代码分析 - CAN总线控制器IP核代码分析

  /* Mode register */

  .reset_mode(reset_mode),

  .listen_only_mode(listen_only_mode),

  .acceptance_filter_mode(acceptance_filter_mode),

  .self_test_mode(self_test_mode),

  /* Command register */

  .release_buffer(release_buffer),

  .tx_request(tx_request),

  .abort_tx(abort_tx),

  .self_rx_request(self_rx_request),

  .single_shot_transmission(single_shot_transmission),

  /* Arbitration Lost Capture Register */

  .read_arbitration_lost_capture_reg(read_arbitration_lost_capture_reg),

  /* Error Code Capture Register */

  .read_error_code_capture_reg(read_error_code_capture_reg),

  .error_capture_code(error_capture_code),

  /* Error Warning Limit register */

  .error_warning_limit(error_warning_limit),

  /* Rx Error Counter register */

  .we_rx_err_cnt(we_rx_err_cnt),

  /* Tx Error Counter register */

  .we_tx_err_cnt(we_tx_err_cnt),

  /* Clock Divider register */

  .extended_mode(extended_mode),

  /* output from can_bsp module */

  .rx_idle(rx_idle),

  .transmitting(transmitting),

  .last_bit_of_inter(last_bit_of_inter),

  .set_reset_mode(set_reset_mode),

  .node_bus_off(node_bus_off),

  .error_status(error_status),

  .rx_err_cnt({rx_err_cnt_dummy, rx_err_cnt[7:0]}),   // The MSB is not displayed. It is just used for easier calculation (no counter overflow).

  .tx_err_cnt({tx_err_cnt_dummy, tx_err_cnt[7:0]}),   // The MSB is not displayed. It is just used for easier calculation (no counter overflow).

  .transmit_status(transmit_status),

  .receive_status(receive_status),

  .tx_successful(tx_successful),

  .need_to_tx(need_to_tx),

  .overrun(overrun),

  .info_empty(info_empty),

  .set_bus_error_irq(set_bus_error_irq),

  .set_arbitration_lost_irq(set_arbitration_lost_irq),

  .arbitration_lost_capture(arbitration_lost_capture),

  .node_error_passive(node_error_passive),

  .node_error_active(node_error_active),

  .rx_message_counter(rx_message_counter),

  /* This section is for BASIC and EXTENDED mode */

  /* Acceptance code register */

  .acceptance_code_0(acceptance_code_0),

  /* Acceptance mask register */

  .acceptance_mask_0(acceptance_mask_0),

  /* End: This section is for BASIC and EXTENDED mode */

  /* This section is for EXTENDED mode */

  /* Acceptance code register */

  .acceptance_code_1(acceptance_code_1),

  .acceptance_code_2(acceptance_code_2),

  .acceptance_code_3(acceptance_code_3),

  /* Acceptance mask register */

  .acceptance_mask_1(acceptance_mask_1),

  .acceptance_mask_2(acceptance_mask_2),

  .acceptance_mask_3(acceptance_mask_3),

  /* End: This section is for EXTENDED mode */

  /* Tx data registers. Holding identifier (basic mode), tx frame information (extended mode) and data */

  .tx_data_0(tx_data_0),

  .tx_data_1(tx_data_1),

  .tx_data_2(tx_data_2),

  .tx_data_3(tx_data_3),

  .tx_data_4(tx_data_4),

  .tx_data_5(tx_data_5),

  .tx_data_6(tx_data_6),

  .tx_data_7(tx_data_7),

  .tx_data_8(tx_data_8),

  .tx_data_9(tx_data_9),

  .tx_data_10(tx_data_10),

  .tx_data_11(tx_data_11),

  .tx_data_12(tx_data_12),

  /* End: Tx data registers */

  /* Tx signal */

  .tx(tx_out),

  .tx_oen(tx_oen)

);

assign tx_o = tx_oen? 1'bz : tx_out;

// Multiplexing wb_dat_o from registers and rx fifo

always @ (extended_mode or addr or reset_mode)

begin

  if (extended_mode & (~reset_mode) & ((addr >= 8'd16) && (addr <= 8'd28)) | (~extended_mode) & ((addr >= 8'd20) && (addr <= 8'd29)))

    data_out_fifo_selected <= 1'b1;

  else

    data_out_fifo_selected <= 1'b0;

end

always @ (posedge clk_i)

begin

//  if (wb_cyc_i & (~wb_we_i))

  if (cs & (~we))

    begin

      if (data_out_fifo_selected)

        data_out <=#Tp data_out_fifo;

      else

        data_out <=#Tp data_out_regs;

    end

end

`ifdef CAN_WISHBONE_IF

  // Combining wb_cyc_i and wb_stb_i signals to cs signal. Than synchronizing to clk_i clock domain.

  always @ (posedge clk_i or posedge rst)

  begin

    if (rst)

      begin

        cs_sync1     <= 1'b0;

        cs_sync2     <= 1'b0;

        cs_sync3     <= 1'b0;

        cs_sync_rst1 <= 1'b0;

        cs_sync_rst2 <= 1'b0;

      end

    else

      begin

        cs_sync1     <=#Tp wb_cyc_i & wb_stb_i & (~cs_sync_rst2) & cs_can_i;

        cs_sync2     <=#Tp cs_sync1            & (~cs_sync_rst2);

        cs_sync3     <=#Tp cs_sync2            & (~cs_sync_rst2);

        cs_sync_rst1 <=#Tp cs_ack3;

        cs_sync_rst2 <=#Tp cs_sync_rst1;

      end

  end

  assign cs = cs_sync2 & (~cs_sync3);

  always @ (posedge wb_clk_i)

  begin

    cs_ack1 <=#Tp cs_sync3;

    cs_ack2 <=#Tp cs_ack1;

    cs_ack3 <=#Tp cs_ack2;

  end

  // Generating acknowledge signal

  always @ (posedge wb_clk_i)

  begin

    wb_ack_o <=#Tp (cs_ack2 & (~cs_ack3));

  end

  assign rst      = wb_rst_i;

  assign we       = wb_we_i;

  assign addr     = wb_adr_i;

  assign data_in  = wb_dat_i;

  assign wb_dat_o = data_out;

`else

  // Latching address

  always @ (negedge clk_i or posedge rst)

  begin

    if (rst)

      addr_latched <= 8'h0;

    else if (ale_i)

      addr_latched <=#Tp port_0_io;

  end

  // Generating delayed wr_i and rd_i signals

  always @ (posedge clk_i or posedge rst)

  begin

    if (rst)

      begin

        wr_i_q <= 1'b0;

        rd_i_q <= 1'b0;

      end

    else

      begin

        wr_i_q <=#Tp wr_i;

        rd_i_q <=#Tp rd_i;

      end

  end

  assign cs = ((wr_i & (~wr_i_q)) | (rd_i & (~rd_i_q))) & cs_can_i;

  assign rst       = rst_i;

  assign we        = wr_i;

  assign addr      = addr_latched;

  assign data_in   = port_0_io;

  assign port_0_io = (cs_can_i & rd_i)? data_out : 8'hz;

`endif

endmodule