418 lines
29 KiB
C++
418 lines
29 KiB
C++
/**********************************************************
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* MIT License
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*
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* Copyright (c) 2018 LNIS - The University of Utah
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*
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* Permission is hereby granted, free of charge, to any person obtaining a copy
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* of this software and associated documentation files (the "Software"), to deal
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* in the Software without restriction, including without limitation the rights
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* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
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* copies of the Software, and to permit persons to whom the Software is
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* furnished to do so, subject to the following conditions:
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*
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* The above copyright notice and this permission notice shall be included in all
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* copies or substantial portions of the Software.
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*
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* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
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* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
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* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
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* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
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* SOFTWARE.
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***********************************************************************/
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/************************************************************************
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* Filename: rr_blocks.h
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* Created by: Xifan Tang
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* Change history:
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* +-------------------------------------+
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* | Date | Author | Notes
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* +-------------------------------------+
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* | 2019/06/12 | Xifan Tang | Created
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* +-------------------------------------+
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***********************************************************************/
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/* IMPORTANT:
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* The following preprocessing flags are added to
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* avoid compilation error when this headers are included in more than 1 times
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*/
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#ifndef RR_BLOCKS_H
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#define RR_BLOCKS_H
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/*
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* Notes in include header files in a head file
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* Only include the neccessary header files
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* that is required by the data types in the function/class declarations!
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*/
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/* Header files should be included in a sequence */
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/* Standard header files required go first */
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#include <vector>
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#include "device_coordinator.h"
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#include "device_port.h"
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#include "vpr_types.h"
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/* RRChan coordinator class */
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/* Object of a routing channel in a routing resource graph
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* This is a collection of rr_nodes, which may be replaced with RRNodeId in new RRGraph
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* Each routing channel is categorized in terms of directionality,
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* being either X-direction or Y-direction
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* ------------- ------
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* | | | |
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* | | | Y |
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* | CLB | | Chan |
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* | | | |
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* | | | |
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* ------------- ------
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* -------------
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* | X |
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* | Channel |
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* -------------
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*/
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class RRChan {
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public: /* Constructors */
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RRChan(const RRChan&); /* Copy Constructor */
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RRChan();
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public: /* Accessors */
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t_rr_type get_type() const;
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size_t get_chan_width() const; /* get the number of tracks in this channel */
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int get_node_track_id(t_rr_node* node) const; /* get the track_id of a node */
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t_rr_node* get_node(size_t track_num) const; /* get the rr_node with the track_id */
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int get_node_segment(t_rr_node* node) const;
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int get_node_segment(size_t track_num) const;
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bool is_mirror(const RRChan& cand) const; /* evaluate if two RR_chan is mirror to each other */
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std::vector<size_t> get_segment_ids() const; /* Get a list of segments used in this routing channel */
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std::vector<size_t> get_node_ids_by_segment_ids(size_t seg_id) const; /* Get a list of segments used in this routing channel */
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public: /* Mutators */
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void set(const RRChan&); /* copy */
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void set_type(t_rr_type type); /* modify type */
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void reserve_node(size_t node_size); /* reseve a number of nodes to the array */
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void add_node(t_rr_node* node, size_t node_segment); /* add a node to the array */
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void rotate(size_t rotate_begin, size_t rotate_end, size_t offset); /* rotate the nodes and node_segments with a given offset */
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void rotate_by_node_direction(enum e_direction node_direction, size_t offset);
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void counter_rotate_by_node_direction(enum e_direction node_direction, size_t offset);
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void rotate(size_t offset); /* rotate the nodes and node_segments with a given offset */
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void mirror_node_direction(); /* mirror node direction */
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void clear(); /* clear the content */
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private: /* internal functions */
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bool valid_type(t_rr_type type) const;
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bool valid_node_type(t_rr_node* node) const;
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bool valid_node_id(size_t node_id) const;
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private: /* Internal Data */
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t_rr_type type_; /* channel type: CHANX or CHANY */
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std::vector<t_rr_node*> nodes_; /* rr nodes of each track in the channel */
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std::vector<size_t> node_segments_; /* segment of each track */
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};
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/* Object including all the RR channels in a device,
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* 1. the RR channels will be in an 2D array
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* 2. Unique Module Name for each channel
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* 3. Instance name for each channel
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* 4. Detailed internal structure of each channel
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* Considering RR channels may share the same structure
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* To be memory efficient, we build a list of unique structures
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* and link each RR channel to
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*/
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class DeviceRRChan {
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public: /* contructor */
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public: /* Accessors */
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RRChan get_module(t_rr_type chan_type, size_t module_id) const;
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RRChan get_module_with_coordinator(t_rr_type chan_type, size_t x, size_t y) const;
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size_t get_num_modules(t_rr_type chan_type) const;
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size_t get_module_id(t_rr_type chan_type, size_t x, size_t y) const;
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public: /* Mutators */
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void init_module_ids(size_t device_height, size_t device_width);
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void add_one_chan_module(t_rr_type chan_type, size_t x, size_t y, RRChan& rr_chan); /* Add a new unique module of RRChan*/
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void clear();
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private: /* internal functions */
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void clear_chan(t_rr_type chan_type);
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void init_chan_module_ids(t_rr_type chan_type, size_t device_width, size_t device_height);
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bool valid_chan_type(t_rr_type chan_type) const;
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bool valid_coordinator(t_rr_type chan_type, size_t x, size_t y) const;
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bool valid_module_id(t_rr_type chan_type, size_t module_id) const;
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private: /* Internal Data */
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std::vector< std::vector<size_t> > chanx_module_ids_; /* Module id in modules_ for each X-direction rr_channel */
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std::vector< std::vector<size_t> > chany_module_ids_; /* Module id in modules_ for each Y-direction rr_channel */
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std::vector<RRChan> chanx_modules_; /* Detailed internal structure of each unique module */
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std::vector<RRChan> chany_modules_; /* Detailed internal structure of each unique module */
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};
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/* Object Generic Switch Block
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* This block contains
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* 1. A switch block
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* 2. A X-direction Connection block locates at the left side of the switch block
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* 2. A Y-direction Connection block locates at the top side of the switch block
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* This is a collection of rr_nodes, which may be replaced with RRNodeId in new RRGraph
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*
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* +---------------------------------+
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* | Y-direction CB |
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* | [x][y + 1] |
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* +---------------------------------+
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*
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* TOP SIDE
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* +-------------+ +---------------------------------+
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* | | | OPIN_NODE CHAN_NODES OPIN_NODES |
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* | | | |
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* | | | OPIN_NODES OPIN_NODES |
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* | X-direction | | |
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* | CB | LEFT SIDE | Switch Block | RIGHT SIDE
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* | [x][y] | | [x][y] |
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* | | | |
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* | | | CHAN_NODES CHAN_NODES |
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* | | | |
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* | | | OPIN_NODES OPIN_NODES |
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* | | | |
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* | | | OPIN_NODE CHAN_NODES OPIN_NODES |
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* +-------------+ +---------------------------------+
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* BOTTOM SIDE
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* num_sides: number of sides of this switch block
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* chan_rr_node: a collection of rr_nodes as routing tracks locating at each side of the Switch block <0..num_sides-1><0..chan_width-1>
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* chan_rr_node_direction: Indicate if this rr_node is an input or an output of the Switch block <0..num_sides-1><0..chan_width-1>
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* ipin_rr_node: a collection of rr_nodes as IPIN of a GRID locating at each side of the Switch block <0..num_sides-1><0..num_ipin_rr_nodes-1>
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* ipin_rr_node_grid_side: specify the side of the input pins on which side of a GRID <0..num_sides-1><0..num_ipin_rr_nodes-1>
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* opin_rr_node: a collection of rr_nodes as OPIN of a GRID locating at each side of the Switch block <0..num_sides-1><0..num_opin_rr_nodes-1>
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* opin_rr_node_grid_side: specify the side of the output pins on which side of a GRID <0..num_sides-1><0..num_opin_rr_nodes-1>
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* num_reserved_conf_bits: number of reserved configuration bits this switch block requires (mainly due to RRAM-based multiplexers)
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* num_conf_bits: number of configuration bits this switch block requires
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*/
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class RRGSB {
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public: /* Contructors */
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RRGSB(const RRGSB&);/* Copy constructor */
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RRGSB();/* Default constructor */
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public: /* Accessors */
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size_t get_num_sides() const; /* Get the number of sides of this SB */
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size_t get_chan_width(enum e_side side) const; /* Get the number of routing tracks on a side */
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size_t get_cb_chan_width(t_rr_type cb_type) const; /* Get the number of routing tracks of a X/Y-direction CB */
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std::vector<enum e_side> get_cb_ipin_sides(t_rr_type cb_type) const; /* Get the sides of CB ipins in the array */
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size_t get_max_chan_width() const; /* Get the maximum number of routing tracks on all sides */
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enum PORTS get_chan_node_direction(enum e_side side, size_t track_id) const; /* Get the direction of a rr_node at a given side and track_id */
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RRChan get_chan(enum e_side side) const; /* get a rr_node at a given side and track_id */
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std::vector<size_t> get_chan_segment_ids(enum e_side side) const; /* Get a list of segments used in this routing channel */
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std::vector<size_t> get_chan_node_ids_by_segment_ids(enum e_side side, size_t seg_id) const; /* Get a list of segments used in this routing channel */
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t_rr_node* get_chan_node(enum e_side side, size_t track_id) const; /* get a rr_node at a given side and track_id */
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size_t get_chan_node_segment(enum e_side side, size_t track_id) const; /* get the segment id of a channel rr_node */
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size_t get_num_ipin_nodes(enum e_side side) const; /* Get the number of IPIN rr_nodes on a side */
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t_rr_node* get_ipin_node(enum e_side side, size_t node_id) const; /* get a rr_node at a given side and track_id */
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enum e_side get_ipin_node_grid_side(enum e_side side, size_t node_id) const; /* get a rr_node at a given side and track_id */
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enum e_side get_ipin_node_grid_side(t_rr_node* ipin_node) const; /* get a rr_node at a given side and track_id */
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size_t get_num_opin_nodes(enum e_side side) const; /* Get the number of OPIN rr_nodes on a side */
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t_rr_node* get_opin_node(enum e_side side, size_t node_id) const; /* get a rr_node at a given side and track_id */
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enum e_side get_opin_node_grid_side(enum e_side side, size_t node_id) const; /* get a rr_node at a given side and track_id */
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enum e_side get_opin_node_grid_side(t_rr_node* opin_node) const; /* get a rr_node at a given side and track_id */
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int get_cb_chan_node_index(t_rr_type cb_type, t_rr_node* node) const;
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int get_chan_node_index(enum e_side node_side, t_rr_node* node) const;
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int get_node_index(t_rr_node* node, enum e_side node_side, enum PORTS node_direction) const; /* Get the node index in the array, return -1 if not found */
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void get_node_side_and_index(t_rr_node* node, enum PORTS node_direction, enum e_side* node_side, int* node_index) const; /* Given a rr_node, try to find its side and index in the Switch block */
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bool is_sb_node_exist_opposite_side(t_rr_node* node, enum e_side node_side) const; /* Check if the node exist in the opposite side of this Switch Block */
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public: /* Accessors: get information about configuration ports */
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size_t get_sb_num_reserved_conf_bits() const;
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size_t get_sb_reserved_conf_bits_lsb() const;
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size_t get_sb_reserved_conf_bits_msb() const;
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size_t get_sb_num_conf_bits() const;
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size_t get_sb_conf_bits_lsb() const;
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size_t get_sb_conf_bits_msb() const;
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size_t get_cb_num_reserved_conf_bits(t_rr_type cb_type) const;
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size_t get_cb_reserved_conf_bits_lsb(t_rr_type cb_type) const;
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size_t get_cb_reserved_conf_bits_msb(t_rr_type cb_type) const;
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size_t get_cb_num_conf_bits(t_rr_type cb_type) const;
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size_t get_cb_conf_bits_lsb(t_rr_type cb_type) const;
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size_t get_cb_conf_bits_msb(t_rr_type cb_type) const;
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bool is_sb_node_passing_wire(const enum e_side node_side, const size_t track_id) const; /* Check if the node imply a short connection inside the SB, which happens to long wires across a FPGA fabric */
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bool is_sb_side_mirror(const RRGSB& cand, enum e_side side) const; /* check if a side of candidate SB is a mirror of the current one */
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bool is_sb_side_segment_mirror(const RRGSB& cand, enum e_side side, size_t seg_id) const; /* check if all the routing segments of a side of candidate SB is a mirror of the current one */
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bool is_sb_mirror(const RRGSB& cand) const; /* check if the candidate SB is a mirror of the current one */
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bool is_sb_mirrorable(const RRGSB& cand) const; /* check if the candidate SB satisfy the basic requirements on being a mirror of the current one */
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bool is_cb_mirror(const RRGSB& cand, t_rr_type cb_type) const; /* check if the candidate SB is a mirror of the current one */
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bool is_cb_exist(t_rr_type cb_type) const; /* check if the candidate SB is a mirror of the current one */
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size_t get_hint_rotate_offset(const RRGSB& cand) const; /* Determine an initial offset in rotating the candidate Switch Block to find a mirror matching*/
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public: /* Cooridinator conversion and output */
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size_t get_x() const; /* get the x coordinator of this switch block */
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size_t get_y() const; /* get the y coordinator of this switch block */
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size_t get_sb_x() const; /* get the x coordinator of this switch block */
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size_t get_sb_y() const; /* get the y coordinator of this switch block */
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DeviceCoordinator get_sb_coordinator() const; /* Get the coordinator of the SB */
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size_t get_cb_x(t_rr_type cb_type) const; /* get the x coordinator of this X/Y-direction block */
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size_t get_cb_y(t_rr_type cb_type) const; /* get the y coordinator of this X/Y-direction block */
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DeviceCoordinator get_cb_coordinator(t_rr_type cb_type) const; /* Get the coordinator of the X/Y-direction CB */
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enum e_side get_cb_chan_side(t_rr_type cb_type) const; /* get the side of a Connection block */
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enum e_side get_cb_chan_side(enum e_side ipin_side) const; /* get the side of a Connection block */
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DeviceCoordinator get_side_block_coordinator(enum e_side side) const;
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DeviceCoordinator get_grid_coordinator() const;
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public: /* Verilog writer */
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const char* gen_gsb_verilog_module_name() const;
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const char* gen_gsb_verilog_instance_name() const;
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const char* gen_sb_verilog_module_name() const;
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const char* gen_sb_verilog_instance_name() const;
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const char* gen_sb_verilog_side_module_name(enum e_side side, size_t seg_id) const;
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const char* gen_sb_verilog_side_instance_name(enum e_side side, size_t seg_id) const;
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const char* gen_cb_verilog_module_name(t_rr_type cb_type) const;
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const char* gen_cb_verilog_instance_name(t_rr_type cb_type) const;
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const char* gen_cb_verilog_routing_track_name(t_rr_type cb_type, size_t track_id) const;
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public: /* Mutators */
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void set(const RRGSB& src); /* get a copy from a source */
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void set_coordinator(size_t x, size_t y);
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void init_num_sides(size_t num_sides); /* Allocate the vectors with the given number of sides */
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void add_chan_node(enum e_side node_side, RRChan& rr_chan, std::vector<enum PORTS> rr_chan_dir); /* Add a node to the chan_rr_node_ list and also assign its direction in chan_rr_node_direction_ */
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void add_ipin_node(t_rr_node* node, const enum e_side node_side, const enum e_side grid_side); /* Add a node to the chan_rr_node_ list and also assign its direction in chan_rr_node_direction_ */
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void add_opin_node(t_rr_node* node, const enum e_side node_side, const enum e_side grid_side); /* Add a node to the chan_rr_node_ list and also assign its direction in chan_rr_node_direction_ */
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void set_sb_num_reserved_conf_bits(size_t num_reserved_conf_bits);
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void set_sb_conf_bits_lsb(size_t conf_bits_lsb);
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void set_sb_conf_bits_msb(size_t conf_bits_msb);
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void set_cb_num_reserved_conf_bits(t_rr_type cb_type, size_t num_reserved_conf_bits);
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void set_cb_conf_bits_lsb(t_rr_type cb_type, size_t conf_bits_lsb);
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void set_cb_conf_bits_msb(t_rr_type cb_type, size_t conf_bits_msb);
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void rotate_side_chan_node_by_direction(enum e_side side, enum e_direction chan_dir, size_t offset); /* rotate all the channel nodes by a given offset */
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void counter_rotate_side_chan_node_by_direction(enum e_side side, enum e_direction chan_dir, size_t offset); /* rotate all the channel nodes by a given offset */
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void rotate_side_chan_node(enum e_side side, size_t offset); /* rotate all the channel nodes by a given offset */
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void rotate_chan_node(size_t offset); /* rotate all the channel nodes by a given offset */
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void rotate_chan_node_in_group(size_t offset); /* rotate all the channel nodes by a given offset */
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void rotate_side_opin_node_in_group(enum e_side side, size_t offset); /* rotate all the opin nodes by a given offset */
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void rotate_opin_node_in_group(size_t offset); /* rotate all the opin nodes by a given offset */
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void rotate_side(enum e_side side, size_t offset); /* rotate all the channel and opin nodes by a given offset */
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void rotate(size_t offset); /* rotate all the channel and opin nodes by a given offset */
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void swap_chan_node(enum e_side src_side, enum e_side des_side); /* swap the chan rr_nodes on two sides */
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void swap_opin_node(enum e_side src_side, enum e_side des_side); /* swap the OPIN rr_nodes on two sides */
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void swap_ipin_node(enum e_side src_side, enum e_side des_side); /* swap the IPIN rr_nodes on two sides */
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void reverse_opin_node(enum e_side side); /* reverse the OPIN rr_nodes on two sides */
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void reverse_ipin_node(enum e_side side); /* reverse the IPIN rr_nodes on two sides */
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public: /* Mutators: cleaners */
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void clear();
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void clear_chan_nodes(enum e_side node_side); /* Clean the chan_width of a side */
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void clear_ipin_nodes(enum e_side node_side); /* Clean the number of IPINs of a side */
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void clear_opin_nodes(enum e_side node_side); /* Clean the number of OPINs of a side */
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void clear_one_side(enum e_side node_side); /* Clean chan/opin/ipin nodes at one side */
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private: /* Internal Mutators */
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void mirror_side_chan_node_direction(enum e_side side); /* Mirror the node direction and port direction of routing track nodes on a side */
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private: /* internal functions */
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bool is_sb_node_mirror (const RRGSB& cand, enum e_side node_side, size_t track_id) const;
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bool is_cb_node_mirror (const RRGSB& cand, t_rr_type cb_type, enum e_side node_side, size_t node_id) const;
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size_t get_track_id_first_short_connection(enum e_side node_side) const;
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bool validate_num_sides() const;
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bool validate_side(enum e_side side) const;
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bool validate_track_id(enum e_side side, size_t track_id) const;
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bool validate_opin_node_id(enum e_side side, size_t node_id) const;
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bool validate_ipin_node_id(enum e_side side, size_t node_id) const;
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bool validate_cb_type(t_rr_type cb_type) const;
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private: /* Internal Data */
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/* Coordinator */
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DeviceCoordinator coordinator_;
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/* Routing channel data */
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std::vector<RRChan> chan_node_;
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std::vector< std::vector<enum PORTS> > chan_node_direction_;
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/* Logic Block Inputs data */
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std::vector< std::vector<t_rr_node*> > ipin_node_;
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std::vector< std::vector<enum e_side> > ipin_node_grid_side_;
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/* Logic Block Outputs data */
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std::vector< std::vector<t_rr_node*> > opin_node_;
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std::vector< std::vector<enum e_side> > opin_node_grid_side_;
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/* Configuration bits */
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ConfPorts sb_conf_port_;
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ConfPorts cbx_conf_port_;
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ConfPorts cby_conf_port_;
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};
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/* Object Device Routing Resource Switch Block
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* This includes:
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* 1. a collection of RRSwitch blocks, each of which can be used to instance Switch blocks in the top-level netlists
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* 2. a collection of unique mirrors of RRGSBs, which can be used to output Verilog / SPICE modules
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* 3. a colleciton of unique rotatable of RRGSBs, which can be used to output Verilog / SPICE modules
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* The rotatable RRGSBs are more generic mirrors, which allow SwitchBlocks to be wired by rotating the pins,
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* further reduce the number of Verilog/SPICE modules outputted. This will lead to rapid layout generation
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*/
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class DeviceRRGSB {
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public: /* Contructors */
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public: /* Accessors */
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DeviceCoordinator get_gsb_range() const; /* get the max coordinator of the switch block array */
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const RRGSB get_gsb(DeviceCoordinator& coordinator) const; /* Get a rr switch block in the array with a coordinator */
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const RRGSB get_gsb(size_t x, size_t y) const; /* Get a rr switch block in the array with a coordinator */
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size_t get_num_gsb_unique_module() const; /* get the number of unique mirrors of GSB */
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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 */
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size_t get_num_sb_unique_module() const; /* get the number of unique mirrors of switch blocks */
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size_t get_num_cb_unique_module(t_rr_type cb_type) const; /* get the number of unique mirrors of CBs */
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size_t get_sb_unique_submodule_id(DeviceCoordinator& coordinator, enum e_side side, size_t seg_id) const;
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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 */
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const 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 */
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const RRGSB get_sb_unique_module(size_t index) const; /* Get a rr switch block which a unique mirror */
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const RRGSB get_sb_unique_module(DeviceCoordinator& coordinator) const; /* Get a rr switch block which a unique mirror */
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const RRGSB& get_cb_unique_module(t_rr_type cb_type, size_t index) const; /* Get a rr switch block which a unique mirror */
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const RRGSB& get_cb_unique_module(t_rr_type cb_type, DeviceCoordinator& coordinator) const;
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size_t get_max_num_sides() const; /* Get the maximum number of sides across the switch blocks */
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size_t get_num_segments() const; /* Get the size of segment_ids */
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size_t get_segment_id(size_t index) const; /* Get a segment id */
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bool is_two_sb_share_same_submodules(DeviceCoordinator& src, DeviceCoordinator& des) const;
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public: /* Mutators */
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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!!! */
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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!!! */
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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!!! */
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void set_cb_num_reserved_conf_bits(DeviceCoordinator& coordinator, t_rr_type cb_type, size_t num_reserved_conf_bits); /* TODO: TOBE DEPRECATED!!! conf_bits should be initialized when creating a switch block!!! */
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void set_cb_conf_bits_lsb(DeviceCoordinator& coordinator, t_rr_type cb_type, size_t conf_bits_lsb); /* TODO: TOBE DEPRECATED!!! conf_bits should be initialized when creating a switch block!!! */
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void set_cb_conf_bits_msb(DeviceCoordinator& coordinator, t_rr_type cb_type, size_t conf_bits_msb); /* TODO: TOBE DEPRECATED!!! conf_bits should be initialized when creating a switch block!!! */
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void reserve(DeviceCoordinator& coordinator); /* Pre-allocate the rr_switch_block array that the device requires */
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void reserve_sb_unique_submodule_id(DeviceCoordinator& coordinator); /* Pre-allocate the rr_sb_unique_module_id matrix that the device requires */
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void resize_upon_need(const DeviceCoordinator& coordinator); /* Resize the rr_switch_block array if needed */
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void add_rr_gsb(const DeviceCoordinator& coordinator, const RRGSB& rr_gsb); /* Add a switch block to the array, which will automatically identify and update the lists of unique mirrors and rotatable mirrors */
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void build_unique_module(); /* Add a switch block to the array, which will automatically identify and update the lists of unique mirrors and rotatable mirrors */
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void clear(); /* clean the content */
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private: /* Internal cleaners */
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void clear_gsb(); /* clean the content */
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void clear_cb_unique_module(t_rr_type cb_type); /* clean the content */
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void clear_cb_unique_module_id(t_rr_type cb_type); /* clean the content */
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void clear_sb_unique_module(); /* clean the content */
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void clear_sb_unique_module_id(); /* clean the content */
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void clear_sb_unique_submodule(); /* clean the content */
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|
void clear_sb_unique_submodule_id(); /* clean the content */
|
|
void clear_gsb_unique_module(); /* clean the content */
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|
void clear_gsb_unique_module_id(); /* clean the content */
|
|
void clear_segment_ids();
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|
private: /* Validators */
|
|
bool validate_coordinator(DeviceCoordinator& coordinator) const; /* Validate if the (x,y) is the range of this device */
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|
bool validate_side(enum e_side side) const; /* validate if side is in the range of unique_side_module_ */
|
|
bool validate_sb_unique_module_index(size_t index) const; /* Validate if the index in the range of unique_mirror vector*/
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|
bool validate_cb_unique_module_index(t_rr_type cb_type, 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;
|
|
bool validate_cb_type(t_rr_type cb_type) const;
|
|
private: /* Internal builders */
|
|
void build_segment_ids(); /* build a map of segment_ids */
|
|
void add_gsb_unique_module(const DeviceCoordinator& coordinator);
|
|
void add_sb_unique_side_submodule(DeviceCoordinator& coordinator, const RRGSB& rr_sb, enum e_side side);
|
|
void add_sb_unique_side_segment_submodule(DeviceCoordinator& coordinator, const RRGSB& rr_sb, enum e_side side, size_t seg_id);
|
|
void add_cb_unique_module(t_rr_type cb_type, const DeviceCoordinator& coordinator);
|
|
void set_cb_unique_module_id(t_rr_type, const DeviceCoordinator& coordinator, size_t 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 */
|
|
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 build_cb_unique_module(t_rr_type cb_type); /* Add a switch block to the array, which will automatically identify and update the lists of unique side module */
|
|
void build_gsb_unique_module(); /* Add a switch block to the array, which will automatically identify and update the lists of unique mirrors and rotatable mirrors */
|
|
private: /* Internal Data */
|
|
std::vector< std::vector<RRGSB> > rr_gsb_;
|
|
|
|
std::vector< std::vector<size_t> > gsb_unique_module_id_; /* A map from rr_gsb to its unique mirror */
|
|
std::vector<DeviceCoordinator> gsb_unique_module_;
|
|
|
|
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< 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< std::vector<size_t> > cbx_unique_module_id_; /* A map from rr_gsb to its unique mirror */
|
|
std::vector<DeviceCoordinator> cbx_unique_module_; /* For each side of connection block, we identify a list of unique modules based on its connection. This is a matrix [0..num_module] */
|
|
|
|
std::vector< std::vector<size_t> > cby_unique_module_id_; /* A map from rr_gsb to its unique mirror */
|
|
std::vector<DeviceCoordinator> cby_unique_module_; /* For each side of connection block, we identify a list of unique modules based on its connection. This is a matrix [0..num_module] */
|
|
|
|
std::vector<size_t> segment_ids_;
|
|
};
|
|
|
|
#endif
|
|
|
|
/************************************************************************
|
|
* End of file : rr_blocks.h
|
|
***********************************************************************/
|
|
|