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NawfalMotii79-PLFM_RADAR/9_Firmware/9_2_FPGA/xfft_2048.v
T
Jason 166464e877 fix(fpga): PR-O.8.1 — drop stale BFP-era ports, fix xsim include path 
Wrapper xfft_2048.v had m_axis_data_tuser and m_axis_status_{tdata,tvalid,
tready} hooked up to the IP, but the regenerated xfft_2048_ip in scaled
mode + Pipelined Streaming + 1 channel + no XK_INDEX/OVFLO doesn't expose
those ports. xelab errored "cannot find port" on all four. Removed.

run_xfft_xsim.sh missed -i "$PROJ_ROOT" so xvlog couldn't resolve
`include "radar_params.vh"` from inside tb/. Fixed.

gen_xfft_2048_ip.tcl header comment described the old Burst I/O 11-stage
schedule; updated to PG109 Pipelined Streaming pair-grouped layout that
matches the actual SCALE_SCH = 12'hAA9 we now drive.

Verified: tb_xfft_2048_xsim 5/5 PASS on real LogiCORE FFT v9.1 IP under
Vivado 2025.2 xsim — DC peak at bin 0, impulse flat spectrum, tone at
bin 128. Closes T-10 (FFT-block synth-mode validation).
2026-05-02 10:20:10 +05:45

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`timescale 1ns / 1ps
// ============================================================================
// xfft_2048.v — 2048-point FFT wrapper (Xilinx LogiCORE for synth/XSim,
// in-house fft_engine fallback for iverilog)
// ============================================================================
// AXI-Stream port list mirrors Xilinx LogiCORE Fast Fourier Transform v9.1
// (PG109). Two implementation branches selected by `FFT_USE_XILINX_IP`:
//
// `define FFT_USE_XILINX_IP → instantiates xfft_2048_ip (LogiCORE FFT v9.1)
// Pipelined Streaming I/O, scaled mode, 32-bit
// input/output (PR-O.7 widening).
// Use for: Vivado synth, remote XSim sim.
//
// `undef FFT_USE_XILINX_IP → instantiates fft_engine batched one-shot
// (collect N → compute → drain N).
// Use for: iverilog local sim only.
//
// Throughput on production silicon (Xilinx IP path): ~N + ~150 cycles per
// transform with full overlap → ~6600 cycles for 3 sequential transforms in
// the matched-filter chain, vs the 16700-cycle PRI budget. Closes RX-NEW-3.
//
// Data format: {Q[31:0], I[31:0]} packed 64-bit on s_axis/m_axis_data_tdata.
// PR-O.7 widened the path from 16- to 32-bit so the IFFT can consume the
// frequency_matched_filter Q30 product directly without the BFP-era
// >>15+saturate that crushed chirp/DC/impulse autocorrelations to zero under
// deterministic /N scaling — see project_mf_chain_dynrange_defect_2026-05-02.
//
// Config tdata layout (16-bit, scaled mode — see AUDIT-C10/C-8 in
// radar_params.vh `RP_FFT_SCALE_SCH):
// bit 0 = FWD/INV (1 = forward, 0 = inverse)
// bits[12:1] = SCALE_SCH (12 bits, fixed schedule from RP_FFT_SCALE_SCH)
// bits[15:13]= byte-align padding
//
// Scaled mode replaces the previous Block-Floating-Point setting. BFP returned
// a per-frame BLK_EXP on m_axis_data_tuser that the bridge dropped — sim and
// silicon disagreed on absolute magnitude per frame, breaking CFAR alpha
// portability. Scaled with schedule `RP_FFT_SCALE_SCH = [1,1,…,1] gives
// deterministic /N output, mirrored in fft_engine.v fallback.
// ============================================================================
module xfft_2048 (
input wire aclk,
input wire aresetn,
// Configuration channel (AXI-Stream slave). 16-bit tdata carries
// {pad[2:0], SCALE_SCH[11:0], FWD/INV} per PG109 Pipelined Streaming I/O
// (PR-O.8: SCALE_SCH width is 2*ceil(NFFT_MAX/2)=12, not 2*NFFT_MAX).
input wire [15:0] s_axis_config_tdata,
input wire s_axis_config_tvalid,
output wire s_axis_config_tready,
// Data input channel (AXI-Stream slave). 64-bit packed {Q[31:0], I[31:0]}.
input wire [63:0] s_axis_data_tdata,
input wire s_axis_data_tvalid,
input wire s_axis_data_tlast,
output wire s_axis_data_tready,
// Data output channel (AXI-Stream master). 64-bit packed {Q[31:0], I[31:0]}.
// No tuser — scaled mode does not emit BLK_EXP, and the IP is configured
// with no XK_INDEX / OVFLO outputs (see gen_xfft_2048_ip.tcl).
output wire [63:0] m_axis_data_tdata,
output wire m_axis_data_tvalid,
output wire m_axis_data_tlast,
input wire m_axis_data_tready
);
`ifdef FFT_USE_XILINX_IP
// ============================================================================
// XILINX LOGICORE FFT v9.1 — production / XSim path
// ============================================================================
// Per the regenerated IP (Pipelined Streaming + scaled + 1 channel + no CP +
// no XK_INDEX / no OVFLO), the IP exposes only the AXI-Stream config / data
// channels and six event signals. There is no m_axis_data_tuser and no
// m_axis_status_* channel in this configuration. Event signals are left
// unconnected — none are consumed downstream.
xfft_2048_ip u_xfft (
.aclk (aclk),
.s_axis_config_tdata (s_axis_config_tdata),
.s_axis_config_tvalid (s_axis_config_tvalid),
.s_axis_config_tready (s_axis_config_tready),
.s_axis_data_tdata (s_axis_data_tdata),
.s_axis_data_tvalid (s_axis_data_tvalid),
.s_axis_data_tready (s_axis_data_tready),
.s_axis_data_tlast (s_axis_data_tlast),
.m_axis_data_tdata (m_axis_data_tdata),
.m_axis_data_tvalid (m_axis_data_tvalid),
.m_axis_data_tready (m_axis_data_tready),
.m_axis_data_tlast (m_axis_data_tlast),
.event_frame_started (),
.event_tlast_unexpected (),
.event_tlast_missing (),
.event_status_channel_halt (),
.event_data_in_channel_halt (),
.event_data_out_channel_halt ()
);
`else
// ============================================================================
// FALLBACK — fft_engine batched one-shot (iverilog path only)
// ============================================================================
// Collect N samples → kick fft_engine → drain N samples. Throughput is
// ~N (collect) + ~160 K (compute) + ~N (drain). NOT representative of the
// real LogiCORE — used only for unit-level iverilog regression coverage.
// ============================================================================
localparam N = 2048;
localparam LOG2N = 11;
localparam CNT_W = LOG2N + 1;
localparam [2:0] S_IDLE = 3'd0,
S_FEED = 3'd1,
S_RUN = 3'd2,
S_OUTPUT = 3'd3;
reg [2:0] state;
reg inverse_reg;
(* ram_style = "block" *) reg signed [31:0] in_buf_re [0:N-1];
(* ram_style = "block" *) reg signed [31:0] in_buf_im [0:N-1];
(* ram_style = "block" *) reg signed [31:0] out_buf_re [0:N-1];
(* ram_style = "block" *) reg signed [31:0] out_buf_im [0:N-1];
reg [CNT_W-1:0] in_count;
reg [CNT_W-1:0] feed_count;
reg [CNT_W-1:0] out_total;
reg [CNT_W-1:0] out_count;
reg fft_start;
reg fft_inverse;
reg signed [31:0] fft_din_re, fft_din_im;
reg fft_din_valid;
wire signed [31:0] fft_dout_re, fft_dout_im;
wire fft_dout_valid;
wire fft_busy;
wire fft_done;
reg in_buf_we;
reg [LOG2N-1:0] in_buf_waddr;
reg signed [31:0] in_buf_wdata_re, in_buf_wdata_im;
reg out_buf_we;
reg [LOG2N-1:0] out_buf_waddr;
reg signed [31:0] out_buf_wdata_re, out_buf_wdata_im;
reg signed [31:0] out_rd_re, out_rd_im;
reg out_rd_valid;
fft_engine #(
.N(N), .LOG2N(LOG2N), .DATA_W(32), .INTERNAL_W(32),
.TWIDDLE_W(16), .TWIDDLE_FILE("fft_twiddle_2048.mem")
) fft_core (
.clk(aclk), .reset_n(aresetn),
.start(fft_start), .inverse(fft_inverse),
.din_re(fft_din_re), .din_im(fft_din_im), .din_valid(fft_din_valid),
.dout_re(fft_dout_re), .dout_im(fft_dout_im), .dout_valid(fft_dout_valid),
.busy(fft_busy), .done(fft_done)
);
assign s_axis_config_tready = (state == S_IDLE);
assign s_axis_data_tready = (state == S_FEED) && (in_count < N);
assign m_axis_data_tdata = {out_rd_im, out_rd_re};
assign m_axis_data_tvalid = out_rd_valid;
assign m_axis_data_tlast = out_rd_valid && (out_count == N);
always @(posedge aclk) begin
if (in_buf_we) begin
in_buf_re[in_buf_waddr] <= in_buf_wdata_re;
in_buf_im[in_buf_waddr] <= in_buf_wdata_im;
end
if (out_buf_we) begin
out_buf_re[out_buf_waddr] <= out_buf_wdata_re;
out_buf_im[out_buf_waddr] <= out_buf_wdata_im;
end
end
always @(posedge aclk or negedge aresetn) begin
if (!aresetn) begin
state <= S_IDLE;
inverse_reg <= 1'b0;
in_count <= 0;
feed_count <= 0;
out_total <= 0;
out_count <= 0;
fft_start <= 1'b0;
fft_inverse <= 1'b0;
fft_din_re <= 0;
fft_din_im <= 0;
fft_din_valid <= 1'b0;
in_buf_we <= 1'b0;
in_buf_waddr <= 0;
in_buf_wdata_re <= 0;
in_buf_wdata_im <= 0;
out_buf_we <= 1'b0;
out_buf_waddr <= 0;
out_buf_wdata_re <= 0;
out_buf_wdata_im <= 0;
out_rd_re <= 0;
out_rd_im <= 0;
out_rd_valid <= 1'b0;
end else begin
fft_start <= 1'b0;
fft_din_valid <= 1'b0;
in_buf_we <= 1'b0;
out_buf_we <= 1'b0;
case (state)
S_IDLE: begin
in_count <= 0;
feed_count <= 0;
out_total <= 0;
out_count <= 0;
out_rd_valid <= 1'b0;
if (s_axis_config_tvalid) begin
inverse_reg <= ~s_axis_config_tdata[0];
state <= S_FEED;
end
end
S_FEED: begin
if (in_count < N) begin
if (s_axis_data_tvalid) begin
in_buf_we <= 1'b1;
in_buf_waddr <= in_count[LOG2N-1:0];
in_buf_wdata_re <= s_axis_data_tdata[31:0];
in_buf_wdata_im <= s_axis_data_tdata[63:32];
in_count <= in_count + 1;
end
end else begin
fft_start <= 1'b1;
fft_inverse <= inverse_reg;
feed_count <= 0;
out_total <= 0;
state <= S_RUN;
end
end
S_RUN: begin
if (feed_count < N) begin
fft_din_re <= in_buf_re[feed_count[LOG2N-1:0]];
fft_din_im <= in_buf_im[feed_count[LOG2N-1:0]];
fft_din_valid <= 1'b1;
feed_count <= feed_count + 1;
end
if (fft_dout_valid && out_total < N) begin
out_buf_we <= 1'b1;
out_buf_waddr <= out_total[LOG2N-1:0];
out_buf_wdata_re <= fft_dout_re;
out_buf_wdata_im <= fft_dout_im;
out_total <= out_total + 1;
end
if (fft_done && out_total >= N) begin
state <= S_OUTPUT;
out_count <= 0;
out_rd_valid <= 1'b0;
end
end
S_OUTPUT: begin
if (m_axis_data_tready || !out_rd_valid) begin
if (out_count < N) begin
out_rd_re <= out_buf_re[out_count[LOG2N-1:0]];
out_rd_im <= out_buf_im[out_count[LOG2N-1:0]];
out_rd_valid <= 1'b1;
out_count <= out_count + 1;
end else begin
out_rd_valid <= 1'b0;
state <= S_IDLE;
end
end
end
default: state <= S_IDLE;
endcase
end
end
`ifdef SIMULATION
integer init_k;
initial begin
for (init_k = 0; init_k < N; init_k = init_k + 1) begin
in_buf_re[init_k] = 0;
in_buf_im[init_k] = 0;
out_buf_re[init_k] = 0;
out_buf_im[init_k] = 0;
end
end
`endif
`endif // FFT_USE_XILINX_IP
endmodule
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