// tb_mlkem_dec_katK_xsim.v - ML-KEM Decaps vs NIST KAT, parametric K (KP) + CASE. // D0 stage: stream dk (=sk) into the design via dk_in_* (routed to // dk_pke/ek_pke/h/z by region) and ct via c_in_*, pulse start with op=2, and // verify the dk PARSE: H(ek) (dbg_dech_o), z (dbg_decz_o), and round-trip a few // ek_pke bytes (dbg_byte sel=0) and dk_pke bytes (sel=1) back out of BRAM. // // xelab -generic_top KP=2|3|4 ; xsim -testplusarg CASE=n // dk/ct/ss vectors: sync_rtl/top/TB/vectors/dec_k{K}_c{N}_{dk,ct,ss,ctn,ssn}.hex `timescale 1ns/1ps module tb_mlkem_dec_katK_xsim; parameter KP = 2; localparam DKB = 768*KP + 96; // dk (=sk) bytes: 1632/2400/3168 localparam EKB = 384*KP + 32; // ek_pke bytes within dk localparam DKPB = 384*KP; // dk_pke bytes localparam CTB = (KP==4) ? 1568 : (32*(10*KP+4)); // ct bytes: 768/1088/1568 reg clk=0, rst_n=0, start_i=0; reg [2:0] k_i; reg [255:0] d_i=0, z_i=0, m_i=0; wire busy_o, done_o; // ek preload port (unused in Decaps; ek_pke comes from dk) reg ek_in_we=0; reg [10:0] ek_in_addr=0; reg [7:0] ek_in_byte=0; // dk / c input ports reg dk_in_we=0; reg [11:0] dk_in_addr=0; reg [7:0] dk_in_byte=0; reg c_in_we=0; reg [10:0] c_in_addr=0; reg [7:0] c_in_byte=0; wire [255:0] ss_o; reg [10:0] dbg_ct_idx_i=0; wire [7:0] dbg_ct_o; reg [5:0] dbg_slot_i=0; reg [7:0] dbg_idx_i=0; wire [11:0] dbg_coeff_o; reg dbg_byte_sel_i=0; reg [10:0] dbg_byte_idx_i=0; wire [7:0] dbg_byte_o; reg [11:0] dbg_dk_idx_i=0; wire [7:0] dbg_dk_o; wire [255:0] dbg_rho_o, dbg_sigma_o, dbg_r_o, dbg_hek_o; wire [255:0] dbg_mprime_o, dbg_kbar_o, dbg_decz_o, dbg_dech_o; mlkem_top dut ( .clk(clk), .rst_n(rst_n), .k_i(k_i), .op_i(2'd2), .d_i(d_i), .z_i(z_i), .msg_i(m_i), .start_i(start_i), .busy_o(busy_o), .done_o(done_o), .ek_in_we(ek_in_we), .ek_in_addr(ek_in_addr), .ek_in_byte(ek_in_byte), .dk_in_we(dk_in_we), .dk_in_addr(dk_in_addr), .dk_in_byte(dk_in_byte), .c_in_we(c_in_we), .c_in_addr(c_in_addr), .c_in_byte(c_in_byte), .ss_o(ss_o), .dbg_ct_idx_i(dbg_ct_idx_i), .dbg_ct_o(dbg_ct_o), .dbg_slot_i(dbg_slot_i), .dbg_idx_i(dbg_idx_i), .dbg_coeff_o(dbg_coeff_o), .dbg_byte_sel_i(dbg_byte_sel_i), .dbg_byte_idx_i(dbg_byte_idx_i), .dbg_byte_o(dbg_byte_o), .dbg_dk_idx_i(dbg_dk_idx_i), .dbg_dk_o(dbg_dk_o), .dbg_rho_o(dbg_rho_o), .dbg_sigma_o(dbg_sigma_o), .dbg_r_o(dbg_r_o), .dbg_hek_o(dbg_hek_o), .dbg_mprime_o(dbg_mprime_o), .dbg_kbar_o(dbg_kbar_o), .dbg_decz_o(dbg_decz_o), .dbg_dech_o(dbg_dech_o) ); always #5 clk = ~clk; reg [7:0] dk_b [0:DKB-1]; reg [7:0] ct_b [0:CTB-1]; reg [7:0] ss_b [0:31]; integer c, i, j, errors, casenum; reg [8*80-1:0] tag, dkfile, ctfile, ssfile; initial begin if (!$value$plusargs("CASE=%d", casenum)) casenum = 0; $sformat(tag, "k%0d", KP); $sformat(dkfile, "sync_rtl/top/TB/vectors/dec_%0s_c%0d_dk.hex", tag, casenum); $sformat(ctfile, "sync_rtl/top/TB/vectors/dec_%0s_c%0d_ct.hex", tag, casenum); $sformat(ssfile, "sync_rtl/top/TB/vectors/dec_%0s_c%0d_ss.hex", tag, casenum); $readmemh(dkfile, dk_b); $readmemh(ctfile, ct_b); $readmemh(ssfile, ss_b); k_i = KP[2:0]; $display("=== ML-KEM K=%0d Decaps KAT case %0d (D0: load+parse) ===", KP, casenum); rst_n=0; repeat(4) @(posedge clk); rst_n=1; @(posedge clk); // ---- stream dk into the design (1 byte/cycle) ---- for (i = 0; i < DKB; i = i + 1) begin dk_in_we = 1'b1; dk_in_addr = i[11:0]; dk_in_byte = dk_b[i]; @(posedge clk); end dk_in_we = 1'b0; // ---- stream ct into c_in_bram (1 byte/cycle) ---- for (i = 0; i < CTB; i = i + 1) begin c_in_we = 1'b1; c_in_addr = i[10:0]; c_in_byte = ct_b[i]; @(posedge clk); end c_in_we = 1'b0; @(posedge clk); // ---- run Decaps ---- start_i=1; @(posedge clk); start_i=0; c=0; while(!done_o && c<2000000) begin @(posedge clk); c=c+1; end if(!done_o) begin $display("FAIL K=%0d case %0d: timeout", KP, casenum); $finish; end $display("=== Decaps D6 done in %0d cyc ===", c); // D6 re-encrypt clobbers bank_a/bank_se/bank_t, so the bank-based stage // checks (D1 v', D2 s_hat/u_hat, D3 w) are no longer valid at end-of-run; // their correctness was proven on earlier per-stage builds and transitively // by c'. Here we check the surviving register/BRAM artifacts: dk parse (D0), // m'/K'/r'/K-bar (D5), and the re-encrypted ciphertext c' (D6). verify_d0; // also initializes errors = 0 verify_d4; // m' (now in m_r, survives the re-encrypt) verify_d5; verify_d6; if (errors == 0) $display("K=%0d CASE %0d PASS (D6): c' = Encrypt(ek,m',r') OK", KP, casenum); else $display("K=%0d CASE %0d FAIL (D6): %0d total errors", KP, casenum, errors); $finish; end initial begin #120000000; $display("FAIL: global timeout"); $finish; end // read one stored coefficient at (slot, idx): present addr, wait for the // bank read (sd_bram, 1 cyc) + dbg_coeff_r register (1 cyc) + settle. task rdcoeff; input [5:0] slot; input [7:0] idx; output [11:0] val; begin dbg_slot_i = slot; dbg_idx_i = idx; @(posedge clk); @(posedge clk); @(posedge clk); val = dbg_coeff_o; end endtask // D0: verify dk parse. H(ek)=dk[768K+32:+32], z=dk[768K+64:+32] captured into // hek_r/z_r (dbg_dech_o/dbg_decz_o). ek_pke=dk[384K:768K+32] in ek_bram // (dbg_byte sel=0), dk_pke=dk[0:384K] in dkp_bram (sel=1). task verify_d0; integer be; reg [7:0] got; begin errors = 0; // H(ek) for (j = 0; j < 32; j = j + 1) if (dbg_dech_o[8*j +: 8] !== dk_b[DKPB + EKB + j]) errors = errors + 1; if (errors == 0) $display(" PASS: H(ek) parsed == dk[768K+32 ..]"); else $display(" FAIL: H(ek) %0d byte mismatches", errors); // z be = 0; for (j = 0; j < 32; j = j + 1) if (dbg_decz_o[8*j +: 8] !== dk_b[DKPB + EKB + 32 + j]) be = be + 1; if (be == 0) $display(" PASS: z parsed == dk[768K+64 ..]"); else $display(" FAIL: z %0d byte mismatches", be); errors = errors + be; // ek_pke round-trip (every 97th byte to keep it quick) be = 0; for (i = 0; i < EKB; i = i + 97) begin dbg_byte_sel_i = 1'b0; dbg_byte_idx_i = i[10:0]; @(posedge clk); @(posedge clk); if (dbg_byte_o !== dk_b[DKPB + i]) begin if (be < 6) $display(" ekpke[%0d] got=%02x exp=%02x", i, dbg_byte_o, dk_b[DKPB+i]); be = be + 1; end end if (be == 0) $display(" PASS: ek_pke round-trip (BRAM) == dk[384K ..]"); else $display(" FAIL: ek_pke %0d byte mismatches", be); errors = errors + be; // dk_pke round-trip be = 0; for (i = 0; i < DKPB; i = i + 97) begin dbg_byte_sel_i = 1'b1; dbg_byte_idx_i = i[10:0]; @(posedge clk); @(posedge clk); if (dbg_byte_o !== dk_b[i]) begin if (be < 6) $display(" dkpke[%0d] got=%02x exp=%02x", i, dbg_byte_o, dk_b[i]); be = be + 1; end end if (be == 0) $display(" PASS: dk_pke round-trip (BRAM) == dk[0 ..]"); else $display(" FAIL: dk_pke %0d byte mismatches", be); errors = errors + be; if (errors == 0) $display(" D0 subcheck PASS: dk parse OK"); else $display(" D0 subcheck FAIL: %0d errors", errors); end endtask // D1: verify u'[i] (bank_se rel i, abs slot K*K+i) and v' (bank_t rel // DEC_VSLOT=2, abs slot K*K+2*K+2) against the decode-decompress golden. reg [11:0] up_g [0:255]; reg [11:0] vp_g [0:255]; task verify_d1; integer i, j, be, ndiff; reg [8*100-1:0] fn; reg [11:0] got; begin ndiff = 0; // u'[i] is NOT checked here: D2's forward NTT transforms u' in place // in bank_se rel 0..K-1, so by the time the run finishes those slots // hold u_hat. u' correctness is proven transitively in verify_d2 // (u_hat == NTT(u') golden). Only v' (bank_a slot 1, untouched) checked. // v' lives in bank_a DEC_VASLOT=1 (abs slot 1). $sformat(fn, "sync_rtl/top/TB/vectors/decgold/dc_k%0d_c%0d_vp.hex", KP, casenum); $readmemh(fn, vp_g); be = 0; for (j = 0; j < 256; j = j + 1) begin rdcoeff(1, j[7:0], got); if (got !== vp_g[j]) begin if (be < 4) $display(" v'[%0d] got=%03x exp=%03x", j, got, vp_g[j]); be = be + 1; end end if (be == 0) $display(" PASS: v' == golden (256 coeffs)"); else $display(" FAIL: v' %0d coeff mismatches", be); ndiff = ndiff + be; errors = errors + ndiff; end endtask // D2: verify s_hat[i] (bank_a slot i*K, byteDecode12 dk_pke) and // u_hat[i] (bank_se rel slot i, = NTT(u'[i])) against golden. reg [11:0] sh_g [0:255]; reg [11:0] uh_g [0:255]; task verify_d2; integer i, j, be, ndiff; reg [8*100-1:0] fn; reg [11:0] got; begin ndiff = 0; for (i = 0; i < KP; i = i + 1) begin // s_hat[i] at bank_a slot i*KP $sformat(fn, "sync_rtl/top/TB/vectors/decgold/dc_k%0d_c%0d_shat_%0d.hex", KP, casenum, i); $readmemh(fn, sh_g); be = 0; for (j = 0; j < 256; j = j + 1) begin rdcoeff(i*KP, j[7:0], got); if (got !== sh_g[j]) begin if (be < 4) $display(" s_hat[%0d][%0d] got=%03x exp=%03x", i, j, got, sh_g[j]); be = be + 1; end end if (be == 0) $display(" PASS: s_hat[%0d] == golden", i); else $display(" FAIL: s_hat[%0d] %0d mismatches", i, be); ndiff = ndiff + be; // u_hat[i] at bank_se rel slot i (abs KP*KP + i) $sformat(fn, "sync_rtl/top/TB/vectors/decgold/dc_k%0d_c%0d_uhat_%0d.hex", KP, casenum, i); $readmemh(fn, uh_g); be = 0; for (j = 0; j < 256; j = j + 1) begin rdcoeff(KP*KP + i, j[7:0], got); if (got !== uh_g[j]) begin if (be < 4) $display(" u_hat[%0d][%0d] got=%03x exp=%03x", i, j, got, uh_g[j]); be = be + 1; end end if (be == 0) $display(" PASS: u_hat[%0d] == golden", i); else $display(" FAIL: u_hat[%0d] %0d mismatches", i, be); ndiff = ndiff + be; end errors = errors + ndiff; end endtask // D3: verify w (bank_t rel UPSUM=1, abs slot K*K+2*K+1) == golden. reg [11:0] w_g [0:255]; task verify_d3; integer j, be; reg [8*100-1:0] fn; reg [11:0] got; begin $sformat(fn, "sync_rtl/top/TB/vectors/decgold/dc_k%0d_c%0d_w.hex", KP, casenum); $readmemh(fn, w_g); be = 0; for (j = 0; j < 256; j = j + 1) begin rdcoeff(KP*KP + 2*KP + 1, j[7:0], got); if (got !== w_g[j]) begin if (be < 4) $display(" w[%0d] got=%03x exp=%03x", j, got, w_g[j]); be = be + 1; end end if (be == 0) $display(" PASS: w == golden (256 coeffs)"); else $display(" FAIL: w %0d coeff mismatches", be); errors = errors + be; end endtask // D4: verify m' = byteEncode_1(Compress_1(w)) == golden (32 bytes via dbg). reg [7:0] mp_g [0:31]; task verify_d4; integer j, be; reg [8*100-1:0] fn; begin $sformat(fn, "sync_rtl/top/TB/vectors/decgold/dc_k%0d_c%0d_mprime.hex", KP, casenum); $readmemh(fn, mp_g); be = 0; for (j = 0; j < 32; j = j + 1) begin if (dbg_mprime_o[8*j +: 8] !== mp_g[j]) begin if (be < 4) $display(" m'[%0d] got=%02x exp=%02x", j, dbg_mprime_o[8*j +: 8], mp_g[j]); be = be + 1; end end if (be == 0) $display(" PASS: m' == golden (32 bytes)"); else $display(" FAIL: m' %0d byte mismatches", be); errors = errors + be; end endtask // D5: verify K' (ss_o), r' (dbg_r_o), K-bar (dbg_kbar_o) against golden. reg [7:0] kp_b [0:31]; reg [7:0] rp_b [0:31]; reg [7:0] kb_b [0:31]; task verify_d5; integer j, be; reg [8*100-1:0] fn; begin // K' = G(m'||h) low half -> ss_o $sformat(fn, "sync_rtl/top/TB/vectors/decgold/dc_k%0d_c%0d_kprime.hex", KP, casenum); $readmemh(fn, kp_b); be = 0; for (j = 0; j < 32; j = j + 1) if (ss_o[8*j +: 8] !== kp_b[j]) begin if (be < 4) $display(" K'[%0d] got=%02x exp=%02x", j, ss_o[8*j +: 8], kp_b[j]); be = be + 1; end if (be == 0) $display(" PASS: K' == golden (32 bytes)"); else $display(" FAIL: K' %0d byte mismatches", be); errors = errors + be; // r' = G(m'||h) high half -> dbg_r_o $sformat(fn, "sync_rtl/top/TB/vectors/decgold/dc_k%0d_c%0d_rprime.hex", KP, casenum); $readmemh(fn, rp_b); be = 0; for (j = 0; j < 32; j = j + 1) if (dbg_r_o[8*j +: 8] !== rp_b[j]) begin if (be < 4) $display(" r'[%0d] got=%02x exp=%02x", j, dbg_r_o[8*j +: 8], rp_b[j]); be = be + 1; end if (be == 0) $display(" PASS: r' == golden (32 bytes)"); else $display(" FAIL: r' %0d byte mismatches", be); errors = errors + be; // K-bar = J(z||c) -> dbg_kbar_o $sformat(fn, "sync_rtl/top/TB/vectors/decgold/dc_k%0d_c%0d_kbar.hex", KP, casenum); $readmemh(fn, kb_b); be = 0; for (j = 0; j < 32; j = j + 1) if (dbg_kbar_o[8*j +: 8] !== kb_b[j]) begin if (be < 4) $display(" K-bar[%0d] got=%02x exp=%02x", j, dbg_kbar_o[8*j +: 8], kb_b[j]); be = be + 1; end if (be == 0) $display(" PASS: K-bar == golden (32 bytes)"); else $display(" FAIL: K-bar %0d byte mismatches", be); errors = errors + be; end endtask // D6: verify c' = K-PKE.Encrypt(ek_pke, m', r') in ct_bram == golden. // ct length = 32*(du*K + dv): K2=768, K3=1088, K4=1568. reg [7:0] cp_b [0:1567]; task verify_d6; integer i, be, ctlen; reg [8*100-1:0] fn; reg [7:0] got; begin ctlen = (KP == 2) ? 768 : (KP == 3) ? 1088 : 1568; $sformat(fn, "sync_rtl/top/TB/vectors/decgold/dc_k%0d_c%0d_cprime.hex", KP, casenum); $readmemh(fn, cp_b); be = 0; for (i = 0; i < ctlen; i = i + 1) begin dbg_ct_idx_i = i[10:0]; @(posedge clk); @(posedge clk); @(posedge clk); got = dbg_ct_o; if (got !== cp_b[i]) begin if (be < 6) $display(" c'[%0d] got=%02x exp=%02x", i, got, cp_b[i]); be = be + 1; end end if (be == 0) $display(" PASS: c' == golden (%0d bytes)", ctlen); else $display(" FAIL: c' %0d byte mismatches", be); errors = errors + be; end endtask endmodule