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31
Top/pwm_block/ip.conf
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@ -1,31 +0,0 @@
[main]
ROOT=UserIP/rgb_pwm_block
VENDOR=user.org
LIBRARY=user
# What folder the IP shows up under in Vivado IPI
TAXONOMY=/UserIP
[interface.s_axi]
INTERFACE=xilinx.com:interface:aximm_rtl:1.0
INFER=true
PORTS=s_axi_awaddr s_axi_awprot s_axi_awvalid s_axi_awready s_axi_wdata s_axi_wstrb s_axi_wvalid s_axi_wready s_axi_bresp s_axi_bvalid s_axi_bready s_axi_araddr s_axi_arprot s_axi_arvalid s_axi_arready s_axi_rdata s_axi_rresp s_axi_rvalid s_axi_rready
[interface.s_axi_aclk]
INTERFACE=xilinx.com:signal:clock_rtl:1.0
ENABLEMENT_DEPENDENCY
INFER=false
MODE=slave
PORT.CLK=s_axi_aclk
PARAMETER.ASSOCIATED_RESET=s_axi_aresetn
PARAMETER.ASSOCIATED_BUSIF=s_axi
[interface.s_axi_aresetn]
INTERFACE=xilinx.com:signal:reset_rtl:1.0
INFER=true
PORTS=s_axi_aresetn
[memmap.s_axi]
BLOCKS=reg_base
BLOCK.reg_base.BASE_ADDRESS=0
BLOCK.reg_base.RANGE=32

1
Top/pwm_block/list/pwm_block.sim
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pwm_block/sim/top_tb.v

3
Top/pwm_block/list/pwm_block.src
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@ -1,4 +1,3 @@
pwm_block/src/rgb_pwm_block.v top=rgb_pwm_block
pwm_block/src/rgb_pwm_block_S_AXI.v
pwm_block/src/top.v top=top
pwm_block/src/pwm_core.v

6
pwm_block/sim/top_tb.v Normal file
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module top_tv
finish
endmodule

79
pwm_block/src/rgb_pwm_block.v
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`timescale 1 ns / 1 ps
module rgb_pwm_block #
(
// Users to add parameters here
// User parameters ends
// Do not modify the parameters beyond this line
// Parameters of Axi Slave Bus Interface S_AXI
parameter integer C_S_AXI_DATA_WIDTH = 32,
parameter integer C_S_AXI_ADDR_WIDTH = 4
)
(
// Users to add ports here
output wire [2:0] RGB_led,
// User ports ends
// Do not modify the ports beyond this line
// Ports of Axi Slave Bus Interface S_AXI
input wire s_axi_aclk,
input wire s_axi_aresetn,
input wire [C_S_AXI_ADDR_WIDTH-1 : 0] s_axi_awaddr,
input wire [2 : 0] s_axi_awprot,
input wire s_axi_awvalid,
output wire s_axi_awready,
input wire [C_S_AXI_DATA_WIDTH-1 : 0] s_axi_wdata,
input wire [(C_S_AXI_DATA_WIDTH/8)-1 : 0] s_axi_wstrb,
input wire s_axi_wvalid,
output wire s_axi_wready,
output wire [1 : 0] s_axi_bresp,
output wire s_axi_bvalid,
input wire s_axi_bready,
input wire [C_S_AXI_ADDR_WIDTH-1 : 0] s_axi_araddr,
input wire [2 : 0] s_axi_arprot,
input wire s_axi_arvalid,
output wire s_axi_arready,
output wire [C_S_AXI_DATA_WIDTH-1 : 0] s_axi_rdata,
output wire [1 : 0] s_axi_rresp,
output wire s_axi_rvalid,
input wire s_axi_rready
);
// Instantiation of Axi Bus Interface S_AXI
rgb_pwm_block_S_AXI # (
.C_S_AXI_DATA_WIDTH(C_S_AXI_DATA_WIDTH),
.C_S_AXI_ADDR_WIDTH(C_S_AXI_ADDR_WIDTH)
) rgb_pwm_block_S_AXI_inst (
.RGB_led(RGB_led),
.S_AXI_ACLK(s_axi_aclk),
.S_AXI_ARESETN(s_axi_aresetn),
.S_AXI_AWADDR(s_axi_awaddr),
.S_AXI_AWPROT(s_axi_awprot),
.S_AXI_AWVALID(s_axi_awvalid),
.S_AXI_AWREADY(s_axi_awready),
.S_AXI_WDATA(s_axi_wdata),
.S_AXI_WSTRB(s_axi_wstrb),
.S_AXI_WVALID(s_axi_wvalid),
.S_AXI_WREADY(s_axi_wready),
.S_AXI_BRESP(s_axi_bresp),
.S_AXI_BVALID(s_axi_bvalid),
.S_AXI_BREADY(s_axi_bready),
.S_AXI_ARADDR(s_axi_araddr),
.S_AXI_ARPROT(s_axi_arprot),
.S_AXI_ARVALID(s_axi_arvalid),
.S_AXI_ARREADY(s_axi_arready),
.S_AXI_RDATA(s_axi_rdata),
.S_AXI_RRESP(s_axi_rresp),
.S_AXI_RVALID(s_axi_rvalid),
.S_AXI_RREADY(s_axi_rready)
);
// Add user logic here
// User logic ends
endmodule

445
pwm_block/src/rgb_pwm_block_S_AXI.v
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`timescale 1 ns / 1 ps
module rgb_pwm_block_S_AXI #
(
// Users to add parameters here
// User parameters ends
// Do not modify the parameters beyond this line
// Width of S_AXI data bus
parameter integer C_S_AXI_DATA_WIDTH = 32,
// Width of S_AXI address bus
parameter integer C_S_AXI_ADDR_WIDTH = 4
)
(
// Users to add ports here
output wire [2:0] RGB_led,
// User ports ends
// Do not modify the ports beyond this line
// Global Clock Signal
input wire S_AXI_ACLK,
// Global Reset Signal. This Signal is Active LOW
input wire S_AXI_ARESETN,
// Write address (issued by master, acceped by Slave)
input wire [C_S_AXI_ADDR_WIDTH-1 : 0] S_AXI_AWADDR,
// Write channel Protection type. This signal indicates the
// privilege and security level of the transaction, and whether
// the transaction is a data access or an instruction access.
input wire [2 : 0] S_AXI_AWPROT,
// Write address valid. This signal indicates that the master signaling
// valid write address and control information.
input wire S_AXI_AWVALID,
// Write address ready. This signal indicates that the slave is ready
// to accept an address and associated control signals.
output wire S_AXI_AWREADY,
// Write data (issued by master, acceped by Slave)
input wire [C_S_AXI_DATA_WIDTH-1 : 0] S_AXI_WDATA,
// Write strobes. This signal indicates which byte lanes hold
// valid data. There is one write strobe bit for each eight
// bits of the write data bus.
input wire [(C_S_AXI_DATA_WIDTH/8)-1 : 0] S_AXI_WSTRB,
// Write valid. This signal indicates that valid write
// data and strobes are available.
input wire S_AXI_WVALID,
// Write ready. This signal indicates that the slave
// can accept the write data.
output wire S_AXI_WREADY,
// Write response. This signal indicates the status
// of the write transaction.
output wire [1 : 0] S_AXI_BRESP,
// Write response valid. This signal indicates that the channel
// is signaling a valid write response.
output wire S_AXI_BVALID,
// Response ready. This signal indicates that the master
// can accept a write response.
input wire S_AXI_BREADY,
// Read address (issued by master, acceped by Slave)
input wire [C_S_AXI_ADDR_WIDTH-1 : 0] S_AXI_ARADDR,
// Protection type. This signal indicates the privilege
// and security level of the transaction, and whether the
// transaction is a data access or an instruction access.
input wire [2 : 0] S_AXI_ARPROT,
// Read address valid. This signal indicates that the channel
// is signaling valid read address and control information.
input wire S_AXI_ARVALID,
// Read address ready. This signal indicates that the slave is
// ready to accept an address and associated control signals.
output wire S_AXI_ARREADY,
// Read data (issued by slave)
output wire [C_S_AXI_DATA_WIDTH-1 : 0] S_AXI_RDATA,
// Read response. This signal indicates the status of the
// read transfer.
output wire [1 : 0] S_AXI_RRESP,
// Read valid. This signal indicates that the channel is
// signaling the required read data.
output wire S_AXI_RVALID,
// Read ready. This signal indicates that the master can
// accept the read data and response information.
input wire S_AXI_RREADY
);
// AXI4LITE signals
reg [C_S_AXI_ADDR_WIDTH-1 : 0] axi_awaddr;
reg axi_awready;
reg axi_wready;
reg [1 : 0] axi_bresp;
reg axi_bvalid;
reg [C_S_AXI_ADDR_WIDTH-1 : 0] axi_araddr;
reg axi_arready;
reg [C_S_AXI_DATA_WIDTH-1 : 0] axi_rdata;
reg [1 : 0] axi_rresp;
reg axi_rvalid;
// Example-specific design signals
// local parameter for addressing 32 bit / 64 bit C_S_AXI_DATA_WIDTH
// ADDR_LSB is used for addressing 32/64 bit registers/memories
// ADDR_LSB = 2 for 32 bits (n downto 2)
// ADDR_LSB = 3 for 64 bits (n downto 3)
localparam integer ADDR_LSB = (C_S_AXI_DATA_WIDTH/32) + 1;
localparam integer OPT_MEM_ADDR_BITS = 1;
//----------------------------------------------
//-- Signals for user logic register space example
//------------------------------------------------
//-- Number of Slave Registers 4
reg [C_S_AXI_DATA_WIDTH-1:0] slv_reg0;
reg [C_S_AXI_DATA_WIDTH-1:0] slv_reg1;
reg [C_S_AXI_DATA_WIDTH-1:0] slv_reg2;
reg [C_S_AXI_DATA_WIDTH-1:0] slv_reg3;
wire slv_reg_rden;
wire slv_reg_wren;
reg [C_S_AXI_DATA_WIDTH-1:0] reg_data_out;
integer byte_index;
reg aw_en;
// I/O Connections assignments
assign S_AXI_AWREADY = axi_awready;
assign S_AXI_WREADY = axi_wready;
assign S_AXI_BRESP = axi_bresp;
assign S_AXI_BVALID = axi_bvalid;
assign S_AXI_ARREADY = axi_arready;
assign S_AXI_RDATA = axi_rdata;
assign S_AXI_RRESP = axi_rresp;
assign S_AXI_RVALID = axi_rvalid;
// Implement axi_awready generation
// axi_awready is asserted for one S_AXI_ACLK clock cycle when both
// S_AXI_AWVALID and S_AXI_WVALID are asserted. axi_awready is
// de-asserted when reset is low.
always @( posedge S_AXI_ACLK )
begin
if ( S_AXI_ARESETN == 1'b0 )
begin
axi_awready <= 1'b0;
aw_en <= 1'b1;
end
else
begin
if (~axi_awready && S_AXI_AWVALID && S_AXI_WVALID && aw_en)
begin
// slave is ready to accept write address when
// there is a valid write address and write data
// on the write address and data bus. This design
// expects no outstanding transactions.
axi_awready <= 1'b1;
aw_en <= 1'b0;
end
else if (S_AXI_BREADY && axi_bvalid)
begin
aw_en <= 1'b1;
axi_awready <= 1'b0;
end
else
begin
axi_awready <= 1'b0;
end
end
end
// Implement axi_awaddr latching
// This process is used to latch the address when both
// S_AXI_AWVALID and S_AXI_WVALID are valid.
always @( posedge S_AXI_ACLK )
begin
if ( S_AXI_ARESETN == 1'b0 )
begin
axi_awaddr <= 0;
end
else
begin
if (~axi_awready && S_AXI_AWVALID && S_AXI_WVALID && aw_en)
begin
// Write Address latching
axi_awaddr <= S_AXI_AWADDR;
end
end
end
// Implement axi_wready generation
// axi_wready is asserted for one S_AXI_ACLK clock cycle when both
// S_AXI_AWVALID and S_AXI_WVALID are asserted. axi_wready is
// de-asserted when reset is low.
always @( posedge S_AXI_ACLK )
begin
if ( S_AXI_ARESETN == 1'b0 )
begin
axi_wready <= 1'b0;
end
else
begin
if (~axi_wready && S_AXI_WVALID && S_AXI_AWVALID && aw_en )
begin
// slave is ready to accept write data when
// there is a valid write address and write data
// on the write address and data bus. This design
// expects no outstanding transactions.
axi_wready <= 1'b1;
end
else
begin
axi_wready <= 1'b0;
end
end
end
// Implement memory mapped register select and write logic generation
// The write data is accepted and written to memory mapped registers when
// axi_awready, S_AXI_WVALID, axi_wready and S_AXI_WVALID are asserted. Write strobes are used to
// select byte enables of slave registers while writing.
// These registers are cleared when reset (active low) is applied.
// Slave register write enable is asserted when valid address and data are available
// and the slave is ready to accept the write address and write data.
assign slv_reg_wren = axi_wready && S_AXI_WVALID && axi_awready && S_AXI_AWVALID;
always @( posedge S_AXI_ACLK )
begin
if ( S_AXI_ARESETN == 1'b0 )
begin
slv_reg0 <= 0;
slv_reg1 <= 0;
slv_reg2 <= 0;
slv_reg3 <= 0;
end
else begin
if (slv_reg_wren)
begin
case ( axi_awaddr[ADDR_LSB+OPT_MEM_ADDR_BITS:ADDR_LSB] )
2'h0:
for ( byte_index = 0; byte_index <= (C_S_AXI_DATA_WIDTH/8)-1; byte_index = byte_index+1 )
if ( S_AXI_WSTRB[byte_index] == 1 ) begin
// Respective byte enables are asserted as per write strobes
// Slave register 0
slv_reg0[(byte_index*8) +: 8] <= S_AXI_WDATA[(byte_index*8) +: 8];
end
2'h1:
for ( byte_index = 0; byte_index <= (C_S_AXI_DATA_WIDTH/8)-1; byte_index = byte_index+1 )
if ( S_AXI_WSTRB[byte_index] == 1 ) begin
// Respective byte enables are asserted as per write strobes
// Slave register 1
slv_reg1[(byte_index*8) +: 8] <= S_AXI_WDATA[(byte_index*8) +: 8];
end
2'h2:
for ( byte_index = 0; byte_index <= (C_S_AXI_DATA_WIDTH/8)-1; byte_index = byte_index+1 )
if ( S_AXI_WSTRB[byte_index] == 1 ) begin
// Respective byte enables are asserted as per write strobes
// Slave register 2
slv_reg2[(byte_index*8) +: 8] <= S_AXI_WDATA[(byte_index*8) +: 8];
end
2'h3:
for ( byte_index = 0; byte_index <= (C_S_AXI_DATA_WIDTH/8)-1; byte_index = byte_index+1 )
if ( S_AXI_WSTRB[byte_index] == 1 ) begin
// Respective byte enables are asserted as per write strobes
// Slave register 3
slv_reg3[(byte_index*8) +: 8] <= S_AXI_WDATA[(byte_index*8) +: 8];
end
default : begin
slv_reg0 <= slv_reg0;
slv_reg1 <= slv_reg1;
slv_reg2 <= slv_reg2;
slv_reg3 <= slv_reg3;
end
endcase
end
end
end
// Implement write response logic generation
// The write response and response valid signals are asserted by the slave
// when axi_wready, S_AXI_WVALID, axi_wready and S_AXI_WVALID are asserted.
// This marks the acceptance of address and indicates the status of
// write transaction.
always @( posedge S_AXI_ACLK )
begin
if ( S_AXI_ARESETN == 1'b0 )
begin
axi_bvalid <= 0;
axi_bresp <= 2'b0;
end
else
begin
if (axi_awready && S_AXI_AWVALID && ~axi_bvalid && axi_wready && S_AXI_WVALID)
begin
// indicates a valid write response is available
axi_bvalid <= 1'b1;
axi_bresp <= 2'b0; // 'OKAY' response
end // work error responses in future
else
begin
if (S_AXI_BREADY && axi_bvalid)
//check if bready is asserted while bvalid is high)
//(there is a possibility that bready is always asserted high)
begin
axi_bvalid <= 1'b0;
end
end
end
end
// Implement axi_arready generation
// axi_arready is asserted for one S_AXI_ACLK clock cycle when
// S_AXI_ARVALID is asserted. axi_awready is
// de-asserted when reset (active low) is asserted.
// The read address is also latched when S_AXI_ARVALID is
// asserted. axi_araddr is reset to zero on reset assertion.
always @( posedge S_AXI_ACLK )
begin
if ( S_AXI_ARESETN == 1'b0 )
begin
axi_arready <= 1'b0;
axi_araddr <= 32'b0;
end
else
begin
if (~axi_arready && S_AXI_ARVALID)
begin
// indicates that the slave has acceped the valid read address
axi_arready <= 1'b1;
// Read address latching
axi_araddr <= S_AXI_ARADDR;
end
else
begin
axi_arready <= 1'b0;
end
end
end
// Implement axi_arvalid generation
// axi_rvalid is asserted for one S_AXI_ACLK clock cycle when both
// S_AXI_ARVALID and axi_arready are asserted. The slave registers
// data are available on the axi_rdata bus at this instance. The
// assertion of axi_rvalid marks the validity of read data on the
// bus and axi_rresp indicates the status of read transaction.axi_rvalid
// is deasserted on reset (active low). axi_rresp and axi_rdata are
// cleared to zero on reset (active low).
always @( posedge S_AXI_ACLK )
begin
if ( S_AXI_ARESETN == 1'b0 )
begin
axi_rvalid <= 0;
axi_rresp <= 0;
end
else
begin
if (axi_arready && S_AXI_ARVALID && ~axi_rvalid)
begin
// Valid read data is available at the read data bus
axi_rvalid <= 1'b1;
axi_rresp <= 2'b0; // 'OKAY' response
end
else if (axi_rvalid && S_AXI_RREADY)
begin
// Read data is accepted by the master
axi_rvalid <= 1'b0;
end
end
end
// Implement memory mapped register select and read logic generation
// Slave register read enable is asserted when valid address is available
// and the slave is ready to accept the read address.
assign slv_reg_rden = axi_arready & S_AXI_ARVALID & ~axi_rvalid;
always @(*)
begin
// Address decoding for reading registers
case ( axi_araddr[ADDR_LSB+OPT_MEM_ADDR_BITS:ADDR_LSB] )
2'h0 : reg_data_out <= slv_reg0;
2'h1 : reg_data_out <= slv_reg1;
2'h2 : reg_data_out <= slv_reg2;
2'h3 : reg_data_out <= slv_reg3;
default : reg_data_out <= 0;
endcase
end
// Output register or memory read data
always @( posedge S_AXI_ACLK )
begin
if ( S_AXI_ARESETN == 1'b0 )
begin
axi_rdata <= 0;
end
else
begin
// When there is a valid read address (S_AXI_ARVALID) with
// acceptance of read address by the slave (axi_arready),
// output the read dada
if (slv_reg_rden)
begin
axi_rdata <= reg_data_out; // register read data
end
end
end
// Add user logic here
wire led_en;
assign led_en = slv_reg1[0];
assign led = led_en ? slv_reg0[7:0] : 0;
wire rst = ~S_AXI_ARESETN;
wire [15:0] duty_R = slv_reg0[15:0];
wire [15:0] duty_G = slv_reg1[15:0];
wire [15:0] duty_B = slv_reg2[15:0];
wire [15:0] widow_width = slv_reg3[31:16];
wire [15:0] pwm_clk_freq = slv_reg3[15:8];
wire [15:0] pwm_oen = slv_reg3[0];
pwm_core core_R(
.clk(pwm_clk),
.rst(rst),
.duty(duty_R),
.window_width(window_width),
.oen(pwm_oen),
.pulse(RGB_led[0])
);
pwm_core core_G(
.clk(pwm_clk),
.rst(rst),
.duty(duty_G),
.window_width(window_width),
.oen(pwm_oen),
.pulse(RGB_led[1])
);
pwm_core core_B(
.clk(pwm_clk),
.rst(rst),
.duty(duty_B),
.window_width(window_width),
.oen(pwm_oen),
.pulse(RGB_led[2])
);
// User logic ends
endmodule