hw/pc: remove needless includes
[qemu/kevin.git] / tests / qtest / npcm7xx_emc-test.c
blobb046f1d76af0aee431c60dc8157371974ea1773f
1 /*
2 * QTests for Nuvoton NPCM7xx EMC Modules.
4 * Copyright 2020 Google LLC
6 * This program is free software; you can redistribute it and/or modify it
7 * under the terms of the GNU General Public License as published by the
8 * Free Software Foundation; either version 2 of the License, or
9 * (at your option) any later version.
11 * This program is distributed in the hope that it will be useful, but WITHOUT
12 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
13 * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
14 * for more details.
17 #include "qemu/osdep.h"
18 #include "libqos/libqos.h"
19 #include "qapi/qmp/qdict.h"
20 #include "qapi/qmp/qnum.h"
21 #include "qemu/bitops.h"
22 #include "qemu/iov.h"
24 /* Name of the emc device. */
25 #define TYPE_NPCM7XX_EMC "npcm7xx-emc"
27 /* Timeout for various operations, in seconds. */
28 #define TIMEOUT_SECONDS 10
30 /* Address in memory of the descriptor. */
31 #define DESC_ADDR (1 << 20) /* 1 MiB */
33 /* Address in memory of the data packet. */
34 #define DATA_ADDR (DESC_ADDR + 4096)
36 #define CRC_LENGTH 4
38 #define NUM_TX_DESCRIPTORS 3
39 #define NUM_RX_DESCRIPTORS 2
41 /* Size of tx,rx test buffers. */
42 #define TX_DATA_LEN 64
43 #define RX_DATA_LEN 64
45 #define TX_STEP_COUNT 10000
46 #define RX_STEP_COUNT 10000
48 /* 32-bit register indices. */
49 typedef enum NPCM7xxPWMRegister {
50 /* Control registers. */
51 REG_CAMCMR,
52 REG_CAMEN,
54 /* There are 16 CAMn[ML] registers. */
55 REG_CAMM_BASE,
56 REG_CAML_BASE,
58 REG_TXDLSA = 0x22,
59 REG_RXDLSA,
60 REG_MCMDR,
61 REG_MIID,
62 REG_MIIDA,
63 REG_FFTCR,
64 REG_TSDR,
65 REG_RSDR,
66 REG_DMARFC,
67 REG_MIEN,
69 /* Status registers. */
70 REG_MISTA,
71 REG_MGSTA,
72 REG_MPCNT,
73 REG_MRPC,
74 REG_MRPCC,
75 REG_MREPC,
76 REG_DMARFS,
77 REG_CTXDSA,
78 REG_CTXBSA,
79 REG_CRXDSA,
80 REG_CRXBSA,
82 NPCM7XX_NUM_EMC_REGS,
83 } NPCM7xxPWMRegister;
85 enum { NUM_CAMML_REGS = 16 };
87 /* REG_CAMCMR fields */
88 /* Enable CAM Compare */
89 #define REG_CAMCMR_ECMP (1 << 4)
90 /* Accept Unicast Packet */
91 #define REG_CAMCMR_AUP (1 << 0)
93 /* REG_MCMDR fields */
94 /* Software Reset */
95 #define REG_MCMDR_SWR (1 << 24)
96 /* Frame Transmission On */
97 #define REG_MCMDR_TXON (1 << 8)
98 /* Accept Long Packet */
99 #define REG_MCMDR_ALP (1 << 1)
100 /* Frame Reception On */
101 #define REG_MCMDR_RXON (1 << 0)
103 /* REG_MIEN fields */
104 /* Enable Transmit Completion Interrupt */
105 #define REG_MIEN_ENTXCP (1 << 18)
106 /* Enable Transmit Interrupt */
107 #define REG_MIEN_ENTXINTR (1 << 16)
108 /* Enable Receive Good Interrupt */
109 #define REG_MIEN_ENRXGD (1 << 4)
110 /* ENable Receive Interrupt */
111 #define REG_MIEN_ENRXINTR (1 << 0)
113 /* REG_MISTA fields */
114 /* Transmit Bus Error Interrupt */
115 #define REG_MISTA_TXBERR (1 << 24)
116 /* Transmit Descriptor Unavailable Interrupt */
117 #define REG_MISTA_TDU (1 << 23)
118 /* Transmit Completion Interrupt */
119 #define REG_MISTA_TXCP (1 << 18)
120 /* Transmit Interrupt */
121 #define REG_MISTA_TXINTR (1 << 16)
122 /* Receive Bus Error Interrupt */
123 #define REG_MISTA_RXBERR (1 << 11)
124 /* Receive Descriptor Unavailable Interrupt */
125 #define REG_MISTA_RDU (1 << 10)
126 /* DMA Early Notification Interrupt */
127 #define REG_MISTA_DENI (1 << 9)
128 /* Maximum Frame Length Interrupt */
129 #define REG_MISTA_DFOI (1 << 8)
130 /* Receive Good Interrupt */
131 #define REG_MISTA_RXGD (1 << 4)
132 /* Packet Too Long Interrupt */
133 #define REG_MISTA_PTLE (1 << 3)
134 /* Receive Interrupt */
135 #define REG_MISTA_RXINTR (1 << 0)
137 typedef struct NPCM7xxEMCTxDesc NPCM7xxEMCTxDesc;
138 typedef struct NPCM7xxEMCRxDesc NPCM7xxEMCRxDesc;
140 struct NPCM7xxEMCTxDesc {
141 uint32_t flags;
142 uint32_t txbsa;
143 uint32_t status_and_length;
144 uint32_t ntxdsa;
147 struct NPCM7xxEMCRxDesc {
148 uint32_t status_and_length;
149 uint32_t rxbsa;
150 uint32_t reserved;
151 uint32_t nrxdsa;
154 /* NPCM7xxEMCTxDesc.flags values */
155 /* Owner: 0 = cpu, 1 = emc */
156 #define TX_DESC_FLAG_OWNER_MASK (1 << 31)
157 /* Transmit interrupt enable */
158 #define TX_DESC_FLAG_INTEN (1 << 2)
160 /* NPCM7xxEMCTxDesc.status_and_length values */
161 /* Transmission complete */
162 #define TX_DESC_STATUS_TXCP (1 << 19)
163 /* Transmit interrupt */
164 #define TX_DESC_STATUS_TXINTR (1 << 16)
166 /* NPCM7xxEMCRxDesc.status_and_length values */
167 /* Owner: 0b00 = cpu, 0b10 = emc */
168 #define RX_DESC_STATUS_OWNER_SHIFT 30
169 #define RX_DESC_STATUS_OWNER_MASK 0xc0000000
170 /* Frame Reception Complete */
171 #define RX_DESC_STATUS_RXGD (1 << 20)
172 /* Packet too long */
173 #define RX_DESC_STATUS_PTLE (1 << 19)
174 /* Receive Interrupt */
175 #define RX_DESC_STATUS_RXINTR (1 << 16)
177 #define RX_DESC_PKT_LEN(word) ((uint32_t) (word) & 0xffff)
179 typedef struct EMCModule {
180 int rx_irq;
181 int tx_irq;
182 uint64_t base_addr;
183 } EMCModule;
185 typedef struct TestData {
186 const EMCModule *module;
187 } TestData;
189 static const EMCModule emc_module_list[] = {
191 .rx_irq = 15,
192 .tx_irq = 16,
193 .base_addr = 0xf0825000
196 .rx_irq = 114,
197 .tx_irq = 115,
198 .base_addr = 0xf0826000
202 /* Returns the index of the EMC module. */
203 static int emc_module_index(const EMCModule *mod)
205 ptrdiff_t diff = mod - emc_module_list;
207 g_assert_true(diff >= 0 && diff < ARRAY_SIZE(emc_module_list));
209 return diff;
212 #ifndef _WIN32
213 static void packet_test_clear(void *sockets)
215 int *test_sockets = sockets;
217 close(test_sockets[0]);
218 g_free(test_sockets);
221 static int *packet_test_init(int module_num, GString *cmd_line)
223 int *test_sockets = g_new(int, 2);
224 int ret = socketpair(PF_UNIX, SOCK_STREAM, 0, test_sockets);
225 g_assert_cmpint(ret, != , -1);
228 * KISS and use -nic. We specify two nics (both emc{0,1}) because there's
229 * currently no way to specify only emc1: The driver implicitly relies on
230 * emc[i] == nd_table[i].
232 if (module_num == 0) {
233 g_string_append_printf(cmd_line,
234 " -nic socket,fd=%d,model=" TYPE_NPCM7XX_EMC " "
235 " -nic user,model=" TYPE_NPCM7XX_EMC " ",
236 test_sockets[1]);
237 } else {
238 g_string_append_printf(cmd_line,
239 " -nic user,model=" TYPE_NPCM7XX_EMC " "
240 " -nic socket,fd=%d,model=" TYPE_NPCM7XX_EMC " ",
241 test_sockets[1]);
244 g_test_queue_destroy(packet_test_clear, test_sockets);
245 return test_sockets;
247 #endif /* _WIN32 */
249 static uint32_t emc_read(QTestState *qts, const EMCModule *mod,
250 NPCM7xxPWMRegister regno)
252 return qtest_readl(qts, mod->base_addr + regno * sizeof(uint32_t));
255 #ifndef _WIN32
256 static void emc_write(QTestState *qts, const EMCModule *mod,
257 NPCM7xxPWMRegister regno, uint32_t value)
259 qtest_writel(qts, mod->base_addr + regno * sizeof(uint32_t), value);
262 static void emc_read_tx_desc(QTestState *qts, uint32_t addr,
263 NPCM7xxEMCTxDesc *desc)
265 qtest_memread(qts, addr, desc, sizeof(*desc));
266 desc->flags = le32_to_cpu(desc->flags);
267 desc->txbsa = le32_to_cpu(desc->txbsa);
268 desc->status_and_length = le32_to_cpu(desc->status_and_length);
269 desc->ntxdsa = le32_to_cpu(desc->ntxdsa);
272 static void emc_write_tx_desc(QTestState *qts, const NPCM7xxEMCTxDesc *desc,
273 uint32_t addr)
275 NPCM7xxEMCTxDesc le_desc;
277 le_desc.flags = cpu_to_le32(desc->flags);
278 le_desc.txbsa = cpu_to_le32(desc->txbsa);
279 le_desc.status_and_length = cpu_to_le32(desc->status_and_length);
280 le_desc.ntxdsa = cpu_to_le32(desc->ntxdsa);
281 qtest_memwrite(qts, addr, &le_desc, sizeof(le_desc));
284 static void emc_read_rx_desc(QTestState *qts, uint32_t addr,
285 NPCM7xxEMCRxDesc *desc)
287 qtest_memread(qts, addr, desc, sizeof(*desc));
288 desc->status_and_length = le32_to_cpu(desc->status_and_length);
289 desc->rxbsa = le32_to_cpu(desc->rxbsa);
290 desc->reserved = le32_to_cpu(desc->reserved);
291 desc->nrxdsa = le32_to_cpu(desc->nrxdsa);
294 static void emc_write_rx_desc(QTestState *qts, const NPCM7xxEMCRxDesc *desc,
295 uint32_t addr)
297 NPCM7xxEMCRxDesc le_desc;
299 le_desc.status_and_length = cpu_to_le32(desc->status_and_length);
300 le_desc.rxbsa = cpu_to_le32(desc->rxbsa);
301 le_desc.reserved = cpu_to_le32(desc->reserved);
302 le_desc.nrxdsa = cpu_to_le32(desc->nrxdsa);
303 qtest_memwrite(qts, addr, &le_desc, sizeof(le_desc));
307 * Reset the EMC module.
308 * The module must be reset before, e.g., TXDLSA,RXDLSA are changed.
310 static bool emc_soft_reset(QTestState *qts, const EMCModule *mod)
312 uint32_t val;
313 uint64_t end_time;
315 emc_write(qts, mod, REG_MCMDR, REG_MCMDR_SWR);
318 * Wait for device to reset as the linux driver does.
319 * During reset the AHB reads 0 for all registers. So first wait for
320 * something that resets to non-zero, and then wait for SWR becoming 0.
322 end_time = g_get_monotonic_time() + TIMEOUT_SECONDS * G_TIME_SPAN_SECOND;
324 do {
325 qtest_clock_step(qts, 100);
326 val = emc_read(qts, mod, REG_FFTCR);
327 } while (val == 0 && g_get_monotonic_time() < end_time);
328 if (val != 0) {
329 do {
330 qtest_clock_step(qts, 100);
331 val = emc_read(qts, mod, REG_MCMDR);
332 if ((val & REG_MCMDR_SWR) == 0) {
334 * N.B. The CAMs have been reset here, so macaddr matching of
335 * incoming packets will not work.
337 return true;
339 } while (g_get_monotonic_time() < end_time);
342 g_message("%s: Timeout expired", __func__);
343 return false;
345 #endif /* _WIN32 */
347 /* Check emc registers are reset to default value. */
348 static void test_init(gconstpointer test_data)
350 const TestData *td = test_data;
351 const EMCModule *mod = td->module;
352 QTestState *qts = qtest_init("-machine quanta-gsj");
353 int i;
355 #define CHECK_REG(regno, value) \
356 do { \
357 g_assert_cmphex(emc_read(qts, mod, (regno)), ==, (value)); \
358 } while (0)
360 CHECK_REG(REG_CAMCMR, 0);
361 CHECK_REG(REG_CAMEN, 0);
362 CHECK_REG(REG_TXDLSA, 0xfffffffc);
363 CHECK_REG(REG_RXDLSA, 0xfffffffc);
364 CHECK_REG(REG_MCMDR, 0);
365 CHECK_REG(REG_MIID, 0);
366 CHECK_REG(REG_MIIDA, 0x00900000);
367 CHECK_REG(REG_FFTCR, 0x0101);
368 CHECK_REG(REG_DMARFC, 0x0800);
369 CHECK_REG(REG_MIEN, 0);
370 CHECK_REG(REG_MISTA, 0);
371 CHECK_REG(REG_MGSTA, 0);
372 CHECK_REG(REG_MPCNT, 0x7fff);
373 CHECK_REG(REG_MRPC, 0);
374 CHECK_REG(REG_MRPCC, 0);
375 CHECK_REG(REG_MREPC, 0);
376 CHECK_REG(REG_DMARFS, 0);
377 CHECK_REG(REG_CTXDSA, 0);
378 CHECK_REG(REG_CTXBSA, 0);
379 CHECK_REG(REG_CRXDSA, 0);
380 CHECK_REG(REG_CRXBSA, 0);
382 #undef CHECK_REG
384 /* Skip over the MAC address registers, which is BASE+0 */
385 for (i = 1; i < NUM_CAMML_REGS; ++i) {
386 g_assert_cmpuint(emc_read(qts, mod, REG_CAMM_BASE + i * 2), ==,
388 g_assert_cmpuint(emc_read(qts, mod, REG_CAML_BASE + i * 2), ==,
392 qtest_quit(qts);
395 #ifndef _WIN32
396 static bool emc_wait_irq(QTestState *qts, const EMCModule *mod, int step,
397 bool is_tx)
399 uint64_t end_time =
400 g_get_monotonic_time() + TIMEOUT_SECONDS * G_TIME_SPAN_SECOND;
402 do {
403 if (qtest_get_irq(qts, is_tx ? mod->tx_irq : mod->rx_irq)) {
404 return true;
406 qtest_clock_step(qts, step);
407 } while (g_get_monotonic_time() < end_time);
409 g_message("%s: Timeout expired", __func__);
410 return false;
413 static bool emc_wait_mista(QTestState *qts, const EMCModule *mod, int step,
414 uint32_t flag)
416 uint64_t end_time =
417 g_get_monotonic_time() + TIMEOUT_SECONDS * G_TIME_SPAN_SECOND;
419 do {
420 uint32_t mista = emc_read(qts, mod, REG_MISTA);
421 if (mista & flag) {
422 return true;
424 qtest_clock_step(qts, step);
425 } while (g_get_monotonic_time() < end_time);
427 g_message("%s: Timeout expired", __func__);
428 return false;
431 static bool wait_socket_readable(int fd)
433 fd_set read_fds;
434 struct timeval tv;
435 int rv;
437 FD_ZERO(&read_fds);
438 FD_SET(fd, &read_fds);
439 tv.tv_sec = TIMEOUT_SECONDS;
440 tv.tv_usec = 0;
441 rv = select(fd + 1, &read_fds, NULL, NULL, &tv);
442 if (rv == -1) {
443 perror("select");
444 } else if (rv == 0) {
445 g_message("%s: Timeout expired", __func__);
447 return rv == 1;
450 /* Initialize *desc (in host endian format). */
451 static void init_tx_desc(NPCM7xxEMCTxDesc *desc, size_t count,
452 uint32_t desc_addr)
454 g_assert(count >= 2);
455 memset(&desc[0], 0, sizeof(*desc) * count);
456 /* Leave the last one alone, owned by the cpu -> stops transmission. */
457 for (size_t i = 0; i < count - 1; ++i) {
458 desc[i].flags =
459 (TX_DESC_FLAG_OWNER_MASK | /* owner = 1: emc */
460 TX_DESC_FLAG_INTEN |
461 0 | /* crc append = 0 */
462 0 /* padding enable = 0 */);
463 desc[i].status_and_length =
464 (0 | /* collision count = 0 */
465 0 | /* SQE = 0 */
466 0 | /* PAU = 0 */
467 0 | /* TXHA = 0 */
468 0 | /* LC = 0 */
469 0 | /* TXABT = 0 */
470 0 | /* NCS = 0 */
471 0 | /* EXDEF = 0 */
472 0 | /* TXCP = 0 */
473 0 | /* DEF = 0 */
474 0 | /* TXINTR = 0 */
475 0 /* length filled in later */);
476 desc[i].ntxdsa = desc_addr + (i + 1) * sizeof(*desc);
480 static void enable_tx(QTestState *qts, const EMCModule *mod,
481 const NPCM7xxEMCTxDesc *desc, size_t count,
482 uint32_t desc_addr, uint32_t mien_flags)
484 /* Write the descriptors to guest memory. */
485 for (size_t i = 0; i < count; ++i) {
486 emc_write_tx_desc(qts, desc + i, desc_addr + i * sizeof(*desc));
489 /* Trigger sending the packet. */
490 /* The module must be reset before changing TXDLSA. */
491 g_assert(emc_soft_reset(qts, mod));
492 emc_write(qts, mod, REG_TXDLSA, desc_addr);
493 emc_write(qts, mod, REG_CTXDSA, ~0);
494 emc_write(qts, mod, REG_MIEN, REG_MIEN_ENTXCP | mien_flags);
496 uint32_t mcmdr = emc_read(qts, mod, REG_MCMDR);
497 mcmdr |= REG_MCMDR_TXON;
498 emc_write(qts, mod, REG_MCMDR, mcmdr);
502 static void emc_send_verify1(QTestState *qts, const EMCModule *mod, int fd,
503 bool with_irq, uint32_t desc_addr,
504 uint32_t next_desc_addr,
505 const char *test_data, int test_size)
507 NPCM7xxEMCTxDesc result_desc;
508 uint32_t expected_mask, expected_value, recv_len;
509 int ret;
510 char buffer[TX_DATA_LEN];
512 g_assert(wait_socket_readable(fd));
514 /* Read the descriptor back. */
515 emc_read_tx_desc(qts, desc_addr, &result_desc);
516 /* Descriptor should be owned by cpu now. */
517 g_assert((result_desc.flags & TX_DESC_FLAG_OWNER_MASK) == 0);
518 /* Test the status bits, ignoring the length field. */
519 expected_mask = 0xffff << 16;
520 expected_value = TX_DESC_STATUS_TXCP;
521 if (with_irq) {
522 expected_value |= TX_DESC_STATUS_TXINTR;
524 g_assert_cmphex((result_desc.status_and_length & expected_mask), ==,
525 expected_value);
527 /* Check data sent to the backend. */
528 recv_len = ~0;
529 ret = recv(fd, &recv_len, sizeof(recv_len), MSG_DONTWAIT);
530 g_assert_cmpint(ret, == , sizeof(recv_len));
532 g_assert(wait_socket_readable(fd));
533 memset(buffer, 0xff, sizeof(buffer));
534 ret = recv(fd, buffer, test_size, MSG_DONTWAIT);
535 g_assert_cmpmem(buffer, ret, test_data, test_size);
538 static void emc_send_verify(QTestState *qts, const EMCModule *mod, int fd,
539 bool with_irq)
541 NPCM7xxEMCTxDesc desc[NUM_TX_DESCRIPTORS];
542 uint32_t desc_addr = DESC_ADDR;
543 static const char test1_data[] = "TEST1";
544 static const char test2_data[] = "Testing 1 2 3 ...";
545 uint32_t data1_addr = DATA_ADDR;
546 uint32_t data2_addr = data1_addr + sizeof(test1_data);
547 bool got_tdu;
548 uint32_t end_desc_addr;
550 /* Prepare test data buffer. */
551 qtest_memwrite(qts, data1_addr, test1_data, sizeof(test1_data));
552 qtest_memwrite(qts, data2_addr, test2_data, sizeof(test2_data));
554 init_tx_desc(&desc[0], NUM_TX_DESCRIPTORS, desc_addr);
555 desc[0].txbsa = data1_addr;
556 desc[0].status_and_length |= sizeof(test1_data);
557 desc[1].txbsa = data2_addr;
558 desc[1].status_and_length |= sizeof(test2_data);
560 enable_tx(qts, mod, &desc[0], NUM_TX_DESCRIPTORS, desc_addr,
561 with_irq ? REG_MIEN_ENTXINTR : 0);
563 /* Prod the device to send the packet. */
564 emc_write(qts, mod, REG_TSDR, 1);
567 * It's problematic to observe the interrupt for each packet.
568 * Instead just wait until all the packets go out.
570 got_tdu = false;
571 while (!got_tdu) {
572 if (with_irq) {
573 g_assert_true(emc_wait_irq(qts, mod, TX_STEP_COUNT,
574 /*is_tx=*/true));
575 } else {
576 g_assert_true(emc_wait_mista(qts, mod, TX_STEP_COUNT,
577 REG_MISTA_TXINTR));
579 got_tdu = !!(emc_read(qts, mod, REG_MISTA) & REG_MISTA_TDU);
580 /* If we don't have TDU yet, reset the interrupt. */
581 if (!got_tdu) {
582 emc_write(qts, mod, REG_MISTA,
583 emc_read(qts, mod, REG_MISTA) & 0xffff0000);
587 end_desc_addr = desc_addr + 2 * sizeof(desc[0]);
588 g_assert_cmphex(emc_read(qts, mod, REG_CTXDSA), ==, end_desc_addr);
589 g_assert_cmphex(emc_read(qts, mod, REG_MISTA), ==,
590 REG_MISTA_TXCP | REG_MISTA_TXINTR | REG_MISTA_TDU);
592 emc_send_verify1(qts, mod, fd, with_irq,
593 desc_addr, end_desc_addr,
594 test1_data, sizeof(test1_data));
595 emc_send_verify1(qts, mod, fd, with_irq,
596 desc_addr + sizeof(desc[0]), end_desc_addr,
597 test2_data, sizeof(test2_data));
600 /* Initialize *desc (in host endian format). */
601 static void init_rx_desc(NPCM7xxEMCRxDesc *desc, size_t count,
602 uint32_t desc_addr, uint32_t data_addr)
604 g_assert_true(count >= 2);
605 memset(desc, 0, sizeof(*desc) * count);
606 desc[0].rxbsa = data_addr;
607 desc[0].status_and_length =
608 (0b10 << RX_DESC_STATUS_OWNER_SHIFT | /* owner = 10: emc */
609 0 | /* RP = 0 */
610 0 | /* ALIE = 0 */
611 0 | /* RXGD = 0 */
612 0 | /* PTLE = 0 */
613 0 | /* CRCE = 0 */
614 0 | /* RXINTR = 0 */
615 0 /* length (filled in later) */);
616 /* Leave the last one alone, owned by the cpu -> stops transmission. */
617 desc[0].nrxdsa = desc_addr + sizeof(*desc);
620 static void enable_rx(QTestState *qts, const EMCModule *mod,
621 const NPCM7xxEMCRxDesc *desc, size_t count,
622 uint32_t desc_addr, uint32_t mien_flags,
623 uint32_t mcmdr_flags)
626 * Write the descriptor to guest memory.
627 * FWIW, IWBN if the docs said the buffer needs to be at least DMARFC
628 * bytes.
630 for (size_t i = 0; i < count; ++i) {
631 emc_write_rx_desc(qts, desc + i, desc_addr + i * sizeof(*desc));
634 /* Trigger receiving the packet. */
635 /* The module must be reset before changing RXDLSA. */
636 g_assert(emc_soft_reset(qts, mod));
637 emc_write(qts, mod, REG_RXDLSA, desc_addr);
638 emc_write(qts, mod, REG_MIEN, REG_MIEN_ENRXGD | mien_flags);
641 * We don't know what the device's macaddr is, so just accept all
642 * unicast packets (AUP).
644 emc_write(qts, mod, REG_CAMCMR, REG_CAMCMR_AUP);
645 emc_write(qts, mod, REG_CAMEN, 1 << 0);
647 uint32_t mcmdr = emc_read(qts, mod, REG_MCMDR);
648 mcmdr |= REG_MCMDR_RXON | mcmdr_flags;
649 emc_write(qts, mod, REG_MCMDR, mcmdr);
653 static void emc_recv_verify(QTestState *qts, const EMCModule *mod, int fd,
654 bool with_irq, bool pump_rsdr)
656 NPCM7xxEMCRxDesc desc[NUM_RX_DESCRIPTORS];
657 uint32_t desc_addr = DESC_ADDR;
658 uint32_t data_addr = DATA_ADDR;
659 int ret;
660 uint32_t expected_mask, expected_value;
661 NPCM7xxEMCRxDesc result_desc;
663 /* Prepare test data buffer. */
664 const char test[RX_DATA_LEN] = "TEST";
665 int len = htonl(sizeof(test));
666 const struct iovec iov[] = {
668 .iov_base = &len,
669 .iov_len = sizeof(len),
671 .iov_base = (char *) test,
672 .iov_len = sizeof(test),
677 * Reset the device BEFORE sending a test packet, otherwise the packet
678 * may get swallowed by an active device of an earlier test.
680 init_rx_desc(&desc[0], NUM_RX_DESCRIPTORS, desc_addr, data_addr);
681 enable_rx(qts, mod, &desc[0], NUM_RX_DESCRIPTORS, desc_addr,
682 with_irq ? REG_MIEN_ENRXINTR : 0, 0);
685 * If requested, prod the device to accept a packet.
686 * This isn't necessary, the linux driver doesn't do this.
687 * Test doing/not-doing this for robustness.
689 if (pump_rsdr) {
690 emc_write(qts, mod, REG_RSDR, 1);
693 /* Send test packet to device's socket. */
694 ret = iov_send(fd, iov, 2, 0, sizeof(len) + sizeof(test));
695 g_assert_cmpint(ret, == , sizeof(test) + sizeof(len));
697 /* Wait for RX interrupt. */
698 if (with_irq) {
699 g_assert_true(emc_wait_irq(qts, mod, RX_STEP_COUNT, /*is_tx=*/false));
700 } else {
701 g_assert_true(emc_wait_mista(qts, mod, RX_STEP_COUNT, REG_MISTA_RXGD));
704 g_assert_cmphex(emc_read(qts, mod, REG_CRXDSA), ==,
705 desc_addr + sizeof(desc[0]));
707 expected_mask = 0xffff;
708 expected_value = (REG_MISTA_DENI |
709 REG_MISTA_RXGD |
710 REG_MISTA_RXINTR);
711 g_assert_cmphex((emc_read(qts, mod, REG_MISTA) & expected_mask),
712 ==, expected_value);
714 /* Read the descriptor back. */
715 emc_read_rx_desc(qts, desc_addr, &result_desc);
716 /* Descriptor should be owned by cpu now. */
717 g_assert((result_desc.status_and_length & RX_DESC_STATUS_OWNER_MASK) == 0);
718 /* Test the status bits, ignoring the length field. */
719 expected_mask = 0xffff << 16;
720 expected_value = RX_DESC_STATUS_RXGD;
721 if (with_irq) {
722 expected_value |= RX_DESC_STATUS_RXINTR;
724 g_assert_cmphex((result_desc.status_and_length & expected_mask), ==,
725 expected_value);
726 g_assert_cmpint(RX_DESC_PKT_LEN(result_desc.status_and_length), ==,
727 RX_DATA_LEN + CRC_LENGTH);
730 char buffer[RX_DATA_LEN];
731 qtest_memread(qts, data_addr, buffer, sizeof(buffer));
732 g_assert_cmpstr(buffer, == , "TEST");
736 static void emc_test_ptle(QTestState *qts, const EMCModule *mod, int fd)
738 NPCM7xxEMCRxDesc desc[NUM_RX_DESCRIPTORS];
739 uint32_t desc_addr = DESC_ADDR;
740 uint32_t data_addr = DATA_ADDR;
741 int ret;
742 NPCM7xxEMCRxDesc result_desc;
743 uint32_t expected_mask, expected_value;
745 /* Prepare test data buffer. */
746 #define PTLE_DATA_LEN 1600
747 char test_data[PTLE_DATA_LEN];
748 int len = htonl(sizeof(test_data));
749 const struct iovec iov[] = {
751 .iov_base = &len,
752 .iov_len = sizeof(len),
754 .iov_base = (char *) test_data,
755 .iov_len = sizeof(test_data),
758 memset(test_data, 42, sizeof(test_data));
761 * Reset the device BEFORE sending a test packet, otherwise the packet
762 * may get swallowed by an active device of an earlier test.
764 init_rx_desc(&desc[0], NUM_RX_DESCRIPTORS, desc_addr, data_addr);
765 enable_rx(qts, mod, &desc[0], NUM_RX_DESCRIPTORS, desc_addr,
766 REG_MIEN_ENRXINTR, REG_MCMDR_ALP);
768 /* Send test packet to device's socket. */
769 ret = iov_send(fd, iov, 2, 0, sizeof(len) + sizeof(test_data));
770 g_assert_cmpint(ret, == , sizeof(test_data) + sizeof(len));
772 /* Wait for RX interrupt. */
773 g_assert_true(emc_wait_irq(qts, mod, RX_STEP_COUNT, /*is_tx=*/false));
775 /* Read the descriptor back. */
776 emc_read_rx_desc(qts, desc_addr, &result_desc);
777 /* Descriptor should be owned by cpu now. */
778 g_assert((result_desc.status_and_length & RX_DESC_STATUS_OWNER_MASK) == 0);
779 /* Test the status bits, ignoring the length field. */
780 expected_mask = 0xffff << 16;
781 expected_value = (RX_DESC_STATUS_RXGD |
782 RX_DESC_STATUS_PTLE |
783 RX_DESC_STATUS_RXINTR);
784 g_assert_cmphex((result_desc.status_and_length & expected_mask), ==,
785 expected_value);
786 g_assert_cmpint(RX_DESC_PKT_LEN(result_desc.status_and_length), ==,
787 PTLE_DATA_LEN + CRC_LENGTH);
790 char buffer[PTLE_DATA_LEN];
791 qtest_memread(qts, data_addr, buffer, sizeof(buffer));
792 g_assert(memcmp(buffer, test_data, PTLE_DATA_LEN) == 0);
796 static void test_tx(gconstpointer test_data)
798 const TestData *td = test_data;
799 GString *cmd_line = g_string_new("-machine quanta-gsj");
800 int *test_sockets = packet_test_init(emc_module_index(td->module),
801 cmd_line);
802 QTestState *qts = qtest_init(cmd_line->str);
805 * TODO: For pedantic correctness test_sockets[0] should be closed after
806 * the fork and before the exec, but that will require some harness
807 * improvements.
809 close(test_sockets[1]);
810 /* Defensive programming */
811 test_sockets[1] = -1;
813 qtest_irq_intercept_in(qts, "/machine/soc/a9mpcore/gic");
815 emc_send_verify(qts, td->module, test_sockets[0], /*with_irq=*/false);
816 emc_send_verify(qts, td->module, test_sockets[0], /*with_irq=*/true);
818 qtest_quit(qts);
821 static void test_rx(gconstpointer test_data)
823 const TestData *td = test_data;
824 GString *cmd_line = g_string_new("-machine quanta-gsj");
825 int *test_sockets = packet_test_init(emc_module_index(td->module),
826 cmd_line);
827 QTestState *qts = qtest_init(cmd_line->str);
830 * TODO: For pedantic correctness test_sockets[0] should be closed after
831 * the fork and before the exec, but that will require some harness
832 * improvements.
834 close(test_sockets[1]);
835 /* Defensive programming */
836 test_sockets[1] = -1;
838 qtest_irq_intercept_in(qts, "/machine/soc/a9mpcore/gic");
840 emc_recv_verify(qts, td->module, test_sockets[0], /*with_irq=*/false,
841 /*pump_rsdr=*/false);
842 emc_recv_verify(qts, td->module, test_sockets[0], /*with_irq=*/false,
843 /*pump_rsdr=*/true);
844 emc_recv_verify(qts, td->module, test_sockets[0], /*with_irq=*/true,
845 /*pump_rsdr=*/false);
846 emc_recv_verify(qts, td->module, test_sockets[0], /*with_irq=*/true,
847 /*pump_rsdr=*/true);
848 emc_test_ptle(qts, td->module, test_sockets[0]);
850 qtest_quit(qts);
852 #endif /* _WIN32 */
854 static void emc_add_test(const char *name, const TestData* td,
855 GTestDataFunc fn)
857 g_autofree char *full_name = g_strdup_printf(
858 "npcm7xx_emc/emc[%d]/%s", emc_module_index(td->module), name);
859 qtest_add_data_func(full_name, td, fn);
861 #define add_test(name, td) emc_add_test(#name, td, test_##name)
863 int main(int argc, char **argv)
865 TestData test_data_list[ARRAY_SIZE(emc_module_list)];
867 g_test_init(&argc, &argv, NULL);
869 for (int i = 0; i < ARRAY_SIZE(emc_module_list); ++i) {
870 TestData *td = &test_data_list[i];
872 td->module = &emc_module_list[i];
874 add_test(init, td);
875 #ifndef _WIN32
876 add_test(tx, td);
877 add_test(rx, td);
878 #endif
881 return g_test_run();