// *************************************************************************** // *************************************************************************** // Copyright 2011(c) Analog Devices, Inc. // // All rights reserved. // // Redistribution and use in source and binary forms, with or without modification, // are permitted provided that the following conditions are met: // - Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // - Redistributions in binary form must reproduce the above copyright // notice, this list of conditions and the following disclaimer in // the documentation and/or other materials provided with the // distribution. // - Neither the name of Analog Devices, Inc. nor the names of its // contributors may be used to endorse or promote products derived // from this software without specific prior written permission. // - The use of this software may or may not infringe the patent rights // of one or more patent holders. This license does not release you // from the requirement that you obtain separate licenses from these // patent holders to use this software. // - Use of the software either in source or binary form, must be run // on or directly connected to an Analog Devices Inc. component. // // THIS SOFTWARE IS PROVIDED BY ANALOG DEVICES "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, // INCLUDING, BUT NOT LIMITED TO, NON-INFRINGEMENT, MERCHANTABILITY AND FITNESS FOR A // PARTICULAR PURPOSE ARE DISCLAIMED. // // IN NO EVENT SHALL ANALOG DEVICES BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, // EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, INTELLECTUAL PROPERTY // RIGHTS, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR // BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, // STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF // THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // *************************************************************************** // *************************************************************************** `timescale 1ns/100ps module ad_gt_es ( lpm_dfe_n, // drp interface up_rstn, up_clk, up_es_drp_sel, up_es_drp_wr, up_es_drp_addr, up_es_drp_wdata, up_es_drp_rdata, up_es_drp_ready, // dma interface up_es_dma_req, up_es_dma_addr, up_es_dma_data, up_es_dma_ack, // processor interface up_es_start, up_es_stop, up_es_init, up_es_sdata0, up_es_sdata1, up_es_sdata2, up_es_sdata3, up_es_sdata4, up_es_qdata0, up_es_qdata1, up_es_qdata2, up_es_qdata3, up_es_qdata4, up_es_prescale, up_es_hoffset_min, up_es_hoffset_max, up_es_hoffset_step, up_es_voffset_min, up_es_voffset_max, up_es_voffset_step, up_es_voffset_range, up_es_start_addr, up_es_status); // parameters parameter integer GTH_GTX_N = 0; // gt address localparam [11:0] ES_DRP_CTRL_ADDR = (GTH_GTX_N == 1) ? 12'h03c : 12'h03d; // GTH-7 12'h03d localparam [11:0] ES_DRP_SDATA0_ADDR = (GTH_GTX_N == 1) ? 12'h049 : 12'h036; // GTH-7 12'h036 localparam [11:0] ES_DRP_SDATA1_ADDR = (GTH_GTX_N == 1) ? 12'h04a : 12'h037; // GTH-7 12'h037 localparam [11:0] ES_DRP_SDATA2_ADDR = (GTH_GTX_N == 1) ? 12'h04b : 12'h038; // GTH-7 12'h038 localparam [11:0] ES_DRP_SDATA3_ADDR = (GTH_GTX_N == 1) ? 12'h04c : 12'h039; // GTH-7 12'h039 localparam [11:0] ES_DRP_SDATA4_ADDR = (GTH_GTX_N == 1) ? 12'h04d : 12'h03a; // GTH-7 12'h03a localparam [11:0] ES_DRP_QDATA0_ADDR = (GTH_GTX_N == 1) ? 12'h044 : 12'h031; // GTH-7 12'h031 localparam [11:0] ES_DRP_QDATA1_ADDR = (GTH_GTX_N == 1) ? 12'h045 : 12'h032; // GTH-7 12'h032 localparam [11:0] ES_DRP_QDATA2_ADDR = (GTH_GTX_N == 1) ? 12'h046 : 12'h033; // GTH-7 12'h033 localparam [11:0] ES_DRP_QDATA3_ADDR = (GTH_GTX_N == 1) ? 12'h047 : 12'h034; // GTH-7 12'h034 localparam [11:0] ES_DRP_QDATA4_ADDR = (GTH_GTX_N == 1) ? 12'h048 : 12'h035; // GTH-7 12'h035 localparam [11:0] ES_DRP_HOFFSET_ADDR = (GTH_GTX_N == 1) ? 12'h04f : 12'h03c; // GTH-7 12'h03c localparam [11:0] ES_DRP_VOFFSET_ADDR = (GTH_GTX_N == 1) ? 12'h097 : 12'h03b; // GTH-7 12'h03b localparam [11:0] ES_DRP_STATUS_ADDR = (GTH_GTX_N == 1) ? 12'h153 : 12'h151; // GTH-7 12'h153 localparam [11:0] ES_DRP_SCNT_ADDR = (GTH_GTX_N == 1) ? 12'h152 : 12'h150; // GTH-7 12'h152 localparam [11:0] ES_DRP_ECNT_ADDR = (GTH_GTX_N == 1) ? 12'h151 : 12'h14f; // GTH-7 12'h151 // state machine localparam [ 5:0] ES_FSM_IDLE = 6'h00; localparam [ 5:0] ES_FSM_STATUS = 6'h01; localparam [ 5:0] ES_FSM_INIT = 6'h02; localparam [ 5:0] ES_FSM_CTRLINIT_READ = 6'h03; localparam [ 5:0] ES_FSM_CTRLINIT_RRDY = 6'h04; localparam [ 5:0] ES_FSM_CTRLINIT_WRITE = 6'h05; localparam [ 5:0] ES_FSM_CTRLINIT_WRDY = 6'h06; localparam [ 5:0] ES_FSM_SDATA0_WRITE = 6'h07; localparam [ 5:0] ES_FSM_SDATA0_WRDY = 6'h08; localparam [ 5:0] ES_FSM_SDATA1_WRITE = 6'h09; localparam [ 5:0] ES_FSM_SDATA1_WRDY = 6'h0a; localparam [ 5:0] ES_FSM_SDATA2_WRITE = 6'h0b; localparam [ 5:0] ES_FSM_SDATA2_WRDY = 6'h0c; localparam [ 5:0] ES_FSM_SDATA3_WRITE = 6'h0d; localparam [ 5:0] ES_FSM_SDATA3_WRDY = 6'h0e; localparam [ 5:0] ES_FSM_SDATA4_WRITE = 6'h0f; localparam [ 5:0] ES_FSM_SDATA4_WRDY = 6'h10; localparam [ 5:0] ES_FSM_QDATA0_WRITE = 6'h11; localparam [ 5:0] ES_FSM_QDATA0_WRDY = 6'h12; localparam [ 5:0] ES_FSM_QDATA1_WRITE = 6'h13; localparam [ 5:0] ES_FSM_QDATA1_WRDY = 6'h14; localparam [ 5:0] ES_FSM_QDATA2_WRITE = 6'h15; localparam [ 5:0] ES_FSM_QDATA2_WRDY = 6'h16; localparam [ 5:0] ES_FSM_QDATA3_WRITE = 6'h17; localparam [ 5:0] ES_FSM_QDATA3_WRDY = 6'h18; localparam [ 5:0] ES_FSM_QDATA4_WRITE = 6'h19; localparam [ 5:0] ES_FSM_QDATA4_WRDY = 6'h1a; localparam [ 5:0] ES_FSM_HOFFSET_READ = 6'h1b; localparam [ 5:0] ES_FSM_HOFFSET_RRDY = 6'h1c; localparam [ 5:0] ES_FSM_HOFFSET_WRITE = 6'h1d; localparam [ 5:0] ES_FSM_HOFFSET_WRDY = 6'h1e; localparam [ 5:0] ES_FSM_VOFFSET_READ = 6'h1f; localparam [ 5:0] ES_FSM_VOFFSET_RRDY = 6'h20; localparam [ 5:0] ES_FSM_VOFFSET_WRITE = 6'h21; localparam [ 5:0] ES_FSM_VOFFSET_WRDY = 6'h22; localparam [ 5:0] ES_FSM_CTRLSTART_READ = 6'h23; localparam [ 5:0] ES_FSM_CTRLSTART_RRDY = 6'h24; localparam [ 5:0] ES_FSM_CTRLSTART_WRITE = 6'h25; localparam [ 5:0] ES_FSM_CTRLSTART_WRDY = 6'h26; localparam [ 5:0] ES_FSM_STATUS_READ = 6'h27; localparam [ 5:0] ES_FSM_STATUS_RRDY = 6'h28; localparam [ 5:0] ES_FSM_CTRLSTOP_READ = 6'h29; localparam [ 5:0] ES_FSM_CTRLSTOP_RRDY = 6'h2a; localparam [ 5:0] ES_FSM_CTRLSTOP_WRITE = 6'h2b; localparam [ 5:0] ES_FSM_CTRLSTOP_WRDY = 6'h2c; localparam [ 5:0] ES_FSM_SCNT_READ = 6'h2d; localparam [ 5:0] ES_FSM_SCNT_RRDY = 6'h2e; localparam [ 5:0] ES_FSM_ECNT_READ = 6'h2f; localparam [ 5:0] ES_FSM_ECNT_RRDY = 6'h30; localparam [ 5:0] ES_FSM_DMA_WRITE = 6'h31; localparam [ 5:0] ES_FSM_DMA_READY = 6'h32; localparam [ 5:0] ES_FSM_UPDATE = 6'h33; input lpm_dfe_n; // drp interface input up_rstn; input up_clk; output up_es_drp_sel; output up_es_drp_wr; output [11:0] up_es_drp_addr; output [15:0] up_es_drp_wdata; input [15:0] up_es_drp_rdata; input up_es_drp_ready; // dma interface output up_es_dma_req; output [31:0] up_es_dma_addr; output [31:0] up_es_dma_data; input up_es_dma_ack; // processor interface input up_es_start; input up_es_stop; input up_es_init; input [15:0] up_es_sdata0; input [15:0] up_es_sdata1; input [15:0] up_es_sdata2; input [15:0] up_es_sdata3; input [15:0] up_es_sdata4; input [15:0] up_es_qdata0; input [15:0] up_es_qdata1; input [15:0] up_es_qdata2; input [15:0] up_es_qdata3; input [15:0] up_es_qdata4; input [ 4:0] up_es_prescale; input [11:0] up_es_hoffset_min; input [11:0] up_es_hoffset_max; input [11:0] up_es_hoffset_step; input [ 7:0] up_es_voffset_min; input [ 7:0] up_es_voffset_max; input [ 7:0] up_es_voffset_step; input [ 1:0] up_es_voffset_range; input [31:0] up_es_start_addr; output up_es_status; // internal registers reg up_es_dma_req = 'd0; reg [31:0] up_es_dma_addr = 'd0; reg [31:0] up_es_dma_data = 'd0; reg up_es_status = 'd0; reg up_es_ut = 'd0; reg [31:0] up_es_addr = 'd0; reg [11:0] up_es_hoffset = 'd0; reg [ 7:0] up_es_voffset = 'd0; reg [15:0] up_es_hoffset_rdata = 'd0; reg [15:0] up_es_voffset_rdata = 'd0; reg [15:0] up_es_ctrl_rdata = 'd0; reg [15:0] up_es_scnt_rdata = 'd0; reg [15:0] up_es_ecnt_rdata = 'd0; reg [ 5:0] up_es_fsm = 'd0; reg up_es_drp_sel = 'd0; reg up_es_drp_wr = 'd0; reg [11:0] up_es_drp_addr = 'd0; reg [15:0] up_es_drp_wdata = 'd0; // internal signals wire up_es_heos_s; wire up_es_eos_s; wire up_es_ut_s; wire [ 7:0] up_es_voffset_2_s; wire [ 7:0] up_es_voffset_n_s; wire [ 7:0] up_es_voffset_s; // dma interface always @(negedge up_rstn or posedge up_clk) begin if (up_rstn == 0) begin up_es_dma_req <= 'b0; up_es_dma_addr <= 'd0; up_es_dma_data <= 'd0; end else begin if ((up_es_dma_req == 1'b1) && (up_es_dma_ack == 1'b1)) begin up_es_dma_req <= 1'b0; up_es_dma_addr <= 32'd0; up_es_dma_data <= 32'd0; end else if (up_es_fsm == ES_FSM_DMA_WRITE) begin up_es_dma_req <= 1'b1; up_es_dma_addr <= up_es_addr; up_es_dma_data <= {up_es_scnt_rdata, up_es_ecnt_rdata}; end end end // prescale, horizontal and vertical offsets assign up_es_heos_s = (up_es_hoffset == up_es_hoffset_max) ? up_es_ut : 1'b0; assign up_es_eos_s = (up_es_voffset == up_es_voffset_max) ? up_es_heos_s : 1'b0; assign up_es_ut_s = up_es_ut & ~lpm_dfe_n; assign up_es_voffset_2_s = ~up_es_voffset + 1'b1; assign up_es_voffset_n_s = {1'b1, up_es_voffset_2_s[6:0]}; assign up_es_voffset_s = (up_es_voffset[7] == 1'b1) ? up_es_voffset_n_s : up_es_voffset; always @(negedge up_rstn or posedge up_clk) begin if (up_rstn == 1'b0) begin up_es_status <= 1'b0; up_es_ut <= 'd0; up_es_addr <= 'd0; up_es_hoffset <= 'd0; up_es_voffset <= 'd0; end else begin if (up_es_fsm == ES_FSM_IDLE) begin up_es_status <= 1'b0; end else begin up_es_status <= 1'b1; end if (up_es_fsm == ES_FSM_IDLE) begin up_es_ut <= lpm_dfe_n; up_es_addr <= up_es_start_addr; up_es_hoffset <= up_es_hoffset_min; up_es_voffset <= up_es_voffset_min; end else if (up_es_fsm == ES_FSM_UPDATE) begin up_es_ut <= ~up_es_ut | lpm_dfe_n; up_es_addr <= up_es_addr + 3'd4; if (up_es_heos_s == 1'b1) begin up_es_hoffset <= up_es_hoffset_min; end else if (up_es_ut == 1'b1) begin up_es_hoffset <= up_es_hoffset + up_es_hoffset_step; end if (up_es_heos_s == 1'b1) begin up_es_voffset <= up_es_voffset + up_es_voffset_step; end end end end // read-modify-write parameters (gt's are full of mixed up controls) always @(negedge up_rstn or posedge up_clk) begin if (up_rstn == 1'b0) begin up_es_hoffset_rdata <= 'd0; up_es_voffset_rdata <= 'd0; up_es_ctrl_rdata <= 'd0; up_es_scnt_rdata <= 'd0; up_es_ecnt_rdata <= 'd0; end else begin if ((up_es_fsm == ES_FSM_HOFFSET_RRDY) && (up_es_drp_ready == 1'b1)) begin up_es_hoffset_rdata <= up_es_drp_rdata; end if ((up_es_fsm == ES_FSM_VOFFSET_RRDY) && (up_es_drp_ready == 1'b1)) begin up_es_voffset_rdata <= up_es_drp_rdata; end if (((up_es_fsm == ES_FSM_CTRLINIT_RRDY) || (up_es_fsm == ES_FSM_CTRLSTART_RRDY) || (up_es_fsm == ES_FSM_CTRLSTOP_RRDY)) && (up_es_drp_ready == 1'b1)) begin up_es_ctrl_rdata <= up_es_drp_rdata; end if ((up_es_fsm == ES_FSM_SCNT_RRDY) && (up_es_drp_ready == 1'b1)) begin up_es_scnt_rdata <= up_es_drp_rdata; end if ((up_es_fsm == ES_FSM_ECNT_RRDY) && (up_es_drp_ready == 1'b1)) begin up_es_ecnt_rdata <= up_es_drp_rdata; end end end // eye scan state machine- write vertical and horizontal offsets // and read back sample and error counters always @(negedge up_rstn or posedge up_clk) begin if (up_rstn == 1'b0) begin up_es_fsm <= ES_FSM_IDLE; end else begin if (up_es_stop == 1'b1) begin up_es_fsm <= ES_FSM_IDLE; end else begin case (up_es_fsm) ES_FSM_IDLE: begin // idle if (up_es_start == 1'b1) begin up_es_fsm <= ES_FSM_STATUS; end else begin up_es_fsm <= ES_FSM_IDLE; end end ES_FSM_STATUS: begin // set status up_es_fsm <= ES_FSM_INIT; end ES_FSM_INIT: begin // initialize if (up_es_init == 1'b1) begin up_es_fsm <= ES_FSM_CTRLINIT_READ; end else begin up_es_fsm <= ES_FSM_HOFFSET_READ; end end ES_FSM_CTRLINIT_READ: begin // control read up_es_fsm <= ES_FSM_CTRLINIT_RRDY; end ES_FSM_CTRLINIT_RRDY: begin // control ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_CTRLINIT_WRITE; end else begin up_es_fsm <= ES_FSM_CTRLINIT_RRDY; end end ES_FSM_CTRLINIT_WRITE: begin // control write up_es_fsm <= ES_FSM_CTRLINIT_WRDY; end ES_FSM_CTRLINIT_WRDY: begin // control ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_SDATA0_WRITE; end else begin up_es_fsm <= ES_FSM_CTRLINIT_WRDY; end end ES_FSM_SDATA0_WRITE: begin // sdata write up_es_fsm <= ES_FSM_SDATA0_WRDY; end ES_FSM_SDATA0_WRDY: begin // sdata ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_SDATA1_WRITE; end else begin up_es_fsm <= ES_FSM_SDATA0_WRDY; end end ES_FSM_SDATA1_WRITE: begin // sdata write up_es_fsm <= ES_FSM_SDATA1_WRDY; end ES_FSM_SDATA1_WRDY: begin // sdata ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_SDATA2_WRITE; end else begin up_es_fsm <= ES_FSM_SDATA1_WRDY; end end ES_FSM_SDATA2_WRITE: begin // sdata write up_es_fsm <= ES_FSM_SDATA2_WRDY; end ES_FSM_SDATA2_WRDY: begin // sdata ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_SDATA3_WRITE; end else begin up_es_fsm <= ES_FSM_SDATA2_WRDY; end end ES_FSM_SDATA3_WRITE: begin // sdata write up_es_fsm <= ES_FSM_SDATA3_WRDY; end ES_FSM_SDATA3_WRDY: begin // sdata ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_SDATA4_WRITE; end else begin up_es_fsm <= ES_FSM_SDATA3_WRDY; end end ES_FSM_SDATA4_WRITE: begin // sdata write up_es_fsm <= ES_FSM_SDATA4_WRDY; end ES_FSM_SDATA4_WRDY: begin // sdata ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_QDATA0_WRITE; end else begin up_es_fsm <= ES_FSM_SDATA4_WRDY; end end ES_FSM_QDATA0_WRITE: begin // qdata write up_es_fsm <= ES_FSM_QDATA0_WRDY; end ES_FSM_QDATA0_WRDY: begin // qdata ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_QDATA1_WRITE; end else begin up_es_fsm <= ES_FSM_QDATA0_WRDY; end end ES_FSM_QDATA1_WRITE: begin // qdata write up_es_fsm <= ES_FSM_QDATA1_WRDY; end ES_FSM_QDATA1_WRDY: begin // qdata ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_QDATA2_WRITE; end else begin up_es_fsm <= ES_FSM_QDATA1_WRDY; end end ES_FSM_QDATA2_WRITE: begin // qdata write up_es_fsm <= ES_FSM_QDATA2_WRDY; end ES_FSM_QDATA2_WRDY: begin // qdata ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_QDATA3_WRITE; end else begin up_es_fsm <= ES_FSM_QDATA2_WRDY; end end ES_FSM_QDATA3_WRITE: begin // qdata write up_es_fsm <= ES_FSM_QDATA3_WRDY; end ES_FSM_QDATA3_WRDY: begin // qdata ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_QDATA4_WRITE; end else begin up_es_fsm <= ES_FSM_QDATA3_WRDY; end end ES_FSM_QDATA4_WRITE: begin // qdata write up_es_fsm <= ES_FSM_QDATA4_WRDY; end ES_FSM_QDATA4_WRDY: begin // qdata ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_HOFFSET_READ; end else begin up_es_fsm <= ES_FSM_QDATA4_WRDY; end end ES_FSM_HOFFSET_READ: begin // horizontal offset read up_es_fsm <= ES_FSM_HOFFSET_RRDY; end ES_FSM_HOFFSET_RRDY: begin // horizontal offset ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_HOFFSET_WRITE; end else begin up_es_fsm <= ES_FSM_HOFFSET_RRDY; end end ES_FSM_HOFFSET_WRITE: begin // horizontal offset write up_es_fsm <= ES_FSM_HOFFSET_WRDY; end ES_FSM_HOFFSET_WRDY: begin // horizontal offset ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_VOFFSET_READ; end else begin up_es_fsm <= ES_FSM_HOFFSET_WRDY; end end ES_FSM_VOFFSET_READ: begin // vertical offset read up_es_fsm <= ES_FSM_VOFFSET_RRDY; end ES_FSM_VOFFSET_RRDY: begin // vertical offset ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_VOFFSET_WRITE; end else begin up_es_fsm <= ES_FSM_VOFFSET_RRDY; end end ES_FSM_VOFFSET_WRITE: begin // vertical offset write up_es_fsm <= ES_FSM_VOFFSET_WRDY; end ES_FSM_VOFFSET_WRDY: begin // vertical offset ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_CTRLSTART_READ; end else begin up_es_fsm <= ES_FSM_VOFFSET_WRDY; end end ES_FSM_CTRLSTART_READ: begin // control read up_es_fsm <= ES_FSM_CTRLSTART_RRDY; end ES_FSM_CTRLSTART_RRDY: begin // control ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_CTRLSTART_WRITE; end else begin up_es_fsm <= ES_FSM_CTRLSTART_RRDY; end end ES_FSM_CTRLSTART_WRITE: begin // control write up_es_fsm <= ES_FSM_CTRLSTART_WRDY; end ES_FSM_CTRLSTART_WRDY: begin // control ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_STATUS_READ; end else begin up_es_fsm <= ES_FSM_CTRLSTART_WRDY; end end ES_FSM_STATUS_READ: begin // status read up_es_fsm <= ES_FSM_STATUS_RRDY; end ES_FSM_STATUS_RRDY: begin // status ready if (up_es_drp_ready == 1'b0) begin up_es_fsm <= ES_FSM_STATUS_RRDY; end else if (up_es_drp_rdata[3:0] == 4'b0101) begin up_es_fsm <= ES_FSM_CTRLSTOP_READ; end else begin up_es_fsm <= ES_FSM_STATUS_READ; end end ES_FSM_CTRLSTOP_READ: begin // control read up_es_fsm <= ES_FSM_CTRLSTOP_RRDY; end ES_FSM_CTRLSTOP_RRDY: begin // control ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_CTRLSTOP_WRITE; end else begin up_es_fsm <= ES_FSM_CTRLSTOP_RRDY; end end ES_FSM_CTRLSTOP_WRITE: begin // control write up_es_fsm <= ES_FSM_CTRLSTOP_WRDY; end ES_FSM_CTRLSTOP_WRDY: begin // control ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_SCNT_READ; end else begin up_es_fsm <= ES_FSM_CTRLSTOP_WRDY; end end ES_FSM_SCNT_READ: begin // read sample count up_es_fsm <= ES_FSM_SCNT_RRDY; end ES_FSM_SCNT_RRDY: begin // sample count ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_ECNT_READ; end else begin up_es_fsm <= ES_FSM_SCNT_RRDY; end end ES_FSM_ECNT_READ: begin // read error count up_es_fsm <= ES_FSM_ECNT_RRDY; end ES_FSM_ECNT_RRDY: begin // error count ready if (up_es_drp_ready == 1'b1) begin up_es_fsm <= ES_FSM_DMA_WRITE; end else begin up_es_fsm <= ES_FSM_ECNT_RRDY; end end ES_FSM_DMA_WRITE: begin // dma write up_es_fsm <= ES_FSM_DMA_READY; end ES_FSM_DMA_READY: begin // dma ack if (up_es_dma_ack == 1'b1) begin up_es_fsm <= ES_FSM_UPDATE; end else begin up_es_fsm <= ES_FSM_DMA_READY; end end ES_FSM_UPDATE: begin // update if (up_es_eos_s == 1'b1) begin up_es_fsm <= ES_FSM_IDLE; end else if (up_es_ut == 1'b1) begin up_es_fsm <= ES_FSM_HOFFSET_READ; end else begin up_es_fsm <= ES_FSM_VOFFSET_READ; end end default: begin up_es_fsm <= ES_FSM_IDLE; end endcase end end end // drp signals controlled by the fsm always @(negedge up_rstn or posedge up_clk) begin if (up_rstn == 1'b0) begin up_es_drp_sel <= 'd0; up_es_drp_wr <= 'd0; up_es_drp_addr <= 'd0; up_es_drp_wdata <= 'd0; end else begin case (up_es_fsm) ES_FSM_CTRLINIT_READ: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b0; up_es_drp_addr <= ES_DRP_CTRL_ADDR; up_es_drp_wdata <= 16'h0000; end ES_FSM_CTRLINIT_WRITE: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b1; up_es_drp_addr <= ES_DRP_CTRL_ADDR; if (GTH_GTX_N == 1) begin up_es_drp_wdata <= {up_es_ctrl_rdata[15:10], 2'b11, up_es_ctrl_rdata[7:5], up_es_prescale}; end else begin up_es_drp_wdata <= {up_es_ctrl_rdata[15:10], 2'b11, up_es_ctrl_rdata[7:0]}; end end ES_FSM_SDATA0_WRITE: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b1; up_es_drp_addr <= ES_DRP_SDATA0_ADDR; up_es_drp_wdata <= up_es_sdata0; end ES_FSM_SDATA1_WRITE: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b1; up_es_drp_addr <= ES_DRP_SDATA1_ADDR; up_es_drp_wdata <= up_es_sdata1; end ES_FSM_SDATA2_WRITE: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b1; up_es_drp_addr <= ES_DRP_SDATA2_ADDR; up_es_drp_wdata <= up_es_sdata2; end ES_FSM_SDATA3_WRITE: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b1; up_es_drp_addr <= ES_DRP_SDATA3_ADDR; up_es_drp_wdata <= up_es_sdata3; end ES_FSM_SDATA4_WRITE: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b1; up_es_drp_addr <= ES_DRP_SDATA4_ADDR; up_es_drp_wdata <= up_es_sdata4; end ES_FSM_QDATA0_WRITE: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b1; up_es_drp_addr <= ES_DRP_QDATA0_ADDR; up_es_drp_wdata <= up_es_qdata0; end ES_FSM_QDATA1_WRITE: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b1; up_es_drp_addr <= ES_DRP_QDATA1_ADDR; up_es_drp_wdata <= up_es_qdata1; end ES_FSM_QDATA2_WRITE: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b1; up_es_drp_addr <= ES_DRP_QDATA2_ADDR; up_es_drp_wdata <= up_es_qdata2; end ES_FSM_QDATA3_WRITE: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b1; up_es_drp_addr <= ES_DRP_QDATA3_ADDR; up_es_drp_wdata <= up_es_qdata3; end ES_FSM_QDATA4_WRITE: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b1; up_es_drp_addr <= ES_DRP_QDATA4_ADDR; up_es_drp_wdata <= up_es_qdata4; end ES_FSM_HOFFSET_READ: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b0; up_es_drp_addr <= ES_DRP_HOFFSET_ADDR; up_es_drp_wdata <= 16'h0000; end ES_FSM_HOFFSET_WRITE: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b1; up_es_drp_addr <= ES_DRP_HOFFSET_ADDR; if (GTH_GTX_N == 1) begin up_es_drp_wdata <= {up_es_hoffset, up_es_hoffset_rdata[3:0]}; end else begin up_es_drp_wdata <= {up_es_hoffset_rdata[15:12], up_es_hoffset}; end end ES_FSM_VOFFSET_READ: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b0; up_es_drp_addr <= ES_DRP_VOFFSET_ADDR; up_es_drp_wdata <= 16'h0000; end ES_FSM_VOFFSET_WRITE: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b1; up_es_drp_addr <= ES_DRP_VOFFSET_ADDR; if (GTH_GTX_N == 1) begin up_es_drp_wdata <= {up_es_voffset_rdata[15:11], up_es_voffset_s[7], up_es_ut_s, up_es_voffset_s[6:0], up_es_voffset_range}; end else begin up_es_drp_wdata <= {up_es_prescale, up_es_voffset_rdata[10:9], up_es_ut_s, up_es_voffset_s}; end end ES_FSM_CTRLSTART_READ: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b0; up_es_drp_addr <= ES_DRP_CTRL_ADDR; up_es_drp_wdata <= 16'h0000; end ES_FSM_CTRLSTART_WRITE: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b1; up_es_drp_addr <= ES_DRP_CTRL_ADDR; if (GTH_GTX_N == 1) begin up_es_drp_wdata <= {6'd1, up_es_ctrl_rdata[9:0]}; end else begin up_es_drp_wdata <= {up_es_ctrl_rdata[15:6], 6'd1}; end end ES_FSM_STATUS_READ: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b0; up_es_drp_addr <= ES_DRP_STATUS_ADDR; up_es_drp_wdata <= 16'h0000; end ES_FSM_CTRLSTOP_READ: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b0; up_es_drp_addr <= ES_DRP_CTRL_ADDR; up_es_drp_wdata <= 16'h0000; end ES_FSM_CTRLSTOP_WRITE: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b1; up_es_drp_addr <= ES_DRP_CTRL_ADDR; if (GTH_GTX_N == 1) begin up_es_drp_wdata <= {6'd0, up_es_ctrl_rdata[9:0]}; end else begin up_es_drp_wdata <= {up_es_ctrl_rdata[15:6], 6'd0}; end end ES_FSM_SCNT_READ: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b0; up_es_drp_addr <= ES_DRP_SCNT_ADDR; up_es_drp_wdata <= 16'h0000; end ES_FSM_ECNT_READ: begin up_es_drp_sel <= 1'b1; up_es_drp_wr <= 1'b0; up_es_drp_addr <= ES_DRP_ECNT_ADDR; up_es_drp_wdata <= 16'h0000; end default: begin up_es_drp_sel <= 1'b0; up_es_drp_wr <= 1'b0; up_es_drp_addr <= 9'h000; up_es_drp_wdata <= 16'h0000; end endcase end end endmodule // *************************************************************************** // ***************************************************************************