pluto_hdl_adi/projects/daq1/cpld/daq1_cpld.v

290 lines
8.5 KiB
Verilog

// ***************************************************************************
// ***************************************************************************
// 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
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// 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.
//
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// 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 daq1_cpld (
// FMC SPI interface
fmc_spi_sclk,
fmc_spi_csn,
fmc_spi_sdio,
fmc_irq,
// on board SPI interface
adc_spicsn,
dac_spicsn,
clk_spicsn,
sclk,
sdio,
// control and status lines
adc_fda,
adc_fdb,
adc_status_p,
adc_status_n,
adc_pwdn_stby,
dac_irqn,
dac_resetn,
clk_status1,
clk_status2,
clk_pwdnn,
clk_syncn,
clk_resetn
);
input fmc_spi_csn;
input fmc_spi_sclk;
inout fmc_spi_sdio;
output fmc_irq;
output adc_spicsn;
output dac_spicsn;
output clk_spicsn;
output sclk;
inout sdio;
// control and status lines
input adc_fda;
input adc_fdb;
input adc_status_p;
input adc_status_n;
output adc_pwdn_stby;
input dac_irqn;
output dac_resetn;
input clk_status1;
input clk_status2;
output clk_pwdnn;
output clk_syncn;
output clk_resetn;
// FMC SPI Selects
localparam [ 7:0] FMC_SPI_SEL_AD9684 = 8'h80;
localparam [ 7:0] FMC_SPI_SEL_AD9122 = 8'h81;
localparam [ 7:0] FMC_SPI_SEL_AD9523 = 8'h82;
localparam [ 7:0] FMC_SPI_SEL_CPLD = 8'h83;
// CPLD Register Map Addresses
localparam [ 6:0] CPLD_VERSION_ADDR = 7'h00;
localparam [ 6:0] ADC_CONTROL_ADDR = 7'h10;
localparam [ 6:0] DAC_CONTROL_ADDR = 7'h11;
localparam [ 6:0] CLK_CONTROL_ADDR = 7'h12;
localparam [ 6:0] IRQ_MASK_ADDR = 7'h13;
localparam [ 6:0] ADC_STATUS_ADDR = 7'h20;
localparam [ 6:0] DAC_STATUS_ADDR = 7'h21;
localparam [ 6:0] CLK_STATUS_ADDR = 7'h22;
localparam [ 7:0] CPLD_VERSION = 8'h11;
// Internal Registers/Signals
reg [ 7:0] fmc_spi_dev_sel = 8'b0;
reg [ 7:0] fmc_cpld_addr = 8'b0;
reg [ 5:0] fmc_spi_counter = 6'b0;
reg fmc_spi_csn_enb = 1'b1;
reg [ 7:0] adc_control = 8'b0;
reg [ 7:0] dac_control = 8'b0;
reg [ 7:0] clk_control = 8'b0;
reg [ 7:0] adc_status = 8'b0;
reg [ 7:0] dac_status = 8'b0;
reg [ 7:0] clk_status = 8'b0;
reg cpld_to_fpga = 1'b0;
reg [ 7:0] cpld_rdata = 8'b0;
reg cpld_rdata_bit = 1'b0;
reg [ 2:0] cpld_rdata_index = 3'h0;
reg [ 7:0] cpld_wdata = 8'b0;
reg [ 7:0] cpld_irq_mask = 8'b0;
reg [ 7:0] cpld_irq = 8'b0;
wire rdnwr;
wire cpld_rdata_s;
// SCLK counter for control signals
always @(posedge fmc_spi_sclk or posedge fmc_spi_csn) begin
if (fmc_spi_csn == 1'b1) begin
fmc_spi_dev_sel <= 8'h0;
fmc_cpld_addr <= 8'h0;
end else begin
if (fmc_spi_counter <= 7) begin
fmc_spi_dev_sel <= {fmc_spi_dev_sel[6:0], fmc_spi_sdio};
end
if (fmc_spi_counter <= 15) begin
fmc_cpld_addr <= {fmc_cpld_addr[6:0], fmc_spi_sdio};
end
end
end
// chip select control
assign adc_spicsn = (fmc_spi_dev_sel == FMC_SPI_SEL_AD9684) ? (fmc_spi_csn | fmc_spi_csn_enb) : 1'b1;
assign dac_spicsn = (fmc_spi_dev_sel == FMC_SPI_SEL_AD9122) ? (fmc_spi_csn | fmc_spi_csn_enb) : 1'b1;
assign clk_spicsn = (fmc_spi_dev_sel == FMC_SPI_SEL_AD9523) ? (fmc_spi_csn | fmc_spi_csn_enb) : 1'b1;
assign cpld_spicsn = (fmc_spi_dev_sel == FMC_SPI_SEL_CPLD) ? (fmc_spi_csn | fmc_spi_csn_enb) : 1'b1;
// SPI control and data
assign sdio = cpld_to_fpga ? 1'bZ : fmc_spi_sdio;
assign fmc_spi_sdio = cpld_to_fpga ? cpld_rdata_s : 1'bZ ;
assign cpld_rdata_s = cpld_spicsn ? sdio : cpld_rdata_bit;
assign rdnwr = fmc_cpld_addr[7];
assign sclk = (~(fmc_spi_csn | fmc_spi_csn_enb)) ? fmc_spi_sclk : 1'b0;
always @(negedge fmc_spi_sclk or posedge fmc_spi_csn) begin
if (fmc_spi_csn == 1'b1) begin
fmc_spi_counter <= 6'h0;
cpld_to_fpga <= 1'b0;
fmc_spi_csn_enb <= 1'b1;
end else begin
fmc_spi_counter <= fmc_spi_counter + 1;
fmc_spi_csn_enb <= (fmc_spi_counter < 7) ? 1'b1 : 1'b0;
if (adc_spicsn & clk_spicsn) begin
cpld_to_fpga <= (fmc_spi_counter >= 15) ? rdnwr : 1'b0;
end else begin
cpld_to_fpga <= (fmc_spi_counter >= 23) ? rdnwr : 1'b0;
end
end
end
// Internal register read access
always @(fmc_cpld_addr) begin
case (fmc_cpld_addr[6:0])
CPLD_VERSION_ADDR :
cpld_rdata <= CPLD_VERSION;
ADC_CONTROL_ADDR :
cpld_rdata <= adc_pwdn_stby;
DAC_CONTROL_ADDR :
cpld_rdata <= dac_resetn;
CLK_CONTROL_ADDR :
cpld_rdata <= {clk_syncn, clk_resetn, clk_pwdnn};
IRQ_MASK_ADDR:
cpld_rdata <= cpld_irq_mask;
ADC_STATUS_ADDR :
cpld_rdata <= {adc_status_p, adc_fdb, adc_fda};
DAC_STATUS_ADDR :
cpld_rdata <= dac_irqn;
CLK_STATUS_ADDR :
cpld_rdata <= {clk_status2, clk_status1};
default:
cpld_rdata <= 8'hFA;
endcase
end
always @(negedge fmc_spi_sclk or posedge fmc_spi_csn) begin
if (fmc_spi_csn == 1'b1) begin
cpld_rdata_bit <= 1'b0;
cpld_rdata_index <= 3'h7;
end else begin
if (cpld_to_fpga == 1'b1) begin
cpld_rdata_bit <= cpld_rdata[cpld_rdata_index];
cpld_rdata_index <= cpld_rdata_index - 1;
end
end
end
// Internal register write access
always @(cpld_to_fpga, cpld_spicsn, fmc_spi_counter) begin
if ((cpld_to_fpga == 1'b0) &&
(cpld_spicsn == 1'b0) &&
(fmc_spi_counter == 8'h18)) begin
case (fmc_cpld_addr[6:0])
ADC_CONTROL_ADDR :
adc_control <= cpld_wdata;
DAC_CONTROL_ADDR :
dac_control <= cpld_wdata;
CLK_CONTROL_ADDR :
clk_control <= cpld_wdata;
IRQ_MASK_ADDR:
cpld_irq_mask <= cpld_wdata;
endcase
end
end
always @(posedge fmc_spi_sclk or posedge fmc_spi_csn) begin
if (fmc_spi_csn == 1'b1) begin
cpld_wdata <= 8'h0;
end else begin
if (fmc_spi_counter >= 16) begin
cpld_wdata <= {cpld_wdata[6:0], fmc_spi_sdio};
end
end
end
// input/output logic
// AD9648
assign adc_pwdn_stby = adc_control[0];
// AD9122
assign dac_resetn = dac_control[0];
// AD9523-1
assign clk_pwdnn = clk_control[0];
assign clk_resetn = clk_control[1];
assign clk_syncn = clk_control[2];
// interrupt logic
always @(*) begin
cpld_irq <= {2'b00, dac_irqn, clk_status2, clk_status1, adc_status_p, adc_fdb, adc_fda};
end
assign fmc_irq = |(~cpld_irq_mask & cpld_irq);
endmodule