abstractaccelerator/opene906/smart_run/logical/mem/dahb_mem_ctrl.v

/*Copyright 2020-2021 T-Head Semiconductor Co., Ltd.

Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at

    http://www.apache.org/licenses/LICENSE-2.0

Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
*/
module dahb_mem_ctrl(
  lite_mmc_hsel,
  lite_yy_haddr,
  lite_yy_hsize,
  lite_yy_htrans,
  lite_yy_hwdata,
  lite_yy_hwrite,
  mmc_lite_hrdata,
  mmc_lite_hready,
  mmc_lite_hresp,
  pad_biu_bigend_b,
  pad_cpu_rst_b,
  pll_core_cpuclk
);

// &Ports; @22
input           lite_mmc_hsel;                 
input   [31:0]  lite_yy_haddr;                 
input   [2 :0]  lite_yy_hsize;                 
input   [1 :0]  lite_yy_htrans;                
input   [31:0]  lite_yy_hwdata;                
input           lite_yy_hwrite;                
input           pad_biu_bigend_b;              
input           pad_cpu_rst_b;                 
input           pll_core_cpuclk;               
output  [31:0]  mmc_lite_hrdata;               
output          mmc_lite_hready;               
output  [1 :0]  mmc_lite_hresp;                

// &Regs; @23
reg     [29:0]  addr_holding;                  
reg     [3 :0]  lite_mem_wen;                  
reg             lite_read_bypass;              
reg             lite_read_bypass_vld;          
reg             lite_read_stall;               
reg             lite_read_stall_vld;           
reg     [31:0]  lite_wbuf_addr;                
reg     [31:0]  lite_wbuf_data;                
reg     [2 :0]  lite_wbuf_size;                
reg             lite_write_req;                
reg             lite_write_stall;              

// &Wires; @24
wire            lite_addr_hit;                 
wire            lite_addr_no_hit;              
wire    [31:0]  lite_bypass_data;              
wire    [31:0]  lite_mem_addr;                 
wire            lite_mem_cen;                  
wire    [31:0]  lite_mem_din;                  
wire    [31:0]  lite_mem_dout;                 
wire            lite_mmc_hsel;                 
wire            lite_read_addr_hit_with_bypass; 
wire            lite_read_addr_hit_with_stall; 
wire            lite_read_req;                 
wire            lite_wbuf_update;              
wire            lite_write_cplt;               
wire            lite_write_en;                 
wire            lite_write_req_en;             
wire            lite_write_stall_en;           
wire    [31:0]  lite_yy_haddr;                 
wire    [2 :0]  lite_yy_hsize;                 
wire    [31:0]  lite_yy_hwdata;                
wire            lite_yy_hwrite;                
wire    [31:0]  mmc_lite_hrdata;               
wire            mmc_lite_hready;               
wire    [1 :0]  mmc_lite_hresp;                
wire            pad_biu_bigend_b;              
wire            pad_cpu_rst_b;                 
wire            pll_core_cpuclk;               
wire    [7 :0]  ram0_din;                      
wire    [7 :0]  ram0_dout;                     
wire    [7 :0]  ram1_din;                      
wire    [7 :0]  ram1_dout;                     
wire    [7 :0]  ram2_din;                      
wire    [7 :0]  ram2_dout;                     
wire    [7 :0]  ram3_din;                      
wire    [7 :0]  ram3_dout;                     
wire    [7 :0]  ram4_dout;                     
wire    [7 :0]  ram5_dout;                     
wire    [7 :0]  ram6_dout;                     
wire    [7 :0]  ram7_dout;                     
wire    [29:0]  ram_addr;                      
wire            ram_clk;                       
wire    [7 :0]  ram_wen;                       

parameter DMEM_WIDTH = 20;

// &Force("nonport","lite_mem_addr"); @27
// &Force("nonport","lite_mem_cen"); @28
// &Force("nonport","lite_mem_din"); @29
// &Force("nonport","lite_mem_dout"); @30
// &Force("nonport","lite_mem_wen"); @31
// &Force("input","lite_yy_htrans"); @32
// &Force("bus", "lite_yy_htrans", 1, 0); @33
// //&Force("nonport",""); @34
// //&Force("nonport",""); @35
// //&Force("nonport",""); @36
// //&Force("nonport",""); @37
// //&Force("nonport",""); @38
// //&Force("nonport",""); @39
// //&Force("nonport",""); @40


//write buffer
assign lite_wbuf_update = lite_yy_hwrite && lite_mmc_hsel;
always @ (posedge pll_core_cpuclk or negedge pad_cpu_rst_b)
begin
  if(!pad_cpu_rst_b)
  begin
    lite_wbuf_addr[31:0] <= 32'b0;
    lite_wbuf_size[2:0]  <= 3'b0;
  end
  else if (lite_wbuf_update)
  begin
    lite_wbuf_addr[31:0] <= lite_yy_haddr;
    lite_wbuf_size[2:0]  <= lite_yy_hsize;
  end
  //else if (lite_write_cplt)
  //begin
  //  lite_wbuf_addr[31:0] <= 32'b0;
  //  lite_wbuf_size[2:0]  <= 3'b0;
  //end
end    
//write data    
always @ (posedge pll_core_cpuclk or negedge pad_cpu_rst_b)
begin
  if(!pad_cpu_rst_b)
  begin
    lite_wbuf_data[31:0] <= 32'b0;
  end
  else if (lite_write_req)
  begin
    lite_wbuf_data[31:0] <= lite_yy_hwdata[31:0];
  end
end
//read first and wirte will stall when address don't hit
assign lite_write_stall_en = lite_write_req && lite_addr_no_hit && lite_read_req;
always @ (posedge pll_core_cpuclk or negedge pad_cpu_rst_b)
begin
  if(!pad_cpu_rst_b)
  begin
    lite_write_stall <= 1'b0;
  end
  else if (lite_write_stall_en)
  begin
    lite_write_stall <= 1'b1;
  end
  else if (lite_write_cplt)
  begin
     lite_write_stall <=1'b0;
  end   
end
//write request from bus interface
assign lite_write_req_en = lite_yy_hwrite && lite_mmc_hsel;
always @ (posedge pll_core_cpuclk or negedge pad_cpu_rst_b)
begin
  if(!pad_cpu_rst_b)
  begin
    lite_write_req <= 1'b0;
  end
  else if (lite_write_req_en)
  begin
    lite_write_req <= 1'b1;
  end
  else
  begin
    lite_write_req <= 1'b0;
  end 
end
//read bypass and read stall
always @(posedge pll_core_cpuclk or negedge pad_cpu_rst_b)
begin
  if(!pad_cpu_rst_b)
  begin
    lite_read_bypass <= 1'b0;
    lite_read_stall  <= 1'b0;
  end
  else
  begin
    lite_read_bypass <= lite_read_addr_hit_with_bypass;
    lite_read_stall  <= lite_read_addr_hit_with_stall;
  end
end

//no read first and write request or write stall 
assign lite_write_en    = ((lite_write_req | lite_write_stall) && (lite_addr_hit | (lite_yy_hwrite && lite_mmc_hsel) | ~lite_mmc_hsel));
assign lite_bypass_data[31:0] = lite_wbuf_data[31:0];
//write complete 
assign lite_write_cplt  = (lite_write_req | lite_write_stall) && (lite_addr_hit | ~lite_mmc_hsel | (lite_yy_hwrite && lite_mmc_hsel));
//read request
assign lite_read_req    = ~lite_yy_hwrite && lite_mmc_hsel;
//address hit
assign lite_addr_no_hit = (lite_yy_haddr[31:2] != lite_wbuf_addr[31:2]);
assign lite_addr_hit    = ~lite_addr_no_hit;
//address hit and read will bypass
assign lite_read_addr_hit_with_bypass = lite_read_req && (lite_write_req | lite_write_stall) && lite_addr_hit && lite_read_bypass_vld;
//address hit but read will stall
assign lite_read_addr_hit_with_stall  = lite_read_req && (lite_write_req | lite_write_stall) && lite_addr_hit && lite_read_stall_vld;

//read bypass or stall
// &CombBeg; @140
always @( lite_yy_haddr[1:0]
       or lite_wbuf_addr[1:0]
       or lite_wbuf_size[2:0]
       or lite_yy_hsize[2:0])
begin
casez({lite_wbuf_size[2:0],lite_yy_hsize[2:0],lite_wbuf_addr[1:0],lite_yy_haddr[1:0]})
//st.b/ld.b
10'b000_000_00_00,
10'b000_000_01_01,
10'b000_000_10_10,
10'b000_000_11_11:
  begin
    lite_read_bypass_vld = 1'b1;
    lite_read_stall_vld = 1'b0;
  end
//st.b/ld.h
10'b000_001_??_??:
  begin
    lite_read_stall_vld = 1'b1;
    lite_read_bypass_vld = 1'b0;
  end
//st.b/ld.w
10'b000_010_??_??:
  begin
    lite_read_stall_vld = 1'b1;
    lite_read_bypass_vld = 1'b0;
  end
//st.h/ld.b
10'b001_000_0?_0?,
10'b001_000_1?_1?:
  begin
    lite_read_bypass_vld = 1'b1;
    lite_read_stall_vld = 1'b0;
  end
//st.h/ld.h
10'b001_001_0?_0?,
10'b001_001_1?_1?:
  begin
    lite_read_bypass_vld = 1'b1;
    lite_read_stall_vld = 1'b0;
  end
//st.h/ld.w
10'b001_010_??_??:
  begin
    lite_read_stall_vld = 1'b1;
    lite_read_bypass_vld = 1'b0;
  end
//st.w/all lds
10'b010_???_??_??:
  begin
    lite_read_bypass_vld = 1'b1;
    lite_read_stall_vld = 1'b0;
  end
default:
  begin
    lite_read_bypass_vld = 1'b0;
    lite_read_stall_vld = 1'b0;
  end
endcase
// &CombEnd; @195
end



//memory select
assign lite_mem_cen = ~(lite_read_req | lite_write_req | lite_write_stall);
//memory write enable
// &CombBeg; @202
always @( lite_wbuf_addr[1:0]
       or lite_wbuf_size[2:0]
       or pad_biu_bigend_b
       or lite_write_en)
begin
  case({pad_biu_bigend_b, lite_write_en, lite_wbuf_size[2:0], lite_wbuf_addr[1:0]})
  7'b0100000: 
    begin 
      lite_mem_wen[3:0] = 4'b0111;
    end
  7'b0100001:
    begin 
      lite_mem_wen[3:0] = 4'b1011;
    end
  7'b0100010:
    begin
      lite_mem_wen[3:0] = 4'b1101;
    end
  7'b0100011:
    begin   
      lite_mem_wen[3:0] = 4'b1110;
    end
  7'b0100100:
    begin
      lite_mem_wen[3:0] = 4'b0011;
    end
  7'b0100110:
    begin
      lite_mem_wen[3:0] = 4'b1100;
    end
  7'b0101000:
    begin
      lite_mem_wen[3:0] = 4'b0000;
    end
  7'b1100000:
    begin
      lite_mem_wen[3:0] = 4'b1110;
    end
  7'b1100001:
    begin
      lite_mem_wen[3:0] = 4'b1101;
    end
  7'b1100010:
    begin
      lite_mem_wen[3:0] = 4'b1011;
    end
  7'b1100011:
    begin
      lite_mem_wen[3:0] = 4'b0111;
    end
  7'b1100100:
    begin
      lite_mem_wen[3:0] = 4'b1100;
    end
  7'b1100110:
    begin
      lite_mem_wen[3:0] = 4'b0011;
    end
  7'b1101000:
     begin
       lite_mem_wen[3:0] = 4'b0000;
     end
  default:
    begin
      lite_mem_wen[3:0] = 4'b1111;
    end
  endcase
// &CombEnd; @265
end

assign lite_mem_addr[31:0] = (lite_write_en | lite_read_stall) ? lite_wbuf_addr[31:0] : lite_yy_haddr[31:0];
assign lite_mem_din[31:0] = (lite_write_stall) ? lite_wbuf_data[31:0] : lite_yy_hwdata[31:0];
assign mmc_lite_hrdata[31:0] = lite_read_bypass ? lite_bypass_data[31:0] : lite_mem_dout[31:0];
assign mmc_lite_hready       = !lite_read_stall;
assign mmc_lite_hresp[1:0]   = 2'b0;



//memory
always @(posedge pll_core_cpuclk)
begin
  if(!lite_mem_cen)
    addr_holding[29:0] <= lite_mem_addr[31:2];
end

assign ram_clk = pll_core_cpuclk;
assign ram_addr[29:0] = lite_mem_cen ? addr_holding[29:0] : lite_mem_addr[31:2];
assign ram_wen[0] = (!lite_mem_cen && !lite_mem_wen[0]) && !ram_addr[17];
assign ram_wen[1] = (!lite_mem_cen && !lite_mem_wen[1]) && !ram_addr[17];
assign ram_wen[2] = (!lite_mem_cen && !lite_mem_wen[2]) && !ram_addr[17];
assign ram_wen[3] = (!lite_mem_cen && !lite_mem_wen[3]) && !ram_addr[17];

assign ram_wen[4] = !lite_mem_cen && !lite_mem_wen[0] && ram_addr[17];
assign ram_wen[5] = !lite_mem_cen && !lite_mem_wen[1] && ram_addr[17];
assign ram_wen[6] = !lite_mem_cen && !lite_mem_wen[2] && ram_addr[17];
assign ram_wen[7] = !lite_mem_cen && !lite_mem_wen[3] && ram_addr[17];

assign ram0_din[7:0] = lite_mem_din[7:0];
assign ram1_din[7:0] = lite_mem_din[15:8];
assign ram2_din[7:0] = lite_mem_din[23:16];
assign ram3_din[7:0] = lite_mem_din[31:24];
assign lite_mem_dout[31:0] = addr_holding[17] ? {ram7_dout[7:0], ram6_dout[7:0], ram5_dout[7:0], ram4_dout[7:0]}
                                              : {ram3_dout[7:0], ram2_dout[7:0], ram1_dout[7:0], ram0_dout[7:0]};

// memory unit is in DPTHx8 size, 4 units are instanced
soc_fpga_ram #(8, 17) ram0(
  .PortAClk (ram_clk),
  .PortAAddr(ram_addr[16:0]),
  .PortADataIn (ram0_din),
  .PortAWriteEnable(ram_wen[0]),
  .PortADataOut(ram0_dout));

soc_fpga_ram #(8, 17) ram1(
  .PortAClk (ram_clk),
  .PortAAddr(ram_addr[16:0]),
  .PortADataIn (ram1_din),
  .PortAWriteEnable(ram_wen[1]),
  .PortADataOut(ram1_dout));

soc_fpga_ram #(8, 17) ram2(
  .PortAClk (ram_clk),
  .PortAAddr(ram_addr[16:0]),
  .PortADataIn (ram2_din),
  .PortAWriteEnable(ram_wen[2]),
  .PortADataOut(ram2_dout));

soc_fpga_ram #(8, 17) ram3(
  .PortAClk (ram_clk),
  .PortAAddr(ram_addr[16:0]),
  .PortADataIn (ram3_din),
  .PortAWriteEnable(ram_wen[3]),
  .PortADataOut(ram3_dout));

soc_fpga_ram #(8, 16) ram4(
  .PortAClk (ram_clk),
  .PortAAddr(ram_addr[15:0]),
  .PortADataIn (ram0_din),
  .PortAWriteEnable(ram_wen[4]),
  .PortADataOut(ram4_dout));

soc_fpga_ram #(8, 16) ram5(
  .PortAClk (ram_clk),
  .PortAAddr(ram_addr[15:0]),
  .PortADataIn (ram1_din),
  .PortAWriteEnable(ram_wen[5]),
  .PortADataOut(ram5_dout));

soc_fpga_ram #(8, 16) ram6(
  .PortAClk (ram_clk),
  .PortAAddr(ram_addr[15:0]),
  .PortADataIn (ram2_din),
  .PortAWriteEnable(ram_wen[6]),
  .PortADataOut(ram6_dout));

soc_fpga_ram #(8, 16) ram7(
  .PortAClk (ram_clk),
  .PortAAddr(ram_addr[15:0]),
  .PortADataIn (ram3_din),
  .PortAWriteEnable(ram_wen[7]),
  .PortADataOut(ram7_dout));


// &Force("nonport", "ram_addr"); @359
// &Force("nonport", "ram0_din"); @360
// &Force("nonport", "ram1_din"); @361
// &Force("nonport", "ram2_din"); @362
// &Force("nonport", "ram3_din"); @363
// &Force("nonport", "ram0_dout"); @364
// &Force("nonport", "ram1_dout"); @365
// &Force("nonport", "ram2_dout"); @366
// &Force("nonport", "ram3_dout"); @367
// &Force("nonport", "ram4_dout"); @368
// &Force("nonport", "ram5_dout"); @369
// &Force("nonport", "ram6_dout"); @370
// &Force("nonport", "ram7_dout"); @371
// &Force("nonport", "ram_wen"); @372
// &Force("nonport", "ram_clk"); @373
// &ModuleEnd; @374
endmodule