Files
retroDE_ps2/sim/tb/integration/tb_sif_iop_bridge_exec.sv
T
thejayman77 ec82764bef Initial commit: retroDE_ps2 — first-of-its-kind PS2 GS FPGA core (DE25-Nano / Agilex 5)
RTL (GS rasterizer, EE core stub, platform bridge, LPDDR4B path), sim regression
(272 TBs), docs, and tooling. Copyrighted PS2 content (BIOS, game code, GS dumps,
and all dump-derived textures/traces) is excluded via .gitignore and stays local.

Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
2026-06-29 20:10:50 -04:00

564 lines
23 KiB
Systemverilog

// retroDE_ps2 — tb_sif_iop_bridge_exec
//
// Execution-visible bridge milestone. Extends the bridge-smoke proof by
// having iop_fetch_stub read back the landed payload through the real
// IOP path — not just a TB-side read port.
//
// Chain:
// ee_ram_stub
// → ee_memory_map_stub → dmac_reg_stub (ch5)
// → sif_dma_iop_ram_bridge_stub
// → iop_memory_map_stub (bridge write port)
// → iop_ram_stub
// ↑
// iop_fetch_stub ← iop_memory_map_stub (CPU read port)
//
// Ordering discipline (per Codex): DO NOT overlap DMA and fetch in this
// first pass. The fetcher stays disabled until the full transfer plus
// bridge flush has completed. Overlap is a later milestone.
//
// Key interface-visible / trace-visible assertions:
// - bridge writes complete before fetch starts
// - IOP IFETCH arg0 walks 0x00, 0x04, 0x08, ... 0x1C (8 words)
// - IFETCH arg1 matches the bridged little-endian unpacking of the
// source qwords
// - map-layer reads tagged master_id=IOP_CPU (2), region=IOP_RAM (2)
// - RAM-layer reads carry the same master_id attribution
`timescale 1ns/1ps
module tb_sif_iop_bridge_exec;
logic clk;
logic rst_n;
initial clk = 1'b0;
always #5 clk = ~clk;
localparam int QWC_VAL = 2;
localparam int EE_RAM_BYTES = 4 * 1024;
localparam int EE_RAM_ADDR_W = $clog2(EE_RAM_BYTES);
localparam int IOP_RAM_BYTES = 4 * 1024;
localparam int IOP_RAM_ADDR_W = $clog2(IOP_RAM_BYTES);
localparam logic [31:0] SOURCE_MADR = 32'h0000_0700;
localparam logic [31:0] DEST_BASE_ADDR = 32'h0000_0000; // = fetcher reset vector
// ------------------------------------------------------------------
// EE-side RAM (source)
// ------------------------------------------------------------------
logic ee_ram_rd_en;
logic [EE_RAM_ADDR_W-1:0] ee_ram_rd_addr;
logic [127:0] ee_ram_rd_data;
logic ee_ram_rd_valid;
logic ee_ram_wr_en;
logic [EE_RAM_ADDR_W-1:0] ee_ram_wr_addr;
logic [127:0] ee_ram_wr_data;
logic [15:0] ee_ram_wr_be;
logic [7:0] ee_ram_master_id;
ee_ram_stub #(.SIZE_BYTES(EE_RAM_BYTES)) u_ee_ram (
.clk(clk), .rst_n(rst_n),
.rd_en(ee_ram_rd_en), .rd_addr(ee_ram_rd_addr),
.rd_data(ee_ram_rd_data), .rd_valid(ee_ram_rd_valid),
.wr_en(ee_ram_wr_en), .wr_addr(ee_ram_wr_addr),
.wr_data(ee_ram_wr_data), .wr_be(ee_ram_wr_be),
.master_id(ee_ram_master_id),
.ev_valid(), .ev_subsys(), .ev_event(),
.ev_arg0(), .ev_arg1(), .ev_arg2(), .ev_arg3(), .ev_flags()
);
assign ee_ram_master_id = ee_ram_rd_en ? 8'd1 : 8'd0;
// ------------------------------------------------------------------
// EE DMAC (ch5) + EE memory map
// ------------------------------------------------------------------
logic dmac_reg_wr_en;
logic [7:0] dmac_reg_offset;
logic [31:0] dmac_reg_wr_data;
logic dmac_mem_rd_en;
logic [31:0] dmac_mem_rd_addr;
logic [127:0] map_to_dmac_rd_data;
logic map_to_dmac_rd_valid;
logic dmac_ep_valid;
logic [127:0] dmac_ep_data;
logic dmac_ep_last;
logic dmac_ep_ready;
logic dmac_ev_valid;
trace_pkg::subsys_e dmac_ev_subsys;
trace_pkg::event_e dmac_ev_event;
logic [63:0] dmac_ev_arg0, dmac_ev_arg1, dmac_ev_arg2, dmac_ev_arg3;
logic [31:0] dmac_ev_flags;
dmac_reg_stub #(.CHANNEL(4'd5), .PATH_ID(4'd5)) u_dmac (
.clk(clk), .rst_n(rst_n),
.reg_wr_en(dmac_reg_wr_en), .reg_offset(dmac_reg_offset),
.reg_wr_data(dmac_reg_wr_data),
.reg_rd_en(1'b0), .reg_rd_data(), .reg_rd_valid(),
.mem_rd_en(dmac_mem_rd_en), .mem_rd_addr(dmac_mem_rd_addr),
.mem_rd_data(map_to_dmac_rd_data), .mem_rd_valid(map_to_dmac_rd_valid),
.ep_valid(dmac_ep_valid), .ep_data(dmac_ep_data),
.ep_last(dmac_ep_last), .ep_ready(dmac_ep_ready),
.irq_completion_o(),
.ev_valid(dmac_ev_valid), .ev_subsys(dmac_ev_subsys),
.ev_event(dmac_ev_event),
.ev_arg0(dmac_ev_arg0), .ev_arg1(dmac_ev_arg1),
.ev_arg2(dmac_ev_arg2), .ev_arg3(dmac_ev_arg3),
.ev_flags(dmac_ev_flags)
);
logic ee_map_ram_rd_en;
logic [24:0] ee_map_ram_rd_addr;
ee_memory_map_stub u_ee_map (
.clk(clk), .rst_n(rst_n),
.ee_rd_en(1'b0), .ee_rd_addr(32'd0),
.ee_rd_data(), .ee_rd_valid(),
.ee_wr_en(1'b0), .ee_wr_addr(32'd0),
.ee_wr_data(32'd0), .ee_wr_be(4'd0),
.dmac_rd_en(dmac_mem_rd_en), .dmac_rd_addr(dmac_mem_rd_addr),
.dmac_rd_data(map_to_dmac_rd_data),
.dmac_rd_valid(map_to_dmac_rd_valid),
.bios_rd_en(), .bios_rd_addr(),
.bios_rd_data(32'd0), .bios_rd_valid(1'b0),
.ram_rd_en(ee_map_ram_rd_en), .ram_rd_addr(ee_map_ram_rd_addr),
.ram_rd_data(ee_ram_rd_data), .ram_rd_valid(ee_ram_rd_valid),
.bridge_wr_en(1'b0), .bridge_wr_addr(32'd0),
.bridge_wr_data(128'd0), .bridge_wr_be(16'd0),
.bridge_master_id(8'd0),
.ram_wr_en(), .ram_wr_addr(), .ram_wr_data(),
.ram_wr_be(), .ram_master_id(),
.ee_dmac_ch2_wr_en(), .ee_dmac_ch2_wr_addr(), .ee_dmac_ch2_wr_data(),
.ee_dmac_ch2_rd_en(), .ee_dmac_ch2_rd_addr(),
.ee_dmac_ch2_rd_data(32'd0), .ee_dmac_ch2_rd_valid(1'b0),
.ee_intc_wr_en(), .ee_intc_wr_addr(), .ee_intc_wr_data(),
.ee_intc_rd_en(), .ee_intc_rd_addr(),
.ee_intc_rd_data(32'd0), .ee_intc_rd_valid(1'b0),
.ee_misc_mmio_wr_en(), .ee_misc_mmio_wr_addr(), .ee_misc_mmio_wr_data(), .ee_misc_mmio_wr_be(),
.ee_misc_mmio_rd_en(), .ee_misc_mmio_rd_addr(),
.ee_misc_mmio_rd_data(32'd0), .ee_misc_mmio_rd_valid(1'b0),
.ee_biu_wr_en(), .ee_biu_wr_addr(), .ee_biu_wr_data(), .ee_biu_wr_be(),
.ee_biu_rd_en(), .ee_biu_rd_addr(),
.ee_biu_rd_data(32'd0), .ee_biu_rd_valid(1'b0),
.ev_valid(), .ev_subsys(), .ev_event(),
.ev_arg0(), .ev_arg1(), .ev_arg2(), .ev_arg3(), .ev_flags()
);
assign ee_ram_rd_en = ee_map_ram_rd_en;
assign ee_ram_rd_addr = ee_map_ram_rd_addr[EE_RAM_ADDR_W-1:0];
// ------------------------------------------------------------------
// Bridge
// ------------------------------------------------------------------
logic bridge_wr_en;
logic [31:0] bridge_wr_addr;
logic [31:0] bridge_wr_data;
logic [3:0] bridge_wr_be;
logic [7:0] bridge_master_id;
sif_dma_iop_ram_bridge_stub
#(.DEST_BASE_ADDR(DEST_BASE_ADDR), .MASTER_ID(8'd3))
u_bridge (
.clk(clk), .rst_n(rst_n),
.in_valid(dmac_ep_valid), .in_data(dmac_ep_data),
.in_last(dmac_ep_last), .in_ready(dmac_ep_ready),
.bridge_wr_en(bridge_wr_en), .bridge_wr_addr(bridge_wr_addr),
.bridge_wr_data(bridge_wr_data), .bridge_wr_be(bridge_wr_be),
.bridge_master_id(bridge_master_id)
);
// ------------------------------------------------------------------
// IOP fetch stub (default reset vector = 0x00000000 = DEST_BASE_ADDR)
// ------------------------------------------------------------------
logic fetch_enable;
logic fetch_rd_en;
logic [31:0] fetch_rd_addr;
logic [31:0] fetch_rd_data;
logic fetch_rd_valid;
logic fetch_ev_valid;
trace_pkg::subsys_e fetch_ev_subsys;
trace_pkg::event_e fetch_ev_event;
logic [63:0] fetch_ev_arg0, fetch_ev_arg1, fetch_ev_arg2, fetch_ev_arg3;
logic [31:0] fetch_ev_flags;
iop_fetch_stub #(.RESET_VECTOR(DEST_BASE_ADDR)) u_fetch (
.clk(clk), .rst_n(rst_n), .enable(fetch_enable),
.rd_en(fetch_rd_en), .rd_addr(fetch_rd_addr),
.rd_data(fetch_rd_data), .rd_valid(fetch_rd_valid),
.ev_valid(fetch_ev_valid), .ev_subsys(fetch_ev_subsys),
.ev_event(fetch_ev_event),
.ev_arg0(fetch_ev_arg0), .ev_arg1(fetch_ev_arg1),
.ev_arg2(fetch_ev_arg2), .ev_arg3(fetch_ev_arg3),
.ev_flags(fetch_ev_flags)
);
// ------------------------------------------------------------------
// IOP map + IOP RAM
// ------------------------------------------------------------------
logic iop_map_ram_rd_en;
logic [20:0] iop_map_ram_rd_addr;
logic [31:0] iop_ram_rd_data;
logic iop_ram_rd_valid;
logic iop_map_ram_wr_en;
logic [20:0] iop_map_ram_wr_addr;
logic [31:0] iop_map_ram_wr_data;
logic [3:0] iop_map_ram_wr_be;
logic [7:0] iop_map_ram_master_id;
logic iop_map_ev_valid;
trace_pkg::subsys_e iop_map_ev_subsys;
trace_pkg::event_e iop_map_ev_event;
logic [63:0] iop_map_ev_arg0, iop_map_ev_arg1, iop_map_ev_arg2, iop_map_ev_arg3;
logic [31:0] iop_map_ev_flags;
iop_memory_map_stub u_iop_map (
.clk(clk), .rst_n(rst_n),
// CPU-side read driven by the fetcher
.iop_rd_en(fetch_rd_en), .iop_rd_addr(fetch_rd_addr),
.iop_rd_data(fetch_rd_data), .iop_rd_valid(fetch_rd_valid),
// No CPU writes in this TB
.iop_wr_en(1'b0), .iop_wr_addr(32'd0),
.iop_wr_data(32'd0), .iop_wr_be(4'd0),
.master_id(8'd2), // IOP_CPU
// Bridge write port
.bridge_wr_en(bridge_wr_en), .bridge_wr_addr(bridge_wr_addr),
.bridge_wr_data(bridge_wr_data), .bridge_wr_be(bridge_wr_be),
.bridge_master_id(bridge_master_id),
// DMA read-master port — unused by this TB
.dma_rd_en(1'b0), .dma_rd_addr(32'd0),
.dma_master_id(8'd0),
.dma_rd_data(), .dma_rd_valid(),
// SIF register-shell port — unused by this TB
.sif_rd_en(), .sif_rd_addr(),
.sif_rd_data(32'd0), .sif_rd_valid(1'b0),
.sif_wr_en(), .sif_wr_addr(), .sif_wr_data(),
// IOP DMAC port — unused by this TB
.iop_dmac_rd_en(), .iop_dmac_rd_addr(),
.iop_dmac_rd_data(32'd0), .iop_dmac_rd_valid(1'b0),
.iop_dmac_wr_en(), .iop_dmac_wr_addr(), .iop_dmac_wr_data(),
// IOP INTC port — unused by this TB
.iop_intc_rd_en(), .iop_intc_rd_addr(),
.iop_intc_rd_data(32'd0), .iop_intc_rd_valid(1'b0),
.iop_intc_wr_en(), .iop_intc_wr_addr(), .iop_intc_wr_data(),
.input_p1(32'd0), .input_p2(32'd0),
// BIOS ROM port — unused by this TB
.bios_rd_en(), .bios_rd_addr(),
.bios_rd_data(32'd0), .bios_rd_valid(1'b0),
.ram_rd_en(iop_map_ram_rd_en), .ram_rd_addr(iop_map_ram_rd_addr),
.ram_rd_data(iop_ram_rd_data), .ram_rd_valid(iop_ram_rd_valid),
.ram_wr_en(iop_map_ram_wr_en), .ram_wr_addr(iop_map_ram_wr_addr),
.ram_wr_data(iop_map_ram_wr_data), .ram_wr_be(iop_map_ram_wr_be),
.ram_master_id(iop_map_ram_master_id),
.ev_valid(iop_map_ev_valid), .ev_subsys(iop_map_ev_subsys),
.ev_event(iop_map_ev_event),
.ev_arg0(iop_map_ev_arg0), .ev_arg1(iop_map_ev_arg1),
.ev_arg2(iop_map_ev_arg2), .ev_arg3(iop_map_ev_arg3),
.ev_flags(iop_map_ev_flags)
);
logic iop_ram_ev_valid;
trace_pkg::subsys_e iop_ram_ev_subsys;
trace_pkg::event_e iop_ram_ev_event;
logic [63:0] iop_ram_ev_arg0, iop_ram_ev_arg1, iop_ram_ev_arg2, iop_ram_ev_arg3;
logic [31:0] iop_ram_ev_flags;
iop_ram_stub #(.SIZE_BYTES(IOP_RAM_BYTES)) u_iop_ram (
.clk(clk), .rst_n(rst_n),
.rd_en(iop_map_ram_rd_en), .rd_addr(iop_map_ram_rd_addr[IOP_RAM_ADDR_W-1:0]),
.rd_data(iop_ram_rd_data), .rd_valid(iop_ram_rd_valid),
.wr_en(iop_map_ram_wr_en), .wr_addr(iop_map_ram_wr_addr[IOP_RAM_ADDR_W-1:0]),
.wr_data(iop_map_ram_wr_data), .wr_be(iop_map_ram_wr_be),
.master_id(iop_map_ram_master_id),
.ev_valid(iop_ram_ev_valid), .ev_subsys(iop_ram_ev_subsys),
.ev_event(iop_ram_ev_event),
.ev_arg0(iop_ram_ev_arg0), .ev_arg1(iop_ram_ev_arg1),
.ev_arg2(iop_ram_ev_arg2), .ev_arg3(iop_ram_ev_arg3),
.ev_flags(iop_ram_ev_flags)
);
// ------------------------------------------------------------------
// Trace sinks
// ------------------------------------------------------------------
trace_sink_stub #(.FILENAME("sif_iop_exec_dmac.trace"), .SINK_LABEL("dmac"))
u_trace_dmac (.clk(clk), .rst_n(rst_n),
.ev_valid(dmac_ev_valid), .ev_subsys(dmac_ev_subsys),
.ev_event(dmac_ev_event), .ev_arg0(dmac_ev_arg0),
.ev_arg1(dmac_ev_arg1), .ev_arg2(dmac_ev_arg2),
.ev_arg3(dmac_ev_arg3), .ev_flags(dmac_ev_flags));
trace_sink_stub #(.FILENAME("sif_iop_exec_iopmap.trace"), .SINK_LABEL("iop_map"))
u_trace_iopmap (.clk(clk), .rst_n(rst_n),
.ev_valid(iop_map_ev_valid), .ev_subsys(iop_map_ev_subsys),
.ev_event(iop_map_ev_event), .ev_arg0(iop_map_ev_arg0),
.ev_arg1(iop_map_ev_arg1), .ev_arg2(iop_map_ev_arg2),
.ev_arg3(iop_map_ev_arg3), .ev_flags(iop_map_ev_flags));
trace_sink_stub #(.FILENAME("sif_iop_exec_iopram.trace"), .SINK_LABEL("iop_ram"))
u_trace_iopram (.clk(clk), .rst_n(rst_n),
.ev_valid(iop_ram_ev_valid), .ev_subsys(iop_ram_ev_subsys),
.ev_event(iop_ram_ev_event), .ev_arg0(iop_ram_ev_arg0),
.ev_arg1(iop_ram_ev_arg1), .ev_arg2(iop_ram_ev_arg2),
.ev_arg3(iop_ram_ev_arg3), .ev_flags(iop_ram_ev_flags));
trace_sink_stub #(.FILENAME("sif_iop_exec_fetch.trace"), .SINK_LABEL("iop_fetch"))
u_trace_fetch (.clk(clk), .rst_n(rst_n),
.ev_valid(fetch_ev_valid), .ev_subsys(fetch_ev_subsys),
.ev_event(fetch_ev_event), .ev_arg0(fetch_ev_arg0),
.ev_arg1(fetch_ev_arg1), .ev_arg2(fetch_ev_arg2),
.ev_arg3(fetch_ev_arg3), .ev_flags(fetch_ev_flags));
// ------------------------------------------------------------------
// Expected payload
// ------------------------------------------------------------------
logic [127:0] src_qword [0:QWC_VAL-1];
logic [31:0] expected_word [0:(QWC_VAL*4)-1];
initial begin
src_qword[0] = 128'hFEED_FEED_FACE_FACE_CAFE_CAFE_BEEF_BEEF;
src_qword[1] = 128'h8888_8888_7777_7777_6666_6666_5555_5555;
expected_word[0] = 32'hBEEF_BEEF; // src_qword[0][31:0]
expected_word[1] = 32'hCAFE_CAFE; // src_qword[0][63:32]
expected_word[2] = 32'hFACE_FACE;
expected_word[3] = 32'hFEED_FEED;
expected_word[4] = 32'h5555_5555;
expected_word[5] = 32'h6666_6666;
expected_word[6] = 32'h7777_7777;
expected_word[7] = 32'h8888_8888;
end
// ------------------------------------------------------------------
// Counters / observers (interface and trace only)
// ------------------------------------------------------------------
longint unsigned cycle_count;
int dma_done_count;
logic dma_done_seen;
int bridge_writes_ram;
int ifetch_count;
int map_reads_fetch_tagged;
int data_mismatches;
longint unsigned last_bridge_write_cycle;
longint unsigned first_fetch_start_cycle;
initial begin
cycle_count = 0;
dma_done_count = 0;
dma_done_seen = 1'b0;
bridge_writes_ram = 0;
ifetch_count = 0;
map_reads_fetch_tagged = 0;
data_mismatches = 0;
last_bridge_write_cycle = 0;
first_fetch_start_cycle = 64'hFFFF_FFFF_FFFF_FFFF;
end
always_ff @(posedge clk) begin
cycle_count <= cycle_count + 64'd1;
if (rst_n && dmac_ev_valid &&
dmac_ev_event == trace_pkg::EV_DMA_DONE) begin
dma_done_count <= dma_done_count + 1;
dma_done_seen <= 1'b1;
end
// Bridge writes observed at RAM layer (master=3).
if (rst_n && iop_ram_ev_valid &&
iop_ram_ev_event == trace_pkg::EV_WRITE &&
iop_ram_ev_arg2[7:0] == 8'd3) begin
bridge_writes_ram <= bridge_writes_ram + 1;
last_bridge_write_cycle <= cycle_count;
end
// IOP IFETCH events — check content + walk pattern.
// Declare locals without inline init (iverilog warns about
// inline init inside always_ff without explicit lifetime).
if (rst_n && fetch_ev_valid &&
fetch_ev_event == trace_pkg::EV_IFETCH) begin : check_fetch
logic [31:0] obs_addr;
logic [31:0] obs_data;
logic [31:0] obs_idx;
obs_addr = fetch_ev_arg0[31:0];
obs_data = fetch_ev_arg1[31:0];
obs_idx = (obs_addr - DEST_BASE_ADDR) >> 2;
ifetch_count <= ifetch_count + 1;
if (first_fetch_start_cycle == 64'hFFFF_FFFF_FFFF_FFFF)
first_fetch_start_cycle <= cycle_count;
if (obs_idx < (QWC_VAL * 4)) begin
if (obs_data !== expected_word[obs_idx[2:0]]) begin
$error("[tb_sif_iop_bridge_exec] IFETCH word[%0d]: addr=0x%08h got 0x%08h expected 0x%08h",
obs_idx, obs_addr, obs_data, expected_word[obs_idx[2:0]]);
data_mismatches <= data_mismatches + 1;
end
end
end
// IOP map reads tagged as IOP_CPU.
if (rst_n && iop_map_ev_valid &&
iop_map_ev_event == trace_pkg::EV_READ &&
iop_map_ev_arg2[7:0] == 8'd2 && // master=IOP_CPU
iop_map_ev_arg3[7:0] == 8'd2) // region=IOP_RAM
map_reads_fetch_tagged <= map_reads_fetch_tagged + 1;
end
// ------------------------------------------------------------------
// Helpers
// ------------------------------------------------------------------
task automatic write_dmac(input logic [7:0] offset, input logic [31:0] data);
@(negedge clk);
dmac_reg_wr_en = 1'b1;
dmac_reg_offset = offset;
dmac_reg_wr_data = data;
@(negedge clk);
dmac_reg_wr_en = 1'b0;
dmac_reg_offset = 8'd0;
dmac_reg_wr_data = 32'd0;
endtask
task automatic preload_ee(input logic [EE_RAM_ADDR_W-1:0] addr,
input logic [127:0] data);
@(negedge clk);
ee_ram_wr_en = 1'b1;
ee_ram_wr_addr = addr;
ee_ram_wr_data = data;
ee_ram_wr_be = 16'hFFFF;
@(negedge clk);
ee_ram_wr_en = 1'b0;
ee_ram_wr_addr = '0;
ee_ram_wr_data = 128'd0;
ee_ram_wr_be = 16'd0;
endtask
// ------------------------------------------------------------------
// Stimulus
// ------------------------------------------------------------------
int errors;
initial begin
rst_n = 1'b0;
fetch_enable = 1'b0; // fetcher off during DMA
dmac_reg_wr_en = 1'b0;
dmac_reg_offset = 8'd0;
dmac_reg_wr_data = 32'd0;
ee_ram_wr_en = 1'b0;
ee_ram_wr_addr = '0;
ee_ram_wr_data = 128'd0;
ee_ram_wr_be = 16'd0;
errors = 0;
repeat (4) @(posedge clk);
rst_n = 1'b1;
repeat (2) @(posedge clk);
// --- Phase 1: preload EE RAM source ---
begin : do_preload
logic [31:0] a;
for (int i = 0; i < QWC_VAL; i++) begin
a = SOURCE_MADR + (i * 32'd16);
preload_ee(a[EE_RAM_ADDR_W-1:0], src_qword[i]);
end
end
// --- Phase 2: run DMA + bridge, keep fetcher disabled ---
write_dmac(8'h10, SOURCE_MADR);
write_dmac(8'h20, 32'd2);
write_dmac(8'h00, 32'h0000_0001);
begin : wait_dma
int spin;
spin = 0;
while (!dma_done_seen && spin < 500) begin
@(posedge clk);
spin = spin + 1;
end
if (!dma_done_seen) begin
$error("[tb_sif_iop_bridge_exec] DMA never completed");
errors = errors + 1;
end
end
// Let the bridge drain its last qword; overlap-prevention
// boundary.
repeat (20) @(posedge clk);
if (bridge_writes_ram !== (QWC_VAL * 4)) begin
$error("[tb_sif_iop_bridge_exec] expected %0d bridge writes at RAM layer before fetch, got %0d",
QWC_VAL * 4, bridge_writes_ram);
errors = errors + 1;
end
// --- Phase 3: enable fetcher, let it walk the landed payload ---
@(negedge clk);
fetch_enable = 1'b1;
repeat (QWC_VAL * 4 + 8) @(posedge clk);
fetch_enable = 1'b0;
repeat (4) @(posedge clk);
// --- Ordering check: fetch started AFTER last bridge write ---
if (first_fetch_start_cycle == 64'hFFFF_FFFF_FFFF_FFFF) begin
$error("[tb_sif_iop_bridge_exec] no IFETCH events observed");
errors = errors + 1;
end
if (first_fetch_start_cycle <= last_bridge_write_cycle) begin
$error("[tb_sif_iop_bridge_exec] fetch (cy %0d) did not strictly follow last bridge write (cy %0d)",
first_fetch_start_cycle, last_bridge_write_cycle);
errors = errors + 1;
end
// ------------------------------------------------------------------
$display("[tb_sif_iop_bridge_exec] dma_done=%0d bridge_writes=%0d ifetches=%0d iop_cpu_reads=%0d mismatches=%0d errors=%0d last_bw_cy=%0d first_fetch_cy=%0d",
dma_done_count, bridge_writes_ram, ifetch_count,
map_reads_fetch_tagged, data_mismatches, errors,
last_bridge_write_cycle, first_fetch_start_cycle);
if (dma_done_count != 1)
$error("expected exactly 1 DMA_DONE, got %0d", dma_done_count);
if (ifetch_count < (QWC_VAL * 4))
$error("expected >= %0d IFETCHes, got %0d",
QWC_VAL * 4, ifetch_count);
if (map_reads_fetch_tagged < (QWC_VAL * 4))
$error("expected >= %0d IOP_CPU-tagged map reads, got %0d",
QWC_VAL * 4, map_reads_fetch_tagged);
if (data_mismatches != 0)
$error("expected zero data mismatches, got %0d", data_mismatches);
if (errors == 0 &&
dma_done_count == 1 &&
bridge_writes_ram == (QWC_VAL * 4) &&
ifetch_count >= (QWC_VAL * 4) &&
map_reads_fetch_tagged >= (QWC_VAL * 4) &&
data_mismatches == 0 &&
first_fetch_start_cycle > last_bridge_write_cycle)
$display("[tb_sif_iop_bridge_exec] PASS");
else
$display("[tb_sif_iop_bridge_exec] FAIL");
$finish;
end
initial begin
#400000;
$error("[tb_sif_iop_bridge_exec] timeout");
$finish;
end
endmodule : tb_sif_iop_bridge_exec