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freebsd-dev/usr.sbin/bhyve/rtc.c

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Import of bhyve hypervisor and utilities, part 1. vmm.ko - kernel module for VT-x, VT-d and hypervisor control bhyve - user-space sequencer and i/o emulation vmmctl - dump of hypervisor register state libvmm - front-end to vmm.ko chardev interface bhyve was designed and implemented by Neel Natu. Thanks to the following folk from NetApp who helped to make this available: Joe CaraDonna Peter Snyder Jeff Heller Sandeep Mann Steve Miller Brian Pawlowski
2011-05-13 04:54:01 +00:00
/*-
various: general adoption of SPDX licensing ID tags. Mainly focus on files that use BSD 2-Clause license, however the tool I was using misidentified many licenses so this was mostly a manual - error prone - task. The Software Package Data Exchange (SPDX) group provides a specification to make it easier for automated tools to detect and summarize well known opensource licenses. We are gradually adopting the specification, noting that the tags are considered only advisory and do not, in any way, superceed or replace the license texts. No functional change intended.
2017-11-27 15:37:16 +00:00
* SPDX-License-Identifier: BSD-2-Clause-FreeBSD
*
Import of bhyve hypervisor and utilities, part 1. vmm.ko - kernel module for VT-x, VT-d and hypervisor control bhyve - user-space sequencer and i/o emulation vmmctl - dump of hypervisor register state libvmm - front-end to vmm.ko chardev interface bhyve was designed and implemented by Neel Natu. Thanks to the following folk from NetApp who helped to make this available: Joe CaraDonna Peter Snyder Jeff Heller Sandeep Mann Steve Miller Brian Pawlowski
2011-05-13 04:54:01 +00:00
* Copyright (c) 2011 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.
*
* $FreeBSD$
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/types.h>
#include <time.h>
#include <assert.h>
Implement RTC CMOS nvram. Init some fields that are used by FreeBSD and UEFI. Tested with nvram(4). Reviewed by: neel
2013-07-11 03:54:35 +00:00
#include <machine/vmm.h>
#include <vmmapi.h>
Rework the DSDT generation code a bit to generate more accurate info about LPC devices. Among other things, the LPC serial ports now appear as ACPI devices. - Move the info for the top-level PCI bus into the PCI emulation code and add ResourceProducer entries for the memory ranges decoded by the bus for memory BARs. - Add a framework to allow each PCI emulation driver to optionally write an entry into the DSDT under the \_SB_.PCI0 namespace. The LPC driver uses this to write a node for the LPC bus (\_SB_.PCI0.ISA). - Add a linker set to allow any LPC devices to write entries into the DSDT below the LPC node. - Move the existing DSDT block for the RTC to the RTC driver. - Add DSDT nodes for the AT PIC, the 8254 ISA timer, and the LPC UART devices. - Add a "SuperIO" device under the LPC node to claim "system resources" aling with a linker set to allow various drivers to add IO or memory ranges that should be claimed as a system resource. - Add system resource entries for the extended RTC IO range, the registers used for ACPI power management, the ELCR, PCI interrupt routing register, and post data register. - Add various helper routines for generating DSDT entries. Reviewed by: neel (earlier version)
2014-01-02 21:26:59 +00:00
#include "acpi.h"
Refactor configuration management in bhyve. Replace the existing ad-hoc configuration via various global variables with a small database of key-value pairs. The database supports heirarchical keys using a MIB-like syntax to name the path to a given key. Values are always stored as strings. The API used to manage configuation values does include wrappers to handling boolean values. Other values use non-string types require parsing by consumers. The configuration values are stored in a tree using nvlists. Leaf nodes hold string values. Configuration values are permitted to reference other configuration values using '%(name)'. This permits constructing template configurations. All existing command line arguments now set configuration values. For devices, the "-s" option parses its option argument to generate a list of key-value pairs for the given device. A new '-o' command line option permits setting an individual configuration variable. The key name is always given as a full path of dot-separated components. A new '-k' command line option parses a simple configuration file. This configuration file holds a flat list of 'key=value' lines where the 'key' is the full path of a configuration variable. Lines starting with a '#' are comments. In general, bhyve starts by parsing command line options in sequence and applying those settings to configuration values. Once this is complete, bhyve then begins initializing its state based on the configuration values. This means that subsequent configuration options or files may override or supplement previously given settings. A special 'config.dump' configuration value can be set to true to help debug configuration issues. When this value is set, bhyve will print out the configuration variables as a flat list of 'key=value' lines. Most command line argments map to a single configuration variable, e.g. '-w' sets the 'x86.strictmsr' value to false. A few command line arguments have less obvious effects: - Multiple '-p' options append their values (as a comma-seperated list) to "vcpu.N.cpuset" values (where N is a decimal vcpu number). - For '-s' options, a pci.<bus>.<slot>.<function> node is created. The first argument to '-s' (the device type) is used as the value of a "device" variable. Additional comma-separated arguments are then parsed into 'key=value' pairs and used to set additional variables under the device node. A PCI device emulation driver can provide its own hook to override the parsing of the additonal '-s' arguments after the device type. After the configuration phase as completed, the init_pci hook then walks the "pci.<bus>.<slot>.<func>" nodes. It uses the "device" value to find the device model to use. The device model's init routine is passed a reference to its nvlist node in the configuration tree which it can query for specific variables. The result is that a lot of the string parsing is removed from the device models and centralized. In addition, adding a new variable just requires teaching the model to look for the new variable. - For '-l' options, a similar model is used where the string is parsed into values that are later read during initialization. One key note here is that the serial ports use the commonly used lowercase names from existing documentation and examples (e.g. "lpc.com1") instead of the uppercase names previously used internally in bhyve. Reviewed by: grehan MFC after: 3 months Differential Revision: https://reviews.freebsd.org/D26035
2019-06-26 20:30:41 +00:00
#include "config.h"
Rework the DSDT generation code a bit to generate more accurate info about LPC devices. Among other things, the LPC serial ports now appear as ACPI devices. - Move the info for the top-level PCI bus into the PCI emulation code and add ResourceProducer entries for the memory ranges decoded by the bus for memory BARs. - Add a framework to allow each PCI emulation driver to optionally write an entry into the DSDT under the \_SB_.PCI0 namespace. The LPC driver uses this to write a node for the LPC bus (\_SB_.PCI0.ISA). - Add a linker set to allow any LPC devices to write entries into the DSDT below the LPC node. - Move the existing DSDT block for the RTC to the RTC driver. - Add DSDT nodes for the AT PIC, the 8254 ISA timer, and the LPC UART devices. - Add a "SuperIO" device under the LPC node to claim "system resources" aling with a linker set to allow various drivers to add IO or memory ranges that should be claimed as a system resource. - Add system resource entries for the extended RTC IO range, the registers used for ACPI power management, the ELCR, PCI interrupt routing register, and post data register. - Add various helper routines for generating DSDT entries. Reviewed by: neel (earlier version)
2014-01-02 21:26:59 +00:00
#include "pci_lpc.h"
Implement RTC CMOS nvram. Init some fields that are used by FreeBSD and UEFI. Tested with nvram(4). Reviewed by: neel
2013-07-11 03:54:35 +00:00
#include "rtc.h"
Import of bhyve hypervisor and utilities, part 1. vmm.ko - kernel module for VT-x, VT-d and hypervisor control bhyve - user-space sequencer and i/o emulation vmmctl - dump of hypervisor register state libvmm - front-end to vmm.ko chardev interface bhyve was designed and implemented by Neel Natu. Thanks to the following folk from NetApp who helped to make this available: Joe CaraDonna Peter Snyder Jeff Heller Sandeep Mann Steve Miller Brian Pawlowski
2011-05-13 04:54:01 +00:00
Replace bhyve's minimal RTC emulation with a fully featured one in vmm.ko. The new RTC emulation supports all interrupt modes: periodic, update ended and alarm. It is also capable of maintaining the date/time and NVRAM contents across virtual machine reset. Also, the date/time fields can now be modified by the guest. Since bhyve now emulates both the PIT and the RTC there is no need for "Legacy Replacement Routing" in the HPET so get rid of it. The RTC device state can be inspected via bhyvectl as follows: bhyvectl --vm=vm --get-rtc-time bhyvectl --vm=vm --set-rtc-time=<unix_time_secs> bhyvectl --vm=vm --rtc-nvram-offset=<offset> --get-rtc-nvram bhyvectl --vm=vm --rtc-nvram-offset=<offset> --set-rtc-nvram=<value> Reviewed by: tychon Discussed with: grehan Differential Revision: https://reviews.freebsd.org/D1385 MFC after: 2 weeks
2014-12-30 22:19:34 +00:00
#define IO_RTC 0x70
Import of bhyve hypervisor and utilities, part 1. vmm.ko - kernel module for VT-x, VT-d and hypervisor control bhyve - user-space sequencer and i/o emulation vmmctl - dump of hypervisor register state libvmm - front-end to vmm.ko chardev interface bhyve was designed and implemented by Neel Natu. Thanks to the following folk from NetApp who helped to make this available: Joe CaraDonna Peter Snyder Jeff Heller Sandeep Mann Steve Miller Brian Pawlowski
2011-05-13 04:54:01 +00:00
Implement RTC CMOS nvram. Init some fields that are used by FreeBSD and UEFI. Tested with nvram(4). Reviewed by: neel
2013-07-11 03:54:35 +00:00
#define RTC_LMEM_LSB 0x34
#define RTC_LMEM_MSB 0x35
#define RTC_HMEM_LSB 0x5b
#define RTC_HMEM_SB 0x5c
#define RTC_HMEM_MSB 0x5d
Fix style(9) space vs tab. Reviewed by: jhb MFC after: 3 weeks. Sponsored by: iXsystems Inc. Differential Revision: https://reviews.freebsd.org/D15768
2018-06-14 01:34:53 +00:00
#define m_64KB (64*1024)
Implement RTC CMOS nvram. Init some fields that are used by FreeBSD and UEFI. Tested with nvram(4). Reviewed by: neel
2013-07-11 03:54:35 +00:00
#define m_16MB (16*1024*1024)
#define m_4GB (4ULL*1024*1024*1024)
Changes to allow the GENERIC+bhye kernel built from this branch to run as a 1/2 CPU guest on an 8.1 bhyve host. bhyve/inout.c inout.h fbsdrun.c - Rather than exiting on accesses to unhandled i/o ports, emulate hardware by returning -1 on reads and ignoring writes to unhandled ports. Support the previous mode by allowing a 'strict' parameter to be set from the command line. The 8.1 guest kernel was vastly cut down from GENERIC and had no ISA devices. Booting GENERIC exposes a massive amount of random touching of i/o ports (hello syscons/vga/atkbdc). bhyve/consport.c dev/bvm/bvm_console.c - implement a simplistic signature for the bvm console by returning 'bv' for an inw on the port. Also, set the priority of the console to CN_REMOTE if the signature was returned. This works better in an environment where multiple consoles are in the kernel (hello syscons) bhyve/rtc.c - return 0 for the access to RTC_EQUIPMENT (yes, you syscons) amd64/vmm/x86.c x86.h - hide a bunch more CPUID leaf 1 bits from the guest to prevent cpufreq drivers from probing. The next step will be to move CPUID handling completely into user-space. This will allow the full spectrum of changes from presenting a lowest-common-denominator CPU type/feature set, to exposing (almost) everything that the host can support. Reviewed by: neel Obtained from: NetApp
2011-05-19 21:53:25 +00:00
Replace bhyve's minimal RTC emulation with a fully featured one in vmm.ko. The new RTC emulation supports all interrupt modes: periodic, update ended and alarm. It is also capable of maintaining the date/time and NVRAM contents across virtual machine reset. Also, the date/time fields can now be modified by the guest. Since bhyve now emulates both the PIT and the RTC there is no need for "Legacy Replacement Routing" in the HPET so get rid of it. The RTC device state can be inspected via bhyvectl as follows: bhyvectl --vm=vm --get-rtc-time bhyvectl --vm=vm --set-rtc-time=<unix_time_secs> bhyvectl --vm=vm --rtc-nvram-offset=<offset> --get-rtc-nvram bhyvectl --vm=vm --rtc-nvram-offset=<offset> --set-rtc-nvram=<value> Reviewed by: tychon Discussed with: grehan Differential Revision: https://reviews.freebsd.org/D1385 MFC after: 2 weeks
2014-12-30 22:19:34 +00:00
/*
* Returns the current RTC time as number of seconds since 00:00:00 Jan 1, 1970
*/
static time_t
Refactor configuration management in bhyve. Replace the existing ad-hoc configuration via various global variables with a small database of key-value pairs. The database supports heirarchical keys using a MIB-like syntax to name the path to a given key. Values are always stored as strings. The API used to manage configuation values does include wrappers to handling boolean values. Other values use non-string types require parsing by consumers. The configuration values are stored in a tree using nvlists. Leaf nodes hold string values. Configuration values are permitted to reference other configuration values using '%(name)'. This permits constructing template configurations. All existing command line arguments now set configuration values. For devices, the "-s" option parses its option argument to generate a list of key-value pairs for the given device. A new '-o' command line option permits setting an individual configuration variable. The key name is always given as a full path of dot-separated components. A new '-k' command line option parses a simple configuration file. This configuration file holds a flat list of 'key=value' lines where the 'key' is the full path of a configuration variable. Lines starting with a '#' are comments. In general, bhyve starts by parsing command line options in sequence and applying those settings to configuration values. Once this is complete, bhyve then begins initializing its state based on the configuration values. This means that subsequent configuration options or files may override or supplement previously given settings. A special 'config.dump' configuration value can be set to true to help debug configuration issues. When this value is set, bhyve will print out the configuration variables as a flat list of 'key=value' lines. Most command line argments map to a single configuration variable, e.g. '-w' sets the 'x86.strictmsr' value to false. A few command line arguments have less obvious effects: - Multiple '-p' options append their values (as a comma-seperated list) to "vcpu.N.cpuset" values (where N is a decimal vcpu number). - For '-s' options, a pci.<bus>.<slot>.<function> node is created. The first argument to '-s' (the device type) is used as the value of a "device" variable. Additional comma-separated arguments are then parsed into 'key=value' pairs and used to set additional variables under the device node. A PCI device emulation driver can provide its own hook to override the parsing of the additonal '-s' arguments after the device type. After the configuration phase as completed, the init_pci hook then walks the "pci.<bus>.<slot>.<func>" nodes. It uses the "device" value to find the device model to use. The device model's init routine is passed a reference to its nvlist node in the configuration tree which it can query for specific variables. The result is that a lot of the string parsing is removed from the device models and centralized. In addition, adding a new variable just requires teaching the model to look for the new variable. - For '-l' options, a similar model is used where the string is parsed into values that are later read during initialization. One key note here is that the serial ports use the commonly used lowercase names from existing documentation and examples (e.g. "lpc.com1") instead of the uppercase names previously used internally in bhyve. Reviewed by: grehan MFC after: 3 months Differential Revision: https://reviews.freebsd.org/D26035
2019-06-26 20:30:41 +00:00
rtc_time(struct vmctx *ctx)
Import of bhyve hypervisor and utilities, part 1. vmm.ko - kernel module for VT-x, VT-d and hypervisor control bhyve - user-space sequencer and i/o emulation vmmctl - dump of hypervisor register state libvmm - front-end to vmm.ko chardev interface bhyve was designed and implemented by Neel Natu. Thanks to the following folk from NetApp who helped to make this available: Joe CaraDonna Peter Snyder Jeff Heller Sandeep Mann Steve Miller Brian Pawlowski
2011-05-13 04:54:01 +00:00
{
Replace bhyve's minimal RTC emulation with a fully featured one in vmm.ko. The new RTC emulation supports all interrupt modes: periodic, update ended and alarm. It is also capable of maintaining the date/time and NVRAM contents across virtual machine reset. Also, the date/time fields can now be modified by the guest. Since bhyve now emulates both the PIT and the RTC there is no need for "Legacy Replacement Routing" in the HPET so get rid of it. The RTC device state can be inspected via bhyvectl as follows: bhyvectl --vm=vm --get-rtc-time bhyvectl --vm=vm --set-rtc-time=<unix_time_secs> bhyvectl --vm=vm --rtc-nvram-offset=<offset> --get-rtc-nvram bhyvectl --vm=vm --rtc-nvram-offset=<offset> --set-rtc-nvram=<value> Reviewed by: tychon Discussed with: grehan Differential Revision: https://reviews.freebsd.org/D1385 MFC after: 2 weeks
2014-12-30 22:19:34 +00:00
struct tm tm;
Import of bhyve hypervisor and utilities, part 1. vmm.ko - kernel module for VT-x, VT-d and hypervisor control bhyve - user-space sequencer and i/o emulation vmmctl - dump of hypervisor register state libvmm - front-end to vmm.ko chardev interface bhyve was designed and implemented by Neel Natu. Thanks to the following folk from NetApp who helped to make this available: Joe CaraDonna Peter Snyder Jeff Heller Sandeep Mann Steve Miller Brian Pawlowski
2011-05-13 04:54:01 +00:00
time_t t;
Replace bhyve's minimal RTC emulation with a fully featured one in vmm.ko. The new RTC emulation supports all interrupt modes: periodic, update ended and alarm. It is also capable of maintaining the date/time and NVRAM contents across virtual machine reset. Also, the date/time fields can now be modified by the guest. Since bhyve now emulates both the PIT and the RTC there is no need for "Legacy Replacement Routing" in the HPET so get rid of it. The RTC device state can be inspected via bhyvectl as follows: bhyvectl --vm=vm --get-rtc-time bhyvectl --vm=vm --set-rtc-time=<unix_time_secs> bhyvectl --vm=vm --rtc-nvram-offset=<offset> --get-rtc-nvram bhyvectl --vm=vm --rtc-nvram-offset=<offset> --set-rtc-nvram=<value> Reviewed by: tychon Discussed with: grehan Differential Revision: https://reviews.freebsd.org/D1385 MFC after: 2 weeks
2014-12-30 22:19:34 +00:00
time(&t);
Refactor configuration management in bhyve. Replace the existing ad-hoc configuration via various global variables with a small database of key-value pairs. The database supports heirarchical keys using a MIB-like syntax to name the path to a given key. Values are always stored as strings. The API used to manage configuation values does include wrappers to handling boolean values. Other values use non-string types require parsing by consumers. The configuration values are stored in a tree using nvlists. Leaf nodes hold string values. Configuration values are permitted to reference other configuration values using '%(name)'. This permits constructing template configurations. All existing command line arguments now set configuration values. For devices, the "-s" option parses its option argument to generate a list of key-value pairs for the given device. A new '-o' command line option permits setting an individual configuration variable. The key name is always given as a full path of dot-separated components. A new '-k' command line option parses a simple configuration file. This configuration file holds a flat list of 'key=value' lines where the 'key' is the full path of a configuration variable. Lines starting with a '#' are comments. In general, bhyve starts by parsing command line options in sequence and applying those settings to configuration values. Once this is complete, bhyve then begins initializing its state based on the configuration values. This means that subsequent configuration options or files may override or supplement previously given settings. A special 'config.dump' configuration value can be set to true to help debug configuration issues. When this value is set, bhyve will print out the configuration variables as a flat list of 'key=value' lines. Most command line argments map to a single configuration variable, e.g. '-w' sets the 'x86.strictmsr' value to false. A few command line arguments have less obvious effects: - Multiple '-p' options append their values (as a comma-seperated list) to "vcpu.N.cpuset" values (where N is a decimal vcpu number). - For '-s' options, a pci.<bus>.<slot>.<function> node is created. The first argument to '-s' (the device type) is used as the value of a "device" variable. Additional comma-separated arguments are then parsed into 'key=value' pairs and used to set additional variables under the device node. A PCI device emulation driver can provide its own hook to override the parsing of the additonal '-s' arguments after the device type. After the configuration phase as completed, the init_pci hook then walks the "pci.<bus>.<slot>.<func>" nodes. It uses the "device" value to find the device model to use. The device model's init routine is passed a reference to its nvlist node in the configuration tree which it can query for specific variables. The result is that a lot of the string parsing is removed from the device models and centralized. In addition, adding a new variable just requires teaching the model to look for the new variable. - For '-l' options, a similar model is used where the string is parsed into values that are later read during initialization. One key note here is that the serial ports use the commonly used lowercase names from existing documentation and examples (e.g. "lpc.com1") instead of the uppercase names previously used internally in bhyve. Reviewed by: grehan MFC after: 3 months Differential Revision: https://reviews.freebsd.org/D26035
2019-06-26 20:30:41 +00:00
if (get_config_bool_default("rtc.use_localtime", true)) {
Add "-u" option to bhyve(8) to indicate that the RTC should maintain UTC time. The default remains localtime for compatibility with the original device model in bhyve(8). This is required for OpenBSD guests which assume that the RTC keeps UTC time. Reviewed by: grehan Pointed out by: Jason Tubnor (jason@tubnor.net) MFC after: 2 weeks
2015-02-24 02:04:16 +00:00
localtime_r(&t, &tm);
t = timegm(&tm);
}
return (t);
Import of bhyve hypervisor and utilities, part 1. vmm.ko - kernel module for VT-x, VT-d and hypervisor control bhyve - user-space sequencer and i/o emulation vmmctl - dump of hypervisor register state libvmm - front-end to vmm.ko chardev interface bhyve was designed and implemented by Neel Natu. Thanks to the following folk from NetApp who helped to make this available: Joe CaraDonna Peter Snyder Jeff Heller Sandeep Mann Steve Miller Brian Pawlowski
2011-05-13 04:54:01 +00:00
}
Implement RTC CMOS nvram. Init some fields that are used by FreeBSD and UEFI. Tested with nvram(4). Reviewed by: neel
2013-07-11 03:54:35 +00:00
void
Refactor configuration management in bhyve. Replace the existing ad-hoc configuration via various global variables with a small database of key-value pairs. The database supports heirarchical keys using a MIB-like syntax to name the path to a given key. Values are always stored as strings. The API used to manage configuation values does include wrappers to handling boolean values. Other values use non-string types require parsing by consumers. The configuration values are stored in a tree using nvlists. Leaf nodes hold string values. Configuration values are permitted to reference other configuration values using '%(name)'. This permits constructing template configurations. All existing command line arguments now set configuration values. For devices, the "-s" option parses its option argument to generate a list of key-value pairs for the given device. A new '-o' command line option permits setting an individual configuration variable. The key name is always given as a full path of dot-separated components. A new '-k' command line option parses a simple configuration file. This configuration file holds a flat list of 'key=value' lines where the 'key' is the full path of a configuration variable. Lines starting with a '#' are comments. In general, bhyve starts by parsing command line options in sequence and applying those settings to configuration values. Once this is complete, bhyve then begins initializing its state based on the configuration values. This means that subsequent configuration options or files may override or supplement previously given settings. A special 'config.dump' configuration value can be set to true to help debug configuration issues. When this value is set, bhyve will print out the configuration variables as a flat list of 'key=value' lines. Most command line argments map to a single configuration variable, e.g. '-w' sets the 'x86.strictmsr' value to false. A few command line arguments have less obvious effects: - Multiple '-p' options append their values (as a comma-seperated list) to "vcpu.N.cpuset" values (where N is a decimal vcpu number). - For '-s' options, a pci.<bus>.<slot>.<function> node is created. The first argument to '-s' (the device type) is used as the value of a "device" variable. Additional comma-separated arguments are then parsed into 'key=value' pairs and used to set additional variables under the device node. A PCI device emulation driver can provide its own hook to override the parsing of the additonal '-s' arguments after the device type. After the configuration phase as completed, the init_pci hook then walks the "pci.<bus>.<slot>.<func>" nodes. It uses the "device" value to find the device model to use. The device model's init routine is passed a reference to its nvlist node in the configuration tree which it can query for specific variables. The result is that a lot of the string parsing is removed from the device models and centralized. In addition, adding a new variable just requires teaching the model to look for the new variable. - For '-l' options, a similar model is used where the string is parsed into values that are later read during initialization. One key note here is that the serial ports use the commonly used lowercase names from existing documentation and examples (e.g. "lpc.com1") instead of the uppercase names previously used internally in bhyve. Reviewed by: grehan MFC after: 3 months Differential Revision: https://reviews.freebsd.org/D26035
2019-06-26 20:30:41 +00:00
rtc_init(struct vmctx *ctx)
Implement RTC CMOS nvram. Init some fields that are used by FreeBSD and UEFI. Tested with nvram(4). Reviewed by: neel
2013-07-11 03:54:35 +00:00
{
size_t himem;
size_t lomem;
int err;
/* XXX init diag/reset code/equipment/checksum ? */
/*
* Report guest memory size in nvram cells as required by UEFI.
* Little-endian encoding.
* 0x34/0x35 - 64KB chunks above 16MB, below 4GB
* 0x5b/0x5c/0x5d - 64KB chunks above 4GB
*/
Provide APIs to directly get 'lowmem' and 'highmem' size directly. Previously the sizes were inferred indirectly based on the size of the mappings at 0 and 4GB respectively. This works fine as long as size of the allocation is identical to the size of the mapping in the guest's address space. However, if the mapping is disjoint then this assumption falls apart (e.g., due to the legacy BIOS hole between 640KB and 1MB).
2014-06-24 02:02:51 +00:00
lomem = (vm_get_lowmem_size(ctx) - m_16MB) / m_64KB;
Replace bhyve's minimal RTC emulation with a fully featured one in vmm.ko. The new RTC emulation supports all interrupt modes: periodic, update ended and alarm. It is also capable of maintaining the date/time and NVRAM contents across virtual machine reset. Also, the date/time fields can now be modified by the guest. Since bhyve now emulates both the PIT and the RTC there is no need for "Legacy Replacement Routing" in the HPET so get rid of it. The RTC device state can be inspected via bhyvectl as follows: bhyvectl --vm=vm --get-rtc-time bhyvectl --vm=vm --set-rtc-time=<unix_time_secs> bhyvectl --vm=vm --rtc-nvram-offset=<offset> --get-rtc-nvram bhyvectl --vm=vm --rtc-nvram-offset=<offset> --set-rtc-nvram=<value> Reviewed by: tychon Discussed with: grehan Differential Revision: https://reviews.freebsd.org/D1385 MFC after: 2 weeks
2014-12-30 22:19:34 +00:00
err = vm_rtc_write(ctx, RTC_LMEM_LSB, lomem);
assert(err == 0);
err = vm_rtc_write(ctx, RTC_LMEM_MSB, lomem >> 8);
assert(err == 0);
Implement RTC CMOS nvram. Init some fields that are used by FreeBSD and UEFI. Tested with nvram(4). Reviewed by: neel
2013-07-11 03:54:35 +00:00
Provide APIs to directly get 'lowmem' and 'highmem' size directly. Previously the sizes were inferred indirectly based on the size of the mappings at 0 and 4GB respectively. This works fine as long as size of the allocation is identical to the size of the mapping in the guest's address space. However, if the mapping is disjoint then this assumption falls apart (e.g., due to the legacy BIOS hole between 640KB and 1MB).
2014-06-24 02:02:51 +00:00
himem = vm_get_highmem_size(ctx) / m_64KB;
Replace bhyve's minimal RTC emulation with a fully featured one in vmm.ko. The new RTC emulation supports all interrupt modes: periodic, update ended and alarm. It is also capable of maintaining the date/time and NVRAM contents across virtual machine reset. Also, the date/time fields can now be modified by the guest. Since bhyve now emulates both the PIT and the RTC there is no need for "Legacy Replacement Routing" in the HPET so get rid of it. The RTC device state can be inspected via bhyvectl as follows: bhyvectl --vm=vm --get-rtc-time bhyvectl --vm=vm --set-rtc-time=<unix_time_secs> bhyvectl --vm=vm --rtc-nvram-offset=<offset> --get-rtc-nvram bhyvectl --vm=vm --rtc-nvram-offset=<offset> --set-rtc-nvram=<value> Reviewed by: tychon Discussed with: grehan Differential Revision: https://reviews.freebsd.org/D1385 MFC after: 2 weeks
2014-12-30 22:19:34 +00:00
err = vm_rtc_write(ctx, RTC_HMEM_LSB, himem);
assert(err == 0);
err = vm_rtc_write(ctx, RTC_HMEM_SB, himem >> 8);
assert(err == 0);
err = vm_rtc_write(ctx, RTC_HMEM_MSB, himem >> 16);
assert(err == 0);
Implement RTC CMOS nvram. Init some fields that are used by FreeBSD and UEFI. Tested with nvram(4). Reviewed by: neel
2013-07-11 03:54:35 +00:00
Refactor configuration management in bhyve. Replace the existing ad-hoc configuration via various global variables with a small database of key-value pairs. The database supports heirarchical keys using a MIB-like syntax to name the path to a given key. Values are always stored as strings. The API used to manage configuation values does include wrappers to handling boolean values. Other values use non-string types require parsing by consumers. The configuration values are stored in a tree using nvlists. Leaf nodes hold string values. Configuration values are permitted to reference other configuration values using '%(name)'. This permits constructing template configurations. All existing command line arguments now set configuration values. For devices, the "-s" option parses its option argument to generate a list of key-value pairs for the given device. A new '-o' command line option permits setting an individual configuration variable. The key name is always given as a full path of dot-separated components. A new '-k' command line option parses a simple configuration file. This configuration file holds a flat list of 'key=value' lines where the 'key' is the full path of a configuration variable. Lines starting with a '#' are comments. In general, bhyve starts by parsing command line options in sequence and applying those settings to configuration values. Once this is complete, bhyve then begins initializing its state based on the configuration values. This means that subsequent configuration options or files may override or supplement previously given settings. A special 'config.dump' configuration value can be set to true to help debug configuration issues. When this value is set, bhyve will print out the configuration variables as a flat list of 'key=value' lines. Most command line argments map to a single configuration variable, e.g. '-w' sets the 'x86.strictmsr' value to false. A few command line arguments have less obvious effects: - Multiple '-p' options append their values (as a comma-seperated list) to "vcpu.N.cpuset" values (where N is a decimal vcpu number). - For '-s' options, a pci.<bus>.<slot>.<function> node is created. The first argument to '-s' (the device type) is used as the value of a "device" variable. Additional comma-separated arguments are then parsed into 'key=value' pairs and used to set additional variables under the device node. A PCI device emulation driver can provide its own hook to override the parsing of the additonal '-s' arguments after the device type. After the configuration phase as completed, the init_pci hook then walks the "pci.<bus>.<slot>.<func>" nodes. It uses the "device" value to find the device model to use. The device model's init routine is passed a reference to its nvlist node in the configuration tree which it can query for specific variables. The result is that a lot of the string parsing is removed from the device models and centralized. In addition, adding a new variable just requires teaching the model to look for the new variable. - For '-l' options, a similar model is used where the string is parsed into values that are later read during initialization. One key note here is that the serial ports use the commonly used lowercase names from existing documentation and examples (e.g. "lpc.com1") instead of the uppercase names previously used internally in bhyve. Reviewed by: grehan MFC after: 3 months Differential Revision: https://reviews.freebsd.org/D26035
2019-06-26 20:30:41 +00:00
err = vm_rtc_settime(ctx, rtc_time(ctx));
Replace bhyve's minimal RTC emulation with a fully featured one in vmm.ko. The new RTC emulation supports all interrupt modes: periodic, update ended and alarm. It is also capable of maintaining the date/time and NVRAM contents across virtual machine reset. Also, the date/time fields can now be modified by the guest. Since bhyve now emulates both the PIT and the RTC there is no need for "Legacy Replacement Routing" in the HPET so get rid of it. The RTC device state can be inspected via bhyvectl as follows: bhyvectl --vm=vm --get-rtc-time bhyvectl --vm=vm --set-rtc-time=<unix_time_secs> bhyvectl --vm=vm --rtc-nvram-offset=<offset> --get-rtc-nvram bhyvectl --vm=vm --rtc-nvram-offset=<offset> --set-rtc-nvram=<value> Reviewed by: tychon Discussed with: grehan Differential Revision: https://reviews.freebsd.org/D1385 MFC after: 2 weeks
2014-12-30 22:19:34 +00:00
assert(err == 0);
}
Rework the DSDT generation code a bit to generate more accurate info about LPC devices. Among other things, the LPC serial ports now appear as ACPI devices. - Move the info for the top-level PCI bus into the PCI emulation code and add ResourceProducer entries for the memory ranges decoded by the bus for memory BARs. - Add a framework to allow each PCI emulation driver to optionally write an entry into the DSDT under the \_SB_.PCI0 namespace. The LPC driver uses this to write a node for the LPC bus (\_SB_.PCI0.ISA). - Add a linker set to allow any LPC devices to write entries into the DSDT below the LPC node. - Move the existing DSDT block for the RTC to the RTC driver. - Add DSDT nodes for the AT PIC, the 8254 ISA timer, and the LPC UART devices. - Add a "SuperIO" device under the LPC node to claim "system resources" aling with a linker set to allow various drivers to add IO or memory ranges that should be claimed as a system resource. - Add system resource entries for the extended RTC IO range, the registers used for ACPI power management, the ELCR, PCI interrupt routing register, and post data register. - Add various helper routines for generating DSDT entries. Reviewed by: neel (earlier version)
2014-01-02 21:26:59 +00:00
static void
rtc_dsdt(void)
{
dsdt_line("");
dsdt_line("Device (RTC)");
dsdt_line("{");
dsdt_line(" Name (_HID, EisaId (\"PNP0B00\"))");
dsdt_line(" Name (_CRS, ResourceTemplate ()");
dsdt_line(" {");
dsdt_indent(2);
dsdt_fixed_ioport(IO_RTC, 2);
dsdt_fixed_irq(8);
dsdt_unindent(2);
dsdt_line(" })");
dsdt_line("}");
}
LPC_DSDT(rtc_dsdt);
Add a comment explaining the intent behind the I/O reservation [0x72-0x77].
2014-10-26 21:17:44 +00:00
/*
* Reserve the extended RTC I/O ports although they are not emulated at this
* time.
*/
Rework the DSDT generation code a bit to generate more accurate info about LPC devices. Among other things, the LPC serial ports now appear as ACPI devices. - Move the info for the top-level PCI bus into the PCI emulation code and add ResourceProducer entries for the memory ranges decoded by the bus for memory BARs. - Add a framework to allow each PCI emulation driver to optionally write an entry into the DSDT under the \_SB_.PCI0 namespace. The LPC driver uses this to write a node for the LPC bus (\_SB_.PCI0.ISA). - Add a linker set to allow any LPC devices to write entries into the DSDT below the LPC node. - Move the existing DSDT block for the RTC to the RTC driver. - Add DSDT nodes for the AT PIC, the 8254 ISA timer, and the LPC UART devices. - Add a "SuperIO" device under the LPC node to claim "system resources" aling with a linker set to allow various drivers to add IO or memory ranges that should be claimed as a system resource. - Add system resource entries for the extended RTC IO range, the registers used for ACPI power management, the ELCR, PCI interrupt routing register, and post data register. - Add various helper routines for generating DSDT entries. Reviewed by: neel (earlier version)
2014-01-02 21:26:59 +00:00
SYSRES_IO(0x72, 6);
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