Module Definition
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Module Instance : tb.dut.u_spid_status

Instance :
SCORELINECONDTOGGLEFSMBRANCHASSERT
99.31 100.00 100.00 97.22 100.00


Instance's subtree :
SCORELINECONDTOGGLEFSMBRANCHASSERT
92.61 100.00 88.46 98.63 83.33


Parent :
SCORELINECONDTOGGLEFSMBRANCHASSERTNAME
92.52 95.20 84.31 97.00 90.62 95.45 dut


Subtrees :
NAMESCORELINECONDTOGGLEFSMBRANCHASSERT
u_csb_rst_scan_mux 64.81 100.00 44.44 50.00
u_sck2csb_status 100.00 100.00 100.00
u_stage_to_commit 100.00 100.00 100.00
u_sw_status_update_sync 99.00 100.00 96.00 100.00 100.00


Since this is the module's only instance, the coverage report is the same as for the module.
Line Coverage for Module : spid_status
Line No.TotalCoveredPercent
TOTAL6565100.00
CONT_ASSIGN9511100.00
CONT_ASSIGN9811100.00
ALWAYS16666100.00
ALWAYS17788100.00
ALWAYS19044100.00
ALWAYS20277100.00
CONT_ASSIGN22411100.00
CONT_ASSIGN22511100.00
CONT_ASSIGN22611100.00
CONT_ASSIGN24111100.00
ALWAYS26433100.00
ALWAYS30944100.00
ALWAYS32255100.00
ALWAYS33633100.00
ALWAYS34466100.00
CONT_ASSIGN35811100.00
ALWAYS36533100.00
ALWAYS37099100.00

94 logic unused_cmd_info; 95 1/1 assign unused_cmd_info = ^cmd_info_i; Tests: T1 T2 T3  96 97 logic unused_p2s_sent; 98 1/1 assign unused_p2s_sent = outclk_p2s_sent_i; Tests: T1 T2 T3  99 100 assign io_mode_o = SingleIO; 101 102 typedef enum logic { 103 StIdle, 104 StActive 105 } st_e; 106 st_e st_q, st_d; 107 108 typedef enum int unsigned { 109 BitBusy = 0, // BUSY bit [0] 110 BitWe = 1 // WEL bit [1] 111 } status_bit_e; 112 113 //////////// 114 // Signal // 115 //////////// 116 logic [StatusW-1:0] sck_status_committed, csb_status_committed; 117 logic [StatusW-1:0] sck_status_staged; 118 logic [StatusW-1:0] sck_sw_status; 119 logic [StatusW-1:0] sck_status_to_commit; 120 121 logic p2s_valid_inclk; 122 spi_byte_t p2s_byte_inclk; 123 124 // FIFO rvalid , rready 125 logic sck_sw_we, sck_sw_ack; 126 //////////////////////////// 127 // Status CSR (incl. CDC) // 128 //////////////////////////// 129 // 130 // Flash mode STATUS register is implemented in this module rather than 131 // relying on the regtool. The reason is that the STATUS read by the SPI 132 // host system. The value should be propagated into SCK domain. Due to the 133 // lack of SCK while CSb is de-asserted, it needs special cares to safely 134 // used in SCK. 135 // 136 // Before returning the STATUS register value to the host system 137 // corresponding to the Read Status commands (05h, 35h, 15h), the logic can 138 // get 8 SCK clock edges. The logic synchronizes CSb into SCK domain first. 139 // Then create a pulse to latch the STATUS register in SCK domain. 140 // 141 // If a command is uploaded (handled by spid_upload), it sets BUSY bit to 1. 142 // The value is latched in the SCK domain first. Then, when CSb is 143 // de-asserted, the logic synchronizes CSb into the bus clock domain to 144 // create a pulse signal. That pulse signal will latch the STATUS register 145 // from SCK domain into the bus clock domain. 146 // 147 // The STATUS register in the bus clock domain can be updated only when CSb 148 // is not asserted in order to prevent any CDC issue. The safest way is to 149 // hand the busclock synched CSb signal over to SCK clock domain again but 150 // it may not be possible to latch the register within the 8th posedge of 151 // the SCK if the bus clock is slow. 152 // 153 // BUSY is set by HW. The value is not directly broadcasted to the 154 // passthrough module. It is, first, applied into the bus clock domain. Then 155 // the signal is broadcasted to Passthrough to filter-out the following 156 // commands until the BUSY signal is released. 157 158 // Design Doc 159 // https://docs.google.com/document/d/1wUIynMYVfVg9HmCL0q5-6r9BuN-XM0z--wGqU0bXRQ0 160 161 // assumes BUSY bit as 0 162 `ASSERT_INIT(BusyBitZero_A, BitBusy == 0) 163 164 // BUSY status in SCK 165 always_ff @(posedge clk_i or negedge sys_rst_ni) begin 166 1/1 if (!sys_rst_ni) begin Tests: T1 T2 T3  167 1/1 sck_status_staged[BitBusy] <= 1'b 0; Tests: T1 T2 T3  168 1/1 end else if (inclk_busy_set_i) begin Tests: T2 T4 T5  169 1/1 sck_status_staged[BitBusy] <= 1'b 1; Tests: T2 T20 T60  170 1/1 end else if (sck_sw_we && (sck_sw_status[BitBusy] == 1'b 0)) begin Tests: T2 T4 T5  171 1/1 sck_status_staged[BitBusy] <= 1'b 0; Tests: T2 T8 T9  172 end MISSING_ELSE 173 end 174 175 // WEL handling 176 always_ff @(posedge clk_i or negedge sys_rst_ni) begin 177 1/1 if (!sys_rst_ni) begin Tests: T1 T2 T3  178 1/1 sck_status_staged[BitWe] <= 1'b 0; Tests: T1 T2 T3  179 1/1 end else if (inclk_we_set_i) begin Tests: T2 T4 T5  180 1/1 sck_status_staged[BitWe] <= 1'b 1; Tests: T2 T8 T15  181 1/1 end else if (inclk_we_clr_i) begin Tests: T2 T4 T5  182 1/1 sck_status_staged[BitWe] <= 1'b 0; Tests: T52 T53 T49  183 1/1 end else if (sck_sw_we && (sck_sw_status[BitWe] == 1'b0)) begin Tests: T2 T4 T5  184 1/1 sck_status_staged[BitWe] <= sck_sw_status[BitWe]; Tests: T2 T8 T9  185 end MISSING_ELSE 186 end 187 188 // Rest of Status 189 always_ff @(posedge clk_i or negedge sys_rst_ni) begin 190 1/1 if (!sys_rst_ni) begin Tests: T1 T2 T3  191 1/1 sck_status_staged[StatusW-1:BitWe+1] <= '0; Tests: T1 T2 T3  192 1/1 end else if (sck_sw_we) begin Tests: T2 T4 T5  193 1/1 sck_status_staged[StatusW-1:BitWe+1] <= sck_sw_status[StatusW-1:BitWe+1]; Tests: T2 T8 T9  194 end MISSING_ELSE 195 end 196 197 // HW-originated WEL and WIP updates bypass the flop so they are committed 198 // immediately. The changes still must be placed in the flops above, so the 199 // staged values are correct for the next update. 200 // TODO(#21700): HW changes should not be allowed while BUSY 201 always_comb begin 202 1/1 sck_status_to_commit = sck_status_staged; Tests: T1 T2 T3  203 1/1 if (inclk_we_set_i) begin Tests: T1 T2 T3  204 1/1 sck_status_to_commit[BitWe] = 1'b1; Tests: T2 T8 T15  205 1/1 end else if (inclk_we_clr_i) begin Tests: T1 T2 T3  206 1/1 sck_status_to_commit[BitWe] = 1'b0; Tests: T52 T53 T49  207 end MISSING_ELSE 208 1/1 if (inclk_busy_set_i) begin Tests: T1 T2 T3  209 1/1 sck_status_to_commit[BitBusy] = 1'b1; Tests: T2 T20 T60  210 end MISSING_ELSE 211 end 212 213 prim_flop_en #( 214 .Width ($bits(sck_status_committed)), 215 .ResetValue('0) 216 ) u_stage_to_commit ( 217 .clk_i (clk_i), 218 .rst_ni (sys_rst_ni), 219 .en_i (inclk_status_commit_i), 220 .d_i (sck_status_to_commit), 221 .q_o (sck_status_committed) 222 ); 223 224 1/1 assign cmd_sync_status_busy_o = sck_status_to_commit[BitBusy]; Tests: T1 T2 T3  225 1/1 assign cmd_sync_status_wel_o = sck_status_to_commit[BitWe]; Tests: T1 T2 T3  226 1/1 assign sck_status_busy_o = sck_status_committed[BitBusy]; Tests: T1 T2 T3  227 228 // Staged to Committed at CSb de-assertion 229 // SW and the passthrough gate only receive the final values of 230 // a transaction. 231 prim_flop #( 232 .Width ($bits(sck_status_committed)), 233 .ResetValue ('0) 234 ) u_sck2csb_status ( 235 .clk_i (clk_csb_i), 236 .rst_ni (sys_rst_ni), 237 .d_i (sck_status_committed), 238 .q_o (csb_status_committed) 239 ); 240 241 1/1 assign csb_busy_broadcast_o = csb_status_committed[BitBusy]; Tests: T1 T2 T3  242 243 // Status in SCK 244 assign sck_sw_ack = 1'b 1; // always accept when clock is valid. 245 246 // For normal SPI flash operation, there should only ever be one write from 247 // the SYS domain to update the status register in response to any command. 248 // Status register bits should never update outside of direct command 249 // responses. Thus, there should never be enough writes to fill the FIFO, 250 // since any subsequent command would clear the prior write. 251 // Note that this means that spi_device does not support using the status 252 // register for anything but the following: 253 // - initial "power-on / reset" values shown to the upstream host 254 // - values the host explicitly programmed via WRITE STATUS REGISTER types 255 // - hardware-updated BUSY and WEL bits 256 // Some SPI flash devices support reporting the address mode in one of the 257 // status bits. This IP does not. Support here would require another 258 // hardware-updated bit, to respond to EN4B and EX4B. 259 // 260 // To effect reliable support for initial values, allow resetting the FIFO 261 // to clear any state that may have built up from a prior session. 262 logic status_fifo_clr_n, status_fifo_rst_n; 263 always_ff @(posedge sys_clk_i or negedge sys_rst_ni) begin 264 1/1 if (!sys_rst_ni) begin Tests: T1 T2 T3  265 1/1 status_fifo_clr_n <= 1'b0; Tests: T1 T2 T3  266 end else begin 267 1/1 status_fifo_clr_n <= !sys_update_clr_i; Tests: T1 T2 T3  268 end 269 end 270 271 prim_clock_mux2 #( 272 .NoFpgaBufG(1'b1) 273 ) u_csb_rst_scan_mux ( 274 .clk0_i(status_fifo_clr_n), 275 .clk1_i(scan_rst_ni), 276 .sel_i(prim_mubi_pkg::mubi4_test_true_strict(scanmode_i)), 277 .clk_o(status_fifo_rst_n) 278 ); 279 280 prim_fifo_async #( 281 .Width (StatusW), 282 .Depth (2), 283 .OutputZeroIfEmpty (1'b 1) 284 ) u_sw_status_update_sync ( 285 .clk_wr_i (sys_clk_i ), 286 .rst_wr_ni (status_fifo_rst_n), 287 .wvalid_i (sys_status_we_i ), 288 .wready_o ( ), // ignore 289 .wdata_i (sys_status_i ), 290 .wdepth_o ( ), 291 292 .clk_rd_i (clk_i ), 293 .rst_rd_ni (status_fifo_rst_n), 294 .rvalid_o (sck_sw_we ), 295 .rready_i (sck_sw_ack ), 296 .rdata_o (sck_sw_status ), 297 .rdepth_o ( ) 298 ); 299 300 // Committed to SYS clk 301 // Timing requirements: 302 // - 3x sys_clk cycles < 8x spi_clk cycles + 1 CSB "cycle" 303 // Breakdown: 304 // - 2 sys_clk cycles to produce sys_csb_deasserted_pulse_i 305 // - 1 sys_clk cycle to latch csb_status_committed 306 // - Must execute before back-to-back WREN -> WRDI 307 // - Other bits have much longer stability 308 always_ff @(posedge sys_clk_i or negedge sys_rst_ni) begin 309 1/1 if (!sys_rst_ni) begin Tests: T1 T2 T3  310 1/1 sys_status_o <= '0; Tests: T1 T2 T3  311 1/1 end else if (sys_csb_deasserted_pulse_i) begin Tests: T1 T2 T3  312 1/1 sys_status_o <= csb_status_committed; Tests: T2 T8 T9  313 end MISSING_ELSE 314 end 315 316 ///////////////// 317 // Data Return // 318 ///////////////// 319 320 // Latch in clk_out 321 always_ff @(posedge clk_out_i or negedge rst_out_ni) begin 322 1/1 if (!rst_out_ni) begin Tests: T1 T2 T3  323 1/1 outclk_p2s_valid_o <= 1'b 0; Tests: T1 T2 T3  324 1/1 outclk_p2s_byte_o <= '0; Tests: T1 T2 T3  325 end else begin 326 1/1 outclk_p2s_valid_o <= p2s_valid_inclk; Tests: T2 T8 T9  327 1/1 outclk_p2s_byte_o <= p2s_byte_inclk; Tests: T2 T8 T9  328 end 329 end 330 331 // cmd_idx to data selector 332 logic [1:0] byte_sel_d, byte_sel_q; 333 logic byte_sel_update; 334 335 always_ff @(posedge clk_i or negedge rst_ni) begin 336 1/1 if (!rst_ni) begin Tests: T1 T2 T3  337 1/1 byte_sel_q <= 2'b 00; Tests: T1 T2 T3  338 end else begin 339 1/1 byte_sel_q <= byte_sel_d; Tests: T2 T8 T9  340 end 341 end 342 343 always_comb begin : byte_sel_input 344 1/1 byte_sel_d = byte_sel_q; Tests: T1 T2 T3  345 346 1/1 if (byte_sel_update) begin Tests: T1 T2 T3  347 // Check input command index and assign initial byte_sel 348 1/1 byte_sel_d = 2'b 00; // default value Tests: T2 T18 T20  349 350 1/1 for (int unsigned i = 0 ; i <= 2 ; i++) begin Tests: T2 T18 T20  351 1/1 if (cmd_info_idx_i == CmdInfoIdxW'(StatusCmdIdx[i])) begin Tests: T2 T18 T20  352 1/1 byte_sel_d = i; Tests: T2 T18 T20  353 end MISSING_ELSE 354 end 355 end MISSING_ELSE 356 end : byte_sel_input 357 358 1/1 assign p2s_byte_inclk = (st_q == StIdle) Tests: T1 T2 T3  359 ? sck_status_committed[8*byte_sel_d+:8] 360 : sck_status_committed[8*byte_sel_q+:8]; 361 362 // State Machine 363 364 always_ff @(posedge clk_i or negedge rst_ni) begin 365 2/2 if (!rst_ni) st_q <= StIdle; Tests: T1 T2 T3  | T1 T2 T3  366 1/1 else st_q <= st_d; Tests: T2 T8 T9  367 end 368 369 always_comb begin 370 1/1 st_d = st_q; Tests: T1 T2 T3  371 372 1/1 byte_sel_update = 1'b 0; Tests: T1 T2 T3  373 374 1/1 p2s_valid_inclk = 1'b 0; Tests: T1 T2 T3  375 376 1/1 unique case (st_q) Tests: T1 T2 T3  377 StIdle: begin 378 1/1 if (sel_dp_i == DpReadStatus) begin Tests: T1 T2 T3  379 1/1 st_d = StActive; Tests: T2 T18 T20  380 // dp asserted after 8th SCK. Should send out the data right away. 381 1/1 byte_sel_update = 1'b 1; Tests: T2 T18 T20  382 1/1 p2s_valid_inclk = 1'b 1; Tests: T2 T18 T20  383 end MISSING_ELSE 384 end 385 386 StActive: begin 387 1/1 p2s_valid_inclk = 1'b 1; Tests: T2 T18 T20  388 // deadend state 389 end 390 391 default: begin 392 st_d = StIdle;

Cond Coverage for Module : spid_status
TotalCoveredPercent
Conditions1818100.00
Logical1818100.00
Non-Logical00
Event00

 LINE       170
 EXPRESSION (sck_sw_we && (sck_sw_status[BitBusy] == 1'b0))
             ----1----    ----------------2---------------
-1--2-StatusTests
01CoveredT2,T4,T5
10CoveredT2,T8,T9
11CoveredT2,T8,T9

 LINE       170
 SUB-EXPRESSION (sck_sw_status[BitBusy] == 1'b0)
                ----------------1---------------
-1-StatusTests
0CoveredT2,T8,T9
1CoveredT2,T4,T5

 LINE       183
 EXPRESSION (sck_sw_we && (sck_sw_status[BitWe] == 1'b0))
             ----1----    ---------------2--------------
-1--2-StatusTests
01CoveredT2,T4,T5
10CoveredT2,T8,T9
11CoveredT2,T8,T9

 LINE       183
 SUB-EXPRESSION (sck_sw_status[BitWe] == 1'b0)
                ---------------1--------------
-1-StatusTests
0CoveredT2,T8,T9
1CoveredT2,T4,T5

 LINE       351
 EXPRESSION (cmd_info_idx_i == 5'(StatusCmdIdx[i]))
            -------------------1-------------------
-1-StatusTests
0CoveredT2,T18,T20
1CoveredT2,T18,T20

 LINE       358
 EXPRESSION ((st_q == StIdle) ? sck_status_committed[(8 * byte_sel_d)+:8] : sck_status_committed[(8 * byte_sel_q)+:8])
             --------1-------
-1-StatusTests
0CoveredT2,T18,T20
1CoveredT1,T2,T3

 LINE       358
 SUB-EXPRESSION (st_q == StIdle)
                --------1-------
-1-StatusTests
0CoveredT1,T2,T3
1CoveredT1,T2,T3

 LINE       378
 EXPRESSION (sel_dp_i == DpReadStatus)
            -------------1------------
-1-StatusTests
0CoveredT1,T2,T3
1CoveredT2,T18,T20

Branch Coverage for Module : spid_status
Line No.TotalCoveredPercent
Branches 36 35 97.22
TERNARY 358 2 2 100.00
IF 166 4 4 100.00
IF 177 5 5 100.00
IF 190 3 3 100.00
IF 203 3 3 100.00
IF 208 2 2 100.00
IF 264 2 2 100.00
IF 309 3 3 100.00
IF 322 2 2 100.00
IF 336 2 2 100.00
IF 346 2 2 100.00
IF 365 2 2 100.00
CASE 376 4 3 75.00


358 assign p2s_byte_inclk = (st_q == StIdle) 359 ? sck_status_committed[8*byte_sel_d+:8] -1- ==> ==>

Branches:
-1-StatusTests
1 Covered T1,T2,T3
0 Covered T2,T18,T20


166 if (!sys_rst_ni) begin -1- 167 sck_status_staged[BitBusy] <= 1'b 0; ==> 168 end else if (inclk_busy_set_i) begin -2- 169 sck_status_staged[BitBusy] <= 1'b 1; ==> 170 end else if (sck_sw_we && (sck_sw_status[BitBusy] == 1'b 0)) begin -3- 171 sck_status_staged[BitBusy] <= 1'b 0; ==> 172 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T2,T20,T60
0 0 1 Covered T2,T8,T9
0 0 0 Covered T2,T4,T5


177 if (!sys_rst_ni) begin -1- 178 sck_status_staged[BitWe] <= 1'b 0; ==> 179 end else if (inclk_we_set_i) begin -2- 180 sck_status_staged[BitWe] <= 1'b 1; ==> 181 end else if (inclk_we_clr_i) begin -3- 182 sck_status_staged[BitWe] <= 1'b 0; ==> 183 end else if (sck_sw_we && (sck_sw_status[BitWe] == 1'b0)) begin -4- 184 sck_status_staged[BitWe] <= sck_sw_status[BitWe]; ==> 185 end MISSING_ELSE ==>

Branches:
-1--2--3--4-StatusTests
1 - - - Covered T1,T2,T3
0 1 - - Covered T2,T8,T15
0 0 1 - Covered T52,T53,T49
0 0 0 1 Covered T2,T8,T9
0 0 0 0 Covered T2,T4,T5


190 if (!sys_rst_ni) begin -1- 191 sck_status_staged[StatusW-1:BitWe+1] <= '0; ==> 192 end else if (sck_sw_we) begin -2- 193 sck_status_staged[StatusW-1:BitWe+1] <= sck_sw_status[StatusW-1:BitWe+1]; ==> 194 end MISSING_ELSE ==>

Branches:
-1--2-StatusTests
1 - Covered T1,T2,T3
0 1 Covered T2,T8,T9
0 0 Covered T2,T4,T5


203 if (inclk_we_set_i) begin -1- 204 sck_status_to_commit[BitWe] = 1'b1; ==> 205 end else if (inclk_we_clr_i) begin -2- 206 sck_status_to_commit[BitWe] = 1'b0; ==> 207 end MISSING_ELSE ==>

Branches:
-1--2-StatusTests
1 - Covered T2,T8,T15
0 1 Covered T52,T53,T49
0 0 Covered T1,T2,T3


208 if (inclk_busy_set_i) begin -1- 209 sck_status_to_commit[BitBusy] = 1'b1; ==> 210 end MISSING_ELSE ==>

Branches:
-1-StatusTests
1 Covered T2,T20,T60
0 Covered T1,T2,T3


264 if (!sys_rst_ni) begin -1- 265 status_fifo_clr_n <= 1'b0; ==> 266 end else begin 267 status_fifo_clr_n <= !sys_update_clr_i; ==>

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


309 if (!sys_rst_ni) begin -1- 310 sys_status_o <= '0; ==> 311 end else if (sys_csb_deasserted_pulse_i) begin -2- 312 sys_status_o <= csb_status_committed; ==> 313 end MISSING_ELSE ==>

Branches:
-1--2-StatusTests
1 - Covered T1,T2,T3
0 1 Covered T2,T8,T9
0 0 Covered T1,T2,T3


322 if (!rst_out_ni) begin -1- 323 outclk_p2s_valid_o <= 1'b 0; ==> 324 outclk_p2s_byte_o <= '0; 325 end else begin 326 outclk_p2s_valid_o <= p2s_valid_inclk; ==>

Branches:
-1-StatusTests
1 Covered T1,T2,T3
0 Covered T2,T8,T9


336 if (!rst_ni) begin -1- 337 byte_sel_q <= 2'b 00; ==> 338 end else begin 339 byte_sel_q <= byte_sel_d; ==>

Branches:
-1-StatusTests
1 Covered T1,T2,T3
0 Covered T2,T8,T9


346 if (byte_sel_update) begin -1- 347 // Check input command index and assign initial byte_sel 348 byte_sel_d = 2'b 00; // default value ==> 349 350 for (int unsigned i = 0 ; i <= 2 ; i++) begin 351 if (cmd_info_idx_i == CmdInfoIdxW'(StatusCmdIdx[i])) begin 352 byte_sel_d = i; 353 end 354 end 355 end MISSING_ELSE ==>

Branches:
-1-StatusTests
1 Covered T2,T18,T20
0 Covered T1,T2,T3


365 if (!rst_ni) st_q <= StIdle; -1- ==> 366 else st_q <= st_d; ==>

Branches:
-1-StatusTests
1 Covered T1,T2,T3
0 Covered T2,T8,T9


376 unique case (st_q) -1- 377 StIdle: begin 378 if (sel_dp_i == DpReadStatus) begin -2- 379 st_d = StActive; ==> 380 // dp asserted after 8th SCK. Should send out the data right away. 381 byte_sel_update = 1'b 1; 382 p2s_valid_inclk = 1'b 1; 383 end MISSING_ELSE ==> 384 end 385 386 StActive: begin 387 p2s_valid_inclk = 1'b 1; ==> 388 // deadend state 389 end 390 391 default: begin 392 st_d = StIdle; ==>

Branches:
-1--2-StatusTests
StIdle 1 Covered T2,T18,T20
StIdle 0 Covered T1,T2,T3
StActive - Covered T2,T18,T20
default - Not Covered


Assert Coverage for Module : spid_status
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
BusyBitZero_A 976 976 0 0


BusyBitZero_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 976 976 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
T7 1 1 0 0
T8 1 1 0 0
T9 1 1 0 0
T10 1 1 0 0

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