Module Definition
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Module Instance : tb.dut.u_sha3.u_keccak

Instance :
SCORELINECONDTOGGLEFSMBRANCHASSERT
91.81 94.55 100.00 73.33 91.18 100.00


Instance's subtree :
SCORELINECONDTOGGLEFSMBRANCHASSERT
94.79 98.83 98.84 100.00 73.33 97.76 100.00


Parent :
SCORELINECONDTOGGLEFSMBRANCHASSERTNAME
95.96 97.56 88.89 100.00 93.33 100.00 u_sha3


Subtrees :
NAMESCORELINECONDTOGGLEFSMBRANCHASSERT
u_keccak_p 99.42 100.00 98.75 98.93 100.00
u_prim_sec_anchor_buf 100.00 100.00
u_round_count 100.00 100.00
u_state_regs 100.00 100.00 100.00 100.00


Since this is the module's only instance, the coverage report is the same as for the module.
Line Coverage for Module : keccak_round
Line No.TotalCoveredPercent
TOTAL11010494.55
CONT_ASSIGN17700
ALWAYS18033100.00
ALWAYS186706592.86
CONT_ASSIGN40711100.00
ALWAYS41177100.00
ALWAYS42433100.00
CONT_ASSIGN45011100.00
ALWAYS46866100.00
CONT_ASSIGN47711100.00
ALWAYS48577100.00
ALWAYS5074375.00
CONT_ASSIGN51811100.00
CONT_ASSIGN54811100.00
CONT_ASSIGN54911100.00
CONT_ASSIGN55111100.00
ALWAYS57533100.00

176 // state inputs 177 unreachable assign rnd_eq_end = (int'(round) == MaxRound - 1); 178 179 keccak_st_e keccak_st, keccak_st_d; 180 3/3 `PRIM_FLOP_SPARSE_FSM(u_state_regs, keccak_st_d, keccak_st, keccak_st_e, KeccakStIdle) Tests: T1 T2 T3  | T1 T2 T3  | T1 T2 T3 
PRIM_FLOP_SPARSE_FSM(u_state_regs, keccak_st_d, keccak_st, keccak_st_e, KeccakStIdle): 180.1 `ifdef SIMULATION 180.2 prim_sparse_fsm_flop #( 180.3 .StateEnumT(keccak_st_e), 180.4 .Width($bits(keccak_st_e)), 180.5 .ResetValue($bits(keccak_st_e)'(KeccakStIdle)), 180.6 .EnableAlertTriggerSVA(1), 180.7 .CustomForceName("keccak_st") 180.8 ) u_state_regs ( 180.9 .clk_i ( clk_i ), 180.10 .rst_ni ( rst_ni ), 180.11 .state_i ( keccak_st_d ), 180.12 .state_o ( ) 180.13 ); 180.14 always_ff @(posedge clk_i or negedge rst_ni) begin 180.15 1/1 if (!rst_ni) begin Tests: T1 T2 T3  180.16 1/1 keccak_st <= KeccakStIdle; Tests: T1 T2 T3  180.17 end else begin 180.18 1/1 keccak_st <= keccak_st_d; Tests: T1 T2 T3  180.19 end 180.20 end 180.21 u_state_regs_A: assert property (@(posedge clk_i) disable iff ((!rst_ni) !== '0) (keccak_st === u_state_regs.state_o)) 180.22 else begin 180.23 `ifdef UVM 180.24 uvm_pkg::uvm_report_error("ASSERT FAILED", "u_state_regs_A", uvm_pkg::UVM_NONE, 180.25 "../src/lowrisc_ip_sha3_0.1/rtl/keccak_round.sv", 180, "", 1); 180.26 `else 180.27 $error("%0t: (%0s:%0d) [%m] [ASSERT FAILED] %0s", $time, `__FILE__, `__LINE__, 180.28 `PRIM_STRINGIFY(u_state_regs_A)); 180.29 `endif 180.30 end 180.31 `else 180.32 prim_sparse_fsm_flop #( 180.33 .StateEnumT(keccak_st_e), 180.34 .Width($bits(keccak_st_e)), 180.35 .ResetValue($bits(keccak_st_e)'(KeccakStIdle)), 180.36 .EnableAlertTriggerSVA(1) 180.37 ) u_state_regs ( 180.38 .clk_i ( `PRIM_FLOP_CLK ), 180.39 .rst_ni ( `PRIM_FLOP_RST ), 180.40 .state_i ( keccak_st_d ), 180.41 .state_o ( keccak_st ) 180.42 ); 180.43 `endif181 182 // Next state logic and output logic 183 // SEC_CM: FSM.SPARSE 184 always_comb begin 185 // Default values 186 1/1 keccak_st_d = keccak_st; Tests: T1 T2 T3  187 188 1/1 xor_message = 1'b 0; Tests: T1 T2 T3  189 1/1 update_storage = 1'b 0; Tests: T1 T2 T3  190 1/1 rst_storage = 1'b 0; Tests: T1 T2 T3  191 192 1/1 inc_rnd_num = 1'b 0; Tests: T1 T2 T3  193 1/1 rst_rnd_num = 1'b 0; Tests: T1 T2 T3  194 195 1/1 keccak_rand_update = 1'b 0; Tests: T1 T2 T3  196 1/1 keccak_rand_consumed = 1'b 0; Tests: T1 T2 T3  197 198 1/1 phase_sel = MuBi4False; Tests: T1 T2 T3  199 1/1 low_then_high_d = low_then_high_q; Tests: T1 T2 T3  200 1/1 dom_in_low_d = dom_in_low_q; Tests: T1 T2 T3  201 1/1 dom_in_rand_ext_d = dom_in_rand_ext_q; Tests: T1 T2 T3  202 1/1 dom_update = 1'b 0; Tests: T1 T2 T3  203 204 1/1 complete_d = 1'b 0; Tests: T1 T2 T3  205 206 1/1 sparse_fsm_error_o = 1'b 0; Tests: T1 T2 T3  207 208 1/1 unique case (keccak_st) Tests: T1 T2 T3  209 KeccakStIdle: begin 210 1/1 if (valid_i) begin Tests: T1 T2 T3  211 // State machine allows Sponge Absorbing only in Idle state. 212 1/1 keccak_st_d = KeccakStIdle; Tests: T1 T2 T11  213 214 1/1 xor_message = 1'b 1; Tests: T1 T2 T11  215 1/1 update_storage = 1'b 1; Tests: T1 T2 T11  216 1/1 end else if (prim_mubi_pkg::mubi4_test_true_strict(clear_i)) begin Tests: T1 T2 T3  217 // Opt1. State machine allows resetting the storage only in Idle 218 // Opt2. storage resets regardless of states but clear_i 219 // Both are added in the design at this time. Will choose the 220 // direction later. 221 1/1 keccak_st_d = KeccakStIdle; Tests: T1 T2 T11  222 223 1/1 rst_storage = 1'b 1; Tests: T1 T2 T11  224 1/1 end else if (EnMasking && run_i) begin Tests: T1 T2 T3  225 // Masked version of Keccak handling 226 1/1 keccak_st_d = KeccakStPhase1; Tests: T1 T2 T11  227 228 // Drive DOM multiplier I/O mux signals for Phase 1. 229 1/1 dom_in_low_d = low_then_high_q; Tests: T1 T2 T11  230 1/1 dom_in_rand_ext_d = 1'b 0; Tests: T1 T2 T11  231 1/1 end else if (!EnMasking && run_i) begin Tests: T1 T2 T3  232 // Unmasked version of Keccak handling 233 unreachable keccak_st_d = KeccakStActive; 234 end else begin 235 1/1 keccak_st_d = KeccakStIdle; Tests: T1 T2 T3  236 end 237 end 238 239 KeccakStActive: begin 240 // Run Keccak single round logic until it reaches MaxRound - 1 241 0/1 ==> update_storage = 1'b 1; 242 243 0/1 ==> if (rnd_eq_end) begin 244 unreachable keccak_st_d = KeccakStIdle; 245 246 unreachable rst_rnd_num = 1'b 1; 247 unreachable complete_d = 1'b 1; 248 end else begin 249 0/1 ==> keccak_st_d = KeccakStActive; 250 251 0/1 ==> inc_rnd_num = 1'b 1; 252 end 253 end 254 255 KeccakStPhase1: begin 256 // Compute Theta, Rho, Pi - The DOM multipliers are not evaluated at 257 // all: their inputs are driven by the first lane halves (same values 258 // as in Phase2Cycle3 of the last round). Also, the intermediate 259 // results we already had in Phase2Cycle3 didn't change. 260 1/1 phase_sel = MuBi4False; Tests: T1 T2 T11  261 1/1 dom_update = 1'b 0; Tests: T1 T2 T11  262 263 // Only update the state and move on once we know the auxiliary 264 // randomness required for Phase2 will be available in the next clock 265 // cycle. 266 // 267 // It's important that the DOM multipliers inside keccak_2share are 268 // presented the new state (updated with update_storage) at the same 269 // time as the new randomness (updated with rand_update_o). Otherwise, 270 // stale entropy is paired with fresh data or vice versa. This could 271 // lead to undesired SCA leakage. 272 1/1 if (rand_early_i || rand_valid_i) begin Tests: T1 T2 T11  273 1/1 keccak_st_d = KeccakStPhase2Cycle1; Tests: T1 T2 T11  274 1/1 update_storage = 1'b 1; Tests: T1 T2 T11  275 1/1 keccak_rand_update = 1'b 1; Tests: T1 T2 T11  276 277 // Update lane halves processing order for this round. 278 1/1 low_then_high_d = rand_aux_i; Tests: T1 T2 T11  279 280 // Drive DOM multiplier I/O mux signals for next phase. 281 1/1 dom_in_low_d = low_then_high_d; Tests: T1 T2 T11  282 1/1 dom_in_rand_ext_d = 1'b 1; Tests: T1 T2 T11  283 end else begin 284 1/1 keccak_st_d = KeccakStPhase1; Tests: T1 T2 T11  285 end 286 end 287 288 KeccakStPhase2Cycle1: begin 289 // Compute first stage of Chi for first lane halves using the DOM 290 // multipliers. Use the fresh randomness provided by the PRNG for 291 // remasking. 292 1/1 phase_sel = MuBi4True; Tests: T1 T2 T11  293 1/1 dom_update = 1'b 1; Tests: T1 T2 T11  294 295 // Trigger randomness update for next cycle. 296 // It's important that the DOM multipliers inside keccak_2share are 297 // presented the second lane halves at the same time as the new 298 // randomness (updated with rand_update_o). Otherwise, stale entropy 299 // is paired with fresh data or vice versa. This could lead to 300 // undesired SCA leakage. 301 1/1 keccak_rand_update = 1'b 1; Tests: T1 T2 T11  302 303 // Unconditionally move to next phase/cycle. 304 1/1 keccak_st_d = KeccakStPhase2Cycle2; Tests: T1 T2 T11  305 306 // Drive DOM multiplier I/O mux signals for next phase. 307 1/1 dom_in_low_d = ~low_then_high_q; Tests: T1 T2 T11  308 1/1 dom_in_rand_ext_d = 1'b 1; Tests: T1 T2 T11  309 end 310 311 KeccakStPhase2Cycle2: begin 312 // Chi Stage 1 for second lane halves. 313 // Chi Stage 2 and Iota for first lane halves. 314 // Compute second stage of Chi and Iota for first lane halves. 315 // Compute first stage of Chi for second lane halves. Use the fresh 316 // randomness provided by the PRNG for remasking the DOM multipliers. 317 1/1 phase_sel = MuBi4True; Tests: T1 T2 T11  318 1/1 dom_update = 1'b 1; Tests: T1 T2 T11  319 320 // Trigger randomness update for next cycle. 321 // It's important that the DOM multipliers inside keccak_2share are 322 // presented the updated state at the same as the new randomness 323 // (updated with rand_update_o) - even if the DOM multipliers don't 324 // update the pipeline registers in the next cycle. Otherwise, stale 325 // entropy is paired with fresh data or vice versa. This could lead to 326 // undesired SCA leakage. 327 1/1 keccak_rand_update = 1'b 1; Tests: T1 T2 T11  328 329 // Trigger auxiliary randomness update for next round. The rand_aux_i 330 // signal is actually going to change in 2 clock cycles from now 331 // (Phase1) based on the PRNG output in the next cycle (Phase2Cycle3) 332 // in which the DOM multipliers don't update the pipeline registers. 333 1/1 keccak_rand_consumed = 1'b 1; Tests: T1 T2 T11  334 335 // Update first lane halves. 336 1/1 update_storage = 1'b 1; Tests: T1 T2 T11  337 338 // Unconditionally move to next phase/cycle. 339 1/1 keccak_st_d = KeccakStPhase2Cycle3; Tests: T1 T2 T11  340 341 // Drive DOM multiplier I/O mux signals for next phase. 342 1/1 dom_in_low_d = low_then_high_q; Tests: T1 T2 T11  343 1/1 dom_in_rand_ext_d = 1'b 0; Tests: T1 T2 T11  344 end 345 346 KeccakStPhase2Cycle3: begin 347 // Compute second stage of Chi and Iota for second lane halves. 348 // Feed again first lane halves to DOM multiplier inputs (now 349 // the updated values become visible) together with intermediate 350 // results of Phase2Cycle2. Don't update the register stage inside 351 // the DOM multipliers. 352 1/1 phase_sel = MuBi4True; Tests: T1 T2 T11  353 1/1 dom_update = 1'b 0; Tests: T1 T2 T11  354 355 // Update second lane halves. 356 // We don't need fresh randomness for the next cycle as the DOM 357 // multipliers inside keccak_2share will keep seeing the first 358 // lane halves in the next cycle. If we updated the randomness, 359 // old data got combined with frash randomness which is not 360 // desirable as it could lead to SCA leakage. 361 1/1 update_storage = 1'b 1; Tests: T1 T2 T11  362 363 1/1 if (rnd_eq_end) begin Tests: T1 T2 T11  364 // We're done. 365 unreachable keccak_st_d = KeccakStIdle; 366 367 unreachable rst_rnd_num = 1'b 1; 368 unreachable complete_d = 1'b 1; 369 end else begin 370 // Continue to the next round. 371 1/1 keccak_st_d = KeccakStPhase1; Tests: T1 T2 T11  372 373 1/1 inc_rnd_num = 1'b 1; Tests: T1 T2 T11  374 375 // Drive DOM multiplier I/O mux signals for next phase. 376 1/1 dom_in_low_d = low_then_high_q; Tests: T1 T2 T11  377 1/1 dom_in_rand_ext_d = 1'b 0; Tests: T1 T2 T11  378 end 379 end 380 381 KeccakStError: begin 382 0/1 ==> keccak_st_d = KeccakStError; 383 end 384 385 KeccakStTerminalError: begin 386 //this state is terminal 387 1/1 keccak_st_d = keccak_st; Tests: T9 T21 T22  388 1/1 sparse_fsm_error_o = 1'b 1; Tests: T9 T21 T22  389 end 390 391 default: begin 392 keccak_st_d = KeccakStTerminalError; 393 sparse_fsm_error_o = 1'b 1; 394 end 395 endcase 396 397 // SEC_CM: FSM.GLOBAL_ESC, FSM.LOCAL_ESC 398 // Unconditionally jump into the terminal error state 399 // if the life cycle controller triggers an escalation. 400 1/1 if (lc_ctrl_pkg::lc_tx_test_true_loose(lc_escalate_en_i)) begin Tests: T1 T2 T3  401 1/1 keccak_st_d = KeccakStTerminalError; Tests: T9 T21 T22  402 end MISSING_ELSE 403 end 404 405 // When taking the lower lane halves in, the upper lane halves are output and 406 // vice versa. 407 1/1 assign dom_out_low_d = ~dom_in_low_d; Tests: T1 T2 T3  408 409 if (EnMasking) begin : gen_regs_dom_ctrl 410 always_ff @(posedge clk_i or negedge rst_ni) begin 411 1/1 if (!rst_ni) begin Tests: T1 T2 T3  412 1/1 low_then_high_q <= 1'b 0; Tests: T1 T2 T3  413 1/1 dom_out_low_q <= 1'b 0; Tests: T1 T2 T3  414 1/1 dom_in_low_q <= 1'b 0; Tests: T1 T2 T3  415 end else begin 416 1/1 low_then_high_q <= low_then_high_d; Tests: T1 T2 T3  417 1/1 dom_out_low_q <= dom_out_low_d; Tests: T1 T2 T3  418 1/1 dom_in_low_q <= dom_in_low_d; Tests: T1 T2 T3  419 end 420 end 421 422 if (!ForceRandExt) begin : gen_reg_dom_in_rand_ext 423 always_ff @(posedge clk_i or negedge rst_ni) begin 424 1/1 if (!rst_ni) begin Tests: T1 T2 T3  425 1/1 dom_in_rand_ext_q <= 1'b 0; Tests: T1 T2 T3  426 end else begin 427 1/1 dom_in_rand_ext_q <= dom_in_rand_ext_d; Tests: T1 T2 T3  428 end 429 end 430 end else begin : gen_force_dom_in_rand_ext 431 // Always forward the externally provided randomness. 432 assign dom_in_rand_ext_q = 1'b 1; 433 // Tie off unused signals. 434 logic unused_dom_in_rand_ext; 435 assign unused_dom_in_rand_ext = dom_in_rand_ext_d; 436 end 437 end else begin : gen_no_regs_dom_ctrl 438 logic unused_dom_ctrl; 439 assign unused_dom_ctrl = 440 ^{low_then_high_d, dom_out_low_d, dom_in_low_d, dom_in_rand_ext_d}; 441 assign low_then_high_q = 1'b 0; 442 assign dom_out_low_q = 1'b 0; 443 assign dom_in_low_q = 1'b 0; 444 assign dom_in_rand_ext_q = 1'b 0; 445 end 446 447 // Ready indicates the keccak_round is able to receive new message. 448 // While keccak_round is processing the data, it blocks the new message to be 449 // XORed into the current state. 450 1/1 assign ready_o = (keccak_st == KeccakStIdle) ? 1'b 1 : 1'b 0; Tests: T1 T2 T3  451 452 //////////////////////////// 453 // Keccak state registers // 454 //////////////////////////// 455 456 // SEC_CM: LOGIC.INTEGRITY 457 logic rst_n; 458 prim_sec_anchor_buf #( 459 .Width(1) 460 ) u_prim_sec_anchor_buf ( 461 .in_i(rst_ni), 462 .out_o(rst_n) 463 ); 464 465 logic [Width-1:0] storage [Share]; 466 logic [Width-1:0] storage_d [Share]; 467 always_ff @(posedge clk_i or negedge rst_n) begin 468 1/1 if (!rst_n) begin Tests: T1 T2 T3  469 1/1 storage <= '{default:'0}; Tests: T1 T2 T3  470 1/1 end else if (rst_storage) begin Tests: T1 T2 T3  471 1/1 storage <= '{default:'0}; Tests: T1 T2 T11  472 1/1 end else if (update_storage) begin Tests: T1 T2 T3  473 1/1 storage <= storage_d; Tests: T1 T2 T11  474 end MISSING_ELSE 475 end 476 477 1/1 assign state_o = storage; Tests: T1 T2 T3  478 479 // Storage register input 480 // The incoming message is XORed with the existing storage registers. 481 // The logic can accept not a block size incoming message chunk but 482 // the size defined in `DInWidth` parameter with its position. 483 484 always_comb begin 485 1/1 storage_d = keccak_out; Tests: T1 T2 T3  486 1/1 if (xor_message) begin Tests: T1 T2 T3  487 1/1 for (int j = 0 ; j < Share ; j++) begin Tests: T1 T2 T11  488 1/1 for (int unsigned i = 0 ; i < DInEntry ; i++) begin Tests: T1 T2 T11  489 // ICEBOX(#18029): handle If Width is not integer divisable by DInWidth 490 // Currently it is not allowed to have partial write 491 // Please see the Assertion `WidthDivisableByDInWidth_A` 492 1/1 if (addr_i == i[DInAddr-1:0]) begin Tests: T1 T2 T11  493 1/1 storage_d[j][i*DInWidth+:DInWidth] = Tests: T1 T2 T11  494 storage[j][i*DInWidth+:DInWidth] ^ data_i[j]; 495 end else begin 496 1/1 storage_d[j][i*DInWidth+:DInWidth] = storage[j][i*DInWidth+:DInWidth]; Tests: T1 T2 T11  497 end 498 end // for i 499 end // for j 500 end // if xor_message MISSING_ELSE 501 end 502 503 // Check the rst_storage integrity 504 logic rst_storage_error; 505 506 always_comb begin : chk_rst_storage 507 1/1 rst_storage_error = 1'b 0; Tests: T1 T2 T3  508 509 1/1 if (rst_storage) begin Tests: T1 T2 T3  510 // FSM should be in KeccakStIdle and clear_i should be high 511 1/1 if ((keccak_st != KeccakStIdle) || Tests: T1 T2 T11  512 prim_mubi_pkg::mubi4_test_false_loose(clear_i)) begin 513 0/1 ==> rst_storage_error = 1'b 1; 514 end MISSING_ELSE 515 end MISSING_ELSE 516 end : chk_rst_storage 517 518 1/1 assign rst_storage_error_o = rst_storage_error ; Tests: T1 T2 T3  519 520 ////////////// 521 // Datapath // 522 ////////////// 523 keccak_2share #( 524 .Width(Width), 525 .EnMasking(EnMasking), 526 .ForceRandExt(ForceRandExt) 527 ) u_keccak_p ( 528 .clk_i, 529 .rst_ni, 530 531 .lc_escalate_en_i, 532 533 .rnd_i(round), 534 535 .phase_sel_i (phase_sel), 536 .dom_out_low_i (dom_out_low_q), 537 .dom_in_low_i (dom_in_low_q), 538 .dom_in_rand_ext_i(dom_in_rand_ext_q), 539 .dom_update_i (dom_update), 540 541 .rand_i(keccak_rand_data), 542 543 .s_i(storage), 544 .s_o(keccak_out) 545 ); 546 547 // keccak entropy handling 548 1/1 assign rand_update_o = keccak_rand_update; Tests: T1 T2 T3  549 1/1 assign rand_consumed_o = keccak_rand_consumed; Tests: T1 T2 T3  550 551 1/1 assign keccak_rand_data = rand_data_i; Tests: T1 T2 T3  552 553 // Round number 554 // This primitive is used to place a hardened counter 555 // SEC_CM: CTR.REDUN 556 prim_count #( 557 .Width(RndW) 558 ) u_round_count ( 559 .clk_i, 560 .rst_ni, 561 .clr_i(rst_rnd_num), 562 .set_i(1'b0), 563 .set_cnt_i('0), 564 .incr_en_i(inc_rnd_num), 565 .decr_en_i(1'b0), 566 .step_i(RndW'(1)), 567 .commit_i(1'b1), 568 .cnt_o(round), 569 .cnt_after_commit_o(), 570 .err_o(round_count_error_o) 571 ); 572 573 // completion signal 574 always_ff @(posedge clk_i or negedge rst_ni) begin 575 1/1 if (!rst_ni) begin Tests: T1 T2 T3  576 1/1 complete_o <= 1'b 0; Tests: T1 T2 T3  577 end else begin 578 1/1 complete_o <= complete_d; Tests: T1 T2 T3 

Cond Coverage for Module : keccak_round
TotalCoveredPercent
Conditions1212100.00
Logical1212100.00
Non-Logical00
Event00

 LINE       177
 EXPRESSION (int'(round) == (MaxRound - 1))
            ---------------1---------------
-1-StatusTests
0CoveredT1,T2,T3
1UnreachableT1,T2,T11

 LINE       224
 EXPRESSION (EnMasking && run_i)
             ----1----    --2--
-1--2-StatusTests
-0CoveredT1,T2,T3
-1CoveredT1,T2,T11

 LINE       272
 EXPRESSION (rand_early_i || rand_valid_i)
             ------1-----    ------2-----
-1--2-StatusTests
00CoveredT1,T2,T11
01CoveredT1,T2,T11
10CoveredT1,T2,T11

 LINE       450
 EXPRESSION ((keccak_st == KeccakStIdle) ? 1'b1 : 1'b0)
             -------------1-------------
-1-StatusTests
0CoveredT1,T2,T11
1CoveredT1,T2,T3

 LINE       450
 SUB-EXPRESSION (keccak_st == KeccakStIdle)
                -------------1-------------
-1-StatusTests
0CoveredT1,T2,T3
1CoveredT1,T2,T3

 LINE       492
 EXPRESSION (addr_i == i[(DInAddr - 1):0])
            ---------------1--------------
-1-StatusTests
0CoveredT1,T2,T11
1CoveredT1,T2,T11

FSM Coverage for Module : keccak_round
Summary for FSM :: keccak_st
TotalCoveredPercent
States 8 6 75.00 (Not included in score)
Transitions 15 11 73.33
Sequences 0 0

State, Transition and Sequence Details for FSM :: keccak_st
statesLine No.CoveredTests
KeccakStActive 233 Not Covered
KeccakStError 382 Not Covered
KeccakStIdle 212 Covered T1,T2,T3
KeccakStPhase1 226 Covered T1,T2,T11
KeccakStPhase2Cycle1 273 Covered T1,T2,T11
KeccakStPhase2Cycle2 304 Covered T1,T2,T11
KeccakStPhase2Cycle3 339 Covered T1,T2,T11
KeccakStTerminalError 401 Covered T9,T21,T22


transitionsLine No.CoveredTests
KeccakStActive->KeccakStIdle 244 Not Covered
KeccakStActive->KeccakStTerminalError 401 Not Covered
KeccakStError->KeccakStTerminalError 401 Not Covered
KeccakStIdle->KeccakStActive 233 Not Covered
KeccakStIdle->KeccakStPhase1 226 Covered T1,T2,T11
KeccakStIdle->KeccakStTerminalError 401 Covered T21,T10,T47
KeccakStPhase1->KeccakStPhase2Cycle1 273 Covered T1,T2,T11
KeccakStPhase1->KeccakStTerminalError 401 Covered T60,T61,T62
KeccakStPhase2Cycle1->KeccakStPhase2Cycle2 304 Covered T1,T2,T11
KeccakStPhase2Cycle1->KeccakStTerminalError 401 Covered T9,T22,T63
KeccakStPhase2Cycle2->KeccakStPhase2Cycle3 339 Covered T1,T2,T11
KeccakStPhase2Cycle2->KeccakStTerminalError 401 Covered T64,T65,T66
KeccakStPhase2Cycle3->KeccakStIdle 365 Covered T1,T2,T11
KeccakStPhase2Cycle3->KeccakStPhase1 371 Covered T1,T2,T11
KeccakStPhase2Cycle3->KeccakStTerminalError 401 Covered T48,T67,T68



Branch Coverage for Module : keccak_round
Line No.TotalCoveredPercent
Branches 34 31 91.18
TERNARY 450 2 2 100.00
IF 180 2 2 100.00
CASE 208 13 11 84.62
IF 400 2 2 100.00
IF 468 4 4 100.00
IF 486 2 2 100.00
IF 509 3 2 66.67
IF 575 2 2 100.00
IF 411 2 2 100.00
IF 424 2 2 100.00


450 assign ready_o = (keccak_st == KeccakStIdle) ? 1'b 1 : 1'b 0; -1- ==> ==>

Branches:
-1-StatusTests
1 Covered T1,T2,T3
0 Covered T1,T2,T11


180 `PRIM_FLOP_SPARSE_FSM(u_state_regs, keccak_st_d, keccak_st, keccak_st_e, KeccakStIdle) -1- ==> ==>

Branches:
-1-StatusTests
1 Covered T1,T2,T3
0 Covered T1,T2,T3


208 unique case (keccak_st) -1- 209 KeccakStIdle: begin 210 if (valid_i) begin -2- 211 // State machine allows Sponge Absorbing only in Idle state. 212 keccak_st_d = KeccakStIdle; ==> 213 214 xor_message = 1'b 1; 215 update_storage = 1'b 1; 216 end else if (prim_mubi_pkg::mubi4_test_true_strict(clear_i)) begin -3- 217 // Opt1. State machine allows resetting the storage only in Idle 218 // Opt2. storage resets regardless of states but clear_i 219 // Both are added in the design at this time. Will choose the 220 // direction later. 221 keccak_st_d = KeccakStIdle; ==> 222 223 rst_storage = 1'b 1; 224 end else if (EnMasking && run_i) begin -4- 225 // Masked version of Keccak handling 226 keccak_st_d = KeccakStPhase1; ==> 227 228 // Drive DOM multiplier I/O mux signals for Phase 1. 229 dom_in_low_d = low_then_high_q; 230 dom_in_rand_ext_d = 1'b 0; 231 end else if (!EnMasking && run_i) begin -5- 232 // Unmasked version of Keccak handling 233 keccak_st_d = KeccakStActive; ==> (Unreachable) 234 end else begin 235 keccak_st_d = KeccakStIdle; ==> 236 end 237 end 238 239 KeccakStActive: begin 240 // Run Keccak single round logic until it reaches MaxRound - 1 241 update_storage = 1'b 1; 242 243 if (rnd_eq_end) begin -6- 244 keccak_st_d = KeccakStIdle; ==> (Unreachable) 245 246 rst_rnd_num = 1'b 1; 247 complete_d = 1'b 1; 248 end else begin 249 keccak_st_d = KeccakStActive; ==> 250 251 inc_rnd_num = 1'b 1; 252 end 253 end 254 255 KeccakStPhase1: begin 256 // Compute Theta, Rho, Pi - The DOM multipliers are not evaluated at 257 // all: their inputs are driven by the first lane halves (same values 258 // as in Phase2Cycle3 of the last round). Also, the intermediate 259 // results we already had in Phase2Cycle3 didn't change. 260 phase_sel = MuBi4False; 261 dom_update = 1'b 0; 262 263 // Only update the state and move on once we know the auxiliary 264 // randomness required for Phase2 will be available in the next clock 265 // cycle. 266 // 267 // It's important that the DOM multipliers inside keccak_2share are 268 // presented the new state (updated with update_storage) at the same 269 // time as the new randomness (updated with rand_update_o). Otherwise, 270 // stale entropy is paired with fresh data or vice versa. This could 271 // lead to undesired SCA leakage. 272 if (rand_early_i || rand_valid_i) begin -7- 273 keccak_st_d = KeccakStPhase2Cycle1; ==> 274 update_storage = 1'b 1; 275 keccak_rand_update = 1'b 1; 276 277 // Update lane halves processing order for this round. 278 low_then_high_d = rand_aux_i; 279 280 // Drive DOM multiplier I/O mux signals for next phase. 281 dom_in_low_d = low_then_high_d; 282 dom_in_rand_ext_d = 1'b 1; 283 end else begin 284 keccak_st_d = KeccakStPhase1; ==> 285 end 286 end 287 288 KeccakStPhase2Cycle1: begin 289 // Compute first stage of Chi for first lane halves using the DOM 290 // multipliers. Use the fresh randomness provided by the PRNG for 291 // remasking. 292 phase_sel = MuBi4True; ==> 293 dom_update = 1'b 1; 294 295 // Trigger randomness update for next cycle. 296 // It's important that the DOM multipliers inside keccak_2share are 297 // presented the second lane halves at the same time as the new 298 // randomness (updated with rand_update_o). Otherwise, stale entropy 299 // is paired with fresh data or vice versa. This could lead to 300 // undesired SCA leakage. 301 keccak_rand_update = 1'b 1; 302 303 // Unconditionally move to next phase/cycle. 304 keccak_st_d = KeccakStPhase2Cycle2; 305 306 // Drive DOM multiplier I/O mux signals for next phase. 307 dom_in_low_d = ~low_then_high_q; 308 dom_in_rand_ext_d = 1'b 1; 309 end 310 311 KeccakStPhase2Cycle2: begin 312 // Chi Stage 1 for second lane halves. 313 // Chi Stage 2 and Iota for first lane halves. 314 // Compute second stage of Chi and Iota for first lane halves. 315 // Compute first stage of Chi for second lane halves. Use the fresh 316 // randomness provided by the PRNG for remasking the DOM multipliers. 317 phase_sel = MuBi4True; ==> 318 dom_update = 1'b 1; 319 320 // Trigger randomness update for next cycle. 321 // It's important that the DOM multipliers inside keccak_2share are 322 // presented the updated state at the same as the new randomness 323 // (updated with rand_update_o) - even if the DOM multipliers don't 324 // update the pipeline registers in the next cycle. Otherwise, stale 325 // entropy is paired with fresh data or vice versa. This could lead to 326 // undesired SCA leakage. 327 keccak_rand_update = 1'b 1; 328 329 // Trigger auxiliary randomness update for next round. The rand_aux_i 330 // signal is actually going to change in 2 clock cycles from now 331 // (Phase1) based on the PRNG output in the next cycle (Phase2Cycle3) 332 // in which the DOM multipliers don't update the pipeline registers. 333 keccak_rand_consumed = 1'b 1; 334 335 // Update first lane halves. 336 update_storage = 1'b 1; 337 338 // Unconditionally move to next phase/cycle. 339 keccak_st_d = KeccakStPhase2Cycle3; 340 341 // Drive DOM multiplier I/O mux signals for next phase. 342 dom_in_low_d = low_then_high_q; 343 dom_in_rand_ext_d = 1'b 0; 344 end 345 346 KeccakStPhase2Cycle3: begin 347 // Compute second stage of Chi and Iota for second lane halves. 348 // Feed again first lane halves to DOM multiplier inputs (now 349 // the updated values become visible) together with intermediate 350 // results of Phase2Cycle2. Don't update the register stage inside 351 // the DOM multipliers. 352 phase_sel = MuBi4True; 353 dom_update = 1'b 0; 354 355 // Update second lane halves. 356 // We don't need fresh randomness for the next cycle as the DOM 357 // multipliers inside keccak_2share will keep seeing the first 358 // lane halves in the next cycle. If we updated the randomness, 359 // old data got combined with frash randomness which is not 360 // desirable as it could lead to SCA leakage. 361 update_storage = 1'b 1; 362 363 if (rnd_eq_end) begin -8- 364 // We're done. 365 keccak_st_d = KeccakStIdle; ==> (Unreachable) 366 367 rst_rnd_num = 1'b 1; 368 complete_d = 1'b 1; 369 end else begin 370 // Continue to the next round. 371 keccak_st_d = KeccakStPhase1; ==> 372 373 inc_rnd_num = 1'b 1; 374 375 // Drive DOM multiplier I/O mux signals for next phase. 376 dom_in_low_d = low_then_high_q; 377 dom_in_rand_ext_d = 1'b 0; 378 end 379 end 380 381 KeccakStError: begin 382 keccak_st_d = KeccakStError; ==> 383 end 384 385 KeccakStTerminalError: begin 386 //this state is terminal 387 keccak_st_d = keccak_st; ==> 388 sparse_fsm_error_o = 1'b 1; 389 end 390 391 default: begin 392 keccak_st_d = KeccakStTerminalError; ==>

Branches:
-1--2--3--4--5--6--7--8-StatusTests
KeccakStIdle 1 - - - - - - Covered T1,T2,T11
KeccakStIdle 0 1 - - - - - Covered T1,T2,T11
KeccakStIdle 0 0 1 - - - - Covered T1,T2,T11
KeccakStIdle 0 0 0 1 - - - Unreachable
KeccakStIdle 0 0 0 0 - - - Covered T1,T2,T3
KeccakStActive - - - - 1 - - Unreachable
KeccakStActive - - - - 0 - - Not Covered
KeccakStPhase1 - - - - - 1 - Covered T1,T2,T11
KeccakStPhase1 - - - - - 0 - Covered T1,T2,T11
KeccakStPhase2Cycle1 - - - - - - - Covered T1,T2,T11
KeccakStPhase2Cycle2 - - - - - - - Covered T1,T2,T11
KeccakStPhase2Cycle3 - - - - - - 1 Unreachable T1,T2,T11
KeccakStPhase2Cycle3 - - - - - - 0 Covered T1,T2,T11
KeccakStError - - - - - - - Not Covered
KeccakStTerminalError - - - - - - - Covered T9,T21,T22
default - - - - - - - Covered T21,T10,T46


400 if (lc_ctrl_pkg::lc_tx_test_true_loose(lc_escalate_en_i)) begin -1- 401 keccak_st_d = KeccakStTerminalError; ==> 402 end MISSING_ELSE ==>

Branches:
-1-StatusTests
1 Covered T9,T21,T22
0 Covered T1,T2,T3


468 if (!rst_n) begin -1- 469 storage <= '{default:'0}; ==> 470 end else if (rst_storage) begin -2- 471 storage <= '{default:'0}; ==> 472 end else if (update_storage) begin -3- 473 storage <= storage_d; ==> 474 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T11
0 0 1 Covered T1,T2,T11
0 0 0 Covered T1,T2,T3


486 if (xor_message) begin -1- 487 for (int j = 0 ; j < Share ; j++) begin ==> 488 for (int unsigned i = 0 ; i < DInEntry ; i++) begin 489 // ICEBOX(#18029): handle If Width is not integer divisable by DInWidth 490 // Currently it is not allowed to have partial write 491 // Please see the Assertion `WidthDivisableByDInWidth_A` 492 if (addr_i == i[DInAddr-1:0]) begin 493 storage_d[j][i*DInWidth+:DInWidth] = 494 storage[j][i*DInWidth+:DInWidth] ^ data_i[j]; 495 end else begin 496 storage_d[j][i*DInWidth+:DInWidth] = storage[j][i*DInWidth+:DInWidth]; 497 end 498 end // for i 499 end // for j 500 end // if xor_message MISSING_ELSE ==>

Branches:
-1-StatusTests
1 Covered T1,T2,T11
0 Covered T1,T2,T3


509 if (rst_storage) begin -1- 510 // FSM should be in KeccakStIdle and clear_i should be high 511 if ((keccak_st != KeccakStIdle) || -2- 512 prim_mubi_pkg::mubi4_test_false_loose(clear_i)) begin 513 rst_storage_error = 1'b 1; ==> 514 end MISSING_ELSE ==> 515 end MISSING_ELSE ==>

Branches:
-1--2-StatusTests
1 1 Not Covered
1 0 Covered T1,T2,T11
0 - Covered T1,T2,T3


575 if (!rst_ni) begin -1- 576 complete_o <= 1'b 0; ==> 577 end else begin 578 complete_o <= complete_d; ==>

Branches:
-1-StatusTests
1 Covered T1,T2,T3
0 Covered T1,T2,T3


411 if (!rst_ni) begin -1- 412 low_then_high_q <= 1'b 0; ==> 413 dom_out_low_q <= 1'b 0; 414 dom_in_low_q <= 1'b 0; 415 end else begin 416 low_then_high_q <= low_then_high_d; ==>

Branches:
-1-StatusTests
1 Covered T1,T2,T3
0 Covered T1,T2,T3


424 if (!rst_ni) begin -1- 425 dom_in_rand_ext_q <= 1'b 0; ==> 426 end else begin 427 dom_in_rand_ext_q <= dom_in_rand_ext_d; ==>

Branches:
-1-StatusTests
1 Covered T1,T2,T3
0 Covered T1,T2,T3


Assert Coverage for Module : keccak_round
TotalAttemptedPercentSucceeded/MatchedPercent
Assertions 6 6 100.00 6 100.00
Cover properties 0 0 0
Cover sequences 0 0 0
Total 6 6 100.00 6 100.00




Assertion Details

NameAttemptsReal SuccessesFailuresIncomplete
ClearAssertStIdle_A 600494255 58971 0 0
OneHot0ValidAndRun_A 600494255 600344491 0 0
ValidRunAssertStIdle_A 600494255 14154514 0 0
WidthDivisableByDInWidth_A 719 719 0 0
gen_mask_st_chk.EnMaskingValidStates_A 600494255 600344491 0 0
u_state_regs_A 600494255 600344491 0 0


ClearAssertStIdle_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 600494255 58971 0 0
T1 7856 7 0 0
T2 6537 3 0 0
T3 1894 0 0 0
T4 165802 27 0 0
T7 23351 15 0 0
T8 138958 16 0 0
T9 3561 0 0 0
T11 4529 3 0 0
T16 0 28 0 0
T50 0 89 0 0
T52 3684 0 0 0
T53 1740 0 0 0
T54 0 3 0 0
T55 0 3 0 0

OneHot0ValidAndRun_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 600494255 600344491 0 0
T1 7856 7786 0 0
T2 6537 6473 0 0
T3 1894 1841 0 0
T4 165802 165705 0 0
T7 23351 23261 0 0
T8 138958 138876 0 0
T9 3561 3424 0 0
T11 4529 4477 0 0
T52 3684 3618 0 0
T53 1740 1652 0 0

ValidRunAssertStIdle_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 600494255 14154514 0 0
T1 7856 390 0 0
T2 6537 220 0 0
T3 1894 0 0 0
T4 165802 2592 0 0
T7 23351 846 0 0
T8 138958 864 0 0
T9 3561 18 0 0
T11 4529 198 0 0
T16 0 1269 0 0
T50 0 4517 0 0
T52 3684 0 0 0
T53 1740 0 0 0
T54 0 220 0 0

WidthDivisableByDInWidth_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 719 719 0 0
T1 1 1 0 0
T2 1 1 0 0
T3 1 1 0 0
T4 1 1 0 0
T7 1 1 0 0
T8 1 1 0 0
T9 1 1 0 0
T11 1 1 0 0
T52 1 1 0 0
T53 1 1 0 0

gen_mask_st_chk.EnMaskingValidStates_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 600494255 600344491 0 0
T1 7856 7786 0 0
T2 6537 6473 0 0
T3 1894 1841 0 0
T4 165802 165705 0 0
T7 23351 23261 0 0
T8 138958 138876 0 0
T9 3561 3424 0 0
T11 4529 4477 0 0
T52 3684 3618 0 0
T53 1740 1652 0 0

u_state_regs_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 600494255 600344491 0 0
T1 7856 7786 0 0
T2 6537 6473 0 0
T3 1894 1841 0 0
T4 165802 165705 0 0
T7 23351 23261 0 0
T8 138958 138876 0 0
T9 3561 3424 0 0
T11 4529 4477 0 0
T52 3684 3618 0 0
T53 1740 1652 0 0

0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100%