Module Definition
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Module Instance : tb.dut.u_prim_ram_1p_scr.u_prim_ram_1p_adv

Instance :
SCORELINECONDTOGGLEFSMBRANCHASSERT
100.00 100.00 100.00 100.00


Instance's subtree :
SCORELINECONDTOGGLEFSMBRANCHASSERT
100.00 100.00 100.00 100.00


Parent :
SCORELINECONDTOGGLEFSMBRANCHASSERTNAME
99.53 98.11 100.00 100.00 100.00 u_prim_ram_1p_scr


Subtrees :
NAMESCORELINECONDTOGGLEFSMBRANCHASSERT
u_mem 100.00 100.00 100.00 100.00
u_req_d_buf 100.00 100.00
u_write_d_buf 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 : prim_ram_1p_adv
Line No.TotalCoveredPercent
TOTAL2525100.00
CONT_ASSIGN10211100.00
CONT_ASSIGN10311100.00
CONT_ASSIGN12311100.00
ALWAYS12633100.00
CONT_ASSIGN13311100.00
CONT_ASSIGN13411100.00
CONT_ASSIGN13511100.00
CONT_ASSIGN13611100.00
CONT_ASSIGN13711100.00
CONT_ASSIGN13800
CONT_ASSIGN14711100.00
CONT_ASSIGN15611100.00
CONT_ASSIGN24811100.00
CONT_ASSIGN24911100.00
CONT_ASSIGN25111100.00
CONT_ASSIGN25511100.00
CONT_ASSIGN31011100.00
CONT_ASSIGN31111100.00
CONT_ASSIGN31211100.00
CONT_ASSIGN31311100.00
CONT_ASSIGN31411100.00
CONT_ASSIGN35311100.00
CONT_ASSIGN35411100.00
CONT_ASSIGN35600
CONT_ASSIGN35911100.00

101 102 1/1 assign req_q_b = mubi4_test_true_loose(req_q); Tests: T1 T2 T3  103 1/1 assign write_q_b = mubi4_test_true_loose(write_q); Tests: T1 T2 T3  104 105 prim_ram_1p #( 106 .MemInitFile (MemInitFile), 107 108 .Width (TotalWidth), 109 .Depth (Depth), 110 .DataBitsPerMask (LocalDataBitsPerMask) 111 ) u_mem ( 112 .clk_i, 113 114 .req_i (req_q_b), 115 .write_i (write_q_b), 116 .addr_i (addr_q), 117 .wdata_i (wdata_q), 118 .wmask_i (wmask_q), 119 .rdata_o (rdata_sram), 120 .cfg_i 121 ); 122 123 1/1 assign rvalid_sram_d = mubi4_and_hi(req_q, mubi4_t'(~write_q)); Tests: T1 T2 T3  124 125 always_ff @(posedge clk_i or negedge rst_ni) begin 126 1/1 if (!rst_ni) begin Tests: T1 T2 T3  127 1/1 rvalid_sram_q <= MuBi4False; Tests: T1 T2 T3  128 end else begin 129 1/1 rvalid_sram_q <= rvalid_sram_d; Tests: T1 T2 T3  130 end 131 end 132 133 1/1 assign req_d = mubi4_bool_to_mubi(req_i); Tests: T1 T2 T3  134 1/1 assign write_d = mubi4_bool_to_mubi(write_i); Tests: T1 T2 T3  135 1/1 assign addr_d = addr_i; Tests: T1 T2 T3  136 1/1 assign rvalid_o = mubi4_test_true_loose(rvalid_q); Tests: T1 T2 T3  137 1/1 assign rdata_o = rdata_q; Tests: T4 T5 T8  138 unreachable assign rerror_o = rerror_q; 139 140 prim_buf #( 141 .Width(MuBi4Width) 142 ) u_req_d_buf ( 143 .in_i (req_d), 144 .out_o(req_buf_b_d) 145 ); 146 147 1/1 assign req_buf_d = mubi4_t'(req_buf_b_d); Tests: T1 T2 T3  148 149 prim_buf #( 150 .Width(MuBi4Width) 151 ) u_write_d_buf ( 152 .in_i (write_d), 153 .out_o(write_buf_b_d) 154 ); 155 156 1/1 assign write_buf_d = mubi4_t'(write_buf_b_d); Tests: T1 T2 T3  157 158 ///////////////////////////// 159 // ECC / Parity Generation // 160 ///////////////////////////// 161 162 if (EnableParity == 0 && EnableECC) begin : gen_secded 163 logic unused_wmask; 164 assign unused_wmask = ^wmask_i; 165 166 // check supported widths 167 `ASSERT_INIT(SecDecWidth_A, Width inside {16, 32}) 168 169 // the wmask is constantly set to 1 in this case 170 `ASSERT(OnlyWordWritePossibleWithEccPortA_A, req_i |-> 171 wmask_i == {Width{1'b1}}) 172 173 assign wmask_d = {TotalWidth{1'b1}}; 174 175 if (Width == 16) begin : gen_secded_22_16 176 if (HammingECC) begin : gen_hamming 177 prim_secded_inv_hamming_22_16_enc u_enc ( 178 .data_i(wdata_i), 179 .data_o(wdata_d) 180 ); 181 prim_secded_inv_hamming_22_16_dec u_dec ( 182 .data_i (rdata_sram), 183 .data_o (rdata_d[0+:Width]), 184 .syndrome_o ( ), 185 .err_o (rerror_d) 186 ); 187 end else begin : gen_hsiao 188 prim_secded_inv_22_16_enc u_enc ( 189 .data_i(wdata_i), 190 .data_o(wdata_d) 191 ); 192 prim_secded_inv_22_16_dec u_dec ( 193 .data_i (rdata_sram), 194 .data_o (rdata_d[0+:Width]), 195 .syndrome_o ( ), 196 .err_o (rerror_d) 197 ); 198 end 199 end else if (Width == 32) begin : gen_secded_39_32 200 if (HammingECC) begin : gen_hamming 201 prim_secded_inv_hamming_39_32_enc u_enc ( 202 .data_i(wdata_i), 203 .data_o(wdata_d) 204 ); 205 prim_secded_inv_hamming_39_32_dec u_dec ( 206 .data_i (rdata_sram), 207 .data_o (rdata_d[0+:Width]), 208 .syndrome_o ( ), 209 .err_o (rerror_d) 210 ); 211 end else begin : gen_hsiao 212 prim_secded_inv_39_32_enc u_enc ( 213 .data_i(wdata_i), 214 .data_o(wdata_d) 215 ); 216 prim_secded_inv_39_32_dec u_dec ( 217 .data_i (rdata_sram), 218 .data_o (rdata_d[0+:Width]), 219 .syndrome_o ( ), 220 .err_o (rerror_d) 221 ); 222 end 223 end 224 225 end else if (EnableParity) begin : gen_byte_parity 226 227 `ASSERT_INIT(WidthNeedsToBeByteAligned_A, Width % 8 == 0) 228 `ASSERT_INIT(ParityNeedsByteWriteMask_A, DataBitsPerMask == 8) 229 230 always_comb begin : p_parity 231 rerror_d = '0; 232 for (int i = 0; i < Width/8; i ++) begin 233 // Data mapping. We have to make 8+1 = 9 bit groups 234 // that have the same write enable such that FPGA tools 235 // can map this correctly to BRAM resources. 236 wmask_d[i*9 +: 8] = wmask_i[i*8 +: 8]; 237 wdata_d[i*9 +: 8] = wdata_i[i*8 +: 8]; 238 rdata_d[i*8 +: 8] = rdata_sram[i*9 +: 8]; 239 240 // parity generation (odd parity) 241 wdata_d[i*9 + 8] = ~(^wdata_i[i*8 +: 8]); 242 wmask_d[i*9 + 8] = &wmask_i[i*8 +: 8]; 243 // parity decoding (errors are always uncorrectable) 244 rerror_d[1] |= ~(^{rdata_sram[i*9 +: 8], rdata_sram[i*9 + 8]}); 245 end 246 end 247 end else begin : gen_nosecded_noparity 248 1/1 assign wmask_d = wmask_i; Tests: T1 T2 T3  249 1/1 assign wdata_d = wdata_i; Tests: T1 T2 T3  250 251 1/1 assign rdata_d = rdata_sram[0+:Width]; Tests: T4 T5 T8  252 assign rerror_d = '0; 253 end 254 255 1/1 assign rvalid_d = rvalid_sram_q; Tests: T1 T2 T3  256 257 ///////////////////////////////////// 258 // Input/Output Pipeline Registers // 259 ///////////////////////////////////// 260 261 if (EnableInputPipeline) begin : gen_regslice_input 262 // Put the register slices between ECC encoding to SRAM port 263 264 // If no ECC or parity is used, do not use prim_flop to allow synthesis 265 // tool to optimize the registers. 266 if (EnableECC || EnableParity) begin : gen_prim_flop 267 prim_flop #( 268 .Width(MuBi4Width), 269 .ResetValue(MuBi4Width'(MuBi4False)) 270 ) u_write_flop ( 271 .clk_i, 272 .rst_ni, 273 .d_i(MuBi4Width'(write_buf_d)), 274 .q_o({write_q}) 275 ); 276 277 prim_flop #( 278 .Width(MuBi4Width), 279 .ResetValue(MuBi4Width'(MuBi4False)) 280 ) u_req_flop ( 281 .clk_i, 282 .rst_ni, 283 .d_i(MuBi4Width'(req_buf_d)), 284 .q_o({req_q}) 285 ); 286 end else begin: gen_no_prim_flop 287 always_ff @(posedge clk_i or negedge rst_ni) begin 288 if (!rst_ni) begin 289 write_q <= MuBi4False; 290 req_q <= MuBi4False; 291 end else begin 292 write_q <= write_buf_d; 293 req_q <= req_buf_d; 294 end 295 end 296 end 297 298 always_ff @(posedge clk_i or negedge rst_ni) begin 299 if (!rst_ni) begin 300 addr_q <= '0; 301 wdata_q <= '0; 302 wmask_q <= '0; 303 end else begin 304 addr_q <= addr_d; 305 wdata_q <= wdata_d; 306 wmask_q <= wmask_d; 307 end 308 end 309 end else begin : gen_dirconnect_input 310 1/1 assign req_q = req_buf_d; Tests: T1 T2 T3  311 1/1 assign write_q = write_buf_d; Tests: T1 T2 T3  312 1/1 assign addr_q = addr_d; Tests: T1 T2 T3  313 1/1 assign wdata_q = wdata_d; Tests: T1 T2 T3  314 1/1 assign wmask_q = wmask_d; Tests: T1 T2 T3  315 end 316 317 if (EnableOutputPipeline) begin : gen_regslice_output 318 // Put the register slices between ECC decoding to output 319 320 // If no ECC or parity is used, do not use prim_flop to allow synthesis 321 // tool to optimize the registers. 322 if (EnableECC || EnableParity) begin : gen_prim_rvalid_flop 323 prim_flop #( 324 .Width(MuBi4Width), 325 .ResetValue(MuBi4Width'(MuBi4False)) 326 ) u_rvalid_flop ( 327 .clk_i, 328 .rst_ni, 329 .d_i(MuBi4Width'(rvalid_d)), 330 .q_o({rvalid_q}) 331 ); 332 end else begin: gen_no_prim_rvalid_flop 333 always_ff @(posedge clk_i or negedge rst_ni) begin 334 if (!rst_ni) begin 335 rvalid_q <= MuBi4False; 336 end else begin 337 rvalid_q <= rvalid_d; 338 end 339 end 340 end 341 342 always_ff @(posedge clk_i or negedge rst_ni) begin 343 if (!rst_ni) begin 344 rdata_q <= '0; 345 rerror_q <= '0; 346 end else begin 347 rdata_q <= rdata_d; 348 // tie to zero if the read data is not valid 349 rerror_q <= rerror_d & {2{mubi4_test_true_loose(rvalid_d)}}; 350 end 351 end 352 end else begin : gen_dirconnect_output 353 1/1 assign rvalid_q = rvalid_d; Tests: T1 T2 T3  354 1/1 assign rdata_q = rdata_d; Tests: T4 T5 T8  355 // tie to zero if the read data is not valid 356 unreachable assign rerror_q = rerror_d & {2{mubi4_test_true_loose(rvalid_d)}}; 357 end 358 359 1/1 assign alert_o = mubi4_test_invalid(req_q) | mubi4_test_invalid(write_q) | Tests: T1 T2 T3 

Branch Coverage for Module : prim_ram_1p_adv
Line No.TotalCoveredPercent
Branches 2 2 100.00
IF 126 2 2 100.00


126 if (!rst_ni) begin -1- 127 rvalid_sram_q <= MuBi4False; ==> 128 end else begin 129 rvalid_sram_q <= rvalid_sram_d; ==>

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


Assert Coverage for Module : prim_ram_1p_adv
TotalAttemptedPercentSucceeded/MatchedPercent
Assertions 1 1 100.00 1 100.00
Cover properties 0 0 0
Cover sequences 0 0 0
Total 1 1 100.00 1 100.00




Assertion Details

NameAttemptsReal SuccessesFailuresIncomplete
CannotHaveEccAndParity_A 905 905 0 0


CannotHaveEccAndParity_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 905 905 0 0
T1 1 1 0 0
T2 1 1 0 0
T3 1 1 0 0
T4 1 1 0 0
T5 1 1 0 0
T6 1 1 0 0
T8 1 1 0 0
T12 1 1 0 0
T13 1 1 0 0
T14 1 1 0 0

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