mirror of https://gitee.com/openkylin/qemu.git
161 lines
7.7 KiB
Plaintext
161 lines
7.7 KiB
Plaintext
QEMU<->ACPI BIOS CPU hotplug interface
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--------------------------------------
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QEMU supports CPU hotplug via ACPI. This document
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describes the interface between QEMU and the ACPI BIOS.
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ACPI BIOS GPE.2 handler is dedicated for notifying OS about CPU hot-add
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and hot-remove events.
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============================================
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Legacy ACPI CPU hotplug interface registers:
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--------------------------------------------
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CPU present bitmap for:
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ICH9-LPC (IO port 0x0cd8-0xcf7, 1-byte access)
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PIIX-PM (IO port 0xaf00-0xaf1f, 1-byte access)
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One bit per CPU. Bit position reflects corresponding CPU APIC ID. Read-only.
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The first DWORD in bitmap is used in write mode to switch from legacy
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to modern CPU hotplug interface, write 0 into it to do switch.
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---------------------------------------------------------------
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QEMU sets corresponding CPU bit on hot-add event and issues SCI
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with GPE.2 event set. CPU present map is read by ACPI BIOS GPE.2 handler
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to notify OS about CPU hot-add events. CPU hot-remove isn't supported.
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=====================================
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Modern ACPI CPU hotplug interface registers:
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-------------------------------------
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Register block base address:
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ICH9-LPC IO port 0x0cd8
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PIIX-PM IO port 0xaf00
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Register block size:
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ACPI_CPU_HOTPLUG_REG_LEN = 12
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All accesses to registers described below, imply little-endian byte order.
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Reserved resisters behavior:
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- write accesses are ignored
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- read accesses return all bits set to 0.
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The last stored value in 'CPU selector' must refer to a possible CPU, otherwise
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- reads from any register return 0
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- writes to any other register are ignored until valid value is stored into it
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On QEMU start, 'CPU selector' is initialized to a valid value, on reset it
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keeps the current value.
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read access:
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offset:
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[0x0-0x3] Command data 2: (DWORD access)
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if value last stored in 'Command field':
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0: reads as 0x0
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3: upper 32 bits of architecture specific CPU ID value
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other values: reserved
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[0x4] CPU device status fields: (1 byte access)
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bits:
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0: Device is enabled and may be used by guest
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1: Device insert event, used to distinguish device for which
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no device check event to OSPM was issued.
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It's valid only when bit 0 is set.
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2: Device remove event, used to distinguish device for which
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no device eject request to OSPM was issued. Firmware must
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ignore this bit.
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3: reserved and should be ignored by OSPM
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4: if set to 1, OSPM requests firmware to perform device eject.
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5-7: reserved and should be ignored by OSPM
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[0x5-0x7] reserved
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[0x8] Command data: (DWORD access)
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contains 0 unless value last stored in 'Command field' is one of:
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0: contains 'CPU selector' value of a CPU with pending event[s]
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3: lower 32 bits of architecture specific CPU ID value
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(in x86 case: APIC ID)
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write access:
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offset:
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[0x0-0x3] CPU selector: (DWORD access)
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selects active CPU device. All following accesses to other
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registers will read/store data from/to selected CPU.
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Valid values: [0 .. max_cpus)
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[0x4] CPU device control fields: (1 byte access)
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bits:
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0: reserved, OSPM must clear it before writing to register.
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1: if set to 1 clears device insert event, set by OSPM
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after it has emitted device check event for the
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selected CPU device
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2: if set to 1 clears device remove event, set by OSPM
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after it has emitted device eject request for the
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selected CPU device.
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3: if set to 1 initiates device eject, set by OSPM when it
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triggers CPU device removal and calls _EJ0 method or by firmware
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when bit #4 is set. In case bit #4 were set, it's cleared as
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part of device eject.
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4: if set to 1, OSPM hands over device eject to firmware.
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Firmware shall issue device eject request as described above
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(bit #3) and OSPM should not touch device eject bit (#3) in case
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it's asked firmware to perform CPU device eject.
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5-7: reserved, OSPM must clear them before writing to register
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[0x5] Command field: (1 byte access)
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value:
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0: selects a CPU device with inserting/removing events and
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following reads from 'Command data' register return
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selected CPU ('CPU selector' value).
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If no CPU with events found, the current 'CPU selector' doesn't
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change and corresponding insert/remove event flags are not modified.
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1: following writes to 'Command data' register set OST event
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register in QEMU
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2: following writes to 'Command data' register set OST status
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register in QEMU
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3: following reads from 'Command data' and 'Command data 2' return
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architecture specific CPU ID value for currently selected CPU.
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other values: reserved
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[0x6-0x7] reserved
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[0x8] Command data: (DWORD access)
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if last stored 'Command field' value:
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1: stores value into OST event register
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2: stores value into OST status register, triggers
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ACPI_DEVICE_OST QMP event from QEMU to external applications
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with current values of OST event and status registers.
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other values: reserved
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Typical usecases:
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- (x86) Detecting and enabling modern CPU hotplug interface.
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QEMU starts with legacy CPU hotplug interface enabled. Detecting and
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switching to modern interface is based on the 2 legacy CPU hotplug features:
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1. Writes into CPU bitmap are ignored.
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2. CPU bitmap always has bit#0 set, corresponding to boot CPU.
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Use following steps to detect and enable modern CPU hotplug interface:
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1. Store 0x0 to the 'CPU selector' register,
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attempting to switch to modern mode
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2. Store 0x0 to the 'CPU selector' register,
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to ensure valid selector value
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3. Store 0x0 to the 'Command field' register,
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4. Read the 'Command data 2' register.
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If read value is 0x0, the modern interface is enabled.
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Otherwise legacy or no CPU hotplug interface available
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- Get a cpu with pending event
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1. Store 0x0 to the 'CPU selector' register.
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2. Store 0x0 to the 'Command field' register.
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3. Read the 'CPU device status fields' register.
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4. If both bit#1 and bit#2 are clear in the value read, there is no CPU
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with a pending event and selected CPU remains unchanged.
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5. Otherwise, read the 'Command data' register. The value read is the
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selector of the CPU with the pending event (which is already
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selected).
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- Enumerate CPUs present/non present CPUs
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01. Set the present CPU count to 0.
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02. Set the iterator to 0.
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03. Store 0x0 to the 'CPU selector' register, to ensure that it's in
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a valid state and that access to other registers won't be ignored.
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04. Store 0x0 to the 'Command field' register to make 'Command data'
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register return 'CPU selector' value of selected CPU
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05. Read the 'CPU device status fields' register.
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06. If bit#0 is set, increment the present CPU count.
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07. Increment the iterator.
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08. Store the iterator to the 'CPU selector' register.
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09. Read the 'Command data' register.
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10. If the value read is not zero, goto 05.
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11. Otherwise store 0x0 to the 'CPU selector' register, to put it
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into a valid state and exit.
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The iterator at this point equals "max_cpus".
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