freebsd-nq/usr.sbin/bhyve/acpi.c
Neel Natu d84882ca8f Allow PCI devices to be configured on all valid bus numbers from 0 to 255.
This is done by representing each bus as root PCI device in ACPI. The device
implements the _BBN method to return the PCI bus number to the guest OS.

Each PCI bus keeps track of the resources that is decodes for devices
configured on the bus: i/o, mmio (32-bit) and mmio (64-bit). These windows
are advertised to the guest via the _CRS object of the root device.

Bus 0 is treated specially since it consumes the I/O ports to access the
PCI config space [0xcf8-0xcff]. It also decodes the legacy I/O ports that
are consumed by devices on the LPC bus. For this reason the LPC bridge can
be configured only on bus 0.

The bus number can be specified using the following command line option
to bhyve(8): "-s <bus>:<slot>:<func>,<emul>[,<config>]"

Discussed with:	grehan@
Reviewed by:	jhb@
2014-02-14 21:34:08 +00:00

970 lines
28 KiB
C

/*-
* Copyright (c) 2012 NetApp, Inc.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY NETAPP, INC ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL NETAPP, INC OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* $FreeBSD$
*/
/*
* bhyve ACPI table generator.
*
* Create the minimal set of ACPI tables required to boot FreeBSD (and
* hopefully other o/s's) by writing out ASL template files for each of
* the tables and the compiling them to AML with the Intel iasl compiler.
* The AML files are then read into guest memory.
*
* The tables are placed in the guest's ROM area just below 1MB physical,
* above the MPTable.
*
* Layout
* ------
* RSDP -> 0xf0400 (36 bytes fixed)
* RSDT -> 0xf0440 (36 bytes + 4*N table addrs, 2 used)
* XSDT -> 0xf0480 (36 bytes + 8*N table addrs, 2 used)
* MADT -> 0xf0500 (depends on #CPUs)
* FADT -> 0xf0600 (268 bytes)
* HPET -> 0xf0740 (56 bytes)
* FACS -> 0xf0780 (64 bytes)
* DSDT -> 0xf0800 (variable - can go up to 0x100000)
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/param.h>
#include <sys/errno.h>
#include <sys/stat.h>
#include <paths.h>
#include <stdarg.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <machine/vmm.h>
#include <vmmapi.h>
#include "bhyverun.h"
#include "acpi.h"
#include "pci_emul.h"
/*
* Define the base address of the ACPI tables, and the offsets to
* the individual tables
*/
#define BHYVE_ACPI_BASE 0xf0400
#define RSDT_OFFSET 0x040
#define XSDT_OFFSET 0x080
#define MADT_OFFSET 0x100
#define FADT_OFFSET 0x200
#define HPET_OFFSET 0x340
#define FACS_OFFSET 0x380
#define DSDT_OFFSET 0x400
#define BHYVE_ASL_TEMPLATE "bhyve.XXXXXXX"
#define BHYVE_ASL_SUFFIX ".aml"
#define BHYVE_ASL_COMPILER "/usr/sbin/iasl"
static int basl_keep_temps;
static int basl_verbose_iasl;
static int basl_ncpu;
static uint32_t basl_acpi_base = BHYVE_ACPI_BASE;
static uint32_t hpet_capabilities;
/*
* Contains the full pathname of the template to be passed
* to mkstemp/mktemps(3)
*/
static char basl_template[MAXPATHLEN];
static char basl_stemplate[MAXPATHLEN];
/*
* State for dsdt_line(), dsdt_indent(), and dsdt_unindent().
*/
static FILE *dsdt_fp;
static int dsdt_indent_level;
static int dsdt_error;
struct basl_fio {
int fd;
FILE *fp;
char f_name[MAXPATHLEN];
};
#define EFPRINTF(...) \
err = fprintf(__VA_ARGS__); if (err < 0) goto err_exit;
#define EFFLUSH(x) \
err = fflush(x); if (err != 0) goto err_exit;
static int
basl_fwrite_rsdp(FILE *fp)
{
int err;
err = 0;
EFPRINTF(fp, "/*\n");
EFPRINTF(fp, " * bhyve RSDP template\n");
EFPRINTF(fp, " */\n");
EFPRINTF(fp, "[0008]\t\tSignature : \"RSD PTR \"\n");
EFPRINTF(fp, "[0001]\t\tChecksum : 43\n");
EFPRINTF(fp, "[0006]\t\tOem ID : \"BHYVE \"\n");
EFPRINTF(fp, "[0001]\t\tRevision : 02\n");
EFPRINTF(fp, "[0004]\t\tRSDT Address : %08X\n",
basl_acpi_base + RSDT_OFFSET);
EFPRINTF(fp, "[0004]\t\tLength : 00000024\n");
EFPRINTF(fp, "[0008]\t\tXSDT Address : 00000000%08X\n",
basl_acpi_base + XSDT_OFFSET);
EFPRINTF(fp, "[0001]\t\tExtended Checksum : 00\n");
EFPRINTF(fp, "[0003]\t\tReserved : 000000\n");
EFFLUSH(fp);
return (0);
err_exit:
return (errno);
}
static int
basl_fwrite_rsdt(FILE *fp)
{
int err;
err = 0;
EFPRINTF(fp, "/*\n");
EFPRINTF(fp, " * bhyve RSDT template\n");
EFPRINTF(fp, " */\n");
EFPRINTF(fp, "[0004]\t\tSignature : \"RSDT\"\n");
EFPRINTF(fp, "[0004]\t\tTable Length : 00000000\n");
EFPRINTF(fp, "[0001]\t\tRevision : 01\n");
EFPRINTF(fp, "[0001]\t\tChecksum : 00\n");
EFPRINTF(fp, "[0006]\t\tOem ID : \"BHYVE \"\n");
EFPRINTF(fp, "[0008]\t\tOem Table ID : \"BVRSDT \"\n");
EFPRINTF(fp, "[0004]\t\tOem Revision : 00000001\n");
/* iasl will fill in the compiler ID/revision fields */
EFPRINTF(fp, "[0004]\t\tAsl Compiler ID : \"xxxx\"\n");
EFPRINTF(fp, "[0004]\t\tAsl Compiler Revision : 00000000\n");
EFPRINTF(fp, "\n");
/* Add in pointers to the MADT, FADT and HPET */
EFPRINTF(fp, "[0004]\t\tACPI Table Address 0 : %08X\n",
basl_acpi_base + MADT_OFFSET);
EFPRINTF(fp, "[0004]\t\tACPI Table Address 1 : %08X\n",
basl_acpi_base + FADT_OFFSET);
EFPRINTF(fp, "[0004]\t\tACPI Table Address 2 : %08X\n",
basl_acpi_base + HPET_OFFSET);
EFFLUSH(fp);
return (0);
err_exit:
return (errno);
}
static int
basl_fwrite_xsdt(FILE *fp)
{
int err;
err = 0;
EFPRINTF(fp, "/*\n");
EFPRINTF(fp, " * bhyve XSDT template\n");
EFPRINTF(fp, " */\n");
EFPRINTF(fp, "[0004]\t\tSignature : \"XSDT\"\n");
EFPRINTF(fp, "[0004]\t\tTable Length : 00000000\n");
EFPRINTF(fp, "[0001]\t\tRevision : 01\n");
EFPRINTF(fp, "[0001]\t\tChecksum : 00\n");
EFPRINTF(fp, "[0006]\t\tOem ID : \"BHYVE \"\n");
EFPRINTF(fp, "[0008]\t\tOem Table ID : \"BVXSDT \"\n");
EFPRINTF(fp, "[0004]\t\tOem Revision : 00000001\n");
/* iasl will fill in the compiler ID/revision fields */
EFPRINTF(fp, "[0004]\t\tAsl Compiler ID : \"xxxx\"\n");
EFPRINTF(fp, "[0004]\t\tAsl Compiler Revision : 00000000\n");
EFPRINTF(fp, "\n");
/* Add in pointers to the MADT, FADT and HPET */
EFPRINTF(fp, "[0004]\t\tACPI Table Address 0 : 00000000%08X\n",
basl_acpi_base + MADT_OFFSET);
EFPRINTF(fp, "[0004]\t\tACPI Table Address 1 : 00000000%08X\n",
basl_acpi_base + FADT_OFFSET);
EFPRINTF(fp, "[0004]\t\tACPI Table Address 2 : 00000000%08X\n",
basl_acpi_base + HPET_OFFSET);
EFFLUSH(fp);
return (0);
err_exit:
return (errno);
}
static int
basl_fwrite_madt(FILE *fp)
{
int err;
int i;
err = 0;
EFPRINTF(fp, "/*\n");
EFPRINTF(fp, " * bhyve MADT template\n");
EFPRINTF(fp, " */\n");
EFPRINTF(fp, "[0004]\t\tSignature : \"APIC\"\n");
EFPRINTF(fp, "[0004]\t\tTable Length : 00000000\n");
EFPRINTF(fp, "[0001]\t\tRevision : 01\n");
EFPRINTF(fp, "[0001]\t\tChecksum : 00\n");
EFPRINTF(fp, "[0006]\t\tOem ID : \"BHYVE \"\n");
EFPRINTF(fp, "[0008]\t\tOem Table ID : \"BVMADT \"\n");
EFPRINTF(fp, "[0004]\t\tOem Revision : 00000001\n");
/* iasl will fill in the compiler ID/revision fields */
EFPRINTF(fp, "[0004]\t\tAsl Compiler ID : \"xxxx\"\n");
EFPRINTF(fp, "[0004]\t\tAsl Compiler Revision : 00000000\n");
EFPRINTF(fp, "\n");
EFPRINTF(fp, "[0004]\t\tLocal Apic Address : FEE00000\n");
EFPRINTF(fp, "[0004]\t\tFlags (decoded below) : 00000001\n");
EFPRINTF(fp, "\t\t\tPC-AT Compatibility : 1\n");
EFPRINTF(fp, "\n");
/* Add a Processor Local APIC entry for each CPU */
for (i = 0; i < basl_ncpu; i++) {
EFPRINTF(fp, "[0001]\t\tSubtable Type : 00\n");
EFPRINTF(fp, "[0001]\t\tLength : 08\n");
/* iasl expects hex values for the proc and apic id's */
EFPRINTF(fp, "[0001]\t\tProcessor ID : %02x\n", i);
EFPRINTF(fp, "[0001]\t\tLocal Apic ID : %02x\n", i);
EFPRINTF(fp, "[0004]\t\tFlags (decoded below) : 00000001\n");
EFPRINTF(fp, "\t\t\tProcessor Enabled : 1\n");
EFPRINTF(fp, "\n");
}
/* Always a single IOAPIC entry, with ID 0 */
EFPRINTF(fp, "[0001]\t\tSubtable Type : 01\n");
EFPRINTF(fp, "[0001]\t\tLength : 0C\n");
/* iasl expects a hex value for the i/o apic id */
EFPRINTF(fp, "[0001]\t\tI/O Apic ID : %02x\n", 0);
EFPRINTF(fp, "[0001]\t\tReserved : 00\n");
EFPRINTF(fp, "[0004]\t\tAddress : fec00000\n");
EFPRINTF(fp, "[0004]\t\tInterrupt : 00000000\n");
EFPRINTF(fp, "\n");
/* Legacy IRQ0 is connected to pin 2 of the IOAPIC */
EFPRINTF(fp, "[0001]\t\tSubtable Type : 02\n");
EFPRINTF(fp, "[0001]\t\tLength : 0A\n");
EFPRINTF(fp, "[0001]\t\tBus : 00\n");
EFPRINTF(fp, "[0001]\t\tSource : 00\n");
EFPRINTF(fp, "[0004]\t\tInterrupt : 00000002\n");
EFPRINTF(fp, "[0002]\t\tFlags (decoded below) : 0005\n");
EFPRINTF(fp, "\t\t\tPolarity : 1\n");
EFPRINTF(fp, "\t\t\tTrigger Mode : 1\n");
EFPRINTF(fp, "\n");
EFPRINTF(fp, "[0001]\t\tSubtable Type : 02\n");
EFPRINTF(fp, "[0001]\t\tLength : 0A\n");
EFPRINTF(fp, "[0001]\t\tBus : 00\n");
EFPRINTF(fp, "[0001]\t\tSource : %02X\n", SCI_INT);
EFPRINTF(fp, "[0004]\t\tInterrupt : %08X\n", SCI_INT);
EFPRINTF(fp, "[0002]\t\tFlags (decoded below) : 0000\n");
EFPRINTF(fp, "\t\t\tPolarity : 3\n");
EFPRINTF(fp, "\t\t\tTrigger Mode : 3\n");
EFPRINTF(fp, "\n");
/* Local APIC NMI is connected to LINT 1 on all CPUs */
EFPRINTF(fp, "[0001]\t\tSubtable Type : 04\n");
EFPRINTF(fp, "[0001]\t\tLength : 06\n");
EFPRINTF(fp, "[0001]\t\tProcessorId : FF\n");
EFPRINTF(fp, "[0002]\t\tFlags (decoded below) : 0005\n");
EFPRINTF(fp, "\t\t\tPolarity : 1\n");
EFPRINTF(fp, "\t\t\tTrigger Mode : 1\n");
EFPRINTF(fp, "[0001]\t\tInterrupt : 01\n");
EFPRINTF(fp, "\n");
EFFLUSH(fp);
return (0);
err_exit:
return (errno);
}
static int
basl_fwrite_fadt(FILE *fp)
{
int err;
err = 0;
EFPRINTF(fp, "/*\n");
EFPRINTF(fp, " * bhyve FADT template\n");
EFPRINTF(fp, " */\n");
EFPRINTF(fp, "[0004]\t\tSignature : \"FACP\"\n");
EFPRINTF(fp, "[0004]\t\tTable Length : 0000010C\n");
EFPRINTF(fp, "[0001]\t\tRevision : 05\n");
EFPRINTF(fp, "[0001]\t\tChecksum : 00\n");
EFPRINTF(fp, "[0006]\t\tOem ID : \"BHYVE \"\n");
EFPRINTF(fp, "[0008]\t\tOem Table ID : \"BVFACP \"\n");
EFPRINTF(fp, "[0004]\t\tOem Revision : 00000001\n");
/* iasl will fill in the compiler ID/revision fields */
EFPRINTF(fp, "[0004]\t\tAsl Compiler ID : \"xxxx\"\n");
EFPRINTF(fp, "[0004]\t\tAsl Compiler Revision : 00000000\n");
EFPRINTF(fp, "\n");
EFPRINTF(fp, "[0004]\t\tFACS Address : %08X\n",
basl_acpi_base + FACS_OFFSET);
EFPRINTF(fp, "[0004]\t\tDSDT Address : %08X\n",
basl_acpi_base + DSDT_OFFSET);
EFPRINTF(fp, "[0001]\t\tModel : 01\n");
EFPRINTF(fp, "[0001]\t\tPM Profile : 00 [Unspecified]\n");
EFPRINTF(fp, "[0002]\t\tSCI Interrupt : %04X\n",
SCI_INT);
EFPRINTF(fp, "[0004]\t\tSMI Command Port : %08X\n",
SMI_CMD);
EFPRINTF(fp, "[0001]\t\tACPI Enable Value : %02X\n",
BHYVE_ACPI_ENABLE);
EFPRINTF(fp, "[0001]\t\tACPI Disable Value : %02X\n",
BHYVE_ACPI_DISABLE);
EFPRINTF(fp, "[0001]\t\tS4BIOS Command : 00\n");
EFPRINTF(fp, "[0001]\t\tP-State Control : 00\n");
EFPRINTF(fp, "[0004]\t\tPM1A Event Block Address : %08X\n",
PM1A_EVT_ADDR);
EFPRINTF(fp, "[0004]\t\tPM1B Event Block Address : 00000000\n");
EFPRINTF(fp, "[0004]\t\tPM1A Control Block Address : %08X\n",
PM1A_CNT_ADDR);
EFPRINTF(fp, "[0004]\t\tPM1B Control Block Address : 00000000\n");
EFPRINTF(fp, "[0004]\t\tPM2 Control Block Address : 00000000\n");
EFPRINTF(fp, "[0004]\t\tPM Timer Block Address : %08X\n",
IO_PMTMR);
EFPRINTF(fp, "[0004]\t\tGPE0 Block Address : 00000000\n");
EFPRINTF(fp, "[0004]\t\tGPE1 Block Address : 00000000\n");
EFPRINTF(fp, "[0001]\t\tPM1 Event Block Length : 04\n");
EFPRINTF(fp, "[0001]\t\tPM1 Control Block Length : 02\n");
EFPRINTF(fp, "[0001]\t\tPM2 Control Block Length : 00\n");
EFPRINTF(fp, "[0001]\t\tPM Timer Block Length : 04\n");
EFPRINTF(fp, "[0001]\t\tGPE0 Block Length : 00\n");
EFPRINTF(fp, "[0001]\t\tGPE1 Block Length : 00\n");
EFPRINTF(fp, "[0001]\t\tGPE1 Base Offset : 00\n");
EFPRINTF(fp, "[0001]\t\t_CST Support : 00\n");
EFPRINTF(fp, "[0002]\t\tC2 Latency : 0000\n");
EFPRINTF(fp, "[0002]\t\tC3 Latency : 0000\n");
EFPRINTF(fp, "[0002]\t\tCPU Cache Size : 0000\n");
EFPRINTF(fp, "[0002]\t\tCache Flush Stride : 0000\n");
EFPRINTF(fp, "[0001]\t\tDuty Cycle Offset : 00\n");
EFPRINTF(fp, "[0001]\t\tDuty Cycle Width : 00\n");
EFPRINTF(fp, "[0001]\t\tRTC Day Alarm Index : 00\n");
EFPRINTF(fp, "[0001]\t\tRTC Month Alarm Index : 00\n");
EFPRINTF(fp, "[0001]\t\tRTC Century Index : 00\n");
EFPRINTF(fp, "[0002]\t\tBoot Flags (decoded below) : 0000\n");
EFPRINTF(fp, "\t\t\tLegacy Devices Supported (V2) : 0\n");
EFPRINTF(fp, "\t\t\t8042 Present on ports 60/64 (V2) : 0\n");
EFPRINTF(fp, "\t\t\tVGA Not Present (V4) : 1\n");
EFPRINTF(fp, "\t\t\tMSI Not Supported (V4) : 0\n");
EFPRINTF(fp, "\t\t\tPCIe ASPM Not Supported (V4) : 1\n");
EFPRINTF(fp, "\t\t\tCMOS RTC Not Present (V5) : 0\n");
EFPRINTF(fp, "[0001]\t\tReserved : 00\n");
EFPRINTF(fp, "[0004]\t\tFlags (decoded below) : 00000000\n");
EFPRINTF(fp, "\t\t\tWBINVD instruction is operational (V1) : 1\n");
EFPRINTF(fp, "\t\t\tWBINVD flushes all caches (V1) : 0\n");
EFPRINTF(fp, "\t\t\tAll CPUs support C1 (V1) : 1\n");
EFPRINTF(fp, "\t\t\tC2 works on MP system (V1) : 0\n");
EFPRINTF(fp, "\t\t\tControl Method Power Button (V1) : 0\n");
EFPRINTF(fp, "\t\t\tControl Method Sleep Button (V1) : 1\n");
EFPRINTF(fp, "\t\t\tRTC wake not in fixed reg space (V1) : 0\n");
EFPRINTF(fp, "\t\t\tRTC can wake system from S4 (V1) : 0\n");
EFPRINTF(fp, "\t\t\t32-bit PM Timer (V1) : 1\n");
EFPRINTF(fp, "\t\t\tDocking Supported (V1) : 0\n");
EFPRINTF(fp, "\t\t\tReset Register Supported (V2) : 1\n");
EFPRINTF(fp, "\t\t\tSealed Case (V3) : 0\n");
EFPRINTF(fp, "\t\t\tHeadless - No Video (V3) : 1\n");
EFPRINTF(fp, "\t\t\tUse native instr after SLP_TYPx (V3) : 0\n");
EFPRINTF(fp, "\t\t\tPCIEXP_WAK Bits Supported (V4) : 0\n");
EFPRINTF(fp, "\t\t\tUse Platform Timer (V4) : 0\n");
EFPRINTF(fp, "\t\t\tRTC_STS valid on S4 wake (V4) : 0\n");
EFPRINTF(fp, "\t\t\tRemote Power-on capable (V4) : 0\n");
EFPRINTF(fp, "\t\t\tUse APIC Cluster Model (V4) : 0\n");
EFPRINTF(fp, "\t\t\tUse APIC Physical Destination Mode (V4) : 1\n");
EFPRINTF(fp, "\t\t\tHardware Reduced (V5) : 0\n");
EFPRINTF(fp, "\t\t\tLow Power S0 Idle (V5) : 0\n");
EFPRINTF(fp, "\n");
EFPRINTF(fp,
"[0012]\t\tReset Register : [Generic Address Structure]\n");
EFPRINTF(fp, "[0001]\t\tSpace ID : 01 [SystemIO]\n");
EFPRINTF(fp, "[0001]\t\tBit Width : 08\n");
EFPRINTF(fp, "[0001]\t\tBit Offset : 00\n");
EFPRINTF(fp, "[0001]\t\tEncoded Access Width : 01 [Byte Access:8]\n");
EFPRINTF(fp, "[0008]\t\tAddress : 0000000000000CF9\n");
EFPRINTF(fp, "\n");
EFPRINTF(fp, "[0001]\t\tValue to cause reset : 06\n");
EFPRINTF(fp, "[0003]\t\tReserved : 000000\n");
EFPRINTF(fp, "[0008]\t\tFACS Address : 00000000%08X\n",
basl_acpi_base + FACS_OFFSET);
EFPRINTF(fp, "[0008]\t\tDSDT Address : 00000000%08X\n",
basl_acpi_base + DSDT_OFFSET);
EFPRINTF(fp,
"[0012]\t\tPM1A Event Block : [Generic Address Structure]\n");
EFPRINTF(fp, "[0001]\t\tSpace ID : 01 [SystemIO]\n");
EFPRINTF(fp, "[0001]\t\tBit Width : 20\n");
EFPRINTF(fp, "[0001]\t\tBit Offset : 00\n");
EFPRINTF(fp, "[0001]\t\tEncoded Access Width : 02 [Word Access:16]\n");
EFPRINTF(fp, "[0008]\t\tAddress : 00000000%08X\n",
PM1A_EVT_ADDR);
EFPRINTF(fp, "\n");
EFPRINTF(fp,
"[0012]\t\tPM1B Event Block : [Generic Address Structure]\n");
EFPRINTF(fp, "[0001]\t\tSpace ID : 01 [SystemIO]\n");
EFPRINTF(fp, "[0001]\t\tBit Width : 00\n");
EFPRINTF(fp, "[0001]\t\tBit Offset : 00\n");
EFPRINTF(fp,
"[0001]\t\tEncoded Access Width : 00 [Undefined/Legacy]\n");
EFPRINTF(fp, "[0008]\t\tAddress : 0000000000000000\n");
EFPRINTF(fp, "\n");
EFPRINTF(fp,
"[0012]\t\tPM1A Control Block : [Generic Address Structure]\n");
EFPRINTF(fp, "[0001]\t\tSpace ID : 01 [SystemIO]\n");
EFPRINTF(fp, "[0001]\t\tBit Width : 10\n");
EFPRINTF(fp, "[0001]\t\tBit Offset : 00\n");
EFPRINTF(fp, "[0001]\t\tEncoded Access Width : 02 [Word Access:16]\n");
EFPRINTF(fp, "[0008]\t\tAddress : 00000000%08X\n",
PM1A_CNT_ADDR);
EFPRINTF(fp, "\n");
EFPRINTF(fp,
"[0012]\t\tPM1B Control Block : [Generic Address Structure]\n");
EFPRINTF(fp, "[0001]\t\tSpace ID : 01 [SystemIO]\n");
EFPRINTF(fp, "[0001]\t\tBit Width : 00\n");
EFPRINTF(fp, "[0001]\t\tBit Offset : 00\n");
EFPRINTF(fp,
"[0001]\t\tEncoded Access Width : 00 [Undefined/Legacy]\n");
EFPRINTF(fp, "[0008]\t\tAddress : 0000000000000000\n");
EFPRINTF(fp, "\n");
EFPRINTF(fp,
"[0012]\t\tPM2 Control Block : [Generic Address Structure]\n");
EFPRINTF(fp, "[0001]\t\tSpace ID : 01 [SystemIO]\n");
EFPRINTF(fp, "[0001]\t\tBit Width : 08\n");
EFPRINTF(fp, "[0001]\t\tBit Offset : 00\n");
EFPRINTF(fp,
"[0001]\t\tEncoded Access Width : 00 [Undefined/Legacy]\n");
EFPRINTF(fp, "[0008]\t\tAddress : 0000000000000000\n");
EFPRINTF(fp, "\n");
/* Valid for bhyve */
EFPRINTF(fp,
"[0012]\t\tPM Timer Block : [Generic Address Structure]\n");
EFPRINTF(fp, "[0001]\t\tSpace ID : 01 [SystemIO]\n");
EFPRINTF(fp, "[0001]\t\tBit Width : 32\n");
EFPRINTF(fp, "[0001]\t\tBit Offset : 00\n");
EFPRINTF(fp,
"[0001]\t\tEncoded Access Width : 03 [DWord Access:32]\n");
EFPRINTF(fp, "[0008]\t\tAddress : 00000000%08X\n",
IO_PMTMR);
EFPRINTF(fp, "\n");
EFPRINTF(fp, "[0012]\t\tGPE0 Block : [Generic Address Structure]\n");
EFPRINTF(fp, "[0001]\t\tSpace ID : 01 [SystemIO]\n");
EFPRINTF(fp, "[0001]\t\tBit Width : 80\n");
EFPRINTF(fp, "[0001]\t\tBit Offset : 00\n");
EFPRINTF(fp, "[0001]\t\tEncoded Access Width : 01 [Byte Access:8]\n");
EFPRINTF(fp, "[0008]\t\tAddress : 0000000000000000\n");
EFPRINTF(fp, "\n");
EFPRINTF(fp, "[0012]\t\tGPE1 Block : [Generic Address Structure]\n");
EFPRINTF(fp, "[0001]\t\tSpace ID : 01 [SystemIO]\n");
EFPRINTF(fp, "[0001]\t\tBit Width : 00\n");
EFPRINTF(fp, "[0001]\t\tBit Offset : 00\n");
EFPRINTF(fp,
"[0001]\t\tEncoded Access Width : 00 [Undefined/Legacy]\n");
EFPRINTF(fp, "[0008]\t\tAddress : 0000000000000000\n");
EFPRINTF(fp, "\n");
EFPRINTF(fp,
"[0012]\t\tSleep Control Register : [Generic Address Structure]\n");
EFPRINTF(fp, "[0001]\t\tSpace ID : 01 [SystemIO]\n");
EFPRINTF(fp, "[0001]\t\tBit Width : 08\n");
EFPRINTF(fp, "[0001]\t\tBit Offset : 00\n");
EFPRINTF(fp, "[0001]\t\tEncoded Access Width : 01 [Byte Access:8]\n");
EFPRINTF(fp, "[0008]\t\tAddress : 0000000000000000\n");
EFPRINTF(fp, "\n");
EFPRINTF(fp,
"[0012]\t\tSleep Status Register : [Generic Address Structure]\n");
EFPRINTF(fp, "[0001]\t\tSpace ID : 01 [SystemIO]\n");
EFPRINTF(fp, "[0001]\t\tBit Width : 08\n");
EFPRINTF(fp, "[0001]\t\tBit Offset : 00\n");
EFPRINTF(fp, "[0001]\t\tEncoded Access Width : 01 [Byte Access:8]\n");
EFPRINTF(fp, "[0008]\t\tAddress : 0000000000000000\n");
EFFLUSH(fp);
return (0);
err_exit:
return (errno);
}
static int
basl_fwrite_hpet(FILE *fp)
{
int err;
err = 0;
EFPRINTF(fp, "/*\n");
EFPRINTF(fp, " * bhyve HPET template\n");
EFPRINTF(fp, " */\n");
EFPRINTF(fp, "[0004]\t\tSignature : \"HPET\"\n");
EFPRINTF(fp, "[0004]\t\tTable Length : 00000000\n");
EFPRINTF(fp, "[0001]\t\tRevision : 01\n");
EFPRINTF(fp, "[0001]\t\tChecksum : 00\n");
EFPRINTF(fp, "[0006]\t\tOem ID : \"BHYVE \"\n");
EFPRINTF(fp, "[0008]\t\tOem Table ID : \"BVHPET \"\n");
EFPRINTF(fp, "[0004]\t\tOem Revision : 00000001\n");
/* iasl will fill in the compiler ID/revision fields */
EFPRINTF(fp, "[0004]\t\tAsl Compiler ID : \"xxxx\"\n");
EFPRINTF(fp, "[0004]\t\tAsl Compiler Revision : 00000000\n");
EFPRINTF(fp, "\n");
EFPRINTF(fp, "[0004]\t\tTimer Block ID : %08X\n", hpet_capabilities);
EFPRINTF(fp,
"[0012]\t\tTimer Block Register : [Generic Address Structure]\n");
EFPRINTF(fp, "[0001]\t\tSpace ID : 00 [SystemMemory]\n");
EFPRINTF(fp, "[0001]\t\tBit Width : 00\n");
EFPRINTF(fp, "[0001]\t\tBit Offset : 00\n");
EFPRINTF(fp,
"[0001]\t\tEncoded Access Width : 00 [Undefined/Legacy]\n");
EFPRINTF(fp, "[0008]\t\tAddress : 00000000FED00000\n");
EFPRINTF(fp, "\n");
EFPRINTF(fp, "[0001]\t\tHPET Number : 00\n");
EFPRINTF(fp, "[0002]\t\tMinimum Clock Ticks : 0000\n");
EFPRINTF(fp, "[0004]\t\tFlags (decoded below) : 00000001\n");
EFPRINTF(fp, "\t\t\t4K Page Protect : 1\n");
EFPRINTF(fp, "\t\t\t64K Page Protect : 0\n");
EFPRINTF(fp, "\n");
EFFLUSH(fp);
return (0);
err_exit:
return (errno);
}
static int
basl_fwrite_facs(FILE *fp)
{
int err;
err = 0;
EFPRINTF(fp, "/*\n");
EFPRINTF(fp, " * bhyve FACS template\n");
EFPRINTF(fp, " */\n");
EFPRINTF(fp, "[0004]\t\tSignature : \"FACS\"\n");
EFPRINTF(fp, "[0004]\t\tLength : 00000040\n");
EFPRINTF(fp, "[0004]\t\tHardware Signature : 00000000\n");
EFPRINTF(fp, "[0004]\t\t32 Firmware Waking Vector : 00000000\n");
EFPRINTF(fp, "[0004]\t\tGlobal Lock : 00000000\n");
EFPRINTF(fp, "[0004]\t\tFlags (decoded below) : 00000000\n");
EFPRINTF(fp, "\t\t\tS4BIOS Support Present : 0\n");
EFPRINTF(fp, "\t\t\t64-bit Wake Supported (V2) : 0\n");
EFPRINTF(fp,
"[0008]\t\t64 Firmware Waking Vector : 0000000000000000\n");
EFPRINTF(fp, "[0001]\t\tVersion : 02\n");
EFPRINTF(fp, "[0003]\t\tReserved : 000000\n");
EFPRINTF(fp, "[0004]\t\tOspmFlags (decoded below) : 00000000\n");
EFPRINTF(fp, "\t\t\t64-bit Wake Env Required (V2) : 0\n");
EFFLUSH(fp);
return (0);
err_exit:
return (errno);
}
/*
* Helper routines for writing to the DSDT from other modules.
*/
void
dsdt_line(const char *fmt, ...)
{
va_list ap;
int err;
if (dsdt_error != 0)
return;
if (strcmp(fmt, "") != 0) {
if (dsdt_indent_level != 0)
EFPRINTF(dsdt_fp, "%*c", dsdt_indent_level * 2, ' ');
va_start(ap, fmt);
if (vfprintf(dsdt_fp, fmt, ap) < 0)
goto err_exit;
va_end(ap);
}
EFPRINTF(dsdt_fp, "\n");
return;
err_exit:
dsdt_error = errno;
}
void
dsdt_indent(int levels)
{
dsdt_indent_level += levels;
assert(dsdt_indent_level >= 0);
}
void
dsdt_unindent(int levels)
{
assert(dsdt_indent_level >= levels);
dsdt_indent_level -= levels;
}
void
dsdt_fixed_ioport(uint16_t iobase, uint16_t length)
{
dsdt_line("IO (Decode16,");
dsdt_line(" 0x%04X, // Range Minimum", iobase);
dsdt_line(" 0x%04X, // Range Maximum", iobase);
dsdt_line(" 0x01, // Alignment");
dsdt_line(" 0x%02X, // Length", length);
dsdt_line(" )");
}
void
dsdt_fixed_irq(uint8_t irq)
{
dsdt_line("IRQNoFlags ()");
dsdt_line(" {%d}", irq);
}
void
dsdt_fixed_mem32(uint32_t base, uint32_t length)
{
dsdt_line("Memory32Fixed (ReadWrite,");
dsdt_line(" 0x%08X, // Address Base", base);
dsdt_line(" 0x%08X, // Address Length", length);
dsdt_line(" )");
}
static int
basl_fwrite_dsdt(FILE *fp)
{
int err;
err = 0;
dsdt_fp = fp;
dsdt_error = 0;
dsdt_indent_level = 0;
dsdt_line("/*");
dsdt_line(" * bhyve DSDT template");
dsdt_line(" */");
dsdt_line("DefinitionBlock (\"bhyve_dsdt.aml\", \"DSDT\", 2,"
"\"BHYVE \", \"BVDSDT \", 0x00000001)");
dsdt_line("{");
dsdt_line(" Name (_S5, Package (0x02)");
dsdt_line(" {");
dsdt_line(" 0x05,");
dsdt_line(" Zero,");
dsdt_line(" })");
pci_write_dsdt();
dsdt_line("");
dsdt_line(" Scope (_SB.PC00)");
dsdt_line(" {");
dsdt_line(" Device (HPET)");
dsdt_line(" {");
dsdt_line(" Name (_HID, EISAID(\"PNP0103\"))");
dsdt_line(" Name (_UID, 0)");
dsdt_line(" Name (_CRS, ResourceTemplate ()");
dsdt_line(" {");
dsdt_indent(4);
dsdt_fixed_mem32(0xFED00000, 0x400);
dsdt_unindent(4);
dsdt_line(" })");
dsdt_line(" }");
dsdt_line(" }");
dsdt_line("}");
if (dsdt_error != 0)
return (dsdt_error);
EFFLUSH(fp);
return (0);
err_exit:
return (errno);
}
static int
basl_open(struct basl_fio *bf, int suffix)
{
int err;
err = 0;
if (suffix) {
strncpy(bf->f_name, basl_stemplate, MAXPATHLEN);
bf->fd = mkstemps(bf->f_name, strlen(BHYVE_ASL_SUFFIX));
} else {
strncpy(bf->f_name, basl_template, MAXPATHLEN);
bf->fd = mkstemp(bf->f_name);
}
if (bf->fd > 0) {
bf->fp = fdopen(bf->fd, "w+");
if (bf->fp == NULL) {
unlink(bf->f_name);
close(bf->fd);
}
} else {
err = 1;
}
return (err);
}
static void
basl_close(struct basl_fio *bf)
{
if (!basl_keep_temps)
unlink(bf->f_name);
fclose(bf->fp);
}
static int
basl_start(struct basl_fio *in, struct basl_fio *out)
{
int err;
err = basl_open(in, 0);
if (!err) {
err = basl_open(out, 1);
if (err) {
basl_close(in);
}
}
return (err);
}
static void
basl_end(struct basl_fio *in, struct basl_fio *out)
{
basl_close(in);
basl_close(out);
}
static int
basl_load(struct vmctx *ctx, int fd, uint64_t off)
{
struct stat sb;
void *gaddr;
if (fstat(fd, &sb) < 0)
return (errno);
gaddr = paddr_guest2host(ctx, basl_acpi_base + off, sb.st_size);
if (gaddr == NULL)
return (EFAULT);
if (read(fd, gaddr, sb.st_size) < 0)
return (errno);
return (0);
}
static int
basl_compile(struct vmctx *ctx, int (*fwrite_section)(FILE *), uint64_t offset)
{
struct basl_fio io[2];
static char iaslbuf[3*MAXPATHLEN + 10];
char *fmt;
int err;
err = basl_start(&io[0], &io[1]);
if (!err) {
err = (*fwrite_section)(io[0].fp);
if (!err) {
/*
* iasl sends the results of the compilation to
* stdout. Shut this down by using the shell to
* redirect stdout to /dev/null, unless the user
* has requested verbose output for debugging
* purposes
*/
fmt = basl_verbose_iasl ?
"%s -p %s %s" :
"/bin/sh -c \"%s -p %s %s\" 1> /dev/null";
snprintf(iaslbuf, sizeof(iaslbuf),
fmt,
BHYVE_ASL_COMPILER,
io[1].f_name, io[0].f_name);
err = system(iaslbuf);
if (!err) {
/*
* Copy the aml output file into guest
* memory at the specified location
*/
err = basl_load(ctx, io[1].fd, offset);
}
}
basl_end(&io[0], &io[1]);
}
return (err);
}
static int
basl_make_templates(void)
{
const char *tmpdir;
int err;
int len;
err = 0;
/*
*
*/
if ((tmpdir = getenv("BHYVE_TMPDIR")) == NULL || *tmpdir == '\0' ||
(tmpdir = getenv("TMPDIR")) == NULL || *tmpdir == '\0') {
tmpdir = _PATH_TMP;
}
len = strlen(tmpdir);
if ((len + sizeof(BHYVE_ASL_TEMPLATE) + 1) < MAXPATHLEN) {
strcpy(basl_template, tmpdir);
while (len > 0 && basl_template[len - 1] == '/')
len--;
basl_template[len] = '/';
strcpy(&basl_template[len + 1], BHYVE_ASL_TEMPLATE);
} else
err = E2BIG;
if (!err) {
/*
* len has been intialized (and maybe adjusted) above
*/
if ((len + sizeof(BHYVE_ASL_TEMPLATE) + 1 +
sizeof(BHYVE_ASL_SUFFIX)) < MAXPATHLEN) {
strcpy(basl_stemplate, tmpdir);
basl_stemplate[len] = '/';
strcpy(&basl_stemplate[len + 1], BHYVE_ASL_TEMPLATE);
len = strlen(basl_stemplate);
strcpy(&basl_stemplate[len], BHYVE_ASL_SUFFIX);
} else
err = E2BIG;
}
return (err);
}
static struct {
int (*wsect)(FILE *fp);
uint64_t offset;
} basl_ftables[] =
{
{ basl_fwrite_rsdp, 0},
{ basl_fwrite_rsdt, RSDT_OFFSET },
{ basl_fwrite_xsdt, XSDT_OFFSET },
{ basl_fwrite_madt, MADT_OFFSET },
{ basl_fwrite_fadt, FADT_OFFSET },
{ basl_fwrite_hpet, HPET_OFFSET },
{ basl_fwrite_facs, FACS_OFFSET },
{ basl_fwrite_dsdt, DSDT_OFFSET },
{ NULL }
};
int
acpi_build(struct vmctx *ctx, int ncpu)
{
int err;
int i;
basl_ncpu = ncpu;
err = vm_get_hpet_capabilities(ctx, &hpet_capabilities);
if (err != 0)
return (err);
/*
* For debug, allow the user to have iasl compiler output sent
* to stdout rather than /dev/null
*/
if (getenv("BHYVE_ACPI_VERBOSE_IASL"))
basl_verbose_iasl = 1;
/*
* Allow the user to keep the generated ASL files for debugging
* instead of deleting them following use
*/
if (getenv("BHYVE_ACPI_KEEPTMPS"))
basl_keep_temps = 1;
i = 0;
err = basl_make_templates();
/*
* Run through all the ASL files, compiling them and
* copying them into guest memory
*/
while (!err && basl_ftables[i].wsect != NULL) {
err = basl_compile(ctx, basl_ftables[i].wsect,
basl_ftables[i].offset);
i++;
}
return (err);
}