/* * IDE test cases * * Copyright (c) 2013 Kevin Wolf * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. */ #include #include #include #include #include "libqtest.h" #include "libqos/pci-pc.h" #include "libqos/malloc-pc.h" #include "qemu-common.h" #include "hw/pci/pci_ids.h" #include "hw/pci/pci_regs.h" #define TEST_IMAGE_SIZE 64 * 1024 * 1024 #define IDE_PCI_DEV 1 #define IDE_PCI_FUNC 1 #define IDE_BASE 0x1f0 #define IDE_PRIMARY_IRQ 14 enum { reg_data = 0x0, reg_nsectors = 0x2, reg_lba_low = 0x3, reg_lba_middle = 0x4, reg_lba_high = 0x5, reg_device = 0x6, reg_status = 0x7, reg_command = 0x7, }; enum { BSY = 0x80, DRDY = 0x40, DF = 0x20, DRQ = 0x08, ERR = 0x01, }; enum { DEV = 0x10, LBA = 0x40, }; enum { bmreg_cmd = 0x0, bmreg_status = 0x2, bmreg_prdt = 0x4, }; enum { CMD_READ_DMA = 0xc8, CMD_WRITE_DMA = 0xca, CMD_FLUSH_CACHE = 0xe7, CMD_IDENTIFY = 0xec, CMDF_ABORT = 0x100, CMDF_NO_BM = 0x200, }; enum { BM_CMD_START = 0x1, BM_CMD_WRITE = 0x8, /* write = from device to memory */ }; enum { BM_STS_ACTIVE = 0x1, BM_STS_ERROR = 0x2, BM_STS_INTR = 0x4, }; enum { PRDT_EOT = 0x80000000, }; #define assert_bit_set(data, mask) g_assert_cmphex((data) & (mask), ==, (mask)) #define assert_bit_clear(data, mask) g_assert_cmphex((data) & (mask), ==, 0) static QPCIBus *pcibus = NULL; static QGuestAllocator *guest_malloc; static char tmp_path[] = "/tmp/qtest.XXXXXX"; static char debug_path[] = "/tmp/qtest-blkdebug.XXXXXX"; static void ide_test_start(const char *cmdline_fmt, ...) { va_list ap; char *cmdline; va_start(ap, cmdline_fmt); cmdline = g_strdup_vprintf(cmdline_fmt, ap); va_end(ap); qtest_start(cmdline); qtest_irq_intercept_in(global_qtest, "ioapic"); guest_malloc = pc_alloc_init(); } static void ide_test_quit(void) { qtest_end(); } static QPCIDevice *get_pci_device(uint16_t *bmdma_base) { QPCIDevice *dev; uint16_t vendor_id, device_id; if (!pcibus) { pcibus = qpci_init_pc(); } /* Find PCI device and verify it's the right one */ dev = qpci_device_find(pcibus, QPCI_DEVFN(IDE_PCI_DEV, IDE_PCI_FUNC)); g_assert(dev != NULL); vendor_id = qpci_config_readw(dev, PCI_VENDOR_ID); device_id = qpci_config_readw(dev, PCI_DEVICE_ID); g_assert(vendor_id == PCI_VENDOR_ID_INTEL); g_assert(device_id == PCI_DEVICE_ID_INTEL_82371SB_1); /* Map bmdma BAR */ *bmdma_base = (uint16_t)(uintptr_t) qpci_iomap(dev, 4); qpci_device_enable(dev); return dev; } static void free_pci_device(QPCIDevice *dev) { /* libqos doesn't have a function for this, so free it manually */ g_free(dev); } typedef struct PrdtEntry { uint32_t addr; uint32_t size; } QEMU_PACKED PrdtEntry; #define assert_bit_set(data, mask) g_assert_cmphex((data) & (mask), ==, (mask)) #define assert_bit_clear(data, mask) g_assert_cmphex((data) & (mask), ==, 0) static int send_dma_request(int cmd, uint64_t sector, int nb_sectors, PrdtEntry *prdt, int prdt_entries) { QPCIDevice *dev; uint16_t bmdma_base; uintptr_t guest_prdt; size_t len; bool from_dev; uint8_t status; int flags; dev = get_pci_device(&bmdma_base); flags = cmd & ~0xff; cmd &= 0xff; switch (cmd) { case CMD_READ_DMA: from_dev = true; break; case CMD_WRITE_DMA: from_dev = false; break; default: g_assert_not_reached(); } if (flags & CMDF_NO_BM) { qpci_config_writew(dev, PCI_COMMAND, PCI_COMMAND_IO | PCI_COMMAND_MEMORY); } /* Select device 0 */ outb(IDE_BASE + reg_device, 0 | LBA); /* Stop any running transfer, clear any pending interrupt */ outb(bmdma_base + bmreg_cmd, 0); outb(bmdma_base + bmreg_status, BM_STS_INTR); /* Setup PRDT */ len = sizeof(*prdt) * prdt_entries; guest_prdt = guest_alloc(guest_malloc, len); memwrite(guest_prdt, prdt, len); outl(bmdma_base + bmreg_prdt, guest_prdt); /* ATA DMA command */ outb(IDE_BASE + reg_nsectors, nb_sectors); outb(IDE_BASE + reg_lba_low, sector & 0xff); outb(IDE_BASE + reg_lba_middle, (sector >> 8) & 0xff); outb(IDE_BASE + reg_lba_high, (sector >> 16) & 0xff); outb(IDE_BASE + reg_command, cmd); /* Start DMA transfer */ outb(bmdma_base + bmreg_cmd, BM_CMD_START | (from_dev ? BM_CMD_WRITE : 0)); if (flags & CMDF_ABORT) { outb(bmdma_base + bmreg_cmd, 0); } /* Wait for the DMA transfer to complete */ do { status = inb(bmdma_base + bmreg_status); } while ((status & (BM_STS_ACTIVE | BM_STS_INTR)) == BM_STS_ACTIVE); g_assert_cmpint(get_irq(IDE_PRIMARY_IRQ), ==, !!(status & BM_STS_INTR)); /* Check IDE status code */ assert_bit_set(inb(IDE_BASE + reg_status), DRDY); assert_bit_clear(inb(IDE_BASE + reg_status), BSY | DRQ); /* Reading the status register clears the IRQ */ g_assert(!get_irq(IDE_PRIMARY_IRQ)); /* Stop DMA transfer if still active */ if (status & BM_STS_ACTIVE) { outb(bmdma_base + bmreg_cmd, 0); } free_pci_device(dev); return status; } static void test_bmdma_simple_rw(void) { uint8_t status; uint8_t *buf; uint8_t *cmpbuf; size_t len = 512; uintptr_t guest_buf = guest_alloc(guest_malloc, len); PrdtEntry prdt[] = { { .addr = cpu_to_le32(guest_buf), .size = cpu_to_le32(len | PRDT_EOT), }, }; buf = g_malloc(len); cmpbuf = g_malloc(len); /* Write 0x55 pattern to sector 0 */ memset(buf, 0x55, len); memwrite(guest_buf, buf, len); status = send_dma_request(CMD_WRITE_DMA, 0, 1, prdt, ARRAY_SIZE(prdt)); g_assert_cmphex(status, ==, BM_STS_INTR); assert_bit_clear(inb(IDE_BASE + reg_status), DF | ERR); /* Write 0xaa pattern to sector 1 */ memset(buf, 0xaa, len); memwrite(guest_buf, buf, len); status = send_dma_request(CMD_WRITE_DMA, 1, 1, prdt, ARRAY_SIZE(prdt)); g_assert_cmphex(status, ==, BM_STS_INTR); assert_bit_clear(inb(IDE_BASE + reg_status), DF | ERR); /* Read and verify 0x55 pattern in sector 0 */ memset(cmpbuf, 0x55, len); status = send_dma_request(CMD_READ_DMA, 0, 1, prdt, ARRAY_SIZE(prdt)); g_assert_cmphex(status, ==, BM_STS_INTR); assert_bit_clear(inb(IDE_BASE + reg_status), DF | ERR); memread(guest_buf, buf, len); g_assert(memcmp(buf, cmpbuf, len) == 0); /* Read and verify 0xaa pattern in sector 1 */ memset(cmpbuf, 0xaa, len); status = send_dma_request(CMD_READ_DMA, 1, 1, prdt, ARRAY_SIZE(prdt)); g_assert_cmphex(status, ==, BM_STS_INTR); assert_bit_clear(inb(IDE_BASE + reg_status), DF | ERR); memread(guest_buf, buf, len); g_assert(memcmp(buf, cmpbuf, len) == 0); g_free(buf); g_free(cmpbuf); } static void test_bmdma_short_prdt(void) { uint8_t status; PrdtEntry prdt[] = { { .addr = 0, .size = cpu_to_le32(0x10 | PRDT_EOT), }, }; /* Normal request */ status = send_dma_request(CMD_READ_DMA, 0, 1, prdt, ARRAY_SIZE(prdt)); g_assert_cmphex(status, ==, 0); assert_bit_clear(inb(IDE_BASE + reg_status), DF | ERR); /* Abort the request before it completes */ status = send_dma_request(CMD_READ_DMA | CMDF_ABORT, 0, 1, prdt, ARRAY_SIZE(prdt)); g_assert_cmphex(status, ==, 0); assert_bit_clear(inb(IDE_BASE + reg_status), DF | ERR); } static void test_bmdma_long_prdt(void) { uint8_t status; PrdtEntry prdt[] = { { .addr = 0, .size = cpu_to_le32(0x1000 | PRDT_EOT), }, }; /* Normal request */ status = send_dma_request(CMD_READ_DMA, 0, 1, prdt, ARRAY_SIZE(prdt)); g_assert_cmphex(status, ==, BM_STS_ACTIVE | BM_STS_INTR); assert_bit_clear(inb(IDE_BASE + reg_status), DF | ERR); /* Abort the request before it completes */ status = send_dma_request(CMD_READ_DMA | CMDF_ABORT, 0, 1, prdt, ARRAY_SIZE(prdt)); g_assert_cmphex(status, ==, BM_STS_INTR); assert_bit_clear(inb(IDE_BASE + reg_status), DF | ERR); } static void test_bmdma_no_busmaster(void) { uint8_t status; /* No PRDT_EOT, each entry addr 0/size 64k, and in theory qemu shouldn't be * able to access it anyway because the Bus Master bit in the PCI command * register isn't set. This is complete nonsense, but it used to be pretty * good at confusing and occasionally crashing qemu. */ PrdtEntry prdt[4096] = { }; status = send_dma_request(CMD_READ_DMA | CMDF_NO_BM, 0, 512, prdt, ARRAY_SIZE(prdt)); /* Not entirely clear what the expected result is, but this is what we get * in practice. At least we want to be aware of any changes. */ g_assert_cmphex(status, ==, BM_STS_ACTIVE | BM_STS_INTR); assert_bit_clear(inb(IDE_BASE + reg_status), DF | ERR); } static void test_bmdma_setup(void) { ide_test_start( "-drive file=%s,if=ide,serial=%s,cache=writeback " "-global ide-hd.ver=%s", tmp_path, "testdisk", "version"); } static void test_bmdma_teardown(void) { ide_test_quit(); } static void string_cpu_to_be16(uint16_t *s, size_t bytes) { g_assert((bytes & 1) == 0); bytes /= 2; while (bytes--) { *s = cpu_to_be16(*s); s++; } } static void test_identify(void) { uint8_t data; uint16_t buf[256]; int i; int ret; ide_test_start( "-drive file=%s,if=ide,serial=%s,cache=writeback " "-global ide-hd.ver=%s", tmp_path, "testdisk", "version"); /* IDENTIFY command on device 0*/ outb(IDE_BASE + reg_device, 0); outb(IDE_BASE + reg_command, CMD_IDENTIFY); /* Read in the IDENTIFY buffer and check registers */ data = inb(IDE_BASE + reg_device); g_assert_cmpint(data & DEV, ==, 0); for (i = 0; i < 256; i++) { data = inb(IDE_BASE + reg_status); assert_bit_set(data, DRDY | DRQ); assert_bit_clear(data, BSY | DF | ERR); ((uint16_t*) buf)[i] = inw(IDE_BASE + reg_data); } data = inb(IDE_BASE + reg_status); assert_bit_set(data, DRDY); assert_bit_clear(data, BSY | DF | ERR | DRQ); /* Check serial number/version in the buffer */ string_cpu_to_be16(&buf[10], 20); ret = memcmp(&buf[10], "testdisk ", 20); g_assert(ret == 0); string_cpu_to_be16(&buf[23], 8); ret = memcmp(&buf[23], "version ", 8); g_assert(ret == 0); /* Write cache enabled bit */ assert_bit_set(buf[85], 0x20); ide_test_quit(); } static void test_flush(void) { uint8_t data; ide_test_start( "-drive file=blkdebug::%s,if=ide,cache=writeback", tmp_path); /* Delay the completion of the flush request until we explicitly do it */ qmp_discard_response("{'execute':'human-monitor-command', 'arguments': {" " 'command-line':" " 'qemu-io ide0-hd0 \"break flush_to_os A\"'} }"); /* FLUSH CACHE command on device 0*/ outb(IDE_BASE + reg_device, 0); outb(IDE_BASE + reg_command, CMD_FLUSH_CACHE); /* Check status while request is in flight*/ data = inb(IDE_BASE + reg_status); assert_bit_set(data, BSY | DRDY); assert_bit_clear(data, DF | ERR | DRQ); /* Complete the command */ qmp_discard_response("{'execute':'human-monitor-command', 'arguments': {" " 'command-line':" " 'qemu-io ide0-hd0 \"resume A\"'} }"); /* Check registers */ data = inb(IDE_BASE + reg_device); g_assert_cmpint(data & DEV, ==, 0); do { data = inb(IDE_BASE + reg_status); } while (data & BSY); assert_bit_set(data, DRDY); assert_bit_clear(data, BSY | DF | ERR | DRQ); ide_test_quit(); } static void prepare_blkdebug_script(const char *debug_fn, const char *event) { FILE *debug_file = fopen(debug_fn, "w"); int ret; fprintf(debug_file, "[inject-error]\n"); fprintf(debug_file, "event = \"%s\"\n", event); fprintf(debug_file, "errno = \"5\"\n"); fprintf(debug_file, "state = \"1\"\n"); fprintf(debug_file, "immediately = \"off\"\n"); fprintf(debug_file, "once = \"on\"\n"); fprintf(debug_file, "[set-state]\n"); fprintf(debug_file, "event = \"%s\"\n", event); fprintf(debug_file, "new_state = \"2\"\n"); fflush(debug_file); g_assert(!ferror(debug_file)); ret = fclose(debug_file); g_assert(ret == 0); } static void test_retry_flush(void) { uint8_t data; const char *s; QDict *response; prepare_blkdebug_script(debug_path, "flush_to_disk"); ide_test_start( "-vnc none " "-drive file=blkdebug:%s:%s,if=ide,cache=writeback,rerror=stop,werror=stop", debug_path, tmp_path); /* FLUSH CACHE command on device 0*/ outb(IDE_BASE + reg_device, 0); outb(IDE_BASE + reg_command, CMD_FLUSH_CACHE); /* Check status while request is in flight*/ data = inb(IDE_BASE + reg_status); assert_bit_set(data, BSY | DRDY); assert_bit_clear(data, DF | ERR | DRQ); for (;; response = NULL) { response = qmp_receive(); if ((qdict_haskey(response, "event")) && (strcmp(qdict_get_str(response, "event"), "STOP") == 0)) { QDECREF(response); break; } QDECREF(response); } /* Complete the command */ s = "{'execute':'cont' }"; qmp_discard_response(s); /* Check registers */ data = inb(IDE_BASE + reg_device); g_assert_cmpint(data & DEV, ==, 0); do { data = inb(IDE_BASE + reg_status); } while (data & BSY); assert_bit_set(data, DRDY); assert_bit_clear(data, BSY | DF | ERR | DRQ); ide_test_quit(); } int main(int argc, char **argv) { const char *arch = qtest_get_arch(); int fd; int ret; /* Check architecture */ if (strcmp(arch, "i386") && strcmp(arch, "x86_64")) { g_test_message("Skipping test for non-x86\n"); return 0; } /* Create temporary blkdebug instructions */ fd = mkstemp(debug_path); g_assert(fd >= 0); close(fd); /* Create a temporary raw image */ fd = mkstemp(tmp_path); g_assert(fd >= 0); ret = ftruncate(fd, TEST_IMAGE_SIZE); g_assert(ret == 0); close(fd); /* Run the tests */ g_test_init(&argc, &argv, NULL); qtest_add_func("/ide/identify", test_identify); qtest_add_func("/ide/bmdma/setup", test_bmdma_setup); qtest_add_func("/ide/bmdma/simple_rw", test_bmdma_simple_rw); qtest_add_func("/ide/bmdma/short_prdt", test_bmdma_short_prdt); qtest_add_func("/ide/bmdma/long_prdt", test_bmdma_long_prdt); qtest_add_func("/ide/bmdma/no_busmaster", test_bmdma_no_busmaster); qtest_add_func("/ide/bmdma/teardown", test_bmdma_teardown); qtest_add_func("/ide/flush", test_flush); qtest_add_func("/ide/retry/flush", test_retry_flush); ret = g_test_run(); /* Cleanup */ unlink(tmp_path); unlink(debug_path); return ret; }