_switch_block to its unique_side_module [0..x][0..y][0..num_sides][num_seg-1]*/
std::vector< std::vector <std::vector<DeviceCoordinator> > > sb_unique_submodule_; /* For each side of switch block, we identify a list of unique modules based on its connection. This is a matrix [0..num_sides-1][0..num_seg-1][0..num_module], num_sides will the max number of sides of all the rr_switch_blocks */
std::vector<size_t> segment_ids_;
};

View File

@ -766,7 +766,7 @@ void dump_compact_verilog_defined_one_switch_box(t_sram_orgz_info* cur_sram_orgz
/* If we have an mirror SB, we should the module name of the mirror !!! */
DeviceCoordinator coordinator = rr_sb.get_sb_coordinator();
RRGSB unique_mirror = device_rr_gsb.get_unique_mirror(coordinator);
RRGSB unique_mirror = device_rr_gsb.get_sb_unique_module(coordinator);
fprintf(fp, "%s ", unique_mirror.gen_sb_verilog_module_name());
fprintf(fp, "%s ", rr_sb.gen_sb_verilog_instance_name());
fprintf(fp, "(");

View File

@ -3146,7 +3146,6 @@ int count_verilog_connection_box_reserved_conf_bits(t_sram_orgz_info* cur_sram_o
return num_reserved_conf_bits;
}
/* Print connection boxes
* Print the sub-circuit of a connection Box (Type: [CHANX|CHANY])
* Actually it is very similiar to switch box but
@ -3456,8 +3455,8 @@ void dump_verilog_routing_resources(t_sram_orgz_info* cur_sram_orgz_info,
for (size_t side = 0; side < device_rr_gsb.get_max_num_sides(); ++side) {
Side side_manager(side);
for (size_t iseg = 0; iseg < device_rr_gsb.get_num_segments(); ++iseg) {
for (size_t isb = 0; isb < device_rr_gsb.get_num_unique_module(side_manager.get_side(), iseg); ++isb) {
RRGSB unique_mirror = device_rr_gsb.get_unique_side_module(isb, side_manager.get_side(), iseg);
for (size_t isb = 0; isb < device_rr_gsb.get_num_sb_unique_submodule(side_manager.get_side(), iseg); ++isb) {
RRGSB unique_mirror = device_rr_gsb.get_sb_unique_submodule(isb, side_manager.get_side(), iseg);
size_t seg_id = device_rr_gsb.get_segment_id(iseg);
dump_verilog_routing_switch_box_unique_side_module(cur_sram_orgz_info, verilog_dir, subckt_dir, isb, seg_id, unique_mirror, side_manager.get_side());
}
@ -3465,8 +3464,8 @@ void dump_verilog_routing_resources(t_sram_orgz_info* cur_sram_orgz_info,
}
/* Output unique modules */
for (size_t isb = 0; isb < device_rr_gsb.get_num_unique_mirror(); ++isb) {
RRGSB unique_mirror = device_rr_gsb.get_unique_mirror(isb);
for (size_t isb = 0; isb < device_rr_gsb.get_num_sb_unique_module(); ++isb) {
RRGSB unique_mirror = device_rr_gsb.get_sb_unique_module(isb);
dump_verilog_routing_switch_box_unique_module(cur_sram_orgz_info, verilog_dir, subckt_dir, unique_mirror);
}

View File

@ -364,10 +364,6 @@ void dump_verilog_top_netlist_internal_wires(t_sram_orgz_info* cur_sram_orgz_inf
return;
}
static
void dump_verilog_defined_one_grid(t_sram_orgz_info* cur_sram_orgz_info,
FILE* fp,
@ -1285,11 +1281,7 @@ void dump_compact_verilog_grid_pins(FILE* fp,
if (1 == first_dump) {
first_dump = 0;
} else {
if (TRUE == dump_port_type) {
fprintf(fp, ",\n");
} else {
fprintf(fp, ",\n");
}
}
if (TRUE == dump_port_type) {
/* Determine this pin is an input or output */
@ -1320,11 +1312,7 @@ void dump_compact_verilog_grid_pins(FILE* fp,
}
if ((0 < num_dumped_port)&&(TRUE == dump_last_comma)) {
if (TRUE == dump_port_type) {
fprintf(fp, ",\n");
} else {
fprintf(fp, ",\n");
}
}
return;
@ -1370,11 +1358,7 @@ void dump_compact_verilog_io_grid_pins(FILE* fp,
if (1 == first_dump) {
first_dump = 0;
} else {
if (TRUE == dump_port_type) {
fprintf(fp, ",\n");
} else {
fprintf(fp, ",\n");
}
}
/* Determine this pin is an input or output */
if (TRUE == dump_port_type) {
@ -1404,11 +1388,7 @@ void dump_compact_verilog_io_grid_pins(FILE* fp,
//}
if ((0 < num_dumped_port)&&(TRUE == dump_last_comma)) {
if (TRUE == dump_port_type) {
fprintf(fp, ",\n");
} else {
fprintf(fp, ",\n");
}
}
return;