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[/] [openmsp430/] [trunk/] [fpga/] [altera_de0_nano_soc/] [rtl/] [verilog/] [opengfx430/] [ogfx_reg_vram_if.v] - Rev 221
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//---------------------------------------------------------------------------- // Copyright (C) 2015 Authors // // This source file may be used and distributed without restriction provided // that this copyright statement is not removed from the file and that any // derivative work contains the original copyright notice and the associated // disclaimer. // // This source file is free software; you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published // by the Free Software Foundation; either version 2.1 of the License, or // (at your option) any later version. // // This source is distributed in the hope that it will be useful, but WITHOUT // ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or // FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public // License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with this source; if not, write to the Free Software Foundation, // Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA // //---------------------------------------------------------------------------- // // *File Name: ogfx_reg_vram_if.v // // *Module Description: // Video-RAM Registers interface. // // *Author(s): // - Olivier Girard, olgirard@gmail.com // //---------------------------------------------------------------------------- // $Rev$ // $LastChangedBy$ // $LastChangedDate$ //---------------------------------------------------------------------------- `ifdef OGFX_NO_INCLUDE `else `include "openGFX430_defines.v" `endif module ogfx_reg_vram_if ( // OUTPUTs vid_ram_cfg_o, // VID_RAMx_CFG Register vid_ram_width_o, // VID_RAMx_WIDTH Register `ifdef VRAM_BIGGER_4_KW vid_ram_addr_hi_o, // VID_RAMx_ADDR_HI Register `endif vid_ram_addr_lo_o, // VID_RAMx_ADDR_LO Register vid_ram_data_o, // VID_RAMx_DATA Register vid_ram_we_o, // Video-RAM Write strobe vid_ram_ce_o, // Video-RAM Chip enable vid_ram_din_o, // Video-RAM Data input vid_ram_addr_nxt_o, // Video-RAM Next address vid_ram_access_o, // Video-RAM Access // INPUTs mclk, // Main system clock puc_rst, // Main system reset vid_ram_cfg_wr_i, // VID_RAMx_CFG Write strobe vid_ram_width_wr_i, // VID_RAMx_WIDTH Write strobe vid_ram_addr_hi_wr_i, // VID_RAMx_ADDR_HI Write strobe vid_ram_addr_lo_wr_i, // VID_RAMx_ADDR_LO Write strobe vid_ram_data_wr_i, // VID_RAMx_DATA Write strobe vid_ram_data_rd_i, // VID_RAMx_DATA Read strobe dbg_freeze_i, // Freeze auto-increment on read when CPU stopped display_width_i, // Display width gfx_mode_1_bpp_i, // Graphic mode 1 bpp resolution gfx_mode_2_bpp_i, // Graphic mode 2 bpp resolution gfx_mode_4_bpp_i, // Graphic mode 4 bpp resolution gfx_mode_8_bpp_i, // Graphic mode 8 bpp resolution gfx_mode_16_bpp_i, // Graphic mode 16 bpp resolution per_din_i, // Peripheral data input vid_ram_base_addr_i, // Video-RAM base address vid_ram_dout_i // Video-RAM data input ); // OUTPUTs //========= output [15:0] vid_ram_cfg_o; // VID_RAMx_CFG Register output [15:0] vid_ram_width_o; // VID_RAMx_WIDTH Register `ifdef VRAM_BIGGER_4_KW output [15:0] vid_ram_addr_hi_o; // VID_RAMx_ADDR_HI Register `endif output [15:0] vid_ram_addr_lo_o; // VID_RAMx_ADDR_LO Register output [15:0] vid_ram_data_o; // VID_RAMx_DATA Register output vid_ram_we_o; // Video-RAM Write strobe output vid_ram_ce_o; // Video-RAM Chip enable output [15:0] vid_ram_din_o; // Video-RAM Data input output [`APIX_MSB:0] vid_ram_addr_nxt_o; // Video-RAM Next address output vid_ram_access_o; // Video-RAM Access // INPUTs //========= input mclk; // Main system clock input puc_rst; // Main system reset input vid_ram_cfg_wr_i; // VID_RAMx_CFG Write strobe input vid_ram_width_wr_i; // VID_RAMx_WIDTH Write strobe input vid_ram_addr_hi_wr_i; // VID_RAMx_ADDR_HI Write strobe input vid_ram_addr_lo_wr_i; // VID_RAMx_ADDR_LO Write strobe input vid_ram_data_wr_i; // VID_RAMx_DATA Write strobe input vid_ram_data_rd_i; // VID_RAMx_DATA Read strobe input dbg_freeze_i; // Freeze auto-increment on read when CPU stopped input [`LPIX_MSB:0] display_width_i; // Display width input gfx_mode_1_bpp_i; // Graphic mode 1 bpp resolution input gfx_mode_2_bpp_i; // Graphic mode 2 bpp resolution input gfx_mode_4_bpp_i; // Graphic mode 4 bpp resolution input gfx_mode_8_bpp_i; // Graphic mode 8 bpp resolution input gfx_mode_16_bpp_i; // Graphic mode 16 bpp resolution input [15:0] per_din_i; // Peripheral data input input [`APIX_MSB:0] vid_ram_base_addr_i; // Video-RAM base address input [15:0] vid_ram_dout_i; // Video-RAM data input //============================================================================= // 1) WIRE AND FUNCTION DECLARATIONS //============================================================================= // 16 bits one-hot decoder function [15:0] one_hot16; input [3:0] binary; begin one_hot16 = 16'h0000; one_hot16[binary] = 1'b1; end endfunction //============================================================================ // 2) REGISTERS //============================================================================ //------------------------------------------------ // VID_RAMx_CFG Register //------------------------------------------------ reg vid_ram_rmw_mode; reg vid_ram_msk_mode; reg vid_ram_win_mode; reg vid_ram_win_x_swap; reg vid_ram_win_y_swap; reg vid_ram_win_cl_swap; always @ (posedge mclk or posedge puc_rst) if (puc_rst) begin vid_ram_win_cl_swap <= 1'b0; vid_ram_win_y_swap <= 1'b0; vid_ram_win_x_swap <= 1'b0; vid_ram_rmw_mode <= 1'b0; vid_ram_msk_mode <= 1'b0; vid_ram_win_mode <= 1'b0; end else if (vid_ram_cfg_wr_i) begin vid_ram_win_cl_swap <= per_din_i[0]; vid_ram_win_y_swap <= per_din_i[1]; vid_ram_win_x_swap <= per_din_i[2]; vid_ram_rmw_mode <= per_din_i[4]; vid_ram_msk_mode <= per_din_i[5]; vid_ram_win_mode <= per_din_i[6]; end assign vid_ram_cfg_o = {8'h00, 1'b0, vid_ram_win_mode, vid_ram_msk_mode, vid_ram_rmw_mode , 1'b0, vid_ram_win_x_swap, vid_ram_win_y_swap, vid_ram_win_cl_swap}; //------------------------------------------------ // VID_RAMx_WIDTH Register //------------------------------------------------ reg [`LPIX_MSB:0] vid_ram_width; // width must be at least 1 wire [`LPIX_MSB:0] vid_ram_width_nxt = (|per_din_i[`LPIX_MSB:0]) ? per_din_i[`LPIX_MSB:0] : {{`LPIX_MSB{1'b0}}, 1'b1}; always @ (posedge mclk or posedge puc_rst) if (puc_rst) vid_ram_width <= {{`LPIX_MSB{1'b0}}, 1'b1}; else if (vid_ram_width_wr_i) vid_ram_width <= vid_ram_width_nxt; wire [16:0] vid_ram_width_tmp = {{16-`LPIX_MSB{1'b0}}, vid_ram_width}; assign vid_ram_width_o = vid_ram_width_tmp[15:0]; //------------------------------------------------ // VID_RAMx_ADDR_HI Register //------------------------------------------------ wire [`APIX_MSB:0] vid_ram_addr; wire [`APIX_MSB:0] vid_ram_addr_inc; wire vid_ram_addr_inc_wr; reg vid_ram_addr_hi_wr_dly; `ifdef VRAM_BIGGER_4_KW reg [`APIX_HI_MSB:0] vid_ram_addr_hi; always @ (posedge mclk or posedge puc_rst) if (puc_rst) vid_ram_addr_hi <= {`APIX_HI_MSB+1{1'b0}}; else if (vid_ram_addr_hi_wr_i) vid_ram_addr_hi <= per_din_i[`APIX_HI_MSB:0]; else if (vid_ram_addr_inc_wr) vid_ram_addr_hi <= vid_ram_addr_inc[`APIX_MSB:16]; wire [16:0] vid_ram_addr_hi_tmp = {{16-`APIX_HI_MSB{1'b0}},vid_ram_addr_hi}; assign vid_ram_addr_hi_o = vid_ram_addr_hi_tmp[15:0]; `endif //------------------------------------------------ // VID_RAMx_ADDR_LO Register //------------------------------------------------ reg [`APIX_LO_MSB:0] vid_ram_addr_lo; always @ (posedge mclk or posedge puc_rst) if (puc_rst) vid_ram_addr_lo <= {`APIX_LO_MSB+1{1'b0}}; else if (vid_ram_addr_lo_wr_i) vid_ram_addr_lo <= per_din_i[`APIX_LO_MSB:0]; else if (vid_ram_addr_inc_wr) vid_ram_addr_lo <= vid_ram_addr_inc[`APIX_LO_MSB:0]; `ifdef VRAM_BIGGER_4_KW assign vid_ram_addr = {vid_ram_addr_hi[`APIX_HI_MSB:0], vid_ram_addr_lo}; assign vid_ram_addr_lo_o = vid_ram_addr_lo; `else assign vid_ram_addr = {vid_ram_addr_lo[`APIX_LO_MSB:0]}; wire [16:0] vid_ram_addr_lo_tmp = {{16-`APIX_LO_MSB{1'b0}},vid_ram_addr_lo}; assign vid_ram_addr_lo_o = vid_ram_addr_lo_tmp[15:0]; `endif // Compute the next address ogfx_reg_vram_addr ogfx_reg_vram_addr_inst ( // OUTPUTs .vid_ram_addr_nxt_o ( vid_ram_addr_inc ), // Next Video-RAM address // INPUTs .mclk ( mclk ), // Main system clock .puc_rst ( puc_rst ), // Main system reset .display_width_i ( display_width_i ), // Display width .gfx_mode_1_bpp_i ( gfx_mode_1_bpp_i ), // Graphic mode 1 bpp resolution .gfx_mode_2_bpp_i ( gfx_mode_2_bpp_i ), // Graphic mode 2 bpp resolution .gfx_mode_4_bpp_i ( gfx_mode_4_bpp_i ), // Graphic mode 4 bpp resolution .gfx_mode_8_bpp_i ( gfx_mode_8_bpp_i ), // Graphic mode 8 bpp resolution .gfx_mode_16_bpp_i ( gfx_mode_16_bpp_i ), // Graphic mode 16 bpp resolution .vid_ram_addr_i ( vid_ram_addr ), // Video-RAM address .vid_ram_addr_init_i ( vid_ram_addr_hi_wr_dly ), // Video-RAM address initialization .vid_ram_addr_step_i ( vid_ram_addr_inc_wr ), // Video-RAM address step .vid_ram_width_i ( vid_ram_width ), // Video-RAM width .vid_ram_msk_mode_i ( vid_ram_msk_mode ), // Video-RAM Mask mode enable .vid_ram_win_mode_i ( vid_ram_win_mode ), // Video-RAM Windows mode enable .vid_ram_win_x_swap_i ( vid_ram_win_x_swap ), // Video-RAM X-Swap configuration .vid_ram_win_y_swap_i ( vid_ram_win_y_swap ), // Video-RAM Y-Swap configuration .vid_ram_win_cl_swap_i ( vid_ram_win_cl_swap ) // Video-RAM CL-Swap configuration ); //------------------------------------------------ // VID_RAMx_DATA Register //------------------------------------------------ // Format input data for masked mode wire [15:0] per_din_mask_mode = (({16{gfx_mode_1_bpp_i & vid_ram_msk_mode }} & {16{per_din_i[0] }}) | ({16{gfx_mode_2_bpp_i & vid_ram_msk_mode }} & {8{per_din_i[1:0]}}) | ({16{gfx_mode_4_bpp_i & vid_ram_msk_mode }} & {4{per_din_i[3:0]}}) | ({16{gfx_mode_8_bpp_i & vid_ram_msk_mode }} & {2{per_din_i[7:0]}}) | ({16{gfx_mode_16_bpp_i | ~vid_ram_msk_mode }} & per_din_i ) ); // Prepare data to be written according to mask mode enable reg [15:0] vid_ram_data_mask; wire [15:0] per_din_ram_nxt = per_din_mask_mode & vid_ram_data_mask; // VIDEO-RAM data Register reg [15:0] vid_ram_data; wire [15:0] vid_ram_data_mux; wire vid_ram_dout_rdy; always @ (posedge mclk or posedge puc_rst) if (puc_rst) vid_ram_data <= 16'h0000; else if (vid_ram_data_wr_i) vid_ram_data <= per_din_ram_nxt | (vid_ram_data_mux & ~vid_ram_data_mask); else if (vid_ram_dout_rdy) vid_ram_data <= vid_ram_dout_i; // Make value available in case of early read assign vid_ram_data_mux = vid_ram_dout_rdy ? vid_ram_dout_i : vid_ram_data; // Format read-path for mask mode wire [15:0] vid_ram_data_rd_mask = vid_ram_data_mux & vid_ram_data_mask; wire vid_ram_data_rd_mask_1_bpp = (|vid_ram_data_rd_mask); wire [1:0] vid_ram_data_rd_mask_2_bpp = {(|{vid_ram_data_rd_mask[15], vid_ram_data_rd_mask[13], vid_ram_data_rd_mask[11], vid_ram_data_rd_mask[9], vid_ram_data_rd_mask[7], vid_ram_data_rd_mask[5], vid_ram_data_rd_mask[3], vid_ram_data_rd_mask[1]}), (|{vid_ram_data_rd_mask[14], vid_ram_data_rd_mask[12], vid_ram_data_rd_mask[10], vid_ram_data_rd_mask[8], vid_ram_data_rd_mask[6], vid_ram_data_rd_mask[4], vid_ram_data_rd_mask[2], vid_ram_data_rd_mask[0]})}; wire [3:0] vid_ram_data_rd_mask_4_bpp = {(|{vid_ram_data_rd_mask[15], vid_ram_data_rd_mask[11], vid_ram_data_rd_mask[7] , vid_ram_data_rd_mask[3]}), (|{vid_ram_data_rd_mask[14], vid_ram_data_rd_mask[10], vid_ram_data_rd_mask[6] , vid_ram_data_rd_mask[2]}), (|{vid_ram_data_rd_mask[13], vid_ram_data_rd_mask[9] , vid_ram_data_rd_mask[5] , vid_ram_data_rd_mask[1]}), (|{vid_ram_data_rd_mask[12], vid_ram_data_rd_mask[8] , vid_ram_data_rd_mask[4] , vid_ram_data_rd_mask[0]})}; wire [7:0] vid_ram_data_rd_mask_8_bpp = {(|{vid_ram_data_rd_mask[15], vid_ram_data_rd_mask[7]}), (|{vid_ram_data_rd_mask[14], vid_ram_data_rd_mask[6]}), (|{vid_ram_data_rd_mask[13], vid_ram_data_rd_mask[5]}), (|{vid_ram_data_rd_mask[12], vid_ram_data_rd_mask[4]}), (|{vid_ram_data_rd_mask[11], vid_ram_data_rd_mask[3]}), (|{vid_ram_data_rd_mask[10], vid_ram_data_rd_mask[2]}), (|{vid_ram_data_rd_mask[9] , vid_ram_data_rd_mask[1]}), (|{vid_ram_data_rd_mask[8] , vid_ram_data_rd_mask[0]})}; wire [15:0] vid_ram_data_rd_mask_16_bpp = vid_ram_data_rd_mask; assign vid_ram_data_o = ({16{gfx_mode_1_bpp_i & vid_ram_msk_mode }} & {{15{1'b0}},vid_ram_data_rd_mask_1_bpp}) | ({16{gfx_mode_2_bpp_i & vid_ram_msk_mode }} & {{14{1'b0}},vid_ram_data_rd_mask_2_bpp}) | ({16{gfx_mode_4_bpp_i & vid_ram_msk_mode }} & {{12{1'b0}},vid_ram_data_rd_mask_4_bpp}) | ({16{gfx_mode_8_bpp_i & vid_ram_msk_mode }} & { {8{1'b0}},vid_ram_data_rd_mask_8_bpp}) | ({16{gfx_mode_16_bpp_i | ~vid_ram_msk_mode }} & vid_ram_data_rd_mask_16_bpp) ; //============================================================================ // 3) VIDEO MEMORY INTERFACE //============================================================================ // // Trigger a VIDEO-RAM write access after: // - a VID_RAMx_DATA register write access // // Trigger a VIDEO-RAM read access immediately after: // - a VID_RAMx_ADDR_LO register write access // - a VID_RAMx_DATA register read access // - a VID_RAMx_DATA register write access in MSK mode (for resolutions lower than 16bpp) // //-------------------------------------------------- // VID_RAM0: Delay software read and write strobes //-------------------------------------------------- // Strobe writing to VID_RAMx_ADDR_LO register always @ (posedge mclk or posedge puc_rst) if (puc_rst) vid_ram_addr_hi_wr_dly <= 1'b0; else vid_ram_addr_hi_wr_dly <= vid_ram_addr_hi_wr_i; // Strobe reading from VID_RAMx_DATA register reg vid_ram_data_rd_dly; always @ (posedge mclk or posedge puc_rst) if (puc_rst) vid_ram_data_rd_dly <= 1'b0; else vid_ram_data_rd_dly <= vid_ram_data_rd_i; // Strobe writing to VID_RAMx_DATA register reg vid_ram_data_wr_dly; always @ (posedge mclk or posedge puc_rst) if (puc_rst) vid_ram_data_wr_dly <= 1'b0; else vid_ram_data_wr_dly <= vid_ram_data_wr_i; // Trigger read access after a write in MSK mode wire vid_ram_data_rd_msk = ((vid_ram_data_wr_dly | vid_ram_data_rd_dly | vid_ram_addr_hi_wr_i) & vid_ram_msk_mode & ~gfx_mode_16_bpp_i); //------------------------------------------------ // Compute VIDEO-RAM Strobes & Data //------------------------------------------------ // Write access strobe // - one cycle after a VID_RAM_DATA register write access assign vid_ram_we_o = vid_ram_data_wr_dly; // Chip enable. // Note: we perform a data read access: // - one cycle after a VID_RAM_DATA register read access (so that the address has been incremented) // - one cycle after a VID_RAM_ADDR_LO register write wire vid_ram_ce_early = (vid_ram_addr_hi_wr_i | vid_ram_data_rd_dly | vid_ram_data_rd_msk | // Read access vid_ram_data_wr_i); // Write access reg [1:0] vid_ram_ce; always @ (posedge mclk or posedge puc_rst) if (puc_rst) vid_ram_ce <= 2'b00; else vid_ram_ce <= {vid_ram_ce[0] & ~vid_ram_data_wr_dly, vid_ram_ce_early}; assign vid_ram_ce_o = vid_ram_ce[0]; // Data to be written assign vid_ram_din_o = {16{vid_ram_ce[0]}} & vid_ram_data; // Update the VRAM_DATA register one cycle after each memory access assign vid_ram_dout_rdy = vid_ram_ce[1]; //------------------------------------------------ // Compute VIDEO-RAM Address //------------------------------------------------ // Mux ram address for early read access when ADDR_LO is updated `ifdef VRAM_BIGGER_4_KW wire [`APIX_MSB:0] vid_ram_addr_mux = vid_ram_addr_hi_wr_i ? {per_din_i[`APIX_HI_MSB:0], vid_ram_addr[15:0]} : vid_ram_data_rd_msk ? vid_ram_addr_inc : vid_ram_addr; `else wire [`APIX_MSB:0] vid_ram_addr_mux = vid_ram_addr_hi_wr_i ? {per_din_i[`APIX_LO_MSB:0]} : vid_ram_data_rd_msk ? vid_ram_addr_inc : vid_ram_addr; `endif // Add frame pointer offset wire [`APIX_MSB:0] vid_ram_addr_offset = vid_ram_base_addr_i + vid_ram_addr_mux; // Detect memory accesses for ADDR update wire vid_ram_access_o = vid_ram_data_wr_i | vid_ram_data_rd_dly | vid_ram_addr_hi_wr_i | vid_ram_data_rd_msk; // Mux Address between the two interfaces wire [`APIX_MSB:0] vid_ram_addr_nxt_o = {`APIX_MSB+1{vid_ram_access_o}} & vid_ram_addr_offset; // Increment the address when accessing the VID_RAMx_DATA register: // - one clock cycle after a write access // - with the read access (if not in read-modify-write mode) assign vid_ram_addr_inc_wr = vid_ram_addr_hi_wr_dly | vid_ram_data_wr_dly | (vid_ram_data_rd_i & ~dbg_freeze_i & ~vid_ram_rmw_mode); // Compute mask for the address LSBs depending on BPP resolution wire [3:0] gfx_mode_addr_msk = ( {4{gfx_mode_1_bpp_i}} | // Take 4 address LSBs in 1bpp mode {1'b0, {3{gfx_mode_2_bpp_i}}} | // Take 3 address LSBs in 2bpp mode {2'b00, {2{gfx_mode_4_bpp_i}}} | // Take 2 address LSBs in 4bpp mode {3'b000, gfx_mode_8_bpp_i}); // Take 1 address LSB in 8bpp mode // Take no address LSB in 16bpp mode // Generate Data-Mask for the mask mode (Bank 0) wire [15:0] vid_ram_data_mask_shift = one_hot16(vid_ram_addr_offset[3:0] & gfx_mode_addr_msk); wire [15:0] vid_ram_data_mask_nxt = ({16{gfx_mode_1_bpp_i }} & vid_ram_data_mask_shift ) | ({16{gfx_mode_2_bpp_i }} & {{2{vid_ram_data_mask_shift[7]}}, {2{vid_ram_data_mask_shift[6]}}, {2{vid_ram_data_mask_shift[5]}}, {2{vid_ram_data_mask_shift[4]}}, {2{vid_ram_data_mask_shift[3]}}, {2{vid_ram_data_mask_shift[2]}}, {2{vid_ram_data_mask_shift[1]}}, {2{vid_ram_data_mask_shift[0]}}}) | ({16{gfx_mode_4_bpp_i }} & {{4{vid_ram_data_mask_shift[3]}}, {4{vid_ram_data_mask_shift[2]}}, {4{vid_ram_data_mask_shift[1]}}, {4{vid_ram_data_mask_shift[0]}}}) | ({16{gfx_mode_8_bpp_i }} & {{8{vid_ram_data_mask_shift[1]}}, {8{vid_ram_data_mask_shift[0]}}}) | ({16{gfx_mode_16_bpp_i}} & {16{1'b1}} ) ; always @ (posedge mclk or posedge puc_rst) if (puc_rst) vid_ram_data_mask <= 16'hffff; else if (vid_ram_data_rd_msk) vid_ram_data_mask <= vid_ram_data_mask_nxt; else if (vid_ram_access_o) vid_ram_data_mask <= 16'hffff; endmodule // ogfx_reg_vram_if `ifdef OGFX_NO_INCLUDE `else `include "openGFX430_undefines.v" `endif