/* * ACPI implementation * * Copyright (c) 2006 Fabrice Bellard * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License version 2 as published by the Free Software Foundation. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, see * * Contributions after 2012-01-13 are licensed under the terms of the * GNU GPL, version 2 or (at your option) any later version. */ #include "qemu/osdep.h" #include "hw/irq.h" #include "hw/acpi/acpi.h" #include "hw/nvram/fw_cfg.h" #include "qemu/config-file.h" #include "qapi/error.h" #include "qapi/opts-visitor.h" #include "qapi/qapi-events-run-state.h" #include "qapi/qapi-visit-acpi.h" #include "qemu/error-report.h" #include "qemu/module.h" #include "qemu/option.h" #include "sysemu/runstate.h" struct acpi_table_header { uint16_t _length; /* our length, not actual part of the hdr */ /* allows easier parsing for fw_cfg clients */ char sig[4] QEMU_NONSTRING; /* ACPI signature (4 ASCII characters) */ uint32_t length; /* Length of table, in bytes, including header */ uint8_t revision; /* ACPI Specification minor version # */ uint8_t checksum; /* To make sum of entire table == 0 */ char oem_id[6] QEMU_NONSTRING; /* OEM identification */ char oem_table_id[8] QEMU_NONSTRING; /* OEM table identification */ uint32_t oem_revision; /* OEM revision number */ char asl_compiler_id[4] QEMU_NONSTRING; /* ASL compiler vendor ID */ uint32_t asl_compiler_revision; /* ASL compiler revision number */ } QEMU_PACKED; #define ACPI_TABLE_HDR_SIZE sizeof(struct acpi_table_header) #define ACPI_TABLE_PFX_SIZE sizeof(uint16_t) /* size of the extra prefix */ static const char unsigned dfl_hdr[ACPI_TABLE_HDR_SIZE - ACPI_TABLE_PFX_SIZE] = "QEMU\0\0\0\0\1\0" /* sig (4), len(4), revno (1), csum (1) */ "QEMUQEQEMUQEMU\1\0\0\0" /* OEM id (6), table (8), revno (4) */ "QEMU\1\0\0\0" /* ASL compiler ID (4), version (4) */ ; char unsigned *acpi_tables; size_t acpi_tables_len; static QemuOptsList qemu_acpi_opts = { .name = "acpi", .implied_opt_name = "data", .head = QTAILQ_HEAD_INITIALIZER(qemu_acpi_opts.head), .desc = { { 0 } } /* validated with OptsVisitor */ }; static void acpi_register_config(void) { qemu_add_opts(&qemu_acpi_opts); } opts_init(acpi_register_config); static int acpi_checksum(const uint8_t *data, int len) { int sum, i; sum = 0; for (i = 0; i < len; i++) { sum += data[i]; } return (-sum) & 0xff; } /* Install a copy of the ACPI table specified in @blob. * * If @has_header is set, @blob starts with the System Description Table Header * structure. Otherwise, "dfl_hdr" is prepended. In any case, each header field * is optionally overwritten from @hdrs. * * It is valid to call this function with * (@blob == NULL && bloblen == 0 && !has_header). * * @hdrs->file and @hdrs->data are ignored. * * SIZE_MAX is considered "infinity" in this function. * * The number of tables that can be installed is not limited, but the 16-bit * counter at the beginning of "acpi_tables" wraps around after UINT16_MAX. */ static void acpi_table_install(const char unsigned *blob, size_t bloblen, bool has_header, const struct AcpiTableOptions *hdrs, Error **errp) { size_t body_start; const char unsigned *hdr_src; size_t body_size, acpi_payload_size; struct acpi_table_header *ext_hdr; unsigned changed_fields; /* Calculate where the ACPI table body starts within the blob, plus where * to copy the ACPI table header from. */ if (has_header) { /* _length | ACPI header in blob | blob body * ^^^^^^^^^^^^^^^^^^^ ^^^^^^^^^^^^^^^^^^^ ^^^^^^^^^ * ACPI_TABLE_PFX_SIZE sizeof dfl_hdr body_size * == body_start * * ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ * acpi_payload_size == bloblen */ body_start = sizeof dfl_hdr; if (bloblen < body_start) { error_setg(errp, "ACPI table claiming to have header is too " "short, available: %zu, expected: %zu", bloblen, body_start); return; } hdr_src = blob; } else { /* _length | ACPI header in template | blob body * ^^^^^^^^^^^^^^^^^^^ ^^^^^^^^^^^^^^^^^^^^^^^ ^^^^^^^^^^ * ACPI_TABLE_PFX_SIZE sizeof dfl_hdr body_size * == bloblen * * ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ * acpi_payload_size */ body_start = 0; hdr_src = dfl_hdr; } body_size = bloblen - body_start; acpi_payload_size = sizeof dfl_hdr + body_size; if (acpi_payload_size > UINT16_MAX) { error_setg(errp, "ACPI table too big, requested: %zu, max: %u", acpi_payload_size, (unsigned)UINT16_MAX); return; } /* We won't fail from here on. Initialize / extend the globals. */ if (acpi_tables == NULL) { acpi_tables_len = sizeof(uint16_t); acpi_tables = g_malloc0(acpi_tables_len); } acpi_tables = g_realloc(acpi_tables, acpi_tables_len + ACPI_TABLE_PFX_SIZE + sizeof dfl_hdr + body_size); ext_hdr = (struct acpi_table_header *)(acpi_tables + acpi_tables_len); acpi_tables_len += ACPI_TABLE_PFX_SIZE; memcpy(acpi_tables + acpi_tables_len, hdr_src, sizeof dfl_hdr); acpi_tables_len += sizeof dfl_hdr; if (blob != NULL) { memcpy(acpi_tables + acpi_tables_len, blob + body_start, body_size); acpi_tables_len += body_size; } /* increase number of tables */ stw_le_p(acpi_tables, lduw_le_p(acpi_tables) + 1u); /* Update the header fields. The strings need not be NUL-terminated. */ changed_fields = 0; ext_hdr->_length = cpu_to_le16(acpi_payload_size); if (hdrs->has_sig) { strncpy(ext_hdr->sig, hdrs->sig, sizeof ext_hdr->sig); ++changed_fields; } if (has_header && le32_to_cpu(ext_hdr->length) != acpi_payload_size) { warn_report("ACPI table has wrong length, header says " "%" PRIu32 ", actual size %zu bytes", le32_to_cpu(ext_hdr->length), acpi_payload_size); } ext_hdr->length = cpu_to_le32(acpi_payload_size); if (hdrs->has_rev) { ext_hdr->revision = hdrs->rev; ++changed_fields; } ext_hdr->checksum = 0; if (hdrs->has_oem_id) { strncpy(ext_hdr->oem_id, hdrs->oem_id, sizeof ext_hdr->oem_id); ++changed_fields; } if (hdrs->has_oem_table_id) { strncpy(ext_hdr->oem_table_id, hdrs->oem_table_id, sizeof ext_hdr->oem_table_id); ++changed_fields; } if (hdrs->has_oem_rev) { ext_hdr->oem_revision = cpu_to_le32(hdrs->oem_rev); ++changed_fields; } if (hdrs->has_asl_compiler_id) { strncpy(ext_hdr->asl_compiler_id, hdrs->asl_compiler_id, sizeof ext_hdr->asl_compiler_id); ++changed_fields; } if (hdrs->has_asl_compiler_rev) { ext_hdr->asl_compiler_revision = cpu_to_le32(hdrs->asl_compiler_rev); ++changed_fields; } if (!has_header && changed_fields == 0) { warn_report("ACPI table: no headers are specified"); } /* recalculate checksum */ ext_hdr->checksum = acpi_checksum((const char unsigned *)ext_hdr + ACPI_TABLE_PFX_SIZE, acpi_payload_size); } void acpi_table_add(const QemuOpts *opts, Error **errp) { AcpiTableOptions *hdrs = NULL; char **pathnames = NULL; char **cur; size_t bloblen = 0; char unsigned *blob = NULL; { Visitor *v; v = opts_visitor_new(opts); visit_type_AcpiTableOptions(v, NULL, &hdrs, errp); visit_free(v); } if (!hdrs) { goto out; } if (hdrs->has_file == hdrs->has_data) { error_setg(errp, "'-acpitable' requires one of 'data' or 'file'"); goto out; } pathnames = g_strsplit(hdrs->has_file ? hdrs->file : hdrs->data, ":", 0); if (pathnames == NULL || pathnames[0] == NULL) { error_setg(errp, "'-acpitable' requires at least one pathname"); goto out; } /* now read in the data files, reallocating buffer as needed */ for (cur = pathnames; *cur; ++cur) { int fd = open(*cur, O_RDONLY | O_BINARY); if (fd < 0) { error_setg(errp, "can't open file %s: %s", *cur, strerror(errno)); goto out; } for (;;) { char unsigned data[8192]; ssize_t r; r = read(fd, data, sizeof data); if (r == 0) { break; } else if (r > 0) { blob = g_realloc(blob, bloblen + r); memcpy(blob + bloblen, data, r); bloblen += r; } else if (errno != EINTR) { error_setg(errp, "can't read file %s: %s", *cur, strerror(errno)); close(fd); goto out; } } close(fd); } acpi_table_install(blob, bloblen, hdrs->has_file, hdrs, errp); out: g_free(blob); g_strfreev(pathnames); qapi_free_AcpiTableOptions(hdrs); } unsigned acpi_table_len(void *current) { struct acpi_table_header *hdr = current - sizeof(hdr->_length); return hdr->_length; } static void *acpi_table_hdr(void *h) { struct acpi_table_header *hdr = h; return &hdr->sig; } uint8_t *acpi_table_first(void) { if (!acpi_tables) { return NULL; } return acpi_table_hdr(acpi_tables + ACPI_TABLE_PFX_SIZE); } uint8_t *acpi_table_next(uint8_t *current) { uint8_t *next = current + acpi_table_len(current); if (next - acpi_tables >= acpi_tables_len) { return NULL; } else { return acpi_table_hdr(next); } } int acpi_get_slic_oem(AcpiSlicOem *oem) { uint8_t *u; for (u = acpi_table_first(); u; u = acpi_table_next(u)) { struct acpi_table_header *hdr = (void *)(u - sizeof(hdr->_length)); if (memcmp(hdr->sig, "SLIC", 4) == 0) { oem->id = hdr->oem_id; oem->table_id = hdr->oem_table_id; return 0; } } return -1; } static void acpi_notify_wakeup(Notifier *notifier, void *data) { ACPIREGS *ar = container_of(notifier, ACPIREGS, wakeup); WakeupReason *reason = data; switch (*reason) { case QEMU_WAKEUP_REASON_RTC: ar->pm1.evt.sts |= (ACPI_BITMASK_WAKE_STATUS | ACPI_BITMASK_RT_CLOCK_STATUS); break; case QEMU_WAKEUP_REASON_PMTIMER: ar->pm1.evt.sts |= (ACPI_BITMASK_WAKE_STATUS | ACPI_BITMASK_TIMER_STATUS); break; case QEMU_WAKEUP_REASON_OTHER: /* ACPI_BITMASK_WAKE_STATUS should be set on resume. Pretend that resume was caused by power button */ ar->pm1.evt.sts |= (ACPI_BITMASK_WAKE_STATUS | ACPI_BITMASK_POWER_BUTTON_STATUS); break; default: break; } } /* ACPI PM1a EVT */ uint16_t acpi_pm1_evt_get_sts(ACPIREGS *ar) { /* Compare ns-clock, not PM timer ticks, because acpi_pm_tmr_update function uses ns for setting the timer. */ int64_t d = qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL); if (d >= muldiv64(ar->tmr.overflow_time, NANOSECONDS_PER_SECOND, PM_TIMER_FREQUENCY)) { ar->pm1.evt.sts |= ACPI_BITMASK_TIMER_STATUS; } return ar->pm1.evt.sts; } static void acpi_pm1_evt_write_sts(ACPIREGS *ar, uint16_t val) { uint16_t pm1_sts = acpi_pm1_evt_get_sts(ar); if (pm1_sts & val & ACPI_BITMASK_TIMER_STATUS) { /* if TMRSTS is reset, then compute the new overflow time */ acpi_pm_tmr_calc_overflow_time(ar); } ar->pm1.evt.sts &= ~val; } static void acpi_pm1_evt_write_en(ACPIREGS *ar, uint16_t val) { ar->pm1.evt.en = val; qemu_system_wakeup_enable(QEMU_WAKEUP_REASON_RTC, val & ACPI_BITMASK_RT_CLOCK_ENABLE); qemu_system_wakeup_enable(QEMU_WAKEUP_REASON_PMTIMER, val & ACPI_BITMASK_TIMER_ENABLE); } void acpi_pm1_evt_power_down(ACPIREGS *ar) { if (ar->pm1.evt.en & ACPI_BITMASK_POWER_BUTTON_ENABLE) { ar->pm1.evt.sts |= ACPI_BITMASK_POWER_BUTTON_STATUS; ar->tmr.update_sci(ar); } } void acpi_pm1_evt_reset(ACPIREGS *ar) { ar->pm1.evt.sts = 0; ar->pm1.evt.en = 0; qemu_system_wakeup_enable(QEMU_WAKEUP_REASON_RTC, 0); qemu_system_wakeup_enable(QEMU_WAKEUP_REASON_PMTIMER, 0); } static uint64_t acpi_pm_evt_read(void *opaque, hwaddr addr, unsigned width) { ACPIREGS *ar = opaque; switch (addr) { case 0: return acpi_pm1_evt_get_sts(ar); case 2: return ar->pm1.evt.en; default: return 0; } } static void acpi_pm_evt_write(void *opaque, hwaddr addr, uint64_t val, unsigned width) { ACPIREGS *ar = opaque; switch (addr) { case 0: acpi_pm1_evt_write_sts(ar, val); ar->pm1.evt.update_sci(ar); break; case 2: acpi_pm1_evt_write_en(ar, val); ar->pm1.evt.update_sci(ar); break; } } static const MemoryRegionOps acpi_pm_evt_ops = { .read = acpi_pm_evt_read, .write = acpi_pm_evt_write, .impl.min_access_size = 2, .valid.min_access_size = 1, .valid.max_access_size = 2, .endianness = DEVICE_LITTLE_ENDIAN, }; void acpi_pm1_evt_init(ACPIREGS *ar, acpi_update_sci_fn update_sci, MemoryRegion *parent) { ar->pm1.evt.update_sci = update_sci; memory_region_init_io(&ar->pm1.evt.io, memory_region_owner(parent), &acpi_pm_evt_ops, ar, "acpi-evt", 4); memory_region_add_subregion(parent, 0, &ar->pm1.evt.io); } /* ACPI PM_TMR */ void acpi_pm_tmr_update(ACPIREGS *ar, bool enable) { int64_t expire_time; /* schedule a timer interruption if needed */ if (enable) { expire_time = muldiv64(ar->tmr.overflow_time, NANOSECONDS_PER_SECOND, PM_TIMER_FREQUENCY); timer_mod(ar->tmr.timer, expire_time); } else { timer_del(ar->tmr.timer); } } static inline int64_t acpi_pm_tmr_get_clock(void) { return muldiv64(qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL), PM_TIMER_FREQUENCY, NANOSECONDS_PER_SECOND); } void acpi_pm_tmr_calc_overflow_time(ACPIREGS *ar) { int64_t d = acpi_pm_tmr_get_clock(); ar->tmr.overflow_time = (d + 0x800000LL) & ~0x7fffffLL; } static uint32_t acpi_pm_tmr_get(ACPIREGS *ar) { uint32_t d = acpi_pm_tmr_get_clock(); return d & 0xffffff; } static void acpi_pm_tmr_timer(void *opaque) { ACPIREGS *ar = opaque; qemu_system_wakeup_request(QEMU_WAKEUP_REASON_PMTIMER, NULL); ar->tmr.update_sci(ar); } static uint64_t acpi_pm_tmr_read(void *opaque, hwaddr addr, unsigned width) { return acpi_pm_tmr_get(opaque); } static void acpi_pm_tmr_write(void *opaque, hwaddr addr, uint64_t val, unsigned width) { /* nothing */ } static const MemoryRegionOps acpi_pm_tmr_ops = { .read = acpi_pm_tmr_read, .write = acpi_pm_tmr_write, .impl.min_access_size = 4, .valid.min_access_size = 1, .valid.max_access_size = 4, .endianness = DEVICE_LITTLE_ENDIAN, }; void acpi_pm_tmr_init(ACPIREGS *ar, acpi_update_sci_fn update_sci, MemoryRegion *parent) { ar->tmr.update_sci = update_sci; ar->tmr.timer = timer_new_ns(QEMU_CLOCK_VIRTUAL, acpi_pm_tmr_timer, ar); memory_region_init_io(&ar->tmr.io, memory_region_owner(parent), &acpi_pm_tmr_ops, ar, "acpi-tmr", 4); memory_region_add_subregion(parent, 8, &ar->tmr.io); } void acpi_pm_tmr_reset(ACPIREGS *ar) { ar->tmr.overflow_time = 0; timer_del(ar->tmr.timer); } /* ACPI PM1aCNT */ static void acpi_pm1_cnt_write(ACPIREGS *ar, uint16_t val) { ar->pm1.cnt.cnt = val & ~(ACPI_BITMASK_SLEEP_ENABLE); if (val & ACPI_BITMASK_SLEEP_ENABLE) { /* change suspend type */ uint16_t sus_typ = (val >> 10) & 7; switch (sus_typ) { case 0: /* soft power off */ qemu_system_shutdown_request(SHUTDOWN_CAUSE_GUEST_SHUTDOWN); break; case 1: qemu_system_suspend_request(); break; default: if (sus_typ == ar->pm1.cnt.s4_val) { /* S4 request */ qapi_event_send_suspend_disk(); qemu_system_shutdown_request(SHUTDOWN_CAUSE_GUEST_SHUTDOWN); } break; } } } void acpi_pm1_cnt_update(ACPIREGS *ar, bool sci_enable, bool sci_disable) { /* ACPI specs 3.0, 4.7.2.5 */ if (sci_enable) { ar->pm1.cnt.cnt |= ACPI_BITMASK_SCI_ENABLE; } else if (sci_disable) { ar->pm1.cnt.cnt &= ~ACPI_BITMASK_SCI_ENABLE; } } static uint64_t acpi_pm_cnt_read(void *opaque, hwaddr addr, unsigned width) { ACPIREGS *ar = opaque; return ar->pm1.cnt.cnt; } static void acpi_pm_cnt_write(void *opaque, hwaddr addr, uint64_t val, unsigned width) { acpi_pm1_cnt_write(opaque, val); } static const MemoryRegionOps acpi_pm_cnt_ops = { .read = acpi_pm_cnt_read, .write = acpi_pm_cnt_write, .impl.min_access_size = 2, .valid.min_access_size = 1, .valid.max_access_size = 2, .endianness = DEVICE_LITTLE_ENDIAN, }; void acpi_pm1_cnt_init(ACPIREGS *ar, MemoryRegion *parent, bool disable_s3, bool disable_s4, uint8_t s4_val) { FWCfgState *fw_cfg; ar->pm1.cnt.s4_val = s4_val; ar->wakeup.notify = acpi_notify_wakeup; qemu_register_wakeup_notifier(&ar->wakeup); /* * Register wake-up support in QMP query-current-machine API */ qemu_register_wakeup_support(); memory_region_init_io(&ar->pm1.cnt.io, memory_region_owner(parent), &acpi_pm_cnt_ops, ar, "acpi-cnt", 2); memory_region_add_subregion(parent, 4, &ar->pm1.cnt.io); fw_cfg = fw_cfg_find(); if (fw_cfg) { uint8_t suspend[6] = {128, 0, 0, 129, 128, 128}; suspend[3] = 1 | ((!disable_s3) << 7); suspend[4] = s4_val | ((!disable_s4) << 7); fw_cfg_add_file(fw_cfg, "etc/system-states", g_memdup(suspend, 6), 6); } } void acpi_pm1_cnt_reset(ACPIREGS *ar) { ar->pm1.cnt.cnt = 0; } /* ACPI GPE */ void acpi_gpe_init(ACPIREGS *ar, uint8_t len) { ar->gpe.len = len; /* Only first len / 2 bytes are ever used, * but the caller in ich9.c migrates full len bytes. * TODO: fix ich9.c and drop the extra allocation. */ ar->gpe.sts = g_malloc0(len); ar->gpe.en = g_malloc0(len); } void acpi_gpe_reset(ACPIREGS *ar) { memset(ar->gpe.sts, 0, ar->gpe.len / 2); memset(ar->gpe.en, 0, ar->gpe.len / 2); } static uint8_t *acpi_gpe_ioport_get_ptr(ACPIREGS *ar, uint32_t addr) { uint8_t *cur = NULL; if (addr < ar->gpe.len / 2) { cur = ar->gpe.sts + addr; } else if (addr < ar->gpe.len) { cur = ar->gpe.en + addr - ar->gpe.len / 2; } else { abort(); } return cur; } void acpi_gpe_ioport_writeb(ACPIREGS *ar, uint32_t addr, uint32_t val) { uint8_t *cur; cur = acpi_gpe_ioport_get_ptr(ar, addr); if (addr < ar->gpe.len / 2) { /* GPE_STS */ *cur = (*cur) & ~val; } else if (addr < ar->gpe.len) { /* GPE_EN */ *cur = val; } else { abort(); } } uint32_t acpi_gpe_ioport_readb(ACPIREGS *ar, uint32_t addr) { uint8_t *cur; uint32_t val; cur = acpi_gpe_ioport_get_ptr(ar, addr); val = 0; if (cur != NULL) { val = *cur; } return val; } void acpi_send_gpe_event(ACPIREGS *ar, qemu_irq irq, AcpiEventStatusBits status) { ar->gpe.sts[0] |= status; acpi_update_sci(ar, irq); } void acpi_update_sci(ACPIREGS *regs, qemu_irq irq) { int sci_level, pm1a_sts; pm1a_sts = acpi_pm1_evt_get_sts(regs); sci_level = ((pm1a_sts & regs->pm1.evt.en & ACPI_BITMASK_PM1_COMMON_ENABLED) != 0) || ((regs->gpe.sts[0] & regs->gpe.en[0]) != 0); qemu_set_irq(irq, sci_level); /* schedule a timer interruption if needed */ acpi_pm_tmr_update(regs, (regs->pm1.evt.en & ACPI_BITMASK_TIMER_ENABLE) && !(pm1a_sts & ACPI_BITMASK_TIMER_STATUS)); }