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x393_testbench02.tf
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x393_testbench02.tf
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/*******************************************************************************
* Module: x393_testbench02
* Date:2015-02-06
* Author: Andrey Filippov
* Description: testbench for the initial x393.v simulation
*
* Copyright (c) 2015 Elphel, Inc.
* x393_testbench02.v is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* x393_testbench02.tf 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/> .
*
* Additional permission under GNU GPL version 3 section 7:
* If you modify this Program, or any covered work, by linking or combining it
* with independent modules provided by the FPGA vendor only (this permission
* does not extend to any 3-rd party modules, "soft cores" or macros) under
* different license terms solely for the purpose of generating binary "bitstream"
* files and/or simulating the code, the copyright holders of this Program give
* you the right to distribute the covered work without those independent modules
* as long as the source code for them is available from the FPGA vendor free of
* charge, and there is no dependence on any encrypted modules for simulating of
* the combined code. This permission applies to you if the distributed code
* contains all the components and scripts required to completely simulate it
* with at least one of the Free Software programs.
*******************************************************************************/
`timescale 1ns/1ps
`include "system_defines.vh"
`define SAME_SENSOR_DATA 1
//`define use200Mhz 1
//`define DEBUG_FIFO 1
`undef WAIT_MRS
`define SET_PER_PIN_DELAYS 1 // set individual (including per-DQ pin delays)
`define READBACK_DELAYS 1
`define PS_PIO_WAIT_COMPLETE 0 // wait until PS PIO module finished transaction before starting a new one
// Disabled already passed test to speedup simulation
//`define TEST_WRITE_LEVELLING 1
//`define TEST_READ_PATTERN 1
//`define TEST_WRITE_BLOCK 1
//`define TEST_READ_BLOCK 1
//`define TEST_SCANLINE_WRITE
`define TEST_SCANLINE_WRITE_WAIT 1 // wait TEST_SCANLINE_WRITE finished (frame_done)
//`define TEST_SCANLINE_READ
`define TEST_READ_SHOW 1
//`define TEST_TILED_WRITE 1
`define TEST_TILED_WRITE_WAIT 1 // wait TEST_SCANLINE_WRITE finished (frame_done)
//`define TEST_TILED_READ 1
//`define TEST_TILED_WRITE32 1
//`define TEST_TILED_READ32 1
`define TEST_AFI_WRITE 1
`define TEST_AFI_READ 1
`define TEST_SENSOR 0
module x393_testbench02 #(
`include "includes/x393_parameters.vh" // SuppressThisWarning VEditor - not used
`include "includes/x393_simulation_parameters.vh"
)(
);
`ifdef IVERILOG
// $display("IVERILOG is defined");
`ifdef NON_VDT_ENVIROMENT
parameter fstname="x393.fst";
`else
`include "IVERILOG_INCLUDE.v"
`endif // NON_VDT_ENVIROMENT
`else // IVERILOG
// $display("IVERILOG is not defined");
`ifdef CVC
`ifdef NON_VDT_ENVIROMENT
parameter fstname = "x393.fst";
`else // NON_VDT_ENVIROMENT
`include "IVERILOG_INCLUDE.v"
`endif // NON_VDT_ENVIROMENT
`else
parameter fstname = "x393.fst";
`endif // CVC
`endif // IVERILOG
`define DEBUG_WR_SINGLE 1
`define DEBUG_RD_DATA 1
//`include "includes/x393_cur_params_sim.vh" // parameters that may need adjustment, should be before x393_localparams.vh
`include "includes/x393_cur_params_target.vh" // SuppressThisWarning VEditor - not used parameters that may need adjustment, should be before x393_localparams.vh
parameter TRIGGER_MODE = 0; // 1; // 0 - auto, 1 - triggered
parameter EXT_TRIGGER_MODE = 1 ; // 0 - internal, 1 - external trigger (camsync)
parameter EXTERNAL_TIMESTAMP = 0; // 1 ; // embed local timestamp, 1 - embed received timestamp
`include "includes/x393_localparams.vh" // SuppressThisWarning VEditor - not used
// VDT - incorrect real number calculation
// localparam FRAME_COMPRESS_CYCLES_INPUT=(FRAME_COMPRESS_CYCLES * CLK0_PER) /CLK1_PER;
// localparam real FRAME_COMPRESS_CYCLES_INPUT=(CLK0_PER * CLK0_PER);
// ========================== parameters from x353 ===================================
`ifdef SYNC_COMPRESS
parameter DEPEND=1'b1;
`else
parameter DEPEND=1'b0;
`endif
`ifdef TEST_ABORT
`endif
parameter SYNC_BIT_LENGTH=8-1; /// 7 pixel clock pulses
parameter FPGA_XTRA_CYCLES= 1500; // 1072+;
// moved to x393_simulation_parameters.vh
// parameter HISTOGRAM_LEFT= 0; //2; // left
// parameter HISTOGRAM_TOP = 2; // top
// parameter HISTOGRAM_WIDTH= 6; // width
// parameter HISTOGRAM_HEIGHT=6; // height
parameter CLK0_PER = 6.25; //160MHz
parameter CLK1_PER = 10.4; //96MHz
parameter CLK3_PER = 83.33; //12MHz
parameter CPU_PER=10.4;
parameter TRIG_PERIOD = 6000 ;
parameter HBLANK= 52; // 12; /// 52; //*********************
parameter WOI_HEIGHT= 32;
parameter BLANK_ROWS_BEFORE= 1; //8; ///2+2 - a little faster than compressor
parameter BLANK_ROWS_AFTER= 1; //8;
parameter TRIG_LINES= 8;
parameter VBLANK= 2; /// 2 lines //SuppressThisWarning Veditor UNUSED
parameter CYCLES_PER_PIXEL= 3; /// 2 for JP4, 3 for JPEG
`ifdef PF
parameter PF_HEIGHT=8;
parameter FULL_HEIGHT=WOI_HEIGHT;
parameter PF_STRIPES=WOI_HEIGHT/PF_HEIGHT;
`else
parameter PF_HEIGHT=0;
parameter FULL_HEIGHT=WOI_HEIGHT+4;
parameter PF_STRIPES=0;
`endif
parameter VIRTUAL_WIDTH= FULL_WIDTH + HBLANK;
parameter VIRTUAL_HEIGHT= FULL_HEIGHT + BLANK_ROWS_BEFORE + BLANK_ROWS_AFTER; //SuppressThisWarning Veditor UNUSED
parameter TRIG_INTERFRAME= 100; /// extra 100 clock cycles between frames //SuppressThisWarning Veditor UNUSED
/// parameter TRIG_OUT_DATA= 'h80000; // internal cable
/// parameter TRIG_EXTERNAL_INPUT= 'h20000; // internal cable, low level on EXT[8]
parameter TRIG_DELAY= 200; /// delay in sensor clock cycles
parameter FULL_WIDTH= WOI_WIDTH+4;
localparam SENSOR_MEMORY_WIDTH_BURSTS = (FULL_WIDTH + 15) >> 4;
localparam SENSOR_MEMORY_MASK = (1 << (FRAME_WIDTH_ROUND_BITS-4)) -1;
localparam SENSOR_MEMORY_FULL_WIDTH_BURSTS = (SENSOR_MEMORY_WIDTH_BURSTS + SENSOR_MEMORY_MASK) & (~SENSOR_MEMORY_MASK);
// localparam FRAME_COMPRESS_CYCLES = (WOI_WIDTH &'h3fff0) * (WOI_HEIGHT &'h3fff0) * CYCLES_PER_PIXEL + FPGA_XTRA_CYCLES;
// in pixel clocks (camsync now has different clock - 100MHz instead of the 96MHz
// localparam TRIG_PERIOD = VIRTUAL_WIDTH * (VIRTUAL_HEIGHT + TRIG_LINES + VBLANK); /// maximal sensor can do
// ========================== end of parameters from x353 ===================================
// Sensor signals - as on sensor pads
wire PX1_MCLK; // input sensor input clock
wire PX1_MRST; // input
wire PX1_ARO; // input
wire PX1_ARST; // input
wire PX1_OFST = 1'b1; // input // I2C address ofset by 2: for simulation 0 - still mode, 1 - video mode.
wire [11:0] PX1_D; // output[11:0]
wire PX1_DCLK; // output sensor output clock (connect to sensor BPF output )
wire PX1_HACT; // output
wire PX1_VACT; // output
wire PX2_MCLK; // input sensor input clock
wire PX2_MRST; // input
wire PX2_ARO; // input
wire PX2_ARST; // input
wire PX2_OFST = 1'b1; // input // I2C address ofset by 2: for simulation 0 - still mode, 1 - video mode.
wire [11:0] PX2_D; // output[11:0]
wire PX2_DCLK; // output sensor output clock (connect to sensor BPF output )
wire PX2_HACT; // output
wire PX2_VACT; // output
wire PX3_MCLK; // input sensor input clock
wire PX3_MRST; // input
wire PX3_ARO; // input
wire PX3_ARST; // input
wire PX3_OFST = 1'b1; // input // I2C address ofset by 2: for simulation 0 - still mode, 1 - video mode.
wire [11:0] PX3_D; // output[11:0]
wire PX3_DCLK; // output sensor output clock (connect to sensor BPF output )
wire PX3_HACT; // output
wire PX3_VACT; // output
wire PX4_MCLK; // input sensor input clock
wire PX4_MRST; // input
wire PX4_ARO; // input
wire PX4_ARST; // input
wire PX4_OFST = 1'b1; // input // I2C address ofset by 2: for simulation 0 - still mode, 1 - video mode.
wire [11:0] PX4_D; // output[11:0]
wire PX4_DCLK; // output sensor output clock (connect to sensor BPF output )
wire PX4_HACT; // output
wire PX4_VACT; // output
// Sensor signals - as on FPGA pads
wire [ 7:0] sns1_dp; // inout[7:0] {PX_MRST, PXD8, PXD6, PXD4, PXD2, PXD0, PX_HACT, PX_DCLK}
wire [ 7:0] sns1_dn; // inout[7:0] {PX_ARST, PXD9, PXD7, PXD5, PXD3, PXD1, PX_VACT, PX_BPF}
wire sns1_clkp; // inout CNVCLK/TDO
wire sns1_clkn; // inout CNVSYNC/TDI
wire sns1_scl; // inout PX_SCL
wire sns1_sda; // inout PX_SDA
wire sns1_ctl; // inout PX_ARO/TCK
wire sns1_pg; // inout SENSPGM
wire [ 7:0] sns2_dp; // inout[7:0] {PX_MRST, PXD8, PXD6, PXD4, PXD2, PXD0, PX_HACT, PX_DCLK}
wire [ 7:0] sns2_dn; // inout[7:0] {PX_ARST, PXD9, PXD7, PXD5, PXD3, PXD1, PX_VACT, PX_BPF}
wire sns2_clkp; // inout CNVCLK/TDO
wire sns2_clkn; // inout CNVSYNC/TDI
wire sns2_scl; // inout PX_SCL
wire sns2_sda; // inout PX_SDA
wire sns2_ctl; // inout PX_ARO/TCK
wire sns2_pg; // inout SENSPGM
wire [ 7:0] sns3_dp; // inout[7:0] {PX_MRST, PXD8, PXD6, PXD4, PXD2, PXD0, PX_HACT, PX_DCLK}
wire [ 7:0] sns3_dn; // inout[7:0] {PX_ARST, PXD9, PXD7, PXD5, PXD3, PXD1, PX_VACT, PX_BPF}
wire sns3_clkp; // inout CNVCLK/TDO
wire sns3_clkn; // inout CNVSYNC/TDI
wire sns3_scl; // inout PX_SCL
wire sns3_sda; // inout PX_SDA
wire sns3_ctl; // inout PX_ARO/TCK
wire sns3_pg; // inout SENSPGM
wire [ 7:0] sns4_dp; // inout[7:0] {PX_MRST, PXD8, PXD6, PXD4, PXD2, PXD0, PX_HACT, PX_DCLK}
wire [ 7:0] sns4_dn; // inout[7:0] {PX_ARST, PXD9, PXD7, PXD5, PXD3, PXD1, PX_VACT, PX_BPF}
wire sns4_clkp; // inout CNVCLK/TDO
wire sns4_clkn; // inout CNVSYNC/TDI
wire sns4_scl; // inout PX_SCL
wire sns4_sda; // inout PX_SDA
wire sns4_ctl; // inout PX_ARO/TCK
wire sns4_pg; // inout SENSPGM
//connect sensor to sensor port 1
assign sns1_dp[6:1] = {PX1_D[10], PX1_D[8], PX1_D[6], PX1_D[4], PX1_D[2], PX1_HACT};
assign PX1_MRST = sns1_dp[7]; // from FPGA to sensor
assign PX1_MCLK = sns1_dp[0]; // from FPGA to sensor
assign sns1_dn[6:0] = {PX1_D[11], PX1_D[9], PX1_D[7], PX1_D[5], PX1_D[3], PX1_VACT, PX1_DCLK};
assign PX1_ARST = sns1_dn[7];
assign sns1_clkn = PX1_D[0]; // inout CNVSYNC/TDI
assign sns1_clkp = PX1_D[1]; // CNVCLK/TDO
assign PX1_ARO = sns1_ctl; // from FPGA to sensor
assign PX2_MRST = sns2_dp[7]; // from FPGA to sensor
assign PX2_MCLK = sns2_dp[0]; // from FPGA to sensor
assign PX2_ARST = sns2_dn[7];
assign PX2_ARO = sns2_ctl; // from FPGA to sensor
assign PX3_MRST = sns3_dp[7]; // from FPGA to sensor
assign PX3_MCLK = sns3_dp[0]; // from FPGA to sensor
assign PX3_ARST = sns3_dn[7];
assign PX3_ARO = sns3_ctl; // from FPGA to sensor
assign PX4_MRST = sns4_dp[7]; // from FPGA to sensor
assign PX4_MCLK = sns4_dp[0]; // from FPGA to sensor
assign PX4_ARST = sns4_dn[7];
assign PX4_ARO = sns4_ctl; // from FPGA to sensor
`ifdef SAME_SENSOR_DATA
assign sns2_dp[6:1] = {PX2_D[10], PX2_D[8], PX2_D[6], PX2_D[4], PX2_D[2], PX2_HACT};
assign sns2_dn[6:0] = {PX2_D[11], PX2_D[9], PX2_D[7], PX2_D[5], PX2_D[3], PX2_VACT, PX2_DCLK};
assign sns2_clkn = PX2_D[0]; // inout CNVSYNC/TDI
assign sns2_clkp = PX2_D[1]; // CNVCLK/TDO
assign sns3_dp[6:1] = {PX3_D[10], PX3_D[8], PX3_D[6], PX3_D[4], PX3_D[2], PX3_HACT};
assign sns3_dn[6:0] = {PX3_D[11], PX3_D[9], PX3_D[7], PX3_D[5], PX3_D[3], PX3_VACT, PX3_DCLK};
assign sns3_clkn = PX3_D[0]; // inout CNVSYNC/TDI
assign sns3_clkp = PX3_D[1]; // CNVCLK/TDO
assign sns4_dp[6:1] = {PX4_D[10], PX4_D[8], PX4_D[6], PX4_D[4], PX4_D[2], PX4_HACT};
assign sns4_dn[6:0] = {PX4_D[11], PX4_D[9], PX4_D[7], PX4_D[5], PX4_D[3], PX4_VACT, PX4_DCLK};
assign sns4_clkn = PX4_D[0]; // inout CNVSYNC/TDI
assign sns4_clkp = PX4_D[1]; // CNVCLK/TDO
`else
//connect sensor to sensor port 2 (all data rotated left by 1 bit)
assign sns2_dp[6:1] = {PX2_D[9], PX2_D[7], PX2_D[5], PX2_D[3], PX2_D[1], PX2_HACT};
assign sns2_dn[6:0] = {PX2_D[10], PX2_D[8], PX2_D[6], PX2_D[4], PX2_D[2], PX2_VACT, PX2_DCLK};
assign sns2_clkn = PX2_D[11]; // inout CNVSYNC/TDI
assign sns2_clkp = PX2_D[0]; // CNVCLK/TDO
//connect sensor to sensor port 3 (all data rotated left by 2 bits
assign sns3_dp[6:1] = {PX3_D[8], PX3_D[6], PX3_D[4], PX3_D[2], PX3_D[0], PX3_HACT};
assign sns3_dn[6:0] = {PX3_D[9], PX3_D[7], PX3_D[5], PX3_D[3], PX3_D[1], PX3_VACT, PX3_DCLK};
assign sns3_clkn = PX3_D[10]; // inout CNVSYNC/TDI
assign sns3_clkp = PX3_D[11]; // CNVCLK/TDO
//connect sensor to sensor port 4 (all data rotated left by 3 bits
assign sns4_dp[6:1] = {PX4_D[5], PX4_D[3], PX4_D[1], PX4_D[11], PX4_D[9], PX4_HACT};
assign sns4_dn[6:0] = {PX4_D[6], PX4_D[4], PX4_D[2], PX4_D[0], PX4_D[10], PX4_VACT, PX4_DCLK};
assign sns4_clkn = PX4_D[7]; // inout CNVSYNC/TDI
assign sns4_clkp = PX4_D[8]; // CNVCLK/TDO
`endif
wire [ 9:0] gpio_pins; // inout[9:0] ([6]-synco0,[7]-syncio0,[8]-synco1,[9]-syncio1)
// Connect trigger outs to triggets in (#10 needed for Icarus)
assign #10 gpio_pins[7] = gpio_pins[6];
assign #10 gpio_pins[9] = gpio_pins[8];
// DDR3 signals
wire SDRST;
wire SDCLK; // output
wire SDNCLK; // output
wire [ADDRESS_NUMBER-1:0] SDA; // output[14:0]
wire [ 2:0] SDBA; // output[2:0]
wire SDWE; // output
wire SDRAS; // output
wire SDCAS; // output
wire SDCKE; // output
wire SDODT; // output
wire [15:0] SDD; // inout[15:0]
wire SDDML; // inout
wire DQSL; // inout
wire NDQSL; // inout
wire SDDMU; // inout
wire DQSU; // inout
wire NDQSU; // inout
wire memclk;
wire ffclk0p; // input
wire ffclk0n; // input
wire ffclk1p; // input
wire ffclk1n; // input
// axi_hp simulation signals
wire HCLK;
wire [31:0] afi_sim_rd_address; // output[31:0]
wire [ 5:0] afi_sim_rid; // output[5:0] SuppressThisWarning VEditor - not used - just view
// reg afi_sim_rd_valid; // input
wire afi_sim_rd_valid; // input
wire afi_sim_rd_ready; // output
// reg [63:0] afi_sim_rd_data; // input[63:0]
wire [63:0] afi_sim_rd_data; // input[63:0]
wire [ 2:0] afi_sim_rd_cap; // output[2:0] SuppressThisWarning VEditor - not used - just view
wire [ 3:0] afi_sim_rd_qos; // output[3:0] SuppressThisWarning VEditor - not used - just view
wire [ 1:0] afi_sim_rd_resp; // input[1:0]
// reg [ 1:0] afi_sim_rd_resp; // input[1:0]
wire [31:0] afi_sim_wr_address; // output[31:0] SuppressThisWarning VEditor - not used - just view
wire [ 5:0] afi_sim_wid; // output[5:0] SuppressThisWarning VEditor - not used - just view
wire afi_sim_wr_valid; // output
wire afi_sim_wr_ready; // input
// reg afi_sim_wr_ready; // input
wire [63:0] afi_sim_wr_data; // output[63:0] SuppressThisWarning VEditor - not used - just view
wire [ 7:0] afi_sim_wr_stb; // output[7:0] SuppressThisWarning VEditor - not used - just view
wire [ 3:0] afi_sim_bresp_latency; // input[3:0]
// reg [ 3:0] afi_sim_bresp_latency; // input[3:0]
wire [ 2:0] afi_sim_wr_cap; // output[2:0] SuppressThisWarning VEditor - not used - just view
wire [ 3:0] afi_sim_wr_qos; // output[3:0] SuppressThisWarning VEditor - not used - just view
assign HCLK = x393_i.ps7_i.SAXIHP0ACLK; // shortcut name
wire [31:0] afi1_sim_wr_address; // output[31:0] SuppressThisWarning VEditor - not used - just view
wire [ 5:0] afi1_sim_wid; // output[5:0] SuppressThisWarning VEditor - not used - just view
wire afi1_sim_wr_valid; // output
wire afi1_sim_wr_ready; // input
// reg afi1_sim_wr_ready; // input
wire [63:0] afi1_sim_wr_data; // output[63:0] SuppressThisWarning VEditor - not used - just view
wire [ 7:0] afi1_sim_wr_stb; // output[7:0] SuppressThisWarning VEditor - not used - just view
wire [ 3:0] afi1_sim_bresp_latency; // input[3:0]
// reg [ 3:0] afi1_sim_bresp_latency; // input[3:0]
wire [ 2:0] afi1_sim_wr_cap; // output[2:0] SuppressThisWarning VEditor - not used - just view
wire [ 3:0] afi1_sim_wr_qos; // output[3:0] SuppressThisWarning VEditor - not used - just view
wire [31:0] sim_cmprs0_addr = (afi1_sim_wr_valid && afi1_sim_wr_ready && (afi1_sim_wid[1:0] == 2'h0))?afi1_sim_wr_address:32'bz; // SuppressThisWarning VEditor - not used - just view
wire [31:0] sim_cmprs1_addr = (afi1_sim_wr_valid && afi1_sim_wr_ready && (afi1_sim_wid[1:0] == 2'h1))?afi1_sim_wr_address:32'bz; // SuppressThisWarning VEditor - not used - just view
wire [31:0] sim_cmprs2_addr = (afi1_sim_wr_valid && afi1_sim_wr_ready && (afi1_sim_wid[1:0] == 2'h2))?afi1_sim_wr_address:32'bz; // SuppressThisWarning VEditor - not used - just view
wire [31:0] sim_cmprs3_addr = (afi1_sim_wr_valid && afi1_sim_wr_ready && (afi1_sim_wid[1:0] == 2'h3))?afi1_sim_wr_address:32'bz; // SuppressThisWarning VEditor - not used - just view
wire [63:0] sim_cmprs0_data = (afi1_sim_wr_valid && afi1_sim_wr_ready && (afi1_sim_wid[1:0] == 2'h0))?afi1_sim_wr_data:64'bz; // SuppressThisWarning VEditor - not used - just view
wire [63:0] sim_cmprs1_data = (afi1_sim_wr_valid && afi1_sim_wr_ready && (afi1_sim_wid[1:0] == 2'h1))?afi1_sim_wr_data:64'bz; // SuppressThisWarning VEditor - not used - just view
wire [63:0] sim_cmprs2_data = (afi1_sim_wr_valid && afi1_sim_wr_ready && (afi1_sim_wid[1:0] == 2'h2))?afi1_sim_wr_data:64'bz; // SuppressThisWarning VEditor - not used - just view
wire [63:0] sim_cmprs3_data = (afi1_sim_wr_valid && afi1_sim_wr_ready && (afi1_sim_wid[1:0] == 2'h3))?afi1_sim_wr_data:64'bz; // SuppressThisWarning VEditor - not used - just view
//x393_i.ps7_i.SAXIHP1ACLK
always @ (posedge x393_i.ps7_i.SAXIHP1ACLK) if (afi1_sim_wr_valid && afi1_sim_wr_ready) begin
if (afi1_sim_wid[1:0] == 2'h0) $display("---sim_cmprs0: %x:%x", afi1_sim_wr_address, afi1_sim_wr_data);
if (afi1_sim_wid[1:0] == 2'h1) $display("---sim_cmprs1: %x:%x", afi1_sim_wr_address, afi1_sim_wr_data);
if (afi1_sim_wid[1:0] == 2'h2) $display("---sim_cmprs2: %x:%x", afi1_sim_wr_address, afi1_sim_wr_data);
if (afi1_sim_wid[1:0] == 2'h3) $display("---sim_cmprs3: %x:%x", afi1_sim_wr_address, afi1_sim_wr_data);
end
// afi loopback (membridge)
assign #1 afi_sim_rd_data= afi_sim_rd_ready?{2'h0,afi_sim_rd_address[31:3],1'h1, 2'h0,afi_sim_rd_address[31:3],1'h0}:64'bx;
assign #1 afi_sim_rd_valid = afi_sim_rd_ready;
assign #1 afi_sim_rd_resp = afi_sim_rd_ready?2'b0:2'bx;
assign #1 afi_sim_wr_ready = afi_sim_wr_valid;
assign #1 afi_sim_bresp_latency=4'h5;
// afi1 (compressor) loopback
assign #1 afi1_sim_wr_ready = afi1_sim_wr_valid;
assign #1 afi1_sim_bresp_latency=4'h5;
// SAXI_GP0 - histograms to system memory
wire SAXI_GP0_CLK;
wire [31:0] saxi_gp0_sim_wr_address; // output[31:0] SuppressThisWarning VEditor - not used - just view
wire [ 5:0] saxi_gp0_sim_wid; // output[5:0] SuppressThisWarning VEditor - not used - just view
wire saxi_gp0_sim_wr_valid; // output
wire saxi_gp0_sim_wr_ready; // input
wire [31:0] saxi_gp0_sim_wr_data; // output[31:0] SuppressThisWarning VEditor - not used - just view
wire [ 3:0] saxi_gp0_sim_wr_stb; // output[3:0] SuppressThisWarning VEditor - not used - just view
wire [ 1:0] saxi_gp0_sim_wr_size; // output[1:0] SuppressThisWarning VEditor - not used - just view
wire [ 3:0] saxi_gp0_sim_bresp_latency; // input[3:0]
wire [ 3:0] saxi_gp0_sim_wr_qos; // output[3:0] SuppressThisWarning VEditor - not used - just view
assign SAXI_GP0_CLK = x393_i.ps7_i.SAXIGP0ACLK;
assign #1 saxi_gp0_sim_wr_ready = saxi_gp0_sim_wr_valid;
assign #1 saxi_gp0_sim_bresp_latency=4'h5;
// axi_hp register access
// PS memory mapped registers to read/write over a separate simulation bus running at HCLK, no waits
reg [31:0] PS_REG_ADDR;
reg PS_REG_WR;
reg PS_REG_RD;
reg PS_REG_WR1;
reg PS_REG_RD1;
reg [31:0] PS_REG_DIN;
wire [31:0] PS_REG_DOUT;
reg [31:0] PS_RDATA; // SuppressThisWarning VEditor - not used - just view
wire [31:0] PS_REG_DOUT1;
/*
reg [31:0] afi_reg_addr;
reg afi_reg_wr;
reg afi_reg_rd;
reg [31:0] afi_reg_din;
wire [31:0] afi_reg_dout;
reg [31:0] AFI_REG_RD; // SuppressThisWarning VEditor - not used - just view
*/
initial begin
PS_REG_ADDR <= 'bx;
PS_REG_WR <= 0;
PS_REG_RD <= 0;
PS_REG_WR1 <= 0;
PS_REG_RD1 <= 0;
PS_REG_DIN <= 'bx;
PS_RDATA <= 'bx;
end
always @ (posedge HCLK) begin
if (PS_REG_RD) PS_RDATA <= PS_REG_DOUT;
else if (PS_REG_RD1) PS_RDATA <= PS_REG_DOUT1;
end
reg [639:0] TEST_TITLE;
// Simulation signals
reg [11:0] ARID_IN_r;
reg [31:0] ARADDR_IN_r;
reg [3:0] ARLEN_IN_r;
reg [1:0] ARSIZE_IN_r;
reg [1:0] ARBURST_IN_r;
reg [11:0] AWID_IN_r;
reg [31:0] AWADDR_IN_r;
reg [3:0] AWLEN_IN_r;
reg [1:0] AWSIZE_IN_r;
reg [1:0] AWBURST_IN_r;
reg [11:0] WID_IN_r;
reg [31:0] WDATA_IN_r;
reg [ 3:0] WSTRB_IN_r;
reg WLAST_IN_r;
reg [11:0] LAST_ARID; // last issued ARID
// SuppressWarnings VEditor : assigned in $readmem() system task
wire [SIMUL_AXI_READ_WIDTH-1:0] SIMUL_AXI_ADDR_W;
// SuppressWarnings VEditor
wire SIMUL_AXI_MISMATCH;
// SuppressWarnings VEditor
reg [31:0] SIMUL_AXI_READ;
// SuppressWarnings VEditor
reg [SIMUL_AXI_READ_WIDTH-1:0] SIMUL_AXI_ADDR;
// SuppressWarnings VEditor
reg SIMUL_AXI_FULL; // some data available
wire SIMUL_AXI_EMPTY= ~rvalid && rready && (rid==LAST_ARID); //SuppressThisWarning VEditor : may be unused, just for simulation // use it to wait for?
reg [31:0] registered_rdata; // here read data from tasks goes
// SuppressWarnings VEditor
reg WAITING_STATUS; // tasks are waiting for status
wire CLK;
reg RST;
reg AR_SET_CMD_r;
wire AR_READY;
reg AW_SET_CMD_r;
wire AW_READY;
reg W_SET_CMD_r;
wire W_READY;
wire [11:0] #(AXI_TASK_HOLD) ARID_IN = ARID_IN_r;
wire [31:0] #(AXI_TASK_HOLD) ARADDR_IN = ARADDR_IN_r;
wire [3:0] #(AXI_TASK_HOLD) ARLEN_IN = ARLEN_IN_r;
wire [1:0] #(AXI_TASK_HOLD) ARSIZE_IN = ARSIZE_IN_r;
wire [1:0] #(AXI_TASK_HOLD) ARBURST_IN = ARBURST_IN_r;
wire [11:0] #(AXI_TASK_HOLD) AWID_IN = AWID_IN_r;
wire [31:0] #(AXI_TASK_HOLD) AWADDR_IN = AWADDR_IN_r;
wire [3:0] #(AXI_TASK_HOLD) AWLEN_IN = AWLEN_IN_r;
wire [1:0] #(AXI_TASK_HOLD) AWSIZE_IN = AWSIZE_IN_r;
wire [1:0] #(AXI_TASK_HOLD) AWBURST_IN = AWBURST_IN_r;
wire [11:0] #(AXI_TASK_HOLD) WID_IN = WID_IN_r;
wire [31:0] #(AXI_TASK_HOLD) WDATA_IN = WDATA_IN_r;
wire [ 3:0] #(AXI_TASK_HOLD) WSTRB_IN = WSTRB_IN_r;
wire #(AXI_TASK_HOLD) WLAST_IN = WLAST_IN_r;
wire #(AXI_TASK_HOLD) AR_SET_CMD = AR_SET_CMD_r;
wire #(AXI_TASK_HOLD) AW_SET_CMD = AW_SET_CMD_r;
wire #(AXI_TASK_HOLD) W_SET_CMD = W_SET_CMD_r;
reg [3:0] RD_LAG; // ready signal lag in axi read channel (0 - RDY=1, 1..15 - RDY is asserted N cycles after valid)
reg [3:0] B_LAG; // ready signal lag in axi arete response channel (0 - RDY=1, 1..15 - RDY is asserted N cycles after valid)
// Simulation modules interconnection
wire [11:0] arid;
wire [31:0] araddr;
wire [3:0] arlen;
wire [1:0] arsize;
wire [1:0] arburst;
// SuppressWarnings VEditor : assigned in $readmem(14) system task
wire [3:0] arcache;
// SuppressWarnings VEditor : assigned in $readmem() system task
wire [2:0] arprot;
wire arvalid;
wire arready;
wire [11:0] awid;
wire [31:0] awaddr;
wire [3:0] awlen;
wire [1:0] awsize;
wire [1:0] awburst;
// SuppressWarnings VEditor : assigned in $readmem() system task
wire [3:0] awcache;
// SuppressWarnings VEditor : assigned in $readmem() system task
wire [2:0] awprot;
wire awvalid;
wire awready;
wire [11:0] wid;
wire [31:0] wdata;
wire [3:0] wstrb;
wire wlast;
wire wvalid;
wire wready;
wire [31:0] rdata;
// SuppressWarnings VEditor : assigned in $readmem() system task
wire [11:0] rid;
wire rlast;
// SuppressWarnings VEditor : assigned in $readmem() system task
wire [1:0] rresp;
wire rvalid;
wire rready;
wire rstb=rvalid && rready;
// SuppressWarnings VEditor : assigned in $readmem() system task
wire [1:0] bresp;
// SuppressWarnings VEditor : assigned in $readmem() system task
wire [11:0] bid;
wire bvalid;
wire bready;
integer NUM_WORDS_READ;
integer NUM_WORDS_EXPECTED;
reg [15:0] ENABLED_CHANNELS = 0; // currently enabled memory channels
// integer SCANLINE_CUR_X;
// integer SCANLINE_CUR_Y;
wire AXI_RD_EMPTY=NUM_WORDS_READ==NUM_WORDS_EXPECTED; //SuppressThisWarning VEditor : may be unused, just for simulation
reg [31:0] DEBUG_DATA;
integer DEBUG_ADDRESS;
//NUM_XFER_BITS=6
// localparam SCANLINE_PAGES_PER_ROW= (WINDOW_WIDTH>>NUM_XFER_BITS)+((WINDOW_WIDTH[NUM_XFER_BITS-1:0]==0)?0:1);
// localparam TILES_PER_ROW= (WINDOW_WIDTH/TILE_WIDTH)+ ((WINDOW_WIDTH % TILE_WIDTH==0)?0:1);
// localparam TILE_ROWS_PER_WINDOW= ((WINDOW_HEIGHT-1)/TILE_VSTEP) + 1;
// localparam TILE_SIZE= TILE_WIDTH*TILE_HEIGHT;
// localparam integer SCANLINE_FULL_XFER= 1<<NUM_XFER_BITS; // 64 - full page transfer in 8-bursts
// localparam integer SCANLINE_LAST_XFER= WINDOW_WIDTH % (1<<NUM_XFER_BITS); // last page transfer size in a row
// integer ii;
// integer SCANLINE_XFER_SIZE;
initial begin
`ifdef IVERILOG
$display("IVERILOG is defined");
`else
$display("IVERILOG is not defined");
`endif
`ifdef ICARUS
$display("ICARUS is defined");
`else
$display("ICARUS is not defined");
`endif
$dumpfile(fstname);
// SuppressWarnings VEditor : assigned in $readmem() system task
$dumpvars(0,x393_testbench02);
// CLK =1'b0;
RST = 1'bx;
AR_SET_CMD_r = 1'b0;
AW_SET_CMD_r = 1'b0;
W_SET_CMD_r = 1'b0;
#500;
// $display ("x393_i.ddrc_sequencer_i.phy_cmd_i.phy_top_i.rst=%d",x393_i.ddrc_sequencer_i.phy_cmd_i.phy_top_i.rst);
#500;
RST = 1'b1;
NUM_WORDS_EXPECTED =0;
// #99000; // same as glbl
#9000; // same as glbl
repeat (20) @(posedge CLK) ;
RST =1'b0;
while (x393_i.mrst) @(posedge CLK) ;
// repeat (4) @(posedge CLK) ;
//set simulation-only parameters
axi_set_b_lag(0); //(1);
axi_set_rd_lag(0);
program_status_all(DEFAULT_STATUS_MODE,'h2a); // mode auto with sequence number increment
enable_memcntrl(1); // enable memory controller
set_up;
axi_set_wbuf_delay(WBUF_DLY_DFLT); //DFLT_WBUF_DELAY - used in synth. code
wait_phase_shifter_ready;
read_all_status; //stuck here
// enable output for address/commands to DDR chip
enable_cmda(1);
repeat (16) @(posedge CLK) ;
// remove reset from DDR chip
activate_sdrst(0); // was enabled at system reset
#5000; // actually 500 usec required
repeat (16) @(posedge CLK) ;
enable_cke(1);
repeat (16) @(posedge CLK) ;
// enable_memcntrl(1); // enable memory controller
enable_memcntrl_channels(16'h0003); // only channel 0 and 1 are enabled
configure_channel_priority(0,0); // lowest priority channel 0
configure_channel_priority(1,0); // lowest priority channel 1
enable_reset_ps_pio(1,0); // enable, no reset
// set MR registers in DDR3 memory, run DCI calibration (long)
wait_ps_pio_ready(DEFAULT_STATUS_MODE, 1); // wait FIFO not half full
schedule_ps_pio ( // schedule software-control memory operation (may need to check FIFO status first)
INITIALIZE_OFFSET, // input [9:0] seq_addr; // sequence start address
0, // input [1:0] page; // buffer page number
0, // input urgent; // high priority request (only for competition with other channels, will not pass in this FIFO)
0, // input chn; // channel buffer to use: 0 - memory read, 1 - memory write
`PS_PIO_WAIT_COMPLETE );// wait_complete; // Do not request a new transaction from the scheduler until previous memory transaction is finished
`ifdef WAIT_MRS
wait_ps_pio_done(DEFAULT_STATUS_MODE, 1);
`else
repeat (32) @(posedge CLK) ; // what delay is needed to be sure? Add to PS_PIO?
// first refreshes will be fast (accummulated while waiting)
`endif
enable_refresh(1);
axi_set_dqs_odelay('h78); //??? dafaults - wrong?
axi_set_dqs_odelay_nominal;
// ====================== Running optional tests ========================
`ifdef TEST_WRITE_LEVELLING
TEST_TITLE = "WRITE_LEVELLING";
$display("===================== TEST_%s =========================",TEST_TITLE);
test_write_levelling;
`endif
`ifdef TEST_READ_PATTERN
TEST_TITLE = "READ_PATTERN";
$display("===================== TEST_%s =========================",TEST_TITLE);
test_read_pattern;
`endif
`ifdef TEST_WRITE_BLOCK
TEST_TITLE = "WRITE_BLOCK";
$display("===================== TEST_%s =========================",TEST_TITLE);
test_write_block;
`endif
`ifdef TEST_READ_BLOCK
TEST_TITLE = "READ_BLOCK";
$display("===================== TEST_%s =========================",TEST_TITLE);
test_read_block;
`endif
`ifdef TESTL_SHORT_SCANLINE
TEST_TITLE = "TESTL_SHORT_SCANLINE";
$display("===================== TEST_%s =========================",TEST_TITLE);
test_scanline_write(
1, // valid: 1 or 3 input [3:0] channel;
SCANLINE_EXTRA_PAGES, // input [1:0] extra_pages;
1, // input wait_done;
1, //WINDOW_WIDTH,
WINDOW_HEIGHT,
WINDOW_X0,
WINDOW_Y0);
test_scanline_read (
1, // valid: 1 or 3 input [3:0] channel;
SCANLINE_EXTRA_PAGES, // input [1:0] extra_pages;
1, // input show_data;
1, // WINDOW_WIDTH,
WINDOW_HEIGHT,
WINDOW_X0,
WINDOW_Y0);
test_scanline_write(
1, // valid: 1 or 3 input [3:0] channel;
SCANLINE_EXTRA_PAGES, // input [1:0] extra_pages;
1, // input wait_done;
2, //WINDOW_WIDTH,
WINDOW_HEIGHT,
WINDOW_X0,
WINDOW_Y0);
test_scanline_read (
1, // valid: 1 or 3 input [3:0] channel;
SCANLINE_EXTRA_PAGES, // input [1:0] extra_pages;
1, // input show_data;
2, // WINDOW_WIDTH,
WINDOW_HEIGHT,
WINDOW_X0,
WINDOW_Y0);
test_scanline_write(
1, // valid: 1 or 3 input [3:0] channel;
SCANLINE_EXTRA_PAGES, // input [1:0] extra_pages;
1, // input wait_done;
3, //WINDOW_WIDTH,
WINDOW_HEIGHT,
WINDOW_X0,
WINDOW_Y0);
test_scanline_read (
1, // valid: 1 or 3 input [3:0] channel;
SCANLINE_EXTRA_PAGES, // input [1:0] extra_pages;
1, // input show_data;
3, // WINDOW_WIDTH,
WINDOW_HEIGHT,
WINDOW_X0,
WINDOW_Y0);
`endif
`ifdef TEST_SCANLINE_WRITE
TEST_TITLE = "SCANLINE_WRITE";
$display("===================== TEST_%s =========================",TEST_TITLE);
test_scanline_write(
3, // valid: 1 or 3 input [3:0] channel; now - 3 only, 1 is for afi
SCANLINE_EXTRA_PAGES, // input [1:0] extra_pages;
1, // input wait_done;
WINDOW_WIDTH,
WINDOW_HEIGHT,
WINDOW_X0,
WINDOW_Y0);
`endif
`ifdef TEST_SCANLINE_READ
TEST_TITLE = "SCANLINE_READ";
$display("===================== TEST_%s =========================",TEST_TITLE);
test_scanline_read (
3, // valid: 1 or 3 input [3:0] channel; now - 3 only, 1 is for afi
SCANLINE_EXTRA_PAGES, // input [1:0] extra_pages;
1, // input show_data;
WINDOW_WIDTH,
WINDOW_HEIGHT,
WINDOW_X0,
WINDOW_Y0);
`endif
`ifdef TEST_TILED_WRITE
TEST_TITLE = "TILED_WRITE";
$display("===================== TEST_%s =========================",TEST_TITLE);
test_tiled_write (
2, // [3:0] channel;
0, // byte32;
TILED_KEEP_OPEN, // keep_open;
TILED_EXTRA_PAGES, // extra_pages;
1, // wait_done;
WINDOW_WIDTH,
WINDOW_HEIGHT,
WINDOW_X0,
WINDOW_Y0,
TILE_WIDTH,
TILE_HEIGHT,
TILE_VSTEP);
`endif
`ifdef TEST_TILED_READ
TEST_TITLE = "TILED_READ";
$display("===================== TEST_%s =========================",TEST_TITLE);
test_tiled_read (
2, // [3:0] channel;
0, // byte32;
TILED_KEEP_OPEN, // keep_open;
TILED_EXTRA_PAGES, // extra_pages;
1, // show_data;
WINDOW_WIDTH,
WINDOW_HEIGHT,
WINDOW_X0,
WINDOW_Y0,
TILE_WIDTH,
TILE_HEIGHT,
TILE_VSTEP);
`endif
`ifdef TEST_TILED_WRITE32
TEST_TITLE = "TILED_WRITE32";
$display("===================== TEST_%s =========================",TEST_TITLE);
test_tiled_write (
2, // 4, // 2, // [3:0] channel;
1, // byte32;
TILED_KEEP_OPEN, // keep_open;
TILED_EXTRA_PAGES, // extra_pages;
1, // wait_done;
WINDOW_WIDTH,
WINDOW_HEIGHT,
WINDOW_X0,
WINDOW_Y0,
TILE_WIDTH,
TILE_HEIGHT,
TILE_VSTEP);
`endif
`ifdef TEST_TILED_READ32
TEST_TITLE = "TILED_READ32";
$display("===================== TEST_%s =========================",TEST_TITLE);
test_tiled_read (
2, // 4, //2, // [3:0] channel;
1, // byte32;
TILED_KEEP_OPEN, // keep_open;
TILED_EXTRA_PAGES, // extra_pages;
1, // show_data;
WINDOW_WIDTH,
WINDOW_HEIGHT,
WINDOW_X0,
WINDOW_Y0,
TILE_WIDTH,
TILE_HEIGHT,
TILE_VSTEP);
`endif
`ifdef TEST_AFI_WRITE
TEST_TITLE = "AFI_WRITE";
$display("===================== TEST_%s =========================",TEST_TITLE);
test_afi_rw (
1, // write_ddr3;
SCANLINE_EXTRA_PAGES,// extra_pages;
0, //FRAME_START_ADDRESS, // input [21:0] frame_start_addr;
FRAME_FULL_WIDTH, // input [15:0] window_full_width; // 13 bit - in 8*16=128 bit bursts
'h81, //'h8b,// WINDOW_WIDTH, // input [15:0] window_width; // 13 bit - in 8*16=128 bit bursts
'h2, // WINDOW_HEIGHT, // input [15:0] window_height; // 16 bit (only 14 are used here)
'h1, //'h0, // WINDOW_X0, // input [15:0] window_left;
'h0, // WINDOW_Y0, // input [15:0] window_top;
0, // input [28:0] start64; // relative start address of the transfer (set to 0 when writing lo_addr64)
AFI_LO_ADDR64, // input [28:0] lo_addr64; // low address of the system memory range, in 64-bit words
AFI_SIZE64, // input [28:0] size64; // size of the system memory range in 64-bit words
0, // input continue; // 0 start from start64, 1 - continue from where it was
0, // disable_need
'h13); //'h3); // cache_mode; // 'h3 - normal, 'h13 - debug
`endif
`ifdef TEST_AFI_READ
TEST_TITLE = "AFI_READ";
$display("===================== TEST_%s =========================",TEST_TITLE);
test_afi_rw (
0, // write_ddr3;
SCANLINE_EXTRA_PAGES,// extra_pages;
0, //FRAME_START_ADDRESS, // input [21:0] frame_start_addr;
FRAME_FULL_WIDTH, // input [15:0] window_full_width; // 13 bit - in 8*16=128 bit bursts
// Try a single-burst write
'h81, // 'h8b, // WINDOW_WIDTH, // input [15:0] window_width; // 13 bit - in 8*16=128 bit bursts
'h2, // WINDOW_HEIGHT, // input [15:0] window_height; // 16 bit (only 14 are used here)
'h1, // 'h0, // WINDOW_X0, // input [15:0] window_left;
'h0, // WINDOW_Y0, // input [15:0] window_top;
0, // input [28:0] start64; // relative start address of the transfer (set to 0 when writing lo_addr64)
AFI_LO_ADDR64, // input [28:0] lo_addr64; // low address of the system memory range, in 64-bit words
AFI_SIZE64, // input [28:0] size64; // size of the system memory range in 64-bit words
0, // input continue; // 0 start from start64, 1 - continue from where it was
0, // disable_need
'h13); //'h3); // cache_mode; // 'h3 - normal, 'h13 - debug
$display("===================== #2 TEST_%s =========================",TEST_TITLE);
test_afi_rw (
0, // write_ddr3;
SCANLINE_EXTRA_PAGES,// extra_pages;
0, //FRAME_START_ADDRESS, // input [21:0] frame_start_addr;
FRAME_FULL_WIDTH, // input [15:0] window_full_width; // 13 bit - in 8*16=128 bit bursts
// Try a single-burst read
'h81, // 'h8b, // WINDOW_WIDTH, // input [15:0] window_width; // 13 bit - in 8*16=128 bit bursts
'h2, // WINDOW_HEIGHT, // input [15:0] window_height; // 16 bit (only 14 are used here)
'h1, // 'h0, // WINDOW_X0, // input [15:0] window_left;
'h0, // WINDOW_Y0, // input [15:0] window_top;
0, // input [28:0] start64; // relative start address of the transfer (set to 0 when writing lo_addr64)
AFI_LO_ADDR64, // input [28:0] lo_addr64; // low address of the system memory range, in 64-bit words
AFI_SIZE64, // input [28:0] size64; // size of the system memory range in 64-bit words
0, // input continue; // 0 start from start64, 1 - continue from where it was
0, // disable_need
'h13); //'h3); // cache_mode; // 'h3 - normal, 'h13 - debug
`endif
`ifdef TEST_SENSOR
`ifdef DEBUG_RING
TEST_TITLE = "DEBUG_STATUS";
$display("===================== TEST_%s =========================",TEST_TITLE);
program_status_debug (
3, // input [1:0] mode;
0); // input [5:0] seq_num;
`endif
TEST_TITLE = "GPIO";
$display("===================== TEST_%s =========================",TEST_TITLE);
program_status_gpio (
3, // input [1:0] mode;
0); // input [5:0] seq_num;
TEST_TITLE = "RTC";
$display("===================== TEST_%s =========================",TEST_TITLE);
program_status_rtc( // also takes snapshot
3, // input [1:0] mode;
0); //input [5:0] seq_num;
set_rtc (
32'h12345678, // input [31:0] sec;
0, //input [19:0] usec;
16'h8000); // input [15:0] corr; maximal correction to the rtc
// camsync_setup (
// 4'hf ); // sensor_mask); //
TEST_TITLE = "RESEST_I2C_SEQUENCER0";
$display("===================== TEST_%s =========================",TEST_TITLE);
set_sensor_i2c_command(
0, // input [1:0] num_sensor;
1'b1, // input rst_cmd; // [14] reset all FIFO (takes 16 clock pulses), also - stops i2c until run command
2'b0, // input [SENSI2C_CMD_RUN_PBITS : 0] run_cmd; // [13:12]3 - run i2c, 2 - stop i2c (needed before software i2c), 1,0 - no change to run state
1'b1, // input set_active;
1'b1, // input active_sda;
1'b1); // input early_release_0;
set_sensor_i2c_table_reg_wr(
0, // input [1:0] num_sensor;
8'h90, // input [7:0] page; // set parameters for 32-bit command with this MSB
7'h48, // input [6:0] slave_addr; // 7-bit slave address
8'h0, // input [7:0] rah; // register address high byte
4'h3, // input [3:0] num_bytes; // number of bytes to send
8'h4); // input [7:0] bit_delay;
set_sensor_i2c_table_reg_rd(
0, // input [1:0] num_sensor;
8'h91, // input [7:0] page; // set parameters for 32-bit command with this MSB
1'b0, // input num_bytes_addr; // number of address bytes (0 - 1, 1 - 2)
3'h2, // input [2:0] num_bytes_rd; // number of bytes to read, with "0" meaning all 8
8'h5); // input [7:0] bit_delay;
TEST_TITLE = "RESEST_I2C_SEQUENCER1";
$display("===================== TEST_%s =========================",TEST_TITLE);
set_sensor_i2c_command(
1, // input [1:0] num_sensor;
1'b1, // input rst_cmd; // [14] reset all FIFO (takes 16 clock pulses), also - stops i2c until run command
2'b0, // input [SENSI2C_CMD_RUN_PBITS : 0] run_cmd; // [13:12]3 - run i2c, 2 - stop i2c (needed before software i2c), 1,0 - no change to run state
1'b1, // input set_active;
1'b0, // input active_sda;
1'b1); // input early_release_0;
set_sensor_i2c_table_reg_wr(
1, // input [1:0] num_sensor;
8'h90, // input [7:0] page; // set parameters for 32-bit command with this MSB
7'h48, // input [6:0] slave_addr; // 7-bit slave address
8'h12, // input [7:0] rah; // register address high byte
4'ha, // input [3:0] num_bytes; // number of bytes to send
8'h4); // input [7:0] bit_delay;
set_sensor_i2c_table_reg_rd(
1, // input [1:0] num_sensor;
8'h91, // input [7:0] page; // set parameters for 32-bit command with this MSB
1'b1, // input num_bytes_addr; // number of address bytes (0 - 1, 1 - 2)