URL
https://opencores.org/ocsvn/opengfx430/opengfx430/trunk
Subversion Repositories opengfx430
[/] [opengfx430/] [trunk/] [core/] [rtl/] [verilog/] [ogfx_reg.v] - Rev 3
Go to most recent revision | Compare with Previous | Blame | View Log
//---------------------------------------------------------------------------- // 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.v // // *Module Description: // Registers for oMSP programming. // // *Author(s): // - Olivier Girard, olgirard@gmail.com // //---------------------------------------------------------------------------- // $Rev$ // $LastChangedBy$ // $LastChangedDate$ //---------------------------------------------------------------------------- `ifdef OGFX_NO_INCLUDE `else `include "openGFX430_defines.v" `endif module ogfx_reg ( // OUTPUTs irq_gfx_o, // Graphic Controller interrupt gpu_data_o, // GPU data gpu_data_avail_o, // GPU data available gpu_enable_o, // GPU enable lt24_reset_n_o, // LT24 Reset (Active Low) lt24_on_o, // LT24 on/off lt24_cfg_clk_o, // LT24 Interface clock configuration lt24_cfg_refr_o, // LT24 Interface refresh configuration lt24_cfg_refr_sync_en_o, // LT24 Interface refresh sync enable configuration lt24_cfg_refr_sync_val_o, // LT24 Interface refresh sync value configuration lt24_cmd_refr_o, // LT24 Interface refresh command lt24_cmd_val_o, // LT24 Generic command value lt24_cmd_has_param_o, // LT24 Generic command has parameters lt24_cmd_param_o, // LT24 Generic command parameter value lt24_cmd_param_rdy_o, // LT24 Generic command trigger lt24_cmd_dfill_o, // LT24 Data fill value lt24_cmd_dfill_wr_o, // LT24 Data fill trigger display_width_o, // Display width display_height_o, // Display height display_size_o, // Display size (number of pixels) display_y_swap_o, // Display configuration: swap Y axis (horizontal symmetry) display_x_swap_o, // Display configuration: swap X axis (vertical symmetry) display_cl_swap_o, // Display configuration: swap column/lines gfx_mode_o, // Video mode (1xx:16bpp / 011:8bpp / 010:4bpp / 001:2bpp / 000:1bpp) per_dout_o, // Peripheral data output refresh_frame_addr_o, // Refresh frame base address refresh_lut_select_o, // Refresh LUT bank selection `ifdef WITH_PROGRAMMABLE_LUT lut_ram_addr_o, // LUT-RAM address lut_ram_din_o, // LUT-RAM data lut_ram_wen_o, // LUT-RAM write strobe (active low) lut_ram_cen_o, // LUT-RAM chip enable (active low) `endif vid_ram_addr_o, // Video-RAM address vid_ram_din_o, // Video-RAM data vid_ram_wen_o, // Video-RAM write strobe (active low) vid_ram_cen_o, // Video-RAM chip enable (active low) // INPUTs dbg_freeze_i, // Freeze address auto-incr on read gpu_cmd_done_evt_i, // GPU command done event gpu_cmd_error_evt_i, // GPU command error event gpu_get_data_i, // GPU get next data lt24_status_i, // LT24 FSM Status lt24_start_evt_i, // LT24 FSM is starting lt24_done_evt_i, // LT24 FSM is done mclk, // Main system clock per_addr_i, // Peripheral address per_din_i, // Peripheral data input per_en_i, // Peripheral enable (high active) per_we_i, // Peripheral write enable (high active) puc_rst, // Main system reset `ifdef WITH_PROGRAMMABLE_LUT lut_ram_dout_i, // LUT-RAM data input `endif vid_ram_dout_i // Video-RAM data input ); // OUTPUTs //========= output irq_gfx_o; // Graphic Controller interrupt output [15:0] gpu_data_o; // GPU data output gpu_data_avail_o; // GPU data available output gpu_enable_o; // GPU enable output lt24_reset_n_o; // LT24 Reset (Active Low) output lt24_on_o; // LT24 on/off output [2:0] lt24_cfg_clk_o; // LT24 Interface clock configuration output [11:0] lt24_cfg_refr_o; // LT24 Interface refresh configuration output lt24_cfg_refr_sync_en_o; // LT24 Interface refresh sync configuration output [9:0] lt24_cfg_refr_sync_val_o; // LT24 Interface refresh sync value configuration output lt24_cmd_refr_o; // LT24 Interface refresh command output [7:0] lt24_cmd_val_o; // LT24 Generic command value output lt24_cmd_has_param_o; // LT24 Generic command has parameters output [15:0] lt24_cmd_param_o; // LT24 Generic command parameter value output lt24_cmd_param_rdy_o; // LT24 Generic command trigger output [15:0] lt24_cmd_dfill_o; // LT24 Data fill value output lt24_cmd_dfill_wr_o; // LT24 Data fill trigger output [`LPIX_MSB:0] display_width_o; // Display width output [`LPIX_MSB:0] display_height_o; // Display height output [`SPIX_MSB:0] display_size_o; // Display size (number of pixels) output display_y_swap_o; // Display configuration: swap Y axis (horizontal symmetry) output display_x_swap_o; // Display configuration: swap X axis (vertical symmetry) output display_cl_swap_o; // Display configuration: swap column/lines output [2:0] gfx_mode_o; // Video mode (1xx:16bpp / 011:8bpp / 010:4bpp / 001:2bpp / 000:1bpp) output [15:0] per_dout_o; // Peripheral data output output [`APIX_MSB:0] refresh_frame_addr_o; // Refresh frame base address output [1:0] refresh_lut_select_o; // Refresh LUT bank selection `ifdef WITH_PROGRAMMABLE_LUT output [`LRAM_MSB:0] lut_ram_addr_o; // LUT-RAM address output [15:0] lut_ram_din_o; // LUT-RAM data output lut_ram_wen_o; // LUT-RAM write strobe (active low) output lut_ram_cen_o; // LUT-RAM chip enable (active low) `endif output [`VRAM_MSB:0] vid_ram_addr_o; // Video-RAM address output [15:0] vid_ram_din_o; // Video-RAM data output vid_ram_wen_o; // Video-RAM write strobe (active low) output vid_ram_cen_o; // Video-RAM chip enable (active low) // INPUTs //========= input dbg_freeze_i; // Freeze address auto-incr on read input gpu_cmd_done_evt_i; // GPU command done event input gpu_cmd_error_evt_i; // GPU command error event input gpu_get_data_i; // GPU get next data input [4:0] lt24_status_i; // LT24 FSM Status input lt24_start_evt_i; // LT24 FSM is starting input lt24_done_evt_i; // LT24 FSM is done input mclk; // Main system clock input [13:0] per_addr_i; // Peripheral address input [15:0] per_din_i; // Peripheral data input input per_en_i; // Peripheral enable (high active) input [1:0] per_we_i; // Peripheral write enable (high active) input puc_rst; // Main system reset `ifdef WITH_PROGRAMMABLE_LUT input [15:0] lut_ram_dout_i; // LUT-RAM data input `endif input [15:0] vid_ram_dout_i; // Video-RAM data input //============================================================================= // 1) PARAMETER DECLARATION //============================================================================= // Register base address (must be aligned to decoder bit width) parameter [14:0] BASE_ADDR = 15'h0200; // Decoder bit width (defines how many bits are considered for address decoding) parameter DEC_WD = 7; // Register addresses offset parameter [DEC_WD-1:0] GFX_CTRL = 'h00, // General control/status/irq GFX_STATUS = 'h08, GFX_IRQ = 'h0A, DISPLAY_WIDTH = 'h10, // Display configuration DISPLAY_HEIGHT = 'h12, DISPLAY_SIZE_HI = 'h14, DISPLAY_SIZE_LO = 'h16, DISPLAY_CFG = 'h18, LT24_CFG = 'h20, // LT24 configuration and Generic command sending LT24_REFRESH = 'h22, LT24_REFRESH_SYNC = 'h24, LT24_CMD = 'h26, LT24_CMD_PARAM = 'h28, LT24_CMD_DFILL = 'h2A, LT24_STATUS = 'h2C, LUT_RAM_ADDR = 'h30, // LUT Memory Access Gate LUT_RAM_DATA = 'h32, FRAME_SELECT = 'h3E, // Frame pointers and selection FRAME0_PTR_HI = 'h40, FRAME0_PTR_LO = 'h42, FRAME1_PTR_HI = 'h44, FRAME1_PTR_LO = 'h46, FRAME2_PTR_HI = 'h48, FRAME2_PTR_LO = 'h4A, FRAME3_PTR_HI = 'h4C, FRAME3_PTR_LO = 'h4E, VID_RAM0_CFG = 'h50, // First Video Memory Access Gate VID_RAM0_WIDTH = 'h52, VID_RAM0_ADDR_HI = 'h54, VID_RAM0_ADDR_LO = 'h56, VID_RAM0_DATA = 'h58, VID_RAM1_CFG = 'h60, // Second Video Memory Access Gate VID_RAM1_WIDTH = 'h62, VID_RAM1_ADDR_HI = 'h64, VID_RAM1_ADDR_LO = 'h66, VID_RAM1_DATA = 'h68, GPU_CMD = 'h70, // Graphic Processing Unit GPU_STAT = 'h72; // Register one-hot decoder utilities parameter DEC_SZ = (1 << DEC_WD); parameter [DEC_SZ-1:0] BASE_REG = {{DEC_SZ-1{1'b0}}, 1'b1}; // Register one-hot decoder parameter [DEC_SZ-1:0] GFX_CTRL_D = (BASE_REG << GFX_CTRL ), GFX_STATUS_D = (BASE_REG << GFX_STATUS ), GFX_IRQ_D = (BASE_REG << GFX_IRQ ), DISPLAY_WIDTH_D = (BASE_REG << DISPLAY_WIDTH ), DISPLAY_HEIGHT_D = (BASE_REG << DISPLAY_HEIGHT ), DISPLAY_SIZE_HI_D = (BASE_REG << DISPLAY_SIZE_HI ), DISPLAY_SIZE_LO_D = (BASE_REG << DISPLAY_SIZE_LO ), DISPLAY_CFG_D = (BASE_REG << DISPLAY_CFG ), LT24_CFG_D = (BASE_REG << LT24_CFG ), LT24_REFRESH_D = (BASE_REG << LT24_REFRESH ), LT24_REFRESH_SYNC_D = (BASE_REG << LT24_REFRESH_SYNC ), LT24_CMD_D = (BASE_REG << LT24_CMD ), LT24_CMD_PARAM_D = (BASE_REG << LT24_CMD_PARAM ), LT24_CMD_DFILL_D = (BASE_REG << LT24_CMD_DFILL ), LT24_STATUS_D = (BASE_REG << LT24_STATUS ), LUT_RAM_ADDR_D = (BASE_REG << LUT_RAM_ADDR ), LUT_RAM_DATA_D = (BASE_REG << LUT_RAM_DATA ), FRAME_SELECT_D = (BASE_REG << FRAME_SELECT ), FRAME0_PTR_HI_D = (BASE_REG << FRAME0_PTR_HI ), FRAME0_PTR_LO_D = (BASE_REG << FRAME0_PTR_LO ), FRAME1_PTR_HI_D = (BASE_REG << FRAME1_PTR_HI ), FRAME1_PTR_LO_D = (BASE_REG << FRAME1_PTR_LO ), FRAME2_PTR_HI_D = (BASE_REG << FRAME2_PTR_HI ), FRAME2_PTR_LO_D = (BASE_REG << FRAME2_PTR_LO ), FRAME3_PTR_HI_D = (BASE_REG << FRAME3_PTR_HI ), FRAME3_PTR_LO_D = (BASE_REG << FRAME3_PTR_LO ), VID_RAM0_CFG_D = (BASE_REG << VID_RAM0_CFG ), VID_RAM0_WIDTH_D = (BASE_REG << VID_RAM0_WIDTH ), VID_RAM0_ADDR_HI_D = (BASE_REG << VID_RAM0_ADDR_HI ), VID_RAM0_ADDR_LO_D = (BASE_REG << VID_RAM0_ADDR_LO ), VID_RAM0_DATA_D = (BASE_REG << VID_RAM0_DATA ), VID_RAM1_CFG_D = (BASE_REG << VID_RAM1_CFG ), VID_RAM1_WIDTH_D = (BASE_REG << VID_RAM1_WIDTH ), VID_RAM1_ADDR_HI_D = (BASE_REG << VID_RAM1_ADDR_HI ), VID_RAM1_ADDR_LO_D = (BASE_REG << VID_RAM1_ADDR_LO ), VID_RAM1_DATA_D = (BASE_REG << VID_RAM1_DATA ), GPU_CMD_D = (BASE_REG << GPU_CMD ), GPU_STAT_D = (BASE_REG << GPU_STAT ); //============================================================================ // 2) REGISTER DECODER //============================================================================ // Local register selection wire reg_sel = per_en_i & (per_addr_i[13:DEC_WD-1]==BASE_ADDR[14:DEC_WD]); // Register local address wire [DEC_WD-1:0] reg_addr = {per_addr_i[DEC_WD-2:0], 1'b0}; // Register address decode wire [DEC_SZ-1:0] reg_dec = (GFX_CTRL_D & {DEC_SZ{(reg_addr == GFX_CTRL )}}) | (GFX_STATUS_D & {DEC_SZ{(reg_addr == GFX_STATUS )}}) | (GFX_IRQ_D & {DEC_SZ{(reg_addr == GFX_IRQ )}}) | (DISPLAY_WIDTH_D & {DEC_SZ{(reg_addr == DISPLAY_WIDTH )}}) | (DISPLAY_HEIGHT_D & {DEC_SZ{(reg_addr == DISPLAY_HEIGHT )}}) | (DISPLAY_SIZE_HI_D & {DEC_SZ{(reg_addr == DISPLAY_SIZE_HI )}}) | (DISPLAY_SIZE_LO_D & {DEC_SZ{(reg_addr == DISPLAY_SIZE_LO )}}) | (DISPLAY_CFG_D & {DEC_SZ{(reg_addr == DISPLAY_CFG )}}) | (LT24_CFG_D & {DEC_SZ{(reg_addr == LT24_CFG )}}) | (LT24_REFRESH_D & {DEC_SZ{(reg_addr == LT24_REFRESH )}}) | (LT24_REFRESH_SYNC_D & {DEC_SZ{(reg_addr == LT24_REFRESH_SYNC )}}) | (LT24_CMD_D & {DEC_SZ{(reg_addr == LT24_CMD )}}) | (LT24_CMD_PARAM_D & {DEC_SZ{(reg_addr == LT24_CMD_PARAM )}}) | (LT24_CMD_DFILL_D & {DEC_SZ{(reg_addr == LT24_CMD_DFILL )}}) | (LT24_STATUS_D & {DEC_SZ{(reg_addr == LT24_STATUS )}}) | (LUT_RAM_ADDR_D & {DEC_SZ{(reg_addr == LUT_RAM_ADDR )}}) | (LUT_RAM_DATA_D & {DEC_SZ{(reg_addr == LUT_RAM_DATA )}}) | (FRAME_SELECT_D & {DEC_SZ{(reg_addr == FRAME_SELECT )}}) | (FRAME0_PTR_HI_D & {DEC_SZ{(reg_addr == FRAME0_PTR_HI )}}) | (FRAME0_PTR_LO_D & {DEC_SZ{(reg_addr == FRAME0_PTR_LO )}}) | (FRAME1_PTR_HI_D & {DEC_SZ{(reg_addr == FRAME1_PTR_HI )}}) | (FRAME1_PTR_LO_D & {DEC_SZ{(reg_addr == FRAME1_PTR_LO )}}) | (FRAME2_PTR_HI_D & {DEC_SZ{(reg_addr == FRAME2_PTR_HI )}}) | (FRAME2_PTR_LO_D & {DEC_SZ{(reg_addr == FRAME2_PTR_LO )}}) | (FRAME3_PTR_HI_D & {DEC_SZ{(reg_addr == FRAME3_PTR_HI )}}) | (FRAME3_PTR_LO_D & {DEC_SZ{(reg_addr == FRAME3_PTR_LO )}}) | (VID_RAM0_CFG_D & {DEC_SZ{(reg_addr == VID_RAM0_CFG )}}) | (VID_RAM0_WIDTH_D & {DEC_SZ{(reg_addr == VID_RAM0_WIDTH )}}) | (VID_RAM0_ADDR_HI_D & {DEC_SZ{(reg_addr == VID_RAM0_ADDR_HI )}}) | (VID_RAM0_ADDR_LO_D & {DEC_SZ{(reg_addr == VID_RAM0_ADDR_LO )}}) | (VID_RAM0_DATA_D & {DEC_SZ{(reg_addr == VID_RAM0_DATA )}}) | (VID_RAM1_CFG_D & {DEC_SZ{(reg_addr == VID_RAM1_CFG )}}) | (VID_RAM1_WIDTH_D & {DEC_SZ{(reg_addr == VID_RAM1_WIDTH )}}) | (VID_RAM1_ADDR_HI_D & {DEC_SZ{(reg_addr == VID_RAM1_ADDR_HI )}}) | (VID_RAM1_ADDR_LO_D & {DEC_SZ{(reg_addr == VID_RAM1_ADDR_LO )}}) | (VID_RAM1_DATA_D & {DEC_SZ{(reg_addr == VID_RAM1_DATA )}}) | (GPU_CMD_D & {DEC_SZ{(reg_addr == GPU_CMD )}}) | (GPU_STAT_D & {DEC_SZ{(reg_addr == GPU_STAT )}}); // Read/Write probes wire reg_write = |per_we_i & reg_sel; wire reg_read = ~|per_we_i & reg_sel; // Read/Write vectors wire [DEC_SZ-1:0] reg_wr = reg_dec & {DEC_SZ{reg_write}}; wire [DEC_SZ-1:0] reg_rd = reg_dec & {DEC_SZ{reg_read}}; // Other wire declarations wire [`APIX_MSB:0] frame0_ptr; `ifdef WITH_FRAME1_POINTER wire [`APIX_MSB:0] frame1_ptr; `endif `ifdef WITH_FRAME2_POINTER wire [`APIX_MSB:0] frame2_ptr; `endif `ifdef WITH_FRAME3_POINTER wire [`APIX_MSB:0] frame3_ptr; `endif wire [`APIX_MSB:0] vid_ram0_base_addr; wire [`APIX_MSB:0] vid_ram1_base_addr; `ifdef WITH_EXTRA_LUT_BANK reg lut_bank_select; `endif reg vid_ram0_addr_lo_wr_dly; reg vid_ram1_addr_lo_wr_dly; wire gpu_fifo_done_evt; wire gpu_fifo_ovfl_evt; //============================================================================ // 3) REGISTERS //============================================================================ //------------------------------------------------ // GFX_CTRL Register //------------------------------------------------ reg [15:0] gfx_ctrl; wire gfx_ctrl_wr = reg_wr[GFX_CTRL]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) gfx_ctrl <= 16'h0000; else if (gfx_ctrl_wr) gfx_ctrl <= per_din_i; // Bitfield assignments wire gfx_irq_refr_done_en = gfx_ctrl[0]; wire gfx_irq_refr_start_en = gfx_ctrl[1]; wire gfx_irq_gpu_fifo_done_en = gfx_ctrl[4]; wire gfx_irq_gpu_fifo_ovfl_en = gfx_ctrl[5]; wire gfx_irq_gpu_cmd_done_en = gfx_ctrl[6]; wire gfx_irq_gpu_cmd_error_en = gfx_ctrl[7]; assign gfx_mode_o = gfx_ctrl[10:8]; // 1xx: 16 bits-per-pixel // 011: 8 bits-per-pixel // 010: 4 bits-per-pixel // 001: 2 bits-per-pixel // 000: 1 bits-per-pixel wire gpu_enable_o = gfx_ctrl[12]; // Video modes decoding wire gfx_mode_1_bpp = (gfx_mode_o == 3'b000); wire gfx_mode_2_bpp = (gfx_mode_o == 3'b001); wire gfx_mode_4_bpp = (gfx_mode_o == 3'b010); wire gfx_mode_8_bpp = (gfx_mode_o == 3'b011); wire gfx_mode_16_bpp = ~(gfx_mode_8_bpp | gfx_mode_4_bpp | gfx_mode_2_bpp | gfx_mode_1_bpp); //------------------------------------------------ // GFX_STATUS Register //------------------------------------------------ wire [15:0] gfx_status; assign gfx_status[0] = lt24_status_i[2]; // Screen Refresh is busy assign gfx_status[15:1] = 15'h0000; //------------------------------------------------ // GFX_IRQ Register //------------------------------------------------ wire [15:0] gfx_irq; // Clear IRQ when 1 is written. Set IRQ when FSM is done wire gfx_irq_refr_done_clr = per_din_i[0] & reg_wr[GFX_IRQ]; wire gfx_irq_refr_done_set = lt24_done_evt_i; wire gfx_irq_refr_start_clr = per_din_i[1] & reg_wr[GFX_IRQ]; wire gfx_irq_refr_start_set = lt24_start_evt_i; wire gfx_irq_gpu_fifo_done_clr = per_din_i[4] & reg_wr[GFX_IRQ]; wire gfx_irq_gpu_fifo_done_set = gpu_fifo_done_evt; wire gfx_irq_gpu_fifo_ovfl_clr = per_din_i[5] & reg_wr[GFX_IRQ]; wire gfx_irq_gpu_fifo_ovfl_set = gpu_fifo_ovfl_evt; wire gfx_irq_gpu_cmd_done_clr = per_din_i[6] & reg_wr[GFX_IRQ]; wire gfx_irq_gpu_cmd_done_set = gpu_cmd_done_evt_i; wire gfx_irq_gpu_cmd_error_clr = per_din_i[7] & reg_wr[GFX_IRQ]; wire gfx_irq_gpu_cmd_error_set = gpu_cmd_error_evt_i; reg gfx_irq_refr_done; reg gfx_irq_refr_start; reg gfx_irq_gpu_fifo_done; reg gfx_irq_gpu_fifo_ovfl; reg gfx_irq_gpu_cmd_done; reg gfx_irq_gpu_cmd_error; always @ (posedge mclk or posedge puc_rst) if (puc_rst) begin gfx_irq_refr_done <= 1'b0; gfx_irq_refr_start <= 1'b0; gfx_irq_gpu_fifo_done <= 1'b0; gfx_irq_gpu_fifo_ovfl <= 1'b0; gfx_irq_gpu_cmd_done <= 1'b0; gfx_irq_gpu_cmd_error <= 1'b0; end else begin gfx_irq_refr_done <= (gfx_irq_refr_done_set | (~gfx_irq_refr_done_clr & gfx_irq_refr_done )); // IRQ set has priority over clear gfx_irq_refr_start <= (gfx_irq_refr_start_set | (~gfx_irq_refr_start_clr & gfx_irq_refr_start )); // IRQ set has priority over clear gfx_irq_gpu_fifo_done <= (gfx_irq_gpu_fifo_done_set | (~gfx_irq_gpu_fifo_done_clr & gfx_irq_gpu_fifo_done)); // IRQ set has priority over clear gfx_irq_gpu_fifo_ovfl <= (gfx_irq_gpu_fifo_ovfl_set | (~gfx_irq_gpu_fifo_ovfl_clr & gfx_irq_gpu_fifo_ovfl)); // IRQ set has priority over clear gfx_irq_gpu_cmd_done <= (gfx_irq_gpu_cmd_done_set | (~gfx_irq_gpu_cmd_done_clr & gfx_irq_gpu_cmd_done )); // IRQ set has priority over clear gfx_irq_gpu_cmd_error <= (gfx_irq_gpu_cmd_error_set | (~gfx_irq_gpu_cmd_error_clr & gfx_irq_gpu_cmd_error)); // IRQ set has priority over clear end assign gfx_irq = {8'h00, gfx_irq_gpu_cmd_error, gfx_irq_gpu_cmd_done, gfx_irq_gpu_fifo_ovfl, gfx_irq_gpu_fifo_done, 2'h0, gfx_irq_refr_start, gfx_irq_refr_done}; assign irq_gfx_o = (gfx_irq_refr_done & gfx_irq_refr_done_en) | (gfx_irq_refr_start & gfx_irq_refr_start_en) | (gfx_irq_gpu_cmd_error & gfx_irq_gpu_cmd_error_en) | (gfx_irq_gpu_cmd_done & gfx_irq_gpu_cmd_done_en) | (gfx_irq_gpu_fifo_ovfl & gfx_irq_gpu_fifo_ovfl_en) | (gfx_irq_gpu_fifo_done & gfx_irq_gpu_fifo_done_en); // Graphic Controller interrupt //------------------------------------------------ // DISPLAY_WIDTH Register //------------------------------------------------ reg [`LPIX_MSB:0] display_width_o; wire display_width_wr = reg_wr[DISPLAY_WIDTH]; wire [`LPIX_MSB:0] display_w_h_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) display_width_o <= {{`LPIX_MSB{1'b0}}, 1'b1}; else if (display_width_wr) display_width_o <= display_w_h_nxt; wire [16:0] display_width_tmp = {{16-`LPIX_MSB{1'b0}}, display_width_o}; wire [15:0] display_width_rd = display_width_tmp[15:0]; //------------------------------------------------ // DISPLAY_HEIGHT Register //------------------------------------------------ reg [`LPIX_MSB:0] display_height_o; wire display_height_wr = reg_wr[DISPLAY_HEIGHT]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) display_height_o <= {{`LPIX_MSB{1'b0}}, 1'b1}; else if (display_height_wr) display_height_o <= display_w_h_nxt; wire [16:0] display_height_tmp = {{16-`LPIX_MSB{1'b0}}, display_height_o}; wire [15:0] display_height_rd = display_height_tmp[15:0]; //------------------------------------------------ // DISPLAY_SIZE_HI Register //------------------------------------------------ `ifdef WITH_DISPLAY_SIZE_HI reg [`SPIX_HI_MSB:0] display_size_hi; wire display_size_hi_wr = reg_wr[DISPLAY_SIZE_HI]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) display_size_hi <= {`SPIX_HI_MSB+1{1'h0}}; else if (display_size_hi_wr) display_size_hi <= per_din_i[`SPIX_HI_MSB:0]; wire [16:0] display_size_hi_tmp = {{16-`SPIX_HI_MSB{1'h0}}, display_size_hi}; wire [15:0] display_size_hi_rd = display_size_hi_tmp[15:0]; `endif //------------------------------------------------ // DISPLAY_SIZE_LO Register //------------------------------------------------ reg [`SPIX_LO_MSB:0] display_size_lo; wire display_size_lo_wr = reg_wr[DISPLAY_SIZE_LO]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) display_size_lo <= {{`SPIX_LO_MSB{1'h0}}, 1'b1}; else if (display_size_lo_wr) display_size_lo <= per_din_i[`SPIX_LO_MSB:0]; wire [16:0] display_size_lo_tmp = {{16-`SPIX_LO_MSB{1'h0}}, display_size_lo}; wire [15:0] display_size_lo_rd = display_size_lo_tmp[15:0]; `ifdef WITH_DISPLAY_SIZE_HI assign display_size_o = {display_size_hi, display_size_lo}; `else assign display_size_o = display_size_lo; `endif //------------------------------------------------ // DISPLAY_CFG Register //------------------------------------------------ reg display_x_swap_o; reg display_y_swap_o; reg display_cl_swap_o; wire display_cfg_wr = reg_wr[DISPLAY_CFG]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) begin display_cl_swap_o <= 1'b0; display_y_swap_o <= 1'b0; display_x_swap_o <= 1'b0; end else if (display_cfg_wr) begin display_cl_swap_o <= per_din_i[0]; display_y_swap_o <= per_din_i[1]; display_x_swap_o <= per_din_i[2]; end wire [15:0] display_cfg = {13'h0000, display_x_swap_o, display_y_swap_o, display_cl_swap_o}; //------------------------------------------------ // LT24_CFG Register //------------------------------------------------ reg [15:0] lt24_cfg; wire lt24_cfg_wr = reg_wr[LT24_CFG]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) lt24_cfg <= 16'h0000; else if (lt24_cfg_wr) lt24_cfg <= per_din_i; // Bitfield assignments assign lt24_cfg_clk_o = lt24_cfg[6:4]; assign lt24_reset_n_o = ~lt24_cfg[1]; assign lt24_on_o = lt24_cfg[0]; //------------------------------------------------ // LT24_REFRESH Register //------------------------------------------------ reg lt24_cmd_refr_o; reg [11:0] lt24_cfg_refr_o; wire lt24_refresh_wr = reg_wr[LT24_REFRESH]; wire lt24_cmd_refr_clr = lt24_done_evt_i & lt24_status_i[2] & (lt24_cfg_refr_o==8'h00); // Auto-clear in manual refresh mode when done always @ (posedge mclk or posedge puc_rst) if (puc_rst) lt24_cmd_refr_o <= 1'h0; else if (lt24_refresh_wr) lt24_cmd_refr_o <= per_din_i[0]; else if (lt24_cmd_refr_clr) lt24_cmd_refr_o <= 1'h0; always @ (posedge mclk or posedge puc_rst) if (puc_rst) lt24_cfg_refr_o <= 12'h000; else if (lt24_refresh_wr) lt24_cfg_refr_o <= per_din_i[15:4]; wire [15:0] lt24_refresh = {lt24_cfg_refr_o, 3'h0, lt24_cmd_refr_o}; //------------------------------------------------ // LT24_REFRESH Register //------------------------------------------------ reg lt24_cfg_refr_sync_en_o; reg [9:0] lt24_cfg_refr_sync_val_o; wire lt24_refresh_sync_wr = reg_wr[LT24_REFRESH_SYNC]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) lt24_cfg_refr_sync_en_o <= 1'h0; else if (lt24_refresh_sync_wr) lt24_cfg_refr_sync_en_o <= per_din_i[15]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) lt24_cfg_refr_sync_val_o <= 10'h000; else if (lt24_refresh_sync_wr) lt24_cfg_refr_sync_val_o <= per_din_i[9:0]; wire [15:0] lt24_refresh_sync = {lt24_cfg_refr_sync_en_o, 5'h00, lt24_cfg_refr_sync_val_o}; //------------------------------------------------ // LT24_CMD Register //------------------------------------------------ reg [15:0] lt24_cmd; wire lt24_cmd_wr = reg_wr[LT24_CMD]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) lt24_cmd <= 16'h0000; else if (lt24_cmd_wr) lt24_cmd <= per_din_i; assign lt24_cmd_val_o = lt24_cmd[7:0]; assign lt24_cmd_has_param_o = lt24_cmd[8]; //------------------------------------------------ // LT24_CMD_PARAM Register //------------------------------------------------ reg [15:0] lt24_cmd_param_o; wire lt24_cmd_param_wr = reg_wr[LT24_CMD_PARAM]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) lt24_cmd_param_o <= 16'h0000; else if (lt24_cmd_param_wr) lt24_cmd_param_o <= per_din_i; reg lt24_cmd_param_rdy_o; always @ (posedge mclk or posedge puc_rst) if (puc_rst) lt24_cmd_param_rdy_o <= 1'b0; else lt24_cmd_param_rdy_o <= lt24_cmd_param_wr; //------------------------------------------------ // LT24_CMD_DFILL Register //------------------------------------------------ reg [15:0] lt24_cmd_dfill_o; assign lt24_cmd_dfill_wr_o = reg_wr[LT24_CMD_DFILL]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) lt24_cmd_dfill_o <= 16'h0000; else if (lt24_cmd_dfill_wr_o) lt24_cmd_dfill_o <= per_din_i; //------------------------------------------------ // LT24_STATUS Register //------------------------------------------------ wire [15:0] lt24_status; assign lt24_status[0] = lt24_status_i[0]; // FSM_BUSY assign lt24_status[1] = lt24_status_i[1]; // WAIT_PARAM assign lt24_status[2] = lt24_status_i[2]; // REFRESH_BUSY assign lt24_status[3] = lt24_status_i[3]; // WAIT_FOR_SCANLINE assign lt24_status[4] = lt24_status_i[4]; // DATA_FILL_BUSY assign lt24_status[15:5] = 11'h000; //------------------------------------------------ // LUT_RAM_ADDR Register //------------------------------------------------ `ifdef WITH_PROGRAMMABLE_LUT reg [7:0] lut_ram_addr; wire [7:0] lut_ram_addr_inc; wire lut_ram_addr_inc_wr; wire lut_ram_addr_wr = reg_wr[LUT_RAM_ADDR]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) lut_ram_addr <= 8'h00; else if (lut_ram_addr_wr) lut_ram_addr <= per_din_i[7:0]; else if (lut_ram_addr_inc_wr) lut_ram_addr <= lut_ram_addr_inc; assign lut_ram_addr_inc = lut_ram_addr + 8'h01; wire [15:0] lut_ram_addr_rd = {8'h00, lut_ram_addr}; `ifdef WITH_EXTRA_LUT_BANK assign lut_ram_addr_o = {lut_bank_select, lut_ram_addr}; `else assign lut_ram_addr_o = lut_ram_addr; `endif `else wire [15:0] lut_ram_addr_rd = 16'h0000; `endif //------------------------------------------------ // LUT_RAM_DATA Register //------------------------------------------------ `ifdef WITH_PROGRAMMABLE_LUT // Update the LUT_RAM_DATA register with regular register write access wire lut_ram_data_wr = reg_wr[LUT_RAM_DATA]; wire lut_ram_data_rd = reg_rd[LUT_RAM_DATA]; reg lut_ram_dout_rdy; // LUT-RAM data Register reg [15:0] lut_ram_data; always @ (posedge mclk or posedge puc_rst) if (puc_rst) lut_ram_data <= 16'h0000; else if (lut_ram_data_wr) lut_ram_data <= per_din_i; else if (lut_ram_dout_rdy) lut_ram_data <= lut_ram_dout_i; // Increment the address after a write or read access to the LUT_RAM_DATA register assign lut_ram_addr_inc_wr = lut_ram_data_wr | lut_ram_data_rd; // Apply peripheral data bus % write strobe during VID_RAMx_DATA write access assign lut_ram_din_o = per_din_i & {16{lut_ram_data_wr}}; assign lut_ram_wen_o = ~(|per_we_i & lut_ram_data_wr); // Trigger a LUT-RAM read access immediately after: // - a LUT-RAM_ADDR register write access // - a LUT-RAM_DATA register read access reg lut_ram_addr_wr_dly; always @ (posedge mclk or posedge puc_rst) if (puc_rst) lut_ram_addr_wr_dly <= 1'b0; else lut_ram_addr_wr_dly <= lut_ram_addr_wr; reg lut_ram_data_rd_dly; always @ (posedge mclk or posedge puc_rst) if (puc_rst) lut_ram_data_rd_dly <= 1'b0; else lut_ram_data_rd_dly <= lut_ram_data_rd; // 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 register write assign lut_ram_cen_o = ~(lut_ram_addr_wr_dly | lut_ram_data_rd_dly | // Read access lut_ram_data_wr); // Write access // Update the VRAM_DATA register one cycle after each memory access always @ (posedge mclk or posedge puc_rst) if (puc_rst) lut_ram_dout_rdy <= 1'b0; else lut_ram_dout_rdy <= ~lut_ram_cen_o; `else wire [15:0] lut_ram_data = 16'h0000; `endif //------------------------------------------------ // FRAME_SELECT Register //------------------------------------------------ wire frame_select_wr = reg_wr[FRAME_SELECT]; `ifdef WITH_PROGRAMMABLE_LUT reg refresh_sw_lut_enable; always @ (posedge mclk or posedge puc_rst) if (puc_rst) refresh_sw_lut_enable <= 1'b0; else if (frame_select_wr) refresh_sw_lut_enable <= per_din_i[2]; `else wire refresh_sw_lut_enable = 1'b0; `endif `ifdef WITH_EXTRA_LUT_BANK reg refresh_sw_lut_select; always @ (posedge mclk or posedge puc_rst) if (puc_rst) begin refresh_sw_lut_select <= 1'b0; lut_bank_select <= 1'b0; end else if (frame_select_wr) begin refresh_sw_lut_select <= per_din_i[3]; lut_bank_select <= per_din_i[15]; end `else assign refresh_sw_lut_select = 1'b0; wire lut_bank_select = 1'b0; `endif wire [1:0] refresh_lut_select_o = {refresh_sw_lut_select, refresh_sw_lut_enable}; `ifdef WITH_FRAME1_POINTER `ifdef WITH_FRAME2_POINTER reg [1:0] refresh_frame_select; reg [1:0] vid_ram0_frame_select; reg [1:0] vid_ram1_frame_select; always @ (posedge mclk or posedge puc_rst) if (puc_rst) begin refresh_frame_select <= 2'h0; vid_ram0_frame_select <= 2'h0; vid_ram1_frame_select <= 2'h0; end else if (frame_select_wr) begin refresh_frame_select <= per_din_i[1:0]; vid_ram0_frame_select <= per_din_i[5:4]; vid_ram1_frame_select <= per_din_i[7:6]; end wire [15:0] frame_select = {lut_bank_select, 7'h00, vid_ram1_frame_select, vid_ram0_frame_select, refresh_lut_select_o, refresh_frame_select}; `else reg refresh_frame_select; reg vid_ram0_frame_select; reg vid_ram1_frame_select; always @ (posedge mclk or posedge puc_rst) if (puc_rst) begin refresh_frame_select <= 1'h0; vid_ram0_frame_select <= 1'h0; vid_ram1_frame_select <= 1'h0; end else if (frame_select_wr) begin refresh_frame_select <= per_din_i[0]; vid_ram0_frame_select <= per_din_i[4]; vid_ram1_frame_select <= per_din_i[6]; end wire [15:0] frame_select = {lut_bank_select, 7'h00, 1'h0, vid_ram1_frame_select, 1'h0, vid_ram0_frame_select, refresh_lut_select_o, 1'h0, refresh_frame_select}; `endif `else wire [15:0] frame_select = {lut_bank_select, 11'h000, refresh_lut_select_o, 2'h0}; `endif // Frame pointer selections `ifdef WITH_FRAME1_POINTER assign refresh_frame_addr_o = (refresh_frame_select==0) ? frame0_ptr : `ifdef WITH_FRAME2_POINTER (refresh_frame_select==1) ? frame1_ptr : `ifdef WITH_FRAME3_POINTER (refresh_frame_select==2) ? frame2_ptr : frame3_ptr ; `else frame2_ptr ; `endif `else frame1_ptr ; `endif assign vid_ram0_base_addr = (vid_ram0_frame_select==0) ? frame0_ptr : `ifdef WITH_FRAME2_POINTER (vid_ram0_frame_select==1) ? frame1_ptr : `ifdef WITH_FRAME3_POINTER (vid_ram0_frame_select==2) ? frame2_ptr : frame3_ptr ; `else frame2_ptr ; `endif `else frame1_ptr ; `endif assign vid_ram1_base_addr = (vid_ram1_frame_select==0) ? frame0_ptr : `ifdef WITH_FRAME2_POINTER (vid_ram1_frame_select==1) ? frame1_ptr : `ifdef WITH_FRAME3_POINTER (vid_ram1_frame_select==2) ? frame2_ptr : frame3_ptr ; `else frame2_ptr ; `endif `else frame1_ptr ; `endif `else assign refresh_frame_addr_o = frame0_ptr; assign vid_ram0_base_addr = frame0_ptr; assign vid_ram1_base_addr = frame0_ptr; `endif //------------------------------------------------ // FRAME0_PTR_HI Register //------------------------------------------------ `ifdef VRAM_BIGGER_4_KW reg [`APIX_HI_MSB:0] frame0_ptr_hi; wire frame0_ptr_hi_wr = reg_wr[FRAME0_PTR_HI]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) frame0_ptr_hi <= {`APIX_HI_MSB+1{1'b0}}; else if (frame0_ptr_hi_wr) frame0_ptr_hi <= per_din_i[`APIX_HI_MSB:0]; wire [16:0] frame0_ptr_hi_tmp = {{16-`APIX_HI_MSB{1'b0}}, frame0_ptr_hi}; wire [15:0] frame0_ptr_hi_rd = frame0_ptr_hi_tmp[15:0]; `endif //------------------------------------------------ // FRAME0_PTR_LO Register //------------------------------------------------ reg [`APIX_LO_MSB:0] frame0_ptr_lo; wire frame0_ptr_lo_wr = reg_wr[FRAME0_PTR_LO]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) frame0_ptr_lo <= {`APIX_LO_MSB+1{1'b0}}; else if (frame0_ptr_lo_wr) frame0_ptr_lo <= per_din_i[`APIX_LO_MSB:0]; `ifdef VRAM_BIGGER_4_KW assign frame0_ptr = {frame0_ptr_hi[`APIX_HI_MSB:0], frame0_ptr_lo}; wire [15:0] frame0_ptr_lo_rd = frame0_ptr_lo; `else assign frame0_ptr = {frame0_ptr_lo[`APIX_LO_MSB:0]}; wire [16:0] frame0_ptr_lo_tmp = {{16-`APIX_LO_MSB{1'b0}}, frame0_ptr_lo}; wire [15:0] frame0_ptr_lo_rd = frame0_ptr_lo_tmp[15:0]; `endif //------------------------------------------------ // FRAME1_PTR_HI Register //------------------------------------------------ `ifdef WITH_FRAME1_POINTER `ifdef VRAM_BIGGER_4_KW reg [`APIX_HI_MSB:0] frame1_ptr_hi; wire frame1_ptr_hi_wr = reg_wr[FRAME1_PTR_HI]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) frame1_ptr_hi <= {`APIX_HI_MSB+1{1'b0}}; else if (frame1_ptr_hi_wr) frame1_ptr_hi <= per_din_i[`APIX_HI_MSB:0]; wire [16:0] frame1_ptr_hi_tmp = {{16-`APIX_HI_MSB{1'b0}}, frame1_ptr_hi}; wire [15:0] frame1_ptr_hi_rd = frame1_ptr_hi_tmp[15:0]; `endif `endif //------------------------------------------------ // FRAME1_PTR_LO Register //------------------------------------------------ `ifdef WITH_FRAME1_POINTER reg [`APIX_LO_MSB:0] frame1_ptr_lo; wire frame1_ptr_lo_wr = reg_wr[FRAME1_PTR_LO]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) frame1_ptr_lo <= {`APIX_LO_MSB+1{1'b0}}; else if (frame1_ptr_lo_wr) frame1_ptr_lo <= per_din_i[`APIX_LO_MSB:0]; `ifdef VRAM_BIGGER_4_KW assign frame1_ptr = {frame1_ptr_hi[`APIX_HI_MSB:0], frame1_ptr_lo}; wire [15:0] frame1_ptr_lo_rd = frame1_ptr_lo; `else assign frame1_ptr = {frame1_ptr_lo[`APIX_LO_MSB:0]}; wire [16:0] frame1_ptr_lo_tmp = {{16-`APIX_LO_MSB{1'b0}}, frame1_ptr_lo}; wire [15:0] frame1_ptr_lo_rd = frame1_ptr_lo_tmp[15:0]; `endif `endif //------------------------------------------------ // FRAME2_PTR_HI Register //------------------------------------------------ `ifdef WITH_FRAME2_POINTER `ifdef VRAM_BIGGER_4_KW reg [`APIX_HI_MSB:0] frame2_ptr_hi; wire frame2_ptr_hi_wr = reg_wr[FRAME2_PTR_HI]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) frame2_ptr_hi <= {`APIX_HI_MSB+1{1'b0}}; else if (frame2_ptr_hi_wr) frame2_ptr_hi <= per_din_i[`APIX_HI_MSB:0]; wire [16:0] frame2_ptr_hi_tmp = {{16-`APIX_HI_MSB{1'b0}}, frame2_ptr_hi}; wire [15:0] frame2_ptr_hi_rd = frame2_ptr_hi_tmp[15:0]; `endif `endif //------------------------------------------------ // FRAME2_PTR_LO Register //------------------------------------------------ `ifdef WITH_FRAME2_POINTER reg [`APIX_LO_MSB:0] frame2_ptr_lo; wire frame2_ptr_lo_wr = reg_wr[FRAME2_PTR_LO]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) frame2_ptr_lo <= {`APIX_LO_MSB+1{1'b0}}; else if (frame2_ptr_lo_wr) frame2_ptr_lo <= per_din_i[`APIX_LO_MSB:0]; `ifdef VRAM_BIGGER_4_KW assign frame2_ptr = {frame2_ptr_hi[`APIX_HI_MSB:0], frame2_ptr_lo}; wire [15:0] frame2_ptr_lo_rd = frame2_ptr_lo; `else assign frame2_ptr = {frame2_ptr_lo[`APIX_LO_MSB:0]}; wire [16:0] frame2_ptr_lo_tmp = {{16-`APIX_LO_MSB{1'b0}}, frame2_ptr_lo}; wire [15:0] frame2_ptr_lo_rd = frame2_ptr_lo_tmp[15:0]; `endif `endif //------------------------------------------------ // FRAME3_PTR_HI Register //------------------------------------------------ `ifdef WITH_FRAME3_POINTER `ifdef VRAM_BIGGER_4_KW reg [`APIX_HI_MSB:0] frame3_ptr_hi; wire frame3_ptr_hi_wr = reg_wr[FRAME3_PTR_HI]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) frame3_ptr_hi <= {`APIX_HI_MSB+1{1'b0}}; else if (frame3_ptr_hi_wr) frame3_ptr_hi <= per_din_i[`APIX_HI_MSB:0]; wire [16:0] frame3_ptr_hi_tmp = {{16-`APIX_HI_MSB{1'b0}},frame3_ptr_hi}; wire [15:0] frame3_ptr_hi_rd = frame3_ptr_hi_tmp[15:0]; `endif `endif //------------------------------------------------ // FRAME3_PTR_LO Register //------------------------------------------------ `ifdef WITH_FRAME3_POINTER reg [`APIX_LO_MSB:0] frame3_ptr_lo; wire frame3_ptr_lo_wr = reg_wr[FRAME3_PTR_LO]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) frame3_ptr_lo <= {`APIX_LO_MSB+1{1'b0}}; else if (frame3_ptr_lo_wr) frame3_ptr_lo <= per_din_i[`APIX_LO_MSB:0]; `ifdef VRAM_BIGGER_4_KW assign frame3_ptr = {frame3_ptr_hi[`APIX_HI_MSB:0], frame3_ptr_lo}; wire [15:0] frame3_ptr_lo_rd = frame3_ptr_lo; `else assign frame3_ptr = {frame3_ptr_lo[`APIX_LO_MSB:0]}; wire [16:0] frame3_ptr_lo_tmp = {{16-`APIX_LO_MSB{1'b0}}, frame3_ptr_lo}; wire [15:0] frame3_ptr_lo_rd = frame3_ptr_lo_tmp[15:0]; `endif `endif //------------------------------------------------ // VID_RAM0 Interface //------------------------------------------------ wire [15:0] vid_ram0_cfg; wire [15:0] vid_ram0_width; `ifdef VRAM_BIGGER_4_KW wire [15:0] vid_ram0_addr_hi; `endif wire [15:0] vid_ram0_addr_lo; wire [15:0] vid_ram0_data; wire vid_ram0_we; wire vid_ram0_ce; wire [15:0] vid_ram0_din; wire [`APIX_MSB:0] vid_ram0_addr_nxt; wire vid_ram0_access; ogfx_reg_vram_if ogfx_reg_vram0_if_inst ( // OUTPUTs .vid_ram_cfg_o ( vid_ram0_cfg ), // VID_RAM0_CFG Register .vid_ram_width_o ( vid_ram0_width ), // VID_RAM0_WIDTH Register `ifdef VRAM_BIGGER_4_KW .vid_ram_addr_hi_o ( vid_ram0_addr_hi ), // VID_RAM0_ADDR_HI Register `endif .vid_ram_addr_lo_o ( vid_ram0_addr_lo ), // VID_RAM0_ADDR_LO Register .vid_ram_data_o ( vid_ram0_data ), // VID_RAM0_DATA Register .vid_ram_we_o ( vid_ram0_we ), // Video-RAM Write strobe .vid_ram_ce_o ( vid_ram0_ce ), // Video-RAM Chip enable .vid_ram_din_o ( vid_ram0_din ), // Video-RAM Data input .vid_ram_addr_nxt_o ( vid_ram0_addr_nxt ), // Video-RAM Next address .vid_ram_access_o ( vid_ram0_access ), // Video-RAM Access // INPUTs .mclk ( mclk ), // Main system clock .puc_rst ( puc_rst ), // Main system reset .vid_ram_cfg_wr_i ( reg_wr[VID_RAM0_CFG] ), // VID_RAM0_CFG Write strobe .vid_ram_width_wr_i ( reg_wr[VID_RAM0_WIDTH] ), // VID_RAM0_WIDTH Write strobe `ifdef VRAM_BIGGER_4_KW .vid_ram_addr_hi_wr_i ( reg_wr[VID_RAM0_ADDR_HI] ), // VID_RAM0_ADDR_HI Write strobe `endif .vid_ram_addr_lo_wr_i ( reg_wr[VID_RAM0_ADDR_LO] ), // VID_RAM0_ADDR_LO Write strobe .vid_ram_data_wr_i ( reg_wr[VID_RAM0_DATA] ), // VID_RAM0_DATA Write strobe .vid_ram_data_rd_i ( reg_rd[VID_RAM0_DATA] ), // VID_RAM0_DATA Read strobe .dbg_freeze_i ( dbg_freeze_i ), // Freeze auto-increment on read when CPU stopped .display_width_i ( display_width_o ), // Display width .gfx_mode_1_bpp_i ( gfx_mode_1_bpp ), // Graphic mode 1 bpp resolution .gfx_mode_2_bpp_i ( gfx_mode_2_bpp ), // Graphic mode 2 bpp resolution .gfx_mode_4_bpp_i ( gfx_mode_4_bpp ), // Graphic mode 4 bpp resolution .gfx_mode_8_bpp_i ( gfx_mode_8_bpp ), // Graphic mode 8 bpp resolution .gfx_mode_16_bpp_i ( gfx_mode_16_bpp ), // Graphic mode 16 bpp resolution .per_din_i ( per_din_i ), // Peripheral data input .vid_ram_base_addr_i ( vid_ram0_base_addr ), // Video-RAM base address .vid_ram_dout_i ( vid_ram_dout_i ) // Video-RAM data input ); //------------------------------------------------ // VID_RAM1 Interface //------------------------------------------------ wire [15:0] vid_ram1_cfg; wire [15:0] vid_ram1_width; `ifdef VRAM_BIGGER_4_KW wire [15:0] vid_ram1_addr_hi; `endif wire [15:0] vid_ram1_addr_lo; wire [15:0] vid_ram1_data; wire vid_ram1_we; wire vid_ram1_ce; wire [15:0] vid_ram1_din; wire [`APIX_MSB:0] vid_ram1_addr_nxt; wire vid_ram1_access; ogfx_reg_vram_if ogfx_reg_vram1_if_inst ( // OUTPUTs .vid_ram_cfg_o ( vid_ram1_cfg ), // VID_RAM1_CFG Register .vid_ram_width_o ( vid_ram1_width ), // VID_RAM1_WIDTH Register `ifdef VRAM_BIGGER_4_KW .vid_ram_addr_hi_o ( vid_ram1_addr_hi ), // VID_RAM1_ADDR_HI Register `endif .vid_ram_addr_lo_o ( vid_ram1_addr_lo ), // VID_RAM1_ADDR_LO Register .vid_ram_data_o ( vid_ram1_data ), // VID_RAM1_DATA Register .vid_ram_we_o ( vid_ram1_we ), // Video-RAM Write strobe .vid_ram_ce_o ( vid_ram1_ce ), // Video-RAM Chip enable .vid_ram_din_o ( vid_ram1_din ), // Video-RAM Data input .vid_ram_addr_nxt_o ( vid_ram1_addr_nxt ), // Video-RAM Next address .vid_ram_access_o ( vid_ram1_access ), // Video-RAM Access // INPUTs .mclk ( mclk ), // Main system clock .puc_rst ( puc_rst ), // Main system reset .vid_ram_cfg_wr_i ( reg_wr[VID_RAM1_CFG] ), // VID_RAM1_CFG Write strobe .vid_ram_width_wr_i ( reg_wr[VID_RAM1_WIDTH] ), // VID_RAM1_WIDTH Write strobe `ifdef VRAM_BIGGER_4_KW .vid_ram_addr_hi_wr_i ( reg_wr[VID_RAM1_ADDR_HI] ), // VID_RAM1_ADDR_HI Write strobe `endif .vid_ram_addr_lo_wr_i ( reg_wr[VID_RAM1_ADDR_LO] ), // VID_RAM1_ADDR_LO Write strobe .vid_ram_data_wr_i ( reg_wr[VID_RAM1_DATA] ), // VID_RAM1_DATA Write strobe .vid_ram_data_rd_i ( reg_rd[VID_RAM1_DATA] ), // VID_RAM1_DATA Read strobe .dbg_freeze_i ( dbg_freeze_i ), // Freeze auto-increment on read when CPU stopped .display_width_i ( display_width_o ), // Display width .gfx_mode_1_bpp_i ( gfx_mode_1_bpp ), // Graphic mode 1 bpp resolution .gfx_mode_2_bpp_i ( gfx_mode_2_bpp ), // Graphic mode 2 bpp resolution .gfx_mode_4_bpp_i ( gfx_mode_4_bpp ), // Graphic mode 4 bpp resolution .gfx_mode_8_bpp_i ( gfx_mode_8_bpp ), // Graphic mode 8 bpp resolution .gfx_mode_16_bpp_i ( gfx_mode_16_bpp ), // Graphic mode 16 bpp resolution .per_din_i ( per_din_i ), // Peripheral data input .vid_ram_base_addr_i ( vid_ram1_base_addr ), // Video-RAM base address .vid_ram_dout_i ( vid_ram_dout_i ) // Video-RAM data input ); //------------------------------------------------ // GPU Interface (GPU_CMD/GPU_STAT) Registers //------------------------------------------------ wire [3:0] gpu_stat_fifo_cnt; wire gpu_stat_fifo_empty; wire gpu_stat_fifo_full; ogfx_reg_fifo ogfx_reg_fifo_gpu_inst ( // OUTPUTs .fifo_cnt_o ( gpu_stat_fifo_cnt ), // Fifo counter .fifo_data_o ( gpu_data_o ), // Read data output .fifo_done_evt_o ( gpu_fifo_done_evt ), // Fifo has been emptied .fifo_empty_o ( gpu_stat_fifo_empty ), // Fifo is currentely empty .fifo_full_o ( gpu_stat_fifo_full ), // Fifo is currentely full .fifo_ovfl_evt_o ( gpu_fifo_ovfl_evt ), // Fifo overflow event // INPUTs .mclk ( mclk ), // Main system clock .puc_rst ( puc_rst ), // Main system reset .fifo_data_i ( per_din_i ), // Read data input .fifo_enable_i ( gpu_enable_o ), // Enable fifo (flushed when disabled) .fifo_pop_i ( gpu_get_data_i ), // Pop data from the fifo .fifo_push_i ( reg_wr[GPU_CMD] ) // Push new data to the fifo ); assign gpu_data_avail_o = ~gpu_stat_fifo_empty; wire [15:0] gpu_stat = {10'h000, gpu_stat_fifo_full, gpu_stat_fifo_empty, gpu_stat_fifo_cnt}; //============================================================================ // 4) DATA OUTPUT GENERATION //============================================================================ // Data output mux wire [15:0] gfx_ctrl_read = gfx_ctrl & {16{reg_rd[GFX_CTRL ]}}; wire [15:0] gfx_status_read = gfx_status & {16{reg_rd[GFX_STATUS ]}}; wire [15:0] gfx_irq_read = gfx_irq & {16{reg_rd[GFX_IRQ ]}}; wire [15:0] display_width_read = display_width_rd & {16{reg_rd[DISPLAY_WIDTH ]}}; wire [15:0] display_height_read = display_height_rd & {16{reg_rd[DISPLAY_HEIGHT ]}}; `ifdef WITH_DISPLAY_SIZE_HI wire [15:0] display_size_hi_read = display_size_hi_rd & {16{reg_rd[DISPLAY_SIZE_HI ]}}; `endif wire [15:0] display_size_lo_read = display_size_lo_rd & {16{reg_rd[DISPLAY_SIZE_LO ]}}; wire [15:0] display_cfg_read = display_cfg & {16{reg_rd[DISPLAY_CFG ]}}; wire [15:0] lt24_cfg_read = lt24_cfg & {16{reg_rd[LT24_CFG ]}}; wire [15:0] lt24_refresh_read = lt24_refresh & {16{reg_rd[LT24_REFRESH ]}}; wire [15:0] lt24_refresh_sync_read = lt24_refresh_sync & {16{reg_rd[LT24_REFRESH_SYNC ]}}; wire [15:0] lt24_cmd_read = lt24_cmd & {16{reg_rd[LT24_CMD ]}}; wire [15:0] lt24_cmd_param_read = lt24_cmd_param_o & {16{reg_rd[LT24_CMD_PARAM ]}}; wire [15:0] lt24_cmd_dfill_read = lt24_cmd_dfill_o & {16{reg_rd[LT24_CMD_DFILL ]}}; wire [15:0] lt24_status_read = lt24_status & {16{reg_rd[LT24_STATUS ]}}; wire [15:0] lut_ram_addr_read = lut_ram_addr_rd & {16{reg_rd[LUT_RAM_ADDR ]}}; wire [15:0] lut_ram_data_read = lut_ram_data & {16{reg_rd[LUT_RAM_DATA ]}}; wire [15:0] frame_select_read = frame_select & {16{reg_rd[FRAME_SELECT ]}}; `ifdef VRAM_BIGGER_4_KW wire [15:0] frame0_ptr_hi_read = frame0_ptr_hi_rd & {16{reg_rd[FRAME0_PTR_HI ]}}; `endif wire [15:0] frame0_ptr_lo_read = frame0_ptr_lo_rd & {16{reg_rd[FRAME0_PTR_LO ]}}; `ifdef WITH_FRAME1_POINTER `ifdef VRAM_BIGGER_4_KW wire [15:0] frame1_ptr_hi_read = frame1_ptr_hi_rd & {16{reg_rd[FRAME1_PTR_HI ]}}; `endif wire [15:0] frame1_ptr_lo_read = frame1_ptr_lo_rd & {16{reg_rd[FRAME1_PTR_LO ]}}; `endif `ifdef WITH_FRAME2_POINTER `ifdef VRAM_BIGGER_4_KW wire [15:0] frame2_ptr_hi_read = frame2_ptr_hi_rd & {16{reg_rd[FRAME2_PTR_HI ]}}; `endif wire [15:0] frame2_ptr_lo_read = frame2_ptr_lo_rd & {16{reg_rd[FRAME2_PTR_LO ]}}; `endif `ifdef WITH_FRAME3_POINTER `ifdef VRAM_BIGGER_4_KW wire [15:0] frame3_ptr_hi_read = frame3_ptr_hi_rd & {16{reg_rd[FRAME3_PTR_HI ]}}; `endif wire [15:0] frame3_ptr_lo_read = frame3_ptr_lo_rd & {16{reg_rd[FRAME3_PTR_LO ]}}; `endif wire [15:0] vid_ram0_cfg_read = vid_ram0_cfg & {16{reg_rd[VID_RAM0_CFG ]}}; wire [15:0] vid_ram0_width_read = vid_ram0_width & {16{reg_rd[VID_RAM0_WIDTH ]}}; `ifdef VRAM_BIGGER_4_KW wire [15:0] vid_ram0_addr_hi_read = vid_ram0_addr_hi & {16{reg_rd[VID_RAM0_ADDR_HI ]}}; `endif wire [15:0] vid_ram0_addr_lo_read = vid_ram0_addr_lo & {16{reg_rd[VID_RAM0_ADDR_LO ]}}; wire [15:0] vid_ram0_data_read = vid_ram0_data & {16{reg_rd[VID_RAM0_DATA ]}}; wire [15:0] vid_ram1_cfg_read = vid_ram1_cfg & {16{reg_rd[VID_RAM1_CFG ]}}; wire [15:0] vid_ram1_width_read = vid_ram1_width & {16{reg_rd[VID_RAM1_WIDTH ]}}; `ifdef VRAM_BIGGER_4_KW wire [15:0] vid_ram1_addr_hi_read = vid_ram1_addr_hi & {16{reg_rd[VID_RAM1_ADDR_HI ]}}; `endif wire [15:0] vid_ram1_addr_lo_read = vid_ram1_addr_lo & {16{reg_rd[VID_RAM1_ADDR_LO ]}}; wire [15:0] vid_ram1_data_read = vid_ram1_data & {16{reg_rd[VID_RAM1_DATA ]}}; wire [15:0] gpu_cmd_read = 16'h0000 & {16{reg_rd[GPU_CMD ]}}; wire [15:0] gpu_stat_read = gpu_stat & {16{reg_rd[GPU_STAT ]}}; wire [15:0] per_dout_o = gfx_ctrl_read | gfx_status_read | gfx_irq_read | display_width_read | display_height_read | `ifdef WITH_DISPLAY_SIZE_HI display_size_hi_read | `endif display_size_lo_read | display_cfg_read | lt24_cfg_read | lt24_refresh_read | lt24_refresh_sync_read | lt24_cmd_read | lt24_cmd_param_read | lt24_cmd_dfill_read | lt24_status_read | lut_ram_addr_read | lut_ram_data_read | frame_select_read | `ifdef VRAM_BIGGER_4_KW frame0_ptr_hi_read | `endif frame0_ptr_lo_read | `ifdef WITH_FRAME1_POINTER `ifdef VRAM_BIGGER_4_KW frame1_ptr_hi_read | `endif frame1_ptr_lo_read | `endif `ifdef WITH_FRAME2_POINTER `ifdef VRAM_BIGGER_4_KW frame2_ptr_hi_read | `endif frame2_ptr_lo_read | `endif `ifdef WITH_FRAME3_POINTER `ifdef VRAM_BIGGER_4_KW frame3_ptr_hi_read | `endif frame3_ptr_lo_read | `endif vid_ram0_cfg_read | vid_ram0_width_read | `ifdef VRAM_BIGGER_4_KW vid_ram0_addr_hi_read | `endif vid_ram0_addr_lo_read | vid_ram0_data_read | vid_ram1_cfg_read | vid_ram1_width_read | `ifdef VRAM_BIGGER_4_KW vid_ram1_addr_hi_read | `endif vid_ram1_addr_lo_read | vid_ram1_data_read | gpu_cmd_read | gpu_stat_read; //============================================================================ // 5) VIDEO MEMORY INTERFACE //============================================================================ // Write access strobe assign vid_ram_wen_o = ~(vid_ram0_we | vid_ram1_we); // Chip enable. assign vid_ram_cen_o = ~(vid_ram0_ce | vid_ram1_ce); // Data to be written assign vid_ram_din_o = (vid_ram0_din | vid_ram1_din); // Detect memory accesses for ADDR update wire vid_ram_access = (vid_ram0_access | vid_ram1_access); // Next Address wire [`APIX_MSB:0] vid_ram_addr_nxt = (vid_ram0_addr_nxt | vid_ram1_addr_nxt); // Align according to graphic mode wire [`VRAM_MSB:0] vid_ram_addr_align = ({`VRAM_AWIDTH{gfx_mode_1_bpp }} & vid_ram_addr_nxt[`APIX_MSB-0:4]) | ({`VRAM_AWIDTH{gfx_mode_2_bpp }} & vid_ram_addr_nxt[`APIX_MSB-1:3]) | ({`VRAM_AWIDTH{gfx_mode_4_bpp }} & vid_ram_addr_nxt[`APIX_MSB-2:2]) | ({`VRAM_AWIDTH{gfx_mode_8_bpp }} & vid_ram_addr_nxt[`APIX_MSB-3:1]) | ({`VRAM_AWIDTH{gfx_mode_16_bpp}} & vid_ram_addr_nxt[`APIX_MSB-4:0]) ; // Generate Video RAM address reg [`VRAM_MSB:0] vid_ram_addr_o; always @ (posedge mclk or posedge puc_rst) if (puc_rst) vid_ram_addr_o <= {`VRAM_AWIDTH{1'b0}}; else if (vid_ram_access) vid_ram_addr_o <= vid_ram_addr_align; endmodule // ogfx_reg `ifdef OGFX_NO_INCLUDE `else `include "openGFX430_undefines.v" `endif
Go to most recent revision | Compare with Previous | Blame | View Log