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joppe:new_structure joppe:master joppe:jtagram joppe:remotesyn

4 Commits
ac6aea90b6 ... jtagram

Author SHA1 Message Date
Joppe Blondel
9322766cef vibed jtagram with script as drop in replacement of serving_ram 2026-02-22 21:27:40 +01:00
Joppe Blondel
20cfece6e3 Added soclet with gpio banks to top 2026-02-22 20:00:42 +01:00
Joppe Blondel
a97028c2ba cleanup 2026-02-22 18:49:03 +01:00
Joppe Blondel
5e951f9b61 Working SERV cpu 2026-02-22 18:48:17 +01:00
40 changed files with 1266 additions and 309 deletions
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3
boards/mimas_v1/constraints.ucf
View File

@@ -2,9 +2,6 @@
NET "aclk" LOC = P126;
NET "aclk" TNM_NET = "SYS_CLK_PIN";
TIMESPEC TS_SYS_CLK_PIN = PERIOD "SYS_CLK_PIN" 10 ns HIGH 50 %;
# Generated clocks
NET "clk_15" TNM_NET = "SYS_CLK_15";
TIMESPEC TS_SYS_CLK_15 = PERIOD "SYS_CLK_15" 13.334 ns HIGH 50%;
# Boards button row
NET "aresetn" LOC = P120;

54
project.cfg
View File

@@ -4,23 +4,17 @@ version = 0.1
out_dir = out
build_dir = build
[server]
hostname = localhost
port = 2020
privkey = /home/joppe/.ssh/id_rsa
pubkey = /home/joppe/.ssh/id_rsa.pub
[target.synth]
toolchain = ISE
ise_settings = /opt/Xilinx/14.7/ISE_DS/settings64.sh
# Toolchain settings
family = spartan6
device = xc6slx9
package = tqg144
speedgrade = -2
toplevel = top_generic
xst_opts = -vlgincdir rtl/util
files_verilog = rtl/toplevel/top_generic.v
files_verilog = rtl/util/conv.vh
rtl/toplevel/top_generic.v
rtl/core/nco_q15.v
rtl/core/sigmadelta_sampler.v
rtl/core/sigmadelta_rcmodel_q15.v
@@ -30,31 +24,6 @@ files_verilog = rtl/toplevel/top_generic.v
rtl/core/decimate_by_r_q15.v
rtl/arch/spartan-6/lvds_comparator.v
rtl/arch/spartan-6/clk_gen.v
files_con = boards/mimas_v1/constraints.ucf
files_other = rtl/util/conv.vh
rtl/util/rc_alpha_q15.vh
[target.ip]
toolchain = ISE_IP
family = spartan6
device = xc6slx9
package = tqg144
speedgrade = -2
files_xco = boards/mimas_v1/ip/clk_gen.xco
[target.serv]
toolchain = ISE
ise_settings = /opt/Xilinx/14.7/ISE_DS/settings64.sh
family = spartan6
device = xc6slx9
package = tqg144
speedgrade = -2
toplevel = top_generic
xst_opts = -vlgincdir rtl
files_con = boards/mimas_v1/constraints.ucf
files_other = sw/blinky/blinky.hex
files_verilog = rtl/util/clog2.vh
rtl/serv/serv_aligner.v
rtl/serv/serv_alu.v
rtl/serv/serv_bufreg.v
@@ -78,10 +47,23 @@ files_verilog = rtl/util/clog2.vh
rtl/serv/servile_rf_mem_if.v
rtl/serv/servile.v
rtl/serv/serving_ram.v
# sim/overrides/serving_ram.v
rtl/serv/serving.v
rtl/wb/wb_gpio.v
rtl/toplevel/top_serv.v
rtl/wb/wb_gpio_banks.v
rtl/core/soclet.v
files_con = boards/mimas_v1/constraints.ucf
files_other = rtl/util/rc_alpha_q15.vh
rtl/util/clog2.vh
sw/blinky/blinky.hex
[target.ip]
toolchain = ISE_IP
ise_settings = /opt/Xilinx/14.7/ISE_DS/settings64.sh
family = spartan6
device = xc6slx9
package = tqg144
speedgrade = -2
files_def = boards/mimas_v1/ip/clk_gen.xco
[target.sim]
toolchain = iverilog
@@ -101,4 +83,4 @@ files_verilog = sim/tb/tb_nco_q15.v
sim/overrides/sigmadelta_sampler.v
sim/overrides/clk_gen.v
files_other = rtl/util/conv.vh
rtl/util/rc_alpha_q15.vh
rtl/util/rc_alpha_q15.vh

6
rtl/arch/spartan-6/clk_gen.v
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@@ -67,9 +67,9 @@
(* CORE_GENERATION_INFO = "clk_gen,clk_wiz_v3_6,{component_name=clk_gen,use_phase_alignment=true,use_min_o_jitter=false,use_max_i_jitter=false,use_dyn_phase_shift=false,use_inclk_switchover=false,use_dyn_reconfig=false,feedback_source=FDBK_AUTO,primtype_sel=DCM_SP,num_out_clk=1,clkin1_period=10.0,clkin2_period=10.0,use_power_down=false,use_reset=false,use_locked=false,use_inclk_stopped=false,use_status=false,use_freeze=false,use_clk_valid=false,feedback_type=SINGLE,clock_mgr_type=AUTO,manual_override=false}" *)
module clk_gen
(// Clock in ports
input clk_in,
input wire clk_in,
// Clock out ports
output clk_out_15
output wire clk_out_15
);
// Input buffering
@@ -78,6 +78,7 @@ module clk_gen
// (.O (clkin1),
// .I (clk_in));
wire clkin1;
assign clkin1 = clk_in;
// Clocking primitive
@@ -145,4 +146,3 @@ module clk_gen
endmodule

49
rtl/arch/spartan-6/jtag_tap_spartan6.v Normal file
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@@ -0,0 +1,49 @@
`default_nettype none
// Spartan-6 JTAG TAP wrapper with an architecture-neutral interface.
// Re-implement this module for other FPGA families with the same port list.
module jtag_tap_spartan6
#(parameter USER_CHAIN = 1)
(
output wire o_drck,
output wire o_capture,
output wire o_shift,
output wire o_update,
output wire o_reset,
output wire o_sel,
output wire o_tdi,
input wire i_tdo
);
wire drck1;
wire drck2;
wire sel1;
wire sel2;
wire tdo1;
wire tdo2;
localparam USE_CHAIN2 = (USER_CHAIN == 2);
assign o_drck = USE_CHAIN2 ? drck2 : drck1;
assign o_sel = USE_CHAIN2 ? sel2 : sel1;
assign tdo1 = USE_CHAIN2 ? 1'b0 : i_tdo;
assign tdo2 = USE_CHAIN2 ? i_tdo : 1'b0;
BSCAN_SPARTAN6
#(.JTAG_CHAIN(USER_CHAIN))
bscan_spartan6
(
.CAPTURE(o_capture),
.DRCK1(drck1),
.DRCK2(drck2),
.RESET(o_reset),
.SEL1(sel1),
.SEL2(sel2),
.SHIFT(o_shift),
.TDI(o_tdi),
.UPDATE(o_update),
.TDO1(tdo1),
.TDO2(tdo2)
);
endmodule

77
rtl/core/soclet.v Normal file
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@@ -0,0 +1,77 @@
`timescale 1ns/1ps
module soclet #(
parameter memfile = "",
parameter memsize = 8192,
parameter sim = 1'b0
)(
input wire i_clk,
input wire i_rst,
input wire [31:0] i_GPI_A,
input wire [31:0] i_GPI_B,
input wire [31:0] i_GPI_C,
input wire [31:0] i_GPI_D,
output wire [31:0] o_GPO_A,
output wire [31:0] o_GPO_B,
output wire [31:0] o_GPO_C,
output wire [31:0] o_GPO_D
);
wire [31:0] wb_adr;
wire [31:0] wb_dat;
wire [31:0] wb_rdt;
wire [3:0] wb_sel;
wire wb_we;
wire wb_stb;
wire wb_ack;
wire [4*32-1:0] GPO;
wire [4*32-1:0] GPI;
assign o_GPO_A = GPO[32*1-1:32*0];
assign o_GPO_B = GPO[32*2-1:32*1];
assign o_GPO_C = GPO[32*3-1:32*2];
assign o_GPO_D = GPO[32*4-1:32*3];
assign GPI[32*1-1:32*0] = i_GPI_A;
assign GPI[32*2-1:32*1] = i_GPI_B;
assign GPI[32*3-1:32*2] = i_GPI_C;
assign GPI[32*4-1:32*3] = i_GPI_D;
serving #(
.memfile(memfile),
.memsize(memsize),
.sim(sim),
.RESET_STRATEGY("MINI"),
.WITH_CSR(1)
) serv (
.i_clk(i_clk),
.i_rst(i_rst),
.i_timer_irq(1'b0),
.i_wb_rdt(wb_rdt),
.i_wb_ack(wb_ack),
.o_wb_adr(wb_adr),
.o_wb_dat(wb_dat),
.o_wb_sel(wb_sel),
.o_wb_we(wb_we),
.o_wb_stb(wb_stb)
);
wb_gpio_banks #(
.BASE_ADDR(32'h40000000),
.NUM_BANKS(4)
) gpio (
.i_wb_clk(i_clk),
.i_wb_rst(i_rst),
.i_wb_dat(wb_dat),
.i_wb_adr(wb_adr),
.i_wb_we(wb_we),
.i_wb_stb(wb_stb),
.i_wb_sel(wb_sel),
.i_gpio(GPI),
.o_wb_rdt(wb_rdt),
.o_wb_ack(wb_ack),
.o_gpio(GPO)
);
endmodule

9
rtl/serv/serv_rf_ram.v
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@@ -4,15 +4,16 @@
* SPDX-FileCopyrightText: 2019 Olof Kindgren <olof@award-winning.me>
* SPDX-License-Identifier: ISC
*/
`include "../util/clog2.vh"
module serv_rf_ram
#(parameter width=0,
parameter csr_regs=4,
parameter depth=32*(32+csr_regs)/width)
(input wire i_clk,
input wire [$clog2(depth)-1:0] i_waddr,
input wire [`CLOG2(depth)-1:0] i_waddr,
input wire [width-1:0] i_wdata,
input wire i_wen,
input wire [$clog2(depth)-1:0] i_raddr,
input wire [`CLOG2(depth)-1:0] i_raddr,
input wire i_ren,
output wire [width-1:0] o_rdata);
@@ -28,7 +29,7 @@ module serv_rf_ram
/* Reads from reg x0 needs to return 0
Check that the part of the read address corresponding to the register
is zero and gate the output
width LSB of reg index $clog2(width)
width LSB of reg index `CLOG2(width)
2 4 1
4 3 2
8 2 3
@@ -38,7 +39,7 @@ module serv_rf_ram
reg regzero;
always @(posedge i_clk)
regzero <= !(|i_raddr[$clog2(depth)-1:5-$clog2(width)]);
regzero <= !(|i_raddr[`CLOG2(depth)-1:5-`CLOG2(width)]);
assign o_rdata = rdata & ~{width{regzero}};

10
rtl/serv/serv_rf_ram_if.v
View File

@@ -5,7 +5,7 @@
* SPDX-License-Identifier: ISC
*/
`default_nettype none
// `include "../util/clog2.vh"
`include "../util/clog2.vh"
module serv_rf_ram_if
#(//Data width. Adjust to preferred width of SRAM data interface
parameter width=8,
@@ -22,8 +22,8 @@ module serv_rf_ram_if
//Internal parameters calculated from above values. Do not change
parameter B=W-1,
parameter raw=clog2(32+csr_regs), //Register address width
parameter l2w=clog2(width), //log2 of width
parameter raw=`CLOG2(32+csr_regs), //Register address width
parameter l2w=`CLOG2(width), //log2 of width
parameter aw=5+raw-l2w) //Address width
(
//SERV side
@@ -51,8 +51,8 @@ module serv_rf_ram_if
input wire [width-1:0] i_rdata);
localparam ratio = width/W;
localparam CMSB = 4-clog2(W); //Counter MSB
localparam l2r = clog2(ratio);
localparam CMSB = 4-`CLOG2(W); //Counter MSB
localparam l2r = `CLOG2(ratio);
reg rgnt;
assign o_ready = rgnt | i_wreq;

3
rtl/serv/serv_rf_top.v
View File

@@ -5,6 +5,7 @@
* SPDX-License-Identifier: ISC
*/
`default_nettype none
`include "../util/clog2.vh"
module serv_rf_top
#(parameter RESET_PC = 32'd0,
@@ -37,7 +38,7 @@ module serv_rf_top
parameter WITH_CSR = 1,
parameter W = 1,
parameter RF_WIDTH = W * 2,
parameter RF_L2D = $clog2((32+(WITH_CSR*4))*32/RF_WIDTH))
parameter RF_L2D = `CLOG2((32+(WITH_CSR*4))*32/RF_WIDTH))
(
input wire clk,
input wire i_rst,

3
rtl/serv/serv_synth_wrapper.v
View File

@@ -5,6 +5,7 @@
* SPDX-License-Identifier: ISC
*/
`default_nettype none
`include "../util/clog2.vh"
module serv_synth_wrapper
#(
@@ -22,7 +23,7 @@ module serv_synth_wrapper
parameter RESET_STRATEGY = "MINI",
parameter WITH_CSR = 1,
parameter RF_WIDTH = 2,
parameter RF_L2D = $clog2((32+(WITH_CSR*4))*32/RF_WIDTH))
parameter RF_L2D = `CLOG2((32+(WITH_CSR*4))*32/RF_WIDTH))
(
input wire clk,
input wire i_rst,

11
rtl/serv/servile.v
View File

@@ -6,6 +6,7 @@
*/
`default_nettype none
`include "../util/clog2.vh"
module servile
#(
parameter width = 1,
@@ -20,7 +21,7 @@ module servile
//Internally calculated. Do not touch
parameter B = width-1,
parameter regs = 32+with_csr*4,
parameter rf_l2d = $clog2(regs*32/rf_width))
parameter rf_l2d = `CLOG2(regs*32/rf_width))
(
input wire i_clk,
input wire i_rst,
@@ -77,14 +78,14 @@ module servile
wire rf_wreq;
wire rf_rreq;
wire [$clog2(regs)-1:0] wreg0;
wire [$clog2(regs)-1:0] wreg1;
wire [`CLOG2(regs)-1:0] wreg0;
wire [`CLOG2(regs)-1:0] wreg1;
wire wen0;
wire wen1;
wire [B:0] wdata0;
wire [B:0] wdata1;
wire [$clog2(regs)-1:0] rreg0;
wire [$clog2(regs)-1:0] rreg1;
wire [`CLOG2(regs)-1:0] rreg0;
wire [`CLOG2(regs)-1:0] rreg1;
wire rf_ready;
wire [B:0] rdata0;
wire [B:0] rdata1;

5
rtl/serv/servile_rf_mem_if.v
View File

@@ -6,14 +6,15 @@
*/
`default_nettype none
`include "../util/clog2.vh"
module servile_rf_mem_if
#(//Memory parameters
parameter depth = 256,
//RF parameters
parameter rf_regs = 32,
//Internally calculated. Do not touch
parameter rf_depth = $clog2(rf_regs*4),
parameter aw = $clog2(depth))
parameter rf_depth = `CLOG2(rf_regs*4),
parameter aw = `CLOG2(depth))
(
input wire i_clk,
input wire i_rst,

10
rtl/serv/serving.v
View File

@@ -18,6 +18,7 @@
*/
`default_nettype none
`include "../util/clog2.vh"
module serving
(
input wire i_clk,
@@ -56,16 +57,17 @@ module serving
wire [rf_width-1:0] rf_rdata;
wire rf_ren;
wire [$clog2(memsize)-1:0] sram_waddr;
wire [`CLOG2(memsize)-1:0] sram_waddr;
wire [rf_width-1:0] sram_wdata;
wire sram_wen;
wire [$clog2(memsize)-1:0] sram_raddr;
wire [`CLOG2(memsize)-1:0] sram_raddr;
wire [rf_width-1:0] sram_rdata;
wire sram_ren;
serving_ram
#(.memfile (memfile),
.depth (memsize))
.depth (memsize),
.sim (sim))
ram
(// Wishbone interface
.i_clk (i_clk),
@@ -98,7 +100,7 @@ module serving
.i_sram_rdata (sram_rdata),
.o_sram_ren (sram_ren),
.i_wb_adr (wb_mem_adr[$clog2(memsize)-1:2]),
.i_wb_adr (wb_mem_adr[`CLOG2(memsize)-1:2]),
.i_wb_stb (wb_mem_stb),
.i_wb_we (wb_mem_we) ,
.i_wb_sel (wb_mem_sel),

45
rtl/serv/serving_ram.v
View File

@@ -18,28 +18,37 @@
*/
`default_nettype none
`include "../util/clog2.vh"
module serving_ram
#(//Memory parameters
parameter depth = 256,
parameter aw = $clog2(depth),
parameter memfile = "")
parameter depth = 256,
parameter aw = `CLOG2(depth),
parameter memfile = "",
parameter sim = 1'b0)
(input wire i_clk,
input wire [aw-1:0] i_waddr,
input wire [7:0] i_wdata,
input wire i_wen,
input wire [aw-1:0] i_raddr,
output reg [7:0] o_rdata);
input wire [aw-1:0] i_waddr,
input wire [7:0] i_wdata,
input wire i_wen,
input wire [aw-1:0] i_raddr,
output reg [7:0] o_rdata);
reg [7:0] mem [0:depth-1] /* verilator public */;
reg [7:0] mem [0:depth-1] /* verilator public */;
always @(posedge i_clk) begin
if (i_wen) mem[i_waddr] <= i_wdata;
o_rdata <= mem[i_raddr];
always @(posedge i_clk) begin
if (i_wen) mem[i_waddr] <= i_wdata;
o_rdata <= mem[i_raddr];
end
integer i;
initial begin
if(sim==1'b1) begin
for (i = 0; i < depth; i = i + 1)
mem[i] = 8'h00;
end
if(|memfile) begin
$display("Preloading %m from %s", memfile);
$readmemh(memfile, mem);
end
end
initial
if(|memfile) begin
$display("Preloading %m from %s", memfile);
$readmemh(memfile, mem);
end
endmodule

54
rtl/serv/serving_ram_dp.v Normal file
View File

@@ -0,0 +1,54 @@
`default_nettype none
`include "../util/clog2.vh"
module serving_ram_dp
#(// Memory parameters
parameter depth = 256,
parameter aw = `CLOG2(depth),
parameter memfile = "",
parameter sim = 1'b0)
(
// CPU port (compatible with serving_ram)
input wire i_clk,
input wire [aw-1:0] i_waddr,
input wire [7:0] i_wdata,
input wire i_wen,
input wire [aw-1:0] i_raddr,
output reg [7:0] o_rdata,
// Debug/programming port
input wire i_dbg_clk,
input wire [aw-1:0] i_dbg_addr,
input wire [7:0] i_dbg_wdata,
input wire i_dbg_wen,
output wire [7:0] o_dbg_rdata
);
reg [7:0] mem [0:depth-1] /* verilator public */;
always @(posedge i_clk) begin
if (i_wen)
mem[i_waddr] <= i_wdata;
o_rdata <= mem[i_raddr];
end
always @(posedge i_dbg_clk) begin
if (i_dbg_wen)
mem[i_dbg_addr] <= i_dbg_wdata;
end
// Asynchronous debug read simplifies JTAG readback logic.
assign o_dbg_rdata = mem[i_dbg_addr];
integer i;
initial begin
if (sim == 1'b1) begin
for (i = 0; i < depth; i = i + 1)
mem[i] = 8'h00;
end
if (|memfile) begin
$display("Preloading %m from %s", memfile);
$readmemh(memfile, mem);
end
end
endmodule

65
rtl/serv/serving_ram_jtag.v Normal file
View File

@@ -0,0 +1,65 @@
`default_nettype none
`include "../util/clog2.vh"
// Drop-in serving RAM variant with USER JTAG programming access.
module serving_ram_jtag
#(
parameter depth = 256,
parameter aw = `CLOG2(depth),
parameter memfile = "",
parameter sim = 1'b0,
parameter USER_CHAIN = 1
)
(
input wire i_clk,
input wire [aw-1:0] i_waddr,
input wire [7:0] i_wdata,
input wire i_wen,
input wire [aw-1:0] i_raddr,
output wire [7:0] o_rdata
);
wire dbg_clk;
wire [aw-1:0] dbg_addr;
wire [7:0] dbg_wdata;
wire dbg_wen;
wire [7:0] dbg_rdata;
serving_ram_dp
#(
.depth(depth),
.aw(aw),
.memfile(memfile),
.sim(sim)
)
i_serving_ram_dp
(
.i_clk(i_clk),
.i_waddr(i_waddr),
.i_wdata(i_wdata),
.i_wen(i_wen),
.i_raddr(i_raddr),
.o_rdata(o_rdata),
.i_dbg_clk(dbg_clk),
.i_dbg_addr(dbg_addr),
.i_dbg_wdata(dbg_wdata),
.i_dbg_wen(dbg_wen),
.o_dbg_rdata(dbg_rdata)
);
serving_ram_jtag_bridge
#(
.depth(depth),
.aw(aw),
.USER_CHAIN(USER_CHAIN)
)
i_serving_ram_jtag_bridge
(
.o_ram_clk(dbg_clk),
.o_ram_addr(dbg_addr),
.o_ram_wdata(dbg_wdata),
.o_ram_wen(dbg_wen),
.i_ram_rdata(dbg_rdata)
);
endmodule

107
rtl/serv/serving_ram_jtag_bridge.v Normal file
View File

@@ -0,0 +1,107 @@
`default_nettype none
`include "../util/clog2.vh"
// Simple USER JTAG data-register protocol (LSB-first):
// bit[0] : write_enable (1=write, 0=read/select)
// bit[32:1] : 32-bit address
// bit[40:33] : write data
//
// On UPDATE:
// - write command: writes byte to RAM
// - read command : updates current read address for next CAPTURE/SHIFT readback
// - RAM uses the lower aw address bits from the 32-bit protocol address
//
// On CAPTURE, readback register loads:
// bit[0] : valid (always 1)
// bit[8:1] : read data at current read address
// remaining bits : zero
module serving_ram_jtag_bridge
#(
parameter depth = 256,
parameter aw = `CLOG2(depth),
parameter USER_CHAIN = 1
)
(
output wire o_ram_clk,
output wire [aw-1:0] o_ram_addr,
output wire [7:0] o_ram_wdata,
output wire o_ram_wen,
input wire [7:0] i_ram_rdata
);
localparam integer JTAG_AW = 32;
localparam integer FRAME_W = 1 + JTAG_AW + 8;
localparam integer PAD_W = FRAME_W - 9;
wire tap_drck;
wire tap_shift;
wire tap_update;
wire tap_reset;
wire tap_sel;
wire tap_tdi;
wire tap_tdo;
reg [FRAME_W-1:0] shift_in;
reg [FRAME_W-1:0] shift_out;
reg [aw-1:0] read_addr;
reg shift_active_d;
wire cmd_write;
wire [JTAG_AW-1:0] cmd_addr;
wire [aw-1:0] cmd_addr_ram;
wire [7:0] cmd_wdata;
assign cmd_write = shift_in[0];
assign cmd_addr = shift_in[JTAG_AW:1];
assign cmd_wdata = shift_in[JTAG_AW+8:JTAG_AW+1];
assign cmd_addr_ram = cmd_addr[aw-1:0];
// Update command shift register and shift response out on DRCK.
// Readback data is loaded on the first shift pulse of a DR scan.
always @(posedge tap_drck or posedge tap_reset) begin
if (tap_reset) begin
shift_in <= {FRAME_W{1'b0}};
shift_out <= {FRAME_W{1'b0}};
shift_active_d <= 1'b0;
end else if (tap_sel && tap_shift) begin
if (!shift_active_d)
shift_out <= {{PAD_W{1'b0}}, i_ram_rdata, 1'b1};
else
shift_out <= {1'b0, shift_out[FRAME_W-1:1]};
shift_in <= {tap_tdi, shift_in[FRAME_W-1:1]};
shift_active_d <= 1'b1;
end else begin
shift_active_d <= 1'b0;
end
end
// Read command selects the address for the next capture.
always @(posedge tap_update or posedge tap_reset) begin
if (tap_reset)
read_addr <= {aw{1'b0}};
else if (tap_sel && !cmd_write)
read_addr <= cmd_addr_ram;
end
assign o_ram_clk = tap_update;
assign o_ram_wen = tap_update & tap_sel & cmd_write;
assign o_ram_wdata = cmd_wdata;
assign o_ram_addr = tap_update ? cmd_addr_ram : read_addr;
assign tap_tdo = shift_out[0];
jtag_tap_spartan6
#(.USER_CHAIN(USER_CHAIN))
i_jtag_tap
(
.o_drck(tap_drck),
.o_capture(),
.o_shift(tap_shift),
.o_update(tap_update),
.o_reset(tap_reset),
.o_sel(tap_sel),
.o_tdi(tap_tdi),
.i_tdo(tap_tdo)
);
endmodule

50
rtl/toplevel/top_generic.v
View File

@@ -22,45 +22,43 @@ module top_generic(
.clk_out_15(clk_15)
);
reg [11:0] count;
localparam integer DIV_MAX = 100_000 - 1; // 1 ms tick at 100 MHz
reg [16:0] div_counter = 0; // enough bits for 100k (2^17=131072)
reg [31:0] freq;
always @(posedge aclk) begin
if (!aresetn) begin
div_counter <= 0;
count <= 0;
end else begin
if (div_counter == DIV_MAX) begin
div_counter <= 0;
if (count == 12'd3999)
count <= 0; // wrap at 4000
else
count <= count + 1'b1; // increment every 1 ms
end else begin
div_counter <= div_counter + 1'b1;
end
end
freq <= count;
end
wire [31:0] GPIO_A;
wire [31:0] GPIO_B;
wire [31:0] GPIO_C;
wire [31:0] GPIO_D;
soclet #(
.memfile("../sw/sweep/sweep.hex")
) mcu (
.i_clk(clk_15),
.i_rst(!aresetn),
.i_GPI_A(GPIO_A),
.i_GPI_B(GPIO_B),
.i_GPI_C(GPIO_C),
.i_GPI_D(GPIO_D),
.o_GPO_A(GPIO_A),
.o_GPO_B(GPIO_B),
.o_GPO_C(GPIO_C),
.o_GPO_D(GPIO_D)
);
wire [15:0] sin_q15;
wire clk_en;
nco_q15 #(
.CLK_HZ(100_000_000),
.FS_HZ(40_000)
.CLK_HZ(15_000_000),
.FS_HZ(80_000)
) nco (
.clk (aclk),
.clk (clk_15),
.rst_n (aresetn),
.freq_hz(freq),
.freq_hz(GPIO_A),
.sin_q15(sin_q15),
.cos_q15(),
.clk_en (clk_en)
);
reg [5:0] dac_code;
always @(posedge aclk) begin
always @(posedge clk_15) begin
dac_code <= q15_to_uq16(sin_q15) >> 10;
end
assign r2r = dac_code;

61
rtl/toplevel/top_serv.v
View File

@@ -1,61 +0,0 @@
`timescale 1ns/1ps
module top_generic(
input wire aclk,
input wire aresetn,
output wire led_green,
output wire led_red,
output wire[5:0] r2r
);
wire [31:0] wb_adr;
wire [31:0] wb_dat;
wire [31:0] wb_rdt;
wire [3:0] wb_sel;
wire wb_we;
wire wb_stb;
wire wb_ack;
wire [31:0] GPIO;
assign led_green = GPIO[0];
assign led_red = GPIO[1];
assign r2r = GPIO[8:2];
serving #(
.memfile("../sw/blinky/blinky.hex"),
.memsize(8192),
.sim(1'b0),
.RESET_STRATEGY("MINI"),
.WITH_CSR(1)
) serv (
.i_clk(aclk),
.i_rst(!aresetn),
.i_timer_irq(1'b0),
.i_wb_rdt(wb_rdt),
.i_wb_ack(wb_ack),
.o_wb_adr(wb_adr),
.o_wb_dat(wb_dat),
.o_wb_sel(wb_sel),
.o_wb_we(wb_we),
.o_wb_stb(wb_stb)
);
wb_gpio #(
.address(32'h80000000)
) gpio (
.i_wb_clk(aclk),
.i_wb_rst(!aresetn),
.i_wb_dat(wb_dat),
.i_wb_adr(wb_adr),
.i_wb_we(wb_we),
.i_wb_stb(wb_stb),
.i_wb_sel(wb_sel),
.o_wb_rdt(wb_rdt),
.o_wb_ack(wb_ack),
.o_gpio(GPIO)
);
endmodule

49
rtl/util/clog2.vh
View File

@@ -1,10 +1,39 @@
function integer clog2;
input integer value;
integer i;
begin
value = value - 1;
for (i = 0; value > 0; i = i + 1)
value = value >> 1;
clog2 = (i < 1) ? 1 : i;
end
endfunction
`ifndef CLOG2_VH
`define CLOG2_VH
// Verilog-2001 compatible ceil(log2(x)) macro (matches $clog2 semantics).
`define CLOG2(x) \
(((x) <= 1) ? 0 : \
((x) <= 2) ? 1 : \
((x) <= 4) ? 2 : \
((x) <= 8) ? 3 : \
((x) <= 16) ? 4 : \
((x) <= 32) ? 5 : \
((x) <= 64) ? 6 : \
((x) <= 128) ? 7 : \
((x) <= 256) ? 8 : \
((x) <= 512) ? 9 : \
((x) <= 1024) ? 10 : \
((x) <= 2048) ? 11 : \
((x) <= 4096) ? 12 : \
((x) <= 8192) ? 13 : \
((x) <= 16384) ? 14 : \
((x) <= 32768) ? 15 : \
((x) <= 65536) ? 16 : \
((x) <= 131072) ? 17 : \
((x) <= 262144) ? 18 : \
((x) <= 524288) ? 19 : \
((x) <= 1048576) ? 20 : \
((x) <= 2097152) ? 21 : \
((x) <= 4194304) ? 22 : \
((x) <= 8388608) ? 23 : \
((x) <= 16777216) ? 24 : \
((x) <= 33554432) ? 25 : \
((x) <= 67108864) ? 26 : \
((x) <= 134217728) ? 27 : \
((x) <= 268435456) ? 28 : \
((x) <= 536870912) ? 29 : \
((x) <= 1073741824) ? 30 : \
((x) <= 2147483648) ? 31 : 32)
`endif

5
rtl/wb/wb_gpio.v
View File

@@ -8,6 +8,7 @@ module wb_gpio #(
input wire [3:0] i_wb_sel,
input wire i_wb_we,
input wire i_wb_stb,
input wire [31:0] i_gpio,
output reg [31:0] o_wb_rdt,
output reg o_wb_ack,
@@ -34,7 +35,7 @@ module wb_gpio #(
if (i_wb_rst) begin
o_wb_rdt <= 32'h0;
end else if (i_wb_stb && !i_wb_we) begin
o_wb_rdt <= o_gpio;
o_wb_rdt <= i_gpio;
end
end
@@ -51,4 +52,4 @@ module wb_gpio #(
end
end
endmodule
endmodule

63
rtl/wb/wb_gpio_banks.v Normal file
View File

@@ -0,0 +1,63 @@
`default_nettype none
module wb_gpio_banks #(
parameter integer NUM_BANKS = 4,
parameter [31:0] BASE_ADDR = 32'h8000_0000
) (
input wire i_wb_clk,
input wire i_wb_rst,
input wire [31:0] i_wb_adr,
input wire [31:0] i_wb_dat,
input wire [3:0] i_wb_sel,
input wire i_wb_we,
input wire i_wb_stb,
input wire [NUM_BANKS*32-1:0] i_gpio,
output reg [31:0] o_wb_rdt,
output reg o_wb_ack,
output wire [NUM_BANKS*32-1:0] o_gpio
);
wire [NUM_BANKS-1:0] bank_sel;
wire [NUM_BANKS-1:0] bank_stb;
wire [NUM_BANKS*32-1:0] bank_rdt;
wire [NUM_BANKS-1:0] bank_ack;
genvar gi;
generate
for (gi = 0; gi < NUM_BANKS; gi = gi + 1) begin : gen_gpio
localparam [31:0] BANK_ADDR = BASE_ADDR + (gi * 4);
assign bank_sel[gi] = (i_wb_adr == BANK_ADDR);
assign bank_stb[gi] = i_wb_stb & bank_sel[gi];
wb_gpio #(
.address(BANK_ADDR)
) u_gpio (
.i_wb_clk(i_wb_clk),
.i_wb_rst(i_wb_rst),
.i_wb_adr(i_wb_adr),
.i_wb_dat(i_wb_dat),
.i_wb_sel(i_wb_sel),
.i_wb_we(i_wb_we),
.i_wb_stb(bank_stb[gi]),
.i_gpio(i_gpio[gi*32 +: 32]),
.o_wb_rdt(bank_rdt[gi*32 +: 32]),
.o_wb_ack(bank_ack[gi]),
.o_gpio(o_gpio[gi*32 +: 32])
);
end
endgenerate
integer bi;
always @* begin
o_wb_rdt = 32'h0000_0000;
o_wb_ack = 1'b0;
for (bi = 0; bi < NUM_BANKS; bi = bi + 1) begin
if (bank_sel[bi]) begin
o_wb_rdt = bank_rdt[bi*32 +: 32];
o_wb_ack = bank_ack[bi];
end
end
end
endmodule

136
scripts/hex_to_coe.py Executable file
View File

@@ -0,0 +1,136 @@
#!/usr/bin/env python3
"""Convert a simple .hex image to Xilinx .coe format.
Supported input:
- One or more hex tokens per line (e.g. "37" or "0x37")
- Optional comments after '#' or '//'
By default, each token is written as one .coe entry (8-bit style memory init).
Use --word-bytes > 1 to pack byte tokens into wider words.
"""
from __future__ import annotations
import argparse
from pathlib import Path
def parse_tokens(path: Path) -> list[int]:
values: list[int] = []
for raw in path.read_text().splitlines():
line = raw.split("//", 1)[0].split("#", 1)[0].strip()
if not line:
continue
for token in line.replace(",", " ").split():
token = token.strip()
if not token:
continue
if token.lower().startswith("0x"):
token = token[2:]
values.append(int(token, 16))
return values
def pack_words(
byte_values: list[int], word_bytes: int, little_endian: bool
) -> tuple[list[int], int]:
if word_bytes <= 0:
raise ValueError("word_bytes must be >= 1")
if word_bytes == 1:
return byte_values[:], 2
words: list[int] = []
width = word_bytes * 2
for i in range(0, len(byte_values), word_bytes):
chunk = byte_values[i : i + word_bytes]
if len(chunk) < word_bytes:
chunk = chunk + [0] * (word_bytes - len(chunk))
word = 0
if little_endian:
for b_idx, b in enumerate(chunk):
word |= (b & 0xFF) << (8 * b_idx)
else:
for b in chunk:
word = (word << 8) | (b & 0xFF)
words.append(word)
return words, width
def main() -> None:
parser = argparse.ArgumentParser(description="Convert .hex to Xilinx .coe")
parser.add_argument("input_hex", type=Path, help="Input .hex file")
parser.add_argument("output_coe", type=Path, help="Output .coe file")
parser.add_argument(
"--word-bytes",
type=int,
default=1,
help="Bytes per output word (default: 1)",
)
parser.add_argument(
"--little-endian",
action="store_true",
help="Pack bytes little-endian when --word-bytes > 1 (default)",
)
parser.add_argument(
"--big-endian",
action="store_true",
help="Pack bytes big-endian when --word-bytes > 1",
)
parser.add_argument(
"--radix",
type=int,
default=16,
choices=[2, 10, 16],
help="COE radix (default: 16)",
)
parser.add_argument(
"--depth",
type=int,
default=0,
help="Optional output depth (pads with zeros up to this many words)",
)
args = parser.parse_args()
if args.little_endian and args.big_endian:
raise SystemExit("Choose only one of --little-endian or --big-endian")
little_endian = True
if args.big_endian:
little_endian = False
byte_values = parse_tokens(args.input_hex)
words, hex_digits = pack_words(byte_values, args.word_bytes, little_endian)
if args.depth > 0 and args.depth < len(words):
raise SystemExit(
f"Requested --depth={args.depth} but image has {len(words)} words"
)
if args.depth > len(words):
words.extend([0] * (args.depth - len(words)))
if args.radix == 16:
data = [f"{w:0{hex_digits}X}" for w in words]
elif args.radix == 10:
data = [str(w) for w in words]
else:
width_bits = args.word_bytes * 8
data = [f"{w:0{width_bits}b}" for w in words]
out_lines = [
f"memory_initialization_radix={args.radix};",
"memory_initialization_vector=",
]
if data:
out_lines.extend(
[f"{v}," for v in data[:-1]] + [f"{data[-1]};"]
)
else:
out_lines.append("0;")
args.output_coe.write_text("\n".join(out_lines) + "\n")
if __name__ == "__main__":
main()

104
scripts/hex_to_mif.py Executable file
View File

@@ -0,0 +1,104 @@
#!/usr/bin/env python3
"""Convert a simple .hex image to a plain .mif-style binary file.
Default output format matches build/mem_8kx8b.mif in this repo:
- one binary word per line
- no header
"""
from __future__ import annotations
import argparse
from pathlib import Path
def parse_tokens(path: Path) -> list[int]:
values: list[int] = []
for raw in path.read_text().splitlines():
line = raw.split("//", 1)[0].split("#", 1)[0].strip()
if not line:
continue
for token in line.replace(",", " ").split():
if token.lower().startswith("0x"):
token = token[2:]
values.append(int(token, 16))
return values
def pack_words(
byte_values: list[int], word_bytes: int, little_endian: bool
) -> list[int]:
if word_bytes <= 0:
raise ValueError("word_bytes must be >= 1")
if word_bytes == 1:
return byte_values[:]
words: list[int] = []
for i in range(0, len(byte_values), word_bytes):
chunk = byte_values[i : i + word_bytes]
if len(chunk) < word_bytes:
chunk = chunk + [0] * (word_bytes - len(chunk))
word = 0
if little_endian:
for b_idx, b in enumerate(chunk):
word |= (b & 0xFF) << (8 * b_idx)
else:
for b in chunk:
word = (word << 8) | (b & 0xFF)
words.append(word)
return words
def main() -> None:
parser = argparse.ArgumentParser(description="Convert .hex to plain .mif")
parser.add_argument("input_hex", type=Path, help="Input .hex file")
parser.add_argument("output_mif", type=Path, help="Output .mif file")
parser.add_argument(
"--word-bytes",
type=int,
default=1,
help="Bytes per output word (default: 1)",
)
parser.add_argument(
"--little-endian",
action="store_true",
help="Pack bytes little-endian when --word-bytes > 1 (default)",
)
parser.add_argument(
"--big-endian",
action="store_true",
help="Pack bytes big-endian when --word-bytes > 1",
)
parser.add_argument(
"--depth",
type=int,
default=0,
help="Optional output depth (pads with zeros up to this many words)",
)
args = parser.parse_args()
if args.little_endian and args.big_endian:
raise SystemExit("Choose only one of --little-endian or --big-endian")
little_endian = True
if args.big_endian:
little_endian = False
words = pack_words(parse_tokens(args.input_hex), args.word_bytes, little_endian)
width_bits = args.word_bytes * 8
max_word = (1 << width_bits) - 1
if args.depth > 0 and args.depth < len(words):
raise SystemExit(
f"Requested --depth={args.depth} but image has {len(words)} words"
)
if args.depth > len(words):
words.extend([0] * (args.depth - len(words)))
lines = [f"{(w & max_word):0{width_bits}b}" for w in words]
args.output_mif.write_text("\n".join(lines) + ("\n" if lines else ""))
if __name__ == "__main__":
main()

196
scripts/jtag_write_ram.py Executable file
View File

@@ -0,0 +1,196 @@
#!/usr/bin/env python3
"""Write a file into serving_ram_jtag over Spartan-6 USER JTAG via OpenOCD.
This script targets the protocol implemented by rtl/serv/serving_ram_jtag_bridge.v:
frame bit[0] = write_enable
frame bit[32:1] = 32-bit address
frame bit[40:33] = data byte
Notes:
- Frame is shifted LSB-first (OpenOCD drscan integer value format matches this).
- USER1/USER2 opcode selection is Spartan-6 specific (IR opcodes 0x02/0x03, IR length 6).
"""
from __future__ import annotations
import argparse
import pathlib
import re
import subprocess
import sys
import tempfile
from typing import Dict, List, Tuple
JTAG_ADDR_W = 32
JTAG_FRAME_W = 1 + JTAG_ADDR_W + 8
def parse_args() -> argparse.Namespace:
p = argparse.ArgumentParser(description="Write file to serving RAM over JTAG")
p.add_argument("input", help="Input file (.bin or readmemh-style .hex/.mem)")
p.add_argument(
"--ram-addr-width",
"--addr-width",
dest="ram_addr_width",
type=int,
default=8,
help="RAM address width (aw) in HDL, default: 8",
)
p.add_argument("--base-addr", type=lambda x: int(x, 0), default=0, help="Base address for .bin input")
p.add_argument("--tap", default="xc6s.tap", help="OpenOCD tap name (default: xc6s.tap)")
p.add_argument(
"--user-chain",
type=int,
choices=[1, 2],
default=1,
help="BSCAN user chain used in HDL (default: 1)",
)
p.add_argument("--openocd-cfg", action="append", default=[], help="OpenOCD -f config file (repeatable)")
p.add_argument("--openocd-cmd", action="append", default=[], help="Extra OpenOCD -c command before programming")
p.add_argument("--limit", type=int, default=None, help="Write only first N bytes")
p.add_argument("--dry-run", action="store_true", help="Generate and print TCL only")
return p.parse_args()
def _strip_line_comments(line: str) -> str:
return line.split("//", 1)[0]
def parse_readmemh_text(path: pathlib.Path) -> Dict[int, int]:
"""Parse a simple readmemh-style file with optional @address directives."""
text = path.read_text(encoding="utf-8")
words: Dict[int, int] = {}
addr = 0
for raw_line in text.splitlines():
line = _strip_line_comments(raw_line).strip()
if not line:
continue
for tok in line.split():
tok = tok.strip()
if not tok:
continue
if tok.startswith("@"):
addr = int(tok[1:], 16)
continue
if not re.fullmatch(r"[0-9a-fA-F]+", tok):
raise ValueError(f"Unsupported token '{tok}' in {path}")
val = int(tok, 16)
if val < 0 or val > 0xFF:
raise ValueError(f"Byte value out of range at address 0x{addr:x}: {tok}")
words[addr] = val
addr += 1
return words
def load_image(path: pathlib.Path, base_addr: int) -> List[Tuple[int, int]]:
suffix = path.suffix.lower()
if suffix == ".bin":
blob = path.read_bytes()
return [(base_addr + i, b) for i, b in enumerate(blob)]
if suffix in {".hex", ".mem", ".vmem"}:
words = parse_readmemh_text(path)
return sorted(words.items())
raise ValueError("Unsupported input format. Use .bin, .hex, .mem, or .vmem")
def build_write_frame(addr: int, data: int) -> int:
return (data << (JTAG_ADDR_W + 1)) | ((addr & ((1 << JTAG_ADDR_W) - 1)) << 1) | 0x1
def build_openocd_tcl(entries: List[Tuple[int, int]], tap: str, user_chain: int, pre_cmds: List[str]) -> str:
ir_opcode = 0x02 if user_chain == 1 else 0x03
lines: List[str] = []
lines.append("init")
for cmd in pre_cmds:
lines.append(cmd)
lines.append(f"irscan {tap} 0x{ir_opcode:x} -endstate IDLE")
for addr, data in entries:
frame = build_write_frame(addr, data)
lines.append(f"drscan {tap} {JTAG_FRAME_W} 0x{frame:x} -endstate IDLE")
lines.append("shutdown")
lines.append("")
return "\n".join(lines)
def run_openocd(cfg_files: List[str], script_path: pathlib.Path) -> int:
cmd = ["openocd"]
for cfg in cfg_files:
cmd += ["-f", cfg]
cmd += ["-f", str(script_path)]
proc = subprocess.run(cmd)
return proc.returncode
def main() -> int:
args = parse_args()
in_path = pathlib.Path(args.input)
if not in_path.exists():
print(f"error: input file not found: {in_path}", file=sys.stderr)
return 2
entries = load_image(in_path, args.base_addr)
if args.limit is not None:
entries = entries[: args.limit]
if not entries:
print("error: no bytes found to write", file=sys.stderr)
return 2
if args.ram_addr_width < 1 or args.ram_addr_width > JTAG_ADDR_W:
print(
f"error: --ram-addr-width must be in [1, {JTAG_ADDR_W}] for this protocol",
file=sys.stderr,
)
return 2
max_jtag_addr = (1 << JTAG_ADDR_W) - 1
max_addr = (1 << args.ram_addr_width) - 1
for addr, _ in entries:
if addr < 0 or addr > max_jtag_addr:
print(
f"error: address 0x{addr:x} exceeds 32-bit protocol range (max 0x{max_jtag_addr:x})",
file=sys.stderr,
)
return 2
if addr > max_addr:
print(
f"error: address 0x{addr:x} exceeds RAM addr width {args.ram_addr_width} (max 0x{max_addr:x})",
file=sys.stderr,
)
return 2
tcl = build_openocd_tcl(entries, args.tap, args.user_chain, args.openocd_cmd)
if args.dry_run:
print(tcl, end="")
print(f"# bytes: {len(entries)}", file=sys.stderr)
return 0
if not args.openocd_cfg:
print("error: provide at least one --openocd-cfg unless using --dry-run", file=sys.stderr)
return 2
with tempfile.NamedTemporaryFile("w", suffix=".tcl", delete=False) as tf:
tf.write(tcl)
tcl_path = pathlib.Path(tf.name)
print(f"Programming {len(entries)} bytes via JTAG...")
rc = run_openocd(args.openocd_cfg, tcl_path)
if rc != 0:
print(f"error: openocd failed with exit code {rc}", file=sys.stderr)
print(f"TCL kept at: {tcl_path}", file=sys.stderr)
return rc
print("Done.")
return 0
if __name__ == "__main__":
raise SystemExit(main())

5
scripts/planahead.sh
View File

@@ -1,4 +1,5 @@
#!/bin/bash
cd build
. /opt/packages/xilinx/ISE/14.7/ISE_DS/settings64.sh
planAhead -mode gui -source ../scripts/planahead.tcl
. /opt/Xilinx/14.7/ISE_DS/settings64.sh
Xephyr :1 -screen 1600x900 &
DISPLAY=:1 planAhead -mode batch -source ../scripts/planahead.tcl

3
scripts/planahead.tcl
View File

@@ -4,4 +4,5 @@ add_files -norecurse ../out/synth/synth.ngc
import_files -force -norecurse
import_files -fileset constrs_1 -force -norecurse ../boards/mimas_v1/constraints.ucf
import_as_run -run impl_1 -twx ../out/synth/timing.twx ../out/synth/synth.ncd
open_run impl_1
open_run impl_1
start_gui

51
sim/overrides/serving_ram.v
View File

@@ -1,51 +0,0 @@
/* serving_ram.v : I/D SRAM for the serving SoC
*
* ISC License
*
* Copyright (C) 2020 Olof Kindgren <olof.kindgren@gmail.com>
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*/
`default_nettype none
module serving_ram
#(//Memory parameters
parameter depth = 256,
parameter aw = $clog2(depth),
parameter memfile = "")
(input wire i_clk,
input wire [aw-1:0] i_waddr,
input wire [7:0] i_wdata,
input wire i_wen,
input wire [aw-1:0] i_raddr,
output reg [7:0] o_rdata);
reg [7:0] mem [0:depth-1] /* verilator public */;
always @(posedge i_clk) begin
if (i_wen) mem[i_waddr] <= i_wdata;
o_rdata <= mem[i_raddr];
end
integer i;
initial begin
// Fill unused/uninitialized memory with a predefined value
for (i = 0; i < depth; i = i + 1)
mem[i] = 8'h00; // <- pick your fill value (00, FF, etc.)
if (|memfile) begin
$display("Preloading %m from %s", memfile);
$readmemh(memfile, mem);
end
end
endmodule

7
sim/tb/tb_serving.v
View File

@@ -33,7 +33,7 @@ module tb_serving();
serving #(
.memfile("../sw/blinky/blinky.hex"),
.memsize(8192),
.sim(1'b0),
.sim(1'b1),
.RESET_STRATEGY("MINI"),
.WITH_CSR(1)
) serv (
@@ -50,7 +50,7 @@ module tb_serving();
);
wb_gpio #(
.address(32'h80000000)
.address(32'h40000000)
) gpio (
.i_wb_clk(clk),
.i_wb_dat(wb_dat),
@@ -58,9 +58,10 @@ module tb_serving();
.i_wb_we(wb_we),
.i_wb_stb(wb_stb),
.i_wb_sel(wb_sel),
.i_gpio(GPIO),
.o_wb_rdt(wb_rdt),
.o_wb_ack(wb_ack),
.o_gpio(GPIO)
);
endmodule
endmodule

8
sw/.gitignore vendored Normal file
View File

@@ -0,0 +1,8 @@
*.o
*.hex
*.bin
*.map
*.elf.asm
*.elf
*.coe
*.mif

60
sw/blinky/Makefile
View File

@@ -1,14 +1,56 @@
TOOLCHAIN_PREFIX?=riscv64-elf-
CC=$(TOOLCHAIN_PREFIX)gcc
OBJCOPY=$(TOOLCHAIN_PREFIX)objcopy
TOOLCHAIN_PREFIX ?= riscv64-elf-
%.elf: %.S link.ld
# $(CC) -nostartfiles -nostdlib -march=rv32i_zicsr -mabi=ilp32 -Tlink.ld -o$@ $<
$(CC) -nostartfiles -nostdlib -ffreestanding -march=rv32i_zicsr -mabi=ilp32 -Tlink.ld -o$@ $<
%.bin: %.elf
CC := $(TOOLCHAIN_PREFIX)gcc
OBJCOPY := $(TOOLCHAIN_PREFIX)objcopy
OBJDUMP := $(TOOLCHAIN_PREFIX)objdump
SIZE := $(TOOLCHAIN_PREFIX)size
TARGET := blinky
SRCS_C := blinky.c
SRCS_S := start.s
OBJS := $(SRCS_C:.c=.o) $(SRCS_S:.s=.o)
ARCH_FLAGS := -march=rv32i_zicsr -mabi=ilp32
CFLAGS := $(ARCH_FLAGS) -Os -ffreestanding -fno-builtin -Wall -Wextra
ASFLAGS := $(ARCH_FLAGS)
LDFLAGS := $(ARCH_FLAGS) -nostdlib -nostartfiles -Wl,-Bstatic,-Tlink.ld,--gc-sections,-Map,$(TARGET).map
HEX_TO_COE := ../../scripts/hex_to_coe.py
HEX_TO_MIF := ../../scripts/hex_to_mif.py
.PHONY: all clean disasm size
all: $(TARGET).elf $(TARGET).bin $(TARGET).hex $(TARGET).coe $(TARGET).mif $(TARGET).elf.asm
$(TARGET).elf: $(OBJS) link.ld
$(CC) $(LDFLAGS) -o $@ $(OBJS)
%.o: %.c
$(CC) $(CFLAGS) -c -o $@ $<
%.o: %.s
$(CC) $(ASFLAGS) -c -o $@ $<
$(TARGET).bin: $(TARGET).elf
$(OBJCOPY) -O binary $< $@
%.hex: %.bin
$(TARGET).hex: $(TARGET).bin
hexdump -v -e '1/1 "%02x\n"' $< > $@
$(TARGET).coe: $(TARGET).hex
$(HEX_TO_COE) $< $@
$(TARGET).mif: $(TARGET).hex
$(HEX_TO_MIF) $< $@
$(TARGET).elf.asm: $(TARGET).elf
$(OBJDUMP) -d -S $< > $@
disasm: $(TARGET).elf.asm
size: $(TARGET).elf
$(SIZE) $<
clean:
rm -f *.elf *.bin *.hex
rm -f $(TARGET).elf $(TARGET).bin $(TARGET).hex $(TARGET).coe $(TARGET).mif \
$(TARGET).elf.asm $(TARGET).map $(OBJS)

17
sw/blinky/blinky.S
View File

@@ -1,17 +0,0 @@
#define GPIO_BASE 0x80000000
#define DELAY 2
.globl _start
_start:
lui a0, %hi(GPIO_BASE)
addi a0, a0, %lo(GPIO_BASE)
addi t0, zero, 0
li t1, DELAY
.lp1:
sb t0, 0(a0)
addi t0, t0, 1
and t2, zero, zero
time1:
addi t2, t2, 1
bne t1, t2, time1
j .lp1

27
sw/blinky/blinky.c Normal file
View File

@@ -0,0 +1,27 @@
#include <stdint.h>
#define GPIO_BASE 0x40000000u
#define VOUT_BASE 0x40000004u
static volatile uint32_t * const gpio = (volatile uint32_t *)GPIO_BASE;
static volatile uint32_t * const vout = (volatile uint32_t *)VOUT_BASE;
static void delay(volatile uint32_t ticks){
while (ticks--) {
__asm__ volatile ("nop");
}
}
int main(void)
{
uint32_t v = 0;
for (;;) {
for(int i=0; i<1000; i++){
*vout = v;
v++;
delay(5u);
}
*gpio ^= 0xffffffff;
}
}

BIN
sw/blinky/blinky.elf
View File

Binary file not shown.

40
sw/blinky/blinky.hex
View File

@@ -1,40 +0,0 @@
37
05
00
80
13
05
05
00
93
02
00
00
13
03
20
00
23
00
55
00
93
82
12
00
b3
73
00
00
93
83
13
00
e3
1e
73
fe
6f
f0
df
fe

33
sw/blinky/link.ld
View File

@@ -1,10 +1,33 @@
OUTPUT_ARCH( "riscv" )
OUTPUT_ARCH("riscv")
ENTRY(_start)
MEMORY
{
RAM (rwx) : ORIGIN = 0x00000000, LENGTH = 8K
}
SECTIONS
{
. = 0x00000000;
.text : { *(.text) }
.data : { *(.data) }
.bss : { *(.bss) }
.text :
{
KEEP(*(.text.init))
*(.text .text.*)
*(.rodata .rodata.*)
} > RAM
.data :
{
*(.data .data.*)
} > RAM
.bss (NOLOAD) :
{
__bss_start = .;
*(.bss .bss.*)
*(COMMON)
__bss_end = .;
} > RAM
. = ALIGN(4);
__stack_top = ORIGIN(RAM) + LENGTH(RAM);
}

23
sw/blinky/start.s Normal file
View File

@@ -0,0 +1,23 @@
.section .text.init
.globl _start
.type _start, @function
_start:
la sp, __stack_top
# Zero .bss
la t0, __bss_start
la t1, __bss_end
1:
bgeu t0, t1, 2f
sw zero, 0(t0)
addi t0, t0, 4
j 1b
2:
call main
3:
j 3b
.size _start, .-_start

56
sw/sweep/Makefile Normal file
View File

@@ -0,0 +1,56 @@
TOOLCHAIN_PREFIX ?= riscv64-elf-
CC := $(TOOLCHAIN_PREFIX)gcc
OBJCOPY := $(TOOLCHAIN_PREFIX)objcopy
OBJDUMP := $(TOOLCHAIN_PREFIX)objdump
SIZE := $(TOOLCHAIN_PREFIX)size
TARGET := sweep
SRCS_C := sweep.c
SRCS_S := start.s
OBJS := $(SRCS_C:.c=.o) $(SRCS_S:.s=.o)
ARCH_FLAGS := -march=rv32i_zicsr -mabi=ilp32
CFLAGS := $(ARCH_FLAGS) -Os -ffreestanding -fno-builtin -Wall -Wextra
ASFLAGS := $(ARCH_FLAGS)
LDFLAGS := $(ARCH_FLAGS) -nostdlib -nostartfiles -Wl,-Bstatic,-Tlink.ld,--gc-sections,-Map,$(TARGET).map
HEX_TO_COE := ../../scripts/hex_to_coe.py
HEX_TO_MIF := ../../scripts/hex_to_mif.py
.PHONY: all clean disasm size
all: $(TARGET).elf $(TARGET).bin $(TARGET).hex $(TARGET).coe $(TARGET).mif $(TARGET).elf.asm
$(TARGET).elf: $(OBJS) link.ld
$(CC) $(LDFLAGS) -o $@ $(OBJS)
%.o: %.c
$(CC) $(CFLAGS) -c -o $@ $<
%.o: %.s
$(CC) $(ASFLAGS) -c -o $@ $<
$(TARGET).bin: $(TARGET).elf
$(OBJCOPY) -O binary $< $@
$(TARGET).hex: $(TARGET).bin
hexdump -v -e '1/1 "%02x\n"' $< > $@
$(TARGET).coe: $(TARGET).hex
$(HEX_TO_COE) $< $@
$(TARGET).mif: $(TARGET).hex
$(HEX_TO_MIF) $< $@
$(TARGET).elf.asm: $(TARGET).elf
$(OBJDUMP) -d -S $< > $@
disasm: $(TARGET).elf.asm
size: $(TARGET).elf
$(SIZE) $<
clean:
rm -f $(TARGET).elf $(TARGET).bin $(TARGET).hex $(TARGET).coe $(TARGET).mif \
$(TARGET).elf.asm $(TARGET).map $(OBJS)

33
sw/sweep/link.ld Normal file
View File

@@ -0,0 +1,33 @@
OUTPUT_ARCH("riscv")
ENTRY(_start)
MEMORY
{
RAM (rwx) : ORIGIN = 0x00000000, LENGTH = 8K
}
SECTIONS
{
.text :
{
KEEP(*(.text.init))
*(.text .text.*)
*(.rodata .rodata.*)
} > RAM
.data :
{
*(.data .data.*)
} > RAM
.bss (NOLOAD) :
{
__bss_start = .;
*(.bss .bss.*)
*(COMMON)
__bss_end = .;
} > RAM
. = ALIGN(4);
__stack_top = ORIGIN(RAM) + LENGTH(RAM);
}

23
sw/sweep/start.s Normal file
View File

@@ -0,0 +1,23 @@
.section .text.init
.globl _start
.type _start, @function
_start:
la sp, __stack_top
# Zero .bss
la t0, __bss_start
la t1, __bss_end
1:
bgeu t0, t1, 2f
sw zero, 0(t0)
addi t0, t0, 4
j 1b
2:
call main
3:
j 3b
.size _start, .-_start

14
sw/sweep/sweep.c Normal file
View File

@@ -0,0 +1,14 @@
#include <stdint.h>
#define GPIO_BASE 0x40000000u
static volatile uint32_t * const R_FREQ = (volatile uint32_t *)GPIO_BASE;
void main(){
for(;;){
for(int i=1000; i<10000; i++){
*R_FREQ = i;
for(int j=0; j<100; j++) asm volatile("nop");
}
}
}