OpenFPGA/openfpga/src/fpga_verilog/verilog_decoders.cpp

/***************************************************************************************
 * This file includes functions to generate Verilog modules of decoders
 ***************************************************************************************/
#include <string>

/* Headers from vtrutil library */
#include "vtr_assert.h"
#include "vtr_log.h"

/* Headers from openfpgautil library */
#include "openfpga_digest.h"
#include "openfpga_decode.h"

#include "decoder_library_utils.h"
#include "module_manager.h"

#include "openfpga_reserved_words.h"
#include "openfpga_naming.h"

#include "verilog_constants.h"
#include "verilog_writer_utils.h"
#include "verilog_decoders.h"

/* begin namespace openfpga */
namespace openfpga {

/***************************************************************************************
 * Create a Verilog module for a decoder with a given output size
 *
 *                     Inputs 
 *                   | | ... | 
 *                   v v     v
 *                 +-----------+
 *                /             \
 *               /    Decoder    \
 *              +-----------------+
 *                | | | ... | | |
 *                v v v     v v v
 *                    Outputs
 *               
 *  The outputs are assumes to be one-hot codes (at most only one '1' exist)
 *  Considering this fact, there are only num_of_outputs conditions to be encoded.
 *  Therefore, the number of inputs is ceil(log(num_of_outputs)/log(2))
 ***************************************************************************************/
static 
void print_verilog_mux_local_decoder_module(std::fstream& fp, 
                                            const ModuleManager& module_manager,
                                            const DecoderLibrary& decoder_lib,
                                            const DecoderId& decoder) {
  /* Get the number of inputs */
  size_t addr_size = decoder_lib.addr_size(decoder);
  size_t data_size = decoder_lib.data_size(decoder);

  /* Validate the FILE handler */
  VTR_ASSERT(true == valid_file_stream(fp));

  /* TODO: create a name for the local encoder */
  std::string module_name = generate_mux_local_decoder_subckt_name(addr_size, data_size);

  /* Create a Verilog Module based on the circuit model, and add to module manager */
  ModuleId module_id = module_manager.find_module(module_name); 
  VTR_ASSERT(true == module_manager.valid_module_id(module_id));
  /* Add module ports */
  /* Add each input port */
  BasicPort addr_port(generate_mux_local_decoder_addr_port_name(), addr_size);
  /* Add each output port */
  BasicPort data_port(generate_mux_local_decoder_data_port_name(), data_size);
  /* Data port is registered. It should be outputted as 
   *   output reg [lsb:msb] data 
   */
  /* Add data_in port */
  BasicPort data_inv_port(generate_mux_local_decoder_data_inv_port_name(), data_size);
  VTR_ASSERT(true == decoder_lib.use_data_inv_port(decoder));

  /* dump module definition + ports */
  print_verilog_module_declaration(fp, module_manager, module_id);
  /* Finish dumping ports */

  print_verilog_comment(fp, std::string("----- BEGIN Verilog codes for Decoder convert " + std::to_string(addr_size) + "-bit addr to " + std::to_string(data_size) + "-bit data -----"));

  /* Print the truth table of this decoder */
  /* Internal logics */
  /* Early exit: Corner case for data size = 1 the logic is very simple:
   * data = addr;  
   * data_inv = ~data_inv
   */
  if (1 == data_size) {
    print_verilog_wire_connection(fp, data_port, addr_port, false);
    print_verilog_wire_connection(fp, data_inv_port, addr_port, true);
    print_verilog_comment(fp, std::string("----- END Verilog codes for Decoder convert " + std::to_string(addr_size) + "-bit addr to " + std::to_string(data_size) + "-bit data -----"));

    /* Put an end to the Verilog module */
    print_verilog_module_end(fp, module_name);
    return;
  }

  /* We use a magic number -1 as the addr=1 should be mapped to ...1
   * Otherwise addr will map addr=1 to ..10 
   * Note that there should be a range for the shift operators
   * We should narrow the encoding to be applied to a given set of data
   * This will lead to that any addr which falls out of the op code of data
   * will give a all-zero code
   * For example: 
   * data is 5-bit while addr is 3-bit 
   * data=8'b0_0000 will be encoded to addr=3'b001;
   * data=8'b0_0001 will be encoded to addr=3'b010;
   * data=8'b0_0010 will be encoded to addr=3'b011;
   * data=8'b0_0100 will be encoded to addr=3'b100;
   * data=8'b0_1000 will be encoded to addr=3'b101;
   * data=8'b1_0000 will be encoded to addr=3'b110;
   * The rest of addr codes 3'b110, 3'b111 will be decoded to data=8'b0_0000;
   */

  fp << "\t" << "always@(" << generate_verilog_port(VERILOG_PORT_CONKT, addr_port) << ")" << std::endl;
  fp << "\t" << "case (" << generate_verilog_port(VERILOG_PORT_CONKT, addr_port) << ")" << std::endl;
  /* Create a string for addr and data */
  for (size_t i = 0; i < data_size; ++i) {
    fp << "\t\t" << generate_verilog_constant_values(itobin_vec(i, addr_size)); 
    fp << " : ";
    fp << generate_verilog_port_constant_values(data_port, ito1hot_vec(i, data_size)); 
    fp << ";" << std::endl;
  }
  fp << "\t\t" << "default : ";
  fp << generate_verilog_port_constant_values(data_port, ito1hot_vec(data_size - 1, data_size)); 
  fp << ";" << std::endl;
  fp << "\t" << "endcase" << std::endl;

  print_verilog_wire_connection(fp, data_inv_port, data_port, true);
  
  print_verilog_comment(fp, std::string("----- END Verilog codes for Decoder convert " + std::to_string(addr_size) + "-bit addr to " + std::to_string(data_size) + "-bit data -----"));

  /* Put an end to the Verilog module */
  print_verilog_module_end(fp, module_name);
}

/***************************************************************************************
 * This function will generate all the unique Verilog modules of local decoders for 
 * the multiplexers used in a FPGA fabric
 * It will reach the goal in two steps:
 * 1. Find the unique local decoders w.r.t. the number of inputs/outputs 
 *    We will generate the subgraphs from the multiplexing graph of each multiplexers
 *    The number of memory bits is the number of outputs.
 *    From that we can infer the number of inputs of each local decoders.
 *    Here is an illustrative example of how local decoders are interfaced with multi-level MUXes
 *
 *        +---------+         +---------+
 *        |  Local  |         |  Local  |
 *        | Decoder |         | Decoder |
 *        |    A    |         |    B    |
 *        +---------+         +---------+
 *          | ... |             | ... |
 *          v     v             v     v
 *      +--------------+    +--------------+
 *      |  MUX Level 0 |--->|  MUX Level 1 |
 *      +--------------+    +--------------+
 * 2. Generate local decoder Verilog modules using behavioral description.
 *    Note that the implementation of local decoders can be dependent on the technology
 *    and standard cell libraries.
 *    Therefore, behavioral Verilog is used and the local decoders should be synthesized 
 *    before running the back-end flow for FPGA fabric 
 *    See more details in the function print_verilog_mux_local_decoder() for more details
 ***************************************************************************************/
void print_verilog_submodule_mux_local_decoders(const ModuleManager& module_manager,
                                                NetlistManager& netlist_manager,
                                                const MuxLibrary& mux_lib,
                                                const CircuitLibrary& circuit_lib,
                                                const std::string& submodule_dir) {
  std::string verilog_fname(submodule_dir + std::string(LOCAL_ENCODER_VERILOG_FILE_NAME));

  /* Create the file stream */
  std::fstream fp;
  fp.open(verilog_fname, std::fstream::out | std::fstream::trunc);

  check_file_stream(verilog_fname.c_str(), fp);

  /* Print out debugging information for if the file is not opened/created properly */
  VTR_LOG("Writing Verilog netlist for local decoders for multiplexers '%s'...",
          verilog_fname.c_str()); 

  print_verilog_file_header(fp, "Local Decoders for Multiplexers"); 

  /* Create a library for local encoders with different sizes */
  DecoderLibrary decoder_lib;
  
  /* Find unique local decoders for unique branches shared by the multiplexers */
  for (auto mux : mux_lib.muxes()) {
    /* Local decoders are need only when users specify them */
    CircuitModelId mux_circuit_model = mux_lib.mux_circuit_model(mux); 
    /* If this MUX does not need local decoder, we skip it */
    if (false == circuit_lib.mux_use_local_encoder(mux_circuit_model)) {
      continue;
    }

    const MuxGraph& mux_graph = mux_lib.mux_graph(mux);
    /* Create a mux graph for the branch circuit */
    std::vector<MuxGraph> branch_mux_graphs = mux_graph.build_mux_branch_graphs();
    /* Add the decoder to the decoder library */
    for (auto branch_mux_graph : branch_mux_graphs) {
      /* The decoder size depends on the number of memories of a branch MUX.
       * Note that only when there are >=2 memories, a decoder is needed
       */
      size_t decoder_data_size = branch_mux_graph.num_memory_bits();
      if (0 == decoder_data_size) {
        continue;
      }
      /* Try to find if the decoder already exists in the library, 
       * If there is no such decoder, add it to the library 
       */
      add_mux_local_decoder_to_library(decoder_lib, decoder_data_size);
    }
  }

  /* Generate Verilog modules for the found unique local encoders */
  for (const auto& decoder : decoder_lib.decoders()) {
    print_verilog_mux_local_decoder_module(fp, module_manager, decoder_lib, decoder);
  }

  /* Close the file stream */
  fp.close();

  /* Add fname to the netlist name list */
  NetlistId nlist_id = netlist_manager.add_netlist(verilog_fname);
  VTR_ASSERT(NetlistId::INVALID() != nlist_id);
  netlist_manager.set_netlist_type(nlist_id, NetlistManager::SUBMODULE_NETLIST);

  VTR_LOG("Done\n");
}

/***************************************************************************************
 * Create a Verilog module for a decoder used as a configuration protocol 
 * in FPGA architecture
 *
 *                     Address
 *                   | | ... | 
 *                   v v     v
 *                 +-----------+
 *        Enable->/             \
 *               /    Decoder    \
 *              +-----------------+
 *                | | | ... | | |
 *                v v v     v v v
 *                    Data output
 *
 *  The outputs are assumes to be one-hot codes (at most only one '1' exist)
 *  Considering this fact, there are only num_of_outputs conditions to be encoded.
 *  Therefore, the number of inputs is ceil(log(num_of_outputs)/log(2))
 *
 *  The decoder has an enable signal which is active at logic '1'. 
 *  When activated, the decoder will output decoding results to the data output port
 *  Otherwise, the data output port will be always all-zero
 ***************************************************************************************/
static 
void print_verilog_arch_decoder_module(std::fstream& fp, 
                                       const ModuleManager& module_manager,
                                       const DecoderLibrary& decoder_lib,
                                       const DecoderId& decoder) {
  /* Get the number of inputs */
  size_t addr_size = decoder_lib.addr_size(decoder);
  size_t data_size = decoder_lib.data_size(decoder);

  /* Validate the FILE handler */
  VTR_ASSERT(true == valid_file_stream(fp));

  /* Create a name for the decoder */
  std::string module_name = generate_memory_decoder_subckt_name(addr_size, data_size);

  /* Create a Verilog Module based on the circuit model, and add to module manager */
  ModuleId module_id = module_manager.find_module(module_name); 
  VTR_ASSERT(true == module_manager.valid_module_id(module_id));
  /* Find module ports */
  /* Enable port */
  ModulePortId enable_port_id = module_manager.find_module_port(module_id, std::string(DECODER_ENABLE_PORT_NAME));
  BasicPort enable_port = module_manager.module_port(module_id, enable_port_id);
  /* Address port */
  ModulePortId addr_port_id = module_manager.find_module_port(module_id, std::string(DECODER_ADDRESS_PORT_NAME));
  BasicPort addr_port = module_manager.module_port(module_id, addr_port_id);
  /* Find each output port */
  ModulePortId data_port_id = module_manager.find_module_port(module_id, std::string(DECODER_DATA_OUT_PORT_NAME));
  BasicPort data_port = module_manager.module_port(module_id, data_port_id);
  /* Data port is registered. It should be outputted as 
   *   output reg [lsb:msb] data 
   */
  BasicPort data_inv_port(std::string(DECODER_DATA_OUT_INV_PORT_NAME), data_size);
  if (true == decoder_lib.use_data_inv_port(decoder)) {
    ModulePortId data_inv_port_id = module_manager.find_module_port(module_id, std::string(DECODER_DATA_OUT_INV_PORT_NAME));
    data_inv_port = module_manager.module_port(module_id, data_inv_port_id);
  }

  /* dump module definition + ports */
  print_verilog_module_declaration(fp, module_manager, module_id);
  /* Finish dumping ports */

  print_verilog_comment(fp, std::string("----- BEGIN Verilog codes for Decoder convert " + std::to_string(addr_size) + "-bit addr to " + std::to_string(data_size) + "-bit data -----"));

  /* Print the truth table of this decoder */
  /* Internal logics */
  /* Early exit: Corner case for data size = 1 the logic is very simple:
   * data = addr;  
   * data_inv = ~data_inv
   */
  if (1 == data_size) {
    fp << "always@(" << generate_verilog_port(VERILOG_PORT_CONKT, addr_port);
    fp << " or " << generate_verilog_port(VERILOG_PORT_CONKT, enable_port);
    fp << ") begin" << std::endl;
    fp << "\tif (" << generate_verilog_port(VERILOG_PORT_CONKT, enable_port) << " == 1'b1) begin" << std::endl;
    fp << "\t\t" << generate_verilog_port_constant_values(data_port, std::vector<size_t>(1, 1)) << ";" << std::endl; 
    fp << "\t" << "end else begin" << std::endl;
    fp << "\t\t" << generate_verilog_port_constant_values(data_port, std::vector<size_t>(1, 0)) << ";" << std::endl; 
    fp << "\t" << "end" << std::endl;
    fp << "end" << std::endl;

    /* Depend on if the inverted data output port is needed or not */
    if (true == decoder_lib.use_data_inv_port(decoder)) {
      print_verilog_wire_connection(fp, data_inv_port, addr_port, true);
    }

    print_verilog_comment(fp, std::string("----- END Verilog codes for Decoder convert " + std::to_string(addr_size) + "-bit addr to " + std::to_string(data_size) + "-bit data -----"));

    /* Put an end to the Verilog module */
    print_verilog_module_end(fp, module_name);
    return;
  }

  /* We use a magic number -1 as the addr=1 should be mapped to ...1
   * Otherwise addr will map addr=1 to ..10 
   * Note that there should be a range for the shift operators
   * We should narrow the encoding to be applied to a given set of data
   * This will lead to that any addr which falls out of the op code of data
   * will give a all-zero code
   * For example: 
   * data is 5-bit while addr is 3-bit 
   * data=8'b0_0000 will be encoded to addr=3'b001;
   * data=8'b0_0001 will be encoded to addr=3'b010;
   * data=8'b0_0010 will be encoded to addr=3'b011;
   * data=8'b0_0100 will be encoded to addr=3'b100;
   * data=8'b0_1000 will be encoded to addr=3'b101;
   * data=8'b1_0000 will be encoded to addr=3'b110;
   * The rest of addr codes 3'b110, 3'b111 will be decoded to data=8'b0_0000;
   */

  fp << "always@(" << generate_verilog_port(VERILOG_PORT_CONKT, addr_port);
  fp << " or " << generate_verilog_port(VERILOG_PORT_CONKT, enable_port);
  fp << ") begin" << std::endl;
  fp << "\tif (" << generate_verilog_port(VERILOG_PORT_CONKT, enable_port) << " == 1'b1) begin" << std::endl;
  fp << "\t\t" << "case (" << generate_verilog_port(VERILOG_PORT_CONKT, addr_port) << ")" << std::endl;
  /* Create a string for addr and data */
  for (size_t i = 0; i < data_size; ++i) {
    fp << "\t\t\t" << generate_verilog_constant_values(itobin_vec(i, addr_size)); 
    fp << " : ";
    fp << generate_verilog_port_constant_values(data_port, ito1hot_vec(i, data_size)); 
    fp << ";" << std::endl;
  }
  /* Different from MUX decoder, we assign default values which is all zero */
  fp << "\t\t\t" << "default"; 
  fp << " : ";
  fp << generate_verilog_port_constant_values(data_port, ito1hot_vec(data_size, data_size)); 
  fp << ";" << std::endl;

  fp << "\t\t" << "endcase" << std::endl;
  fp << "\t" << "end" << std::endl;

  /* If enable is not active, we should give all zero */
  fp << "\t" << "else begin" << std::endl;
  fp << "\t\t" << generate_verilog_port_constant_values(data_port, ito1hot_vec(data_size, data_size)); 
  fp << ";" << std::endl;
  fp << "\t" << "end" << std::endl;
  
  fp << "end" << std::endl;

  if (true == decoder_lib.use_data_inv_port(decoder)) {
    print_verilog_wire_connection(fp, data_inv_port, data_port, true);
  }
  
  print_verilog_comment(fp, std::string("----- END Verilog codes for Decoder convert " + std::to_string(addr_size) + "-bit addr to " + std::to_string(data_size) + "-bit data -----"));

  /* Put an end to the Verilog module */
  print_verilog_module_end(fp, module_name);
}

/***************************************************************************************
 * Create a Verilog module for a decoder with data_in used as a configuration protocol 
 * in FPGA architecture
 *
 *                     Address
 *                   | | ... | 
 *                   v v     v
 *                 +-----------+
 *        Enable->/             \<-data_in
 *               /    Decoder    \
 *              +-----------------+
 *                | | | ... | | |
 *                v v v     v v v
 *                    Data output
 *
 *  The outputs are assumes to be one-hot codes (at most only one '1' exist)
 *  Only the data output at the address bit will show data_in
 *
 *  The decoder has an enable signal which is active at logic '1'. 
 *  When activated, the decoder will output decoding results to the data output port
 *  Otherwise, the data output port will be always all-zero
 ***************************************************************************************/
static 
void print_verilog_arch_decoder_with_data_in_module(std::fstream& fp, 
                                                    const ModuleManager& module_manager,
                                                    const DecoderLibrary& decoder_lib,
                                                    const DecoderId& decoder) {
  /* Get the number of inputs */
  size_t addr_size = decoder_lib.addr_size(decoder);
  size_t data_size = decoder_lib.data_size(decoder);
  VTR_ASSERT(true == decoder_lib.use_data_in(decoder));

  /* Validate the FILE handler */
  VTR_ASSERT(true == valid_file_stream(fp));

  /* Create a name for the decoder */
  std::string module_name = generate_memory_decoder_with_data_in_subckt_name(addr_size, data_size);

  /* Create a Verilog Module based on the circuit model, and add to module manager */
  ModuleId module_id = module_manager.find_module(module_name); 
  VTR_ASSERT(true == module_manager.valid_module_id(module_id));
  /* Find module ports */
  /* Enable port */
  ModulePortId enable_port_id = module_manager.find_module_port(module_id, std::string(DECODER_ENABLE_PORT_NAME));
  BasicPort enable_port = module_manager.module_port(module_id, enable_port_id);
  /* Address port */
  ModulePortId addr_port_id = module_manager.find_module_port(module_id, std::string(DECODER_ADDRESS_PORT_NAME));
  BasicPort addr_port = module_manager.module_port(module_id, addr_port_id);
  /* Find data-in port*/
  ModulePortId din_port_id = module_manager.find_module_port(module_id, std::string(DECODER_DATA_IN_PORT_NAME));
  BasicPort din_port = module_manager.module_port(module_id, din_port_id);
  /* Find each output port */
  ModulePortId data_port_id = module_manager.find_module_port(module_id, std::string(DECODER_DATA_OUT_PORT_NAME));
  BasicPort data_port = module_manager.module_port(module_id, data_port_id);
  /* Data port is registered. It should be outputted as 
   *   output reg [lsb:msb] data 
   */
  BasicPort data_inv_port(std::string(DECODER_DATA_OUT_INV_PORT_NAME), data_size);
  if (true == decoder_lib.use_data_inv_port(decoder)) {
    ModulePortId data_inv_port_id = module_manager.find_module_port(module_id, std::string(DECODER_DATA_OUT_INV_PORT_NAME));
    data_inv_port = module_manager.module_port(module_id, data_inv_port_id);
  }

  /* dump module definition + ports */
  print_verilog_module_declaration(fp, module_manager, module_id);
  /* Finish dumping ports */

  print_verilog_comment(fp, std::string("----- BEGIN Verilog codes for Decoder convert " + std::to_string(addr_size) + "-bit addr to " + std::to_string(data_size) + "-bit data -----"));

  /* Print the truth table of this decoder */
  /* Internal logics */
  /* Early exit: Corner case for data size = 1 the logic is very simple:
   * data = addr;  
   * data_inv = ~data_inv
   */
  if (1 == data_size) {
    fp << "always@(" << generate_verilog_port(VERILOG_PORT_CONKT, addr_port);
    fp << " or " << generate_verilog_port(VERILOG_PORT_CONKT, enable_port);
    fp << ") begin" << std::endl;
    fp << "\tif (" << generate_verilog_port(VERILOG_PORT_CONKT, enable_port) << " == 1'b1) begin" << std::endl;
    fp << "\t\t" << generate_verilog_port(VERILOG_PORT_CONKT, din_port) << ";" << std::endl; 
    fp << "\t" << "end else begin" << std::endl;
    fp << "\t\t" << generate_verilog_port_constant_values(data_port, std::vector<size_t>(1, 0)) << ";" << std::endl; 
    fp << "\t" << "end" << std::endl;
    fp << "end" << std::endl;

    /* Depend on if the inverted data output port is needed or not */
    if (true == decoder_lib.use_data_inv_port(decoder)) {
      print_verilog_wire_connection(fp, data_inv_port, addr_port, true);
    }

    print_verilog_comment(fp, std::string("----- END Verilog codes for Decoder convert " + std::to_string(addr_size) + "-bit addr to " + std::to_string(data_size) + "-bit data -----"));

    /* Put an end to the Verilog module */
    print_verilog_module_end(fp, module_name);
    return;
  }

  /* Only the selected data output bit will be set to the value of data_in, 
   * other data output bits will be '0'
   */
  fp << "always@(" << generate_verilog_port(VERILOG_PORT_CONKT, addr_port);
  fp << ", " << generate_verilog_port(VERILOG_PORT_CONKT, enable_port);
  fp << ", " << generate_verilog_port(VERILOG_PORT_CONKT, din_port);
  fp << ") begin" << std::endl;

  fp << "\tif (" << generate_verilog_port(VERILOG_PORT_CONKT, enable_port) << " == 1'b1) begin" << std::endl;
  fp << "\t\t" << generate_verilog_port(VERILOG_PORT_CONKT, data_port); 
  fp << " = ";
  std::string high_res_str = "{" + std::to_string(data_port.get_width()) + "{1'bz}}";
  fp << high_res_str;
  fp << ";" << std::endl;
  fp << "\t\t" << "case (" << generate_verilog_port(VERILOG_PORT_CONKT, addr_port) << ")" << std::endl;
  /* Create a string for addr and data */
  for (size_t i = 0; i < data_size; ++i) {
    BasicPort cur_data_port(data_port.get_name(), i, i);
    fp << "\t\t\t" << generate_verilog_constant_values(itobin_vec(i, addr_size)); 
    fp << " : ";
    fp << generate_verilog_port(VERILOG_PORT_CONKT, cur_data_port); 
    fp << " = ";
    fp << generate_verilog_port(VERILOG_PORT_CONKT, din_port); 
    fp << ";" << std::endl;
  }
  /* Different from MUX decoder, we assign default values which is all zero */
  fp << "\t\t\t" << "default"; 
  fp << " : ";
  fp << generate_verilog_port_constant_values(data_port, ito1hot_vec(data_size, data_size)); 
  fp << ";" << std::endl;

  fp << "\t\t" << "endcase" << std::endl;
  fp << "\t" << "end" << std::endl;

  /* If enable is not active, we should give all zero */
  fp << "\t" << "else begin" << std::endl;
  fp << "\t\t" << generate_verilog_port_constant_values(data_port, ito1hot_vec(data_size, data_size)); 
  fp << ";" << std::endl;
  fp << "\t" << "end" << std::endl;
  
  fp << "end" << std::endl;


  if (true == decoder_lib.use_data_inv_port(decoder)) {
    print_verilog_wire_connection(fp, data_inv_port, data_port, true);
  }
  
  print_verilog_comment(fp, std::string("----- END Verilog codes for Decoder convert " + std::to_string(addr_size) + "-bit addr to " + std::to_string(data_size) + "-bit data -----"));

  /* Put an end to the Verilog module */
  print_verilog_module_end(fp, module_name);
}

/***************************************************************************************
 * This function will generate all the unique Verilog modules of decoders for 
 * configuration protocols in a FPGA fabric
 * It will generate these decoder Verilog modules using behavioral description.
 * Note that the implementation of local decoders can be dependent on the technology
 * and standard cell libraries.
 * Therefore, behavioral Verilog is used and the local decoders should be synthesized 
 * before running the back-end flow for FPGA fabric 
 * See more details in the function print_verilog_arch_decoder() for more details
 ***************************************************************************************/
void print_verilog_submodule_arch_decoders(const ModuleManager& module_manager,
                                           NetlistManager& netlist_manager,
                                           const DecoderLibrary& decoder_lib,
                                           const std::string& submodule_dir) {
  std::string verilog_fname(submodule_dir + std::string(ARCH_ENCODER_VERILOG_FILE_NAME));

  /* Create the file stream */
  std::fstream fp;
  fp.open(verilog_fname, std::fstream::out | std::fstream::trunc);

  check_file_stream(verilog_fname.c_str(), fp);

  /* Print out debugging information for if the file is not opened/created properly */
  VTR_LOG("Writing Verilog netlist for configuration decoders '%s'...",
          verilog_fname.c_str()); 

  print_verilog_file_header(fp, "Decoders for fabric configuration protocol "); 

  /* Generate Verilog modules for the found unique local encoders */
  for (const auto& decoder : decoder_lib.decoders()) {
    if (true == decoder_lib.use_data_in(decoder)) {
      print_verilog_arch_decoder_with_data_in_module(fp, module_manager, decoder_lib, decoder);
    } else {
      print_verilog_arch_decoder_module(fp, module_manager, decoder_lib, decoder);
    }
  }

  /* Close the file stream */
  fp.close();

  /* Add fname to the netlist name list */
  NetlistId nlist_id = netlist_manager.add_netlist(verilog_fname);
  VTR_ASSERT(NetlistId::INVALID() != nlist_id);
  netlist_manager.set_netlist_type(nlist_id, NetlistManager::SUBMODULE_NETLIST);

  VTR_LOG("Done\n");
}


} /* end namespace openfpga */