Hypercall Op-codes (hcalls)

Overview

Virtualization on 64-bit Power Book3S Platforms is based on the PAPR specification [1] which describes the run-time environment for a guest operating system and how it should interact with the hypervisor for privileged operations. Currently there are two PAPR compliant hypervisors:

  • IBM PowerVM (PHYP): IBM’s proprietary hypervisor that supports AIX, IBM-i and Linux as supported guests (termed as Logical Partitions or LPARS). It supports the full PAPR specification.
  • Qemu/KVM: Supports PPC64 linux guests running on a PPC64 linux host. Though it only implements a subset of PAPR specification called LoPAPR [2].

On PPC64 arch a guest kernel running on top of a PAPR hypervisor is called a pSeries guest. A pseries guest runs in a supervisor mode (HV=0) and must issue hypercalls to the hypervisor whenever it needs to perform an action that is hypervisor priviledged [3] or for other services managed by the hypervisor.

Hence a Hypercall (hcall) is essentially a request by the pseries guest asking hypervisor to perform a privileged operation on behalf of the guest. The guest issues a with necessary input operands. The hypervisor after performing the privilege operation returns a status code and output operands back to the guest.

HCALL ABI

The ABI specification for a hcall between a pseries guest and PAPR hypervisor is covered in section 14.5.3 of ref [2]. Switch to the Hypervisor context is done via the instruction HVCS that expects the Opcode for hcall is set in r3 and any in-arguments for the hcall are provided in registers r4-r12. If values have to be passed through a memory buffer, the data stored in that buffer should be in Big-endian byte order.

Once control is returns back to the guest after hypervisor has serviced the ‘HVCS’ instruction the return value of the hcall is available in r3 and any out values are returned in registers r4-r12. Again like in case of in-arguments, any out values stored in a memory buffer will be in Big-endian byte order.

Powerpc arch code provides convenient wrappers named plpar_hcall_xxx defined in a arch specific header [4] to issue hcalls from the linux kernel running as pseries guest.

Register Conventions

Any hcall should follow same register convention as described in section 2.2.1.1 of “64-Bit ELF V2 ABI Specification: Power Architecture”[5]. Table below summarizes these conventions:

Register Range Volatile (Y/N) Purpose
r0 Y Optional-usage
r1 N Stack Pointer
r2 N TOC
r3 Y hcall opcode/return value
r4-r10 Y in and out values
r11 Y Optional-usage/Environmental pointer
r12 Y Optional-usage/Function entry address at global entry point
r13 N Thread-Pointer
r14-r31 N Local Variables
LR Y Link Register
CTR Y Loop Counter
XER Y Fixed-point exception register.
CR0-1 Y Condition register fields.
CR2-4 N Condition register fields.
CR5-7 Y Condition register fields.
Others N  

DRC & DRC Indexes

DR1                                  Guest
+--+        +------------+         +---------+
|  | <----> |            |         |  User   |
+--+  DRC1  |            |   DRC   |  Space  |
            |    PAPR    |  Index  +---------+
DR2         | Hypervisor |         |         |
+--+        |            | <-----> |  Kernel |
|  | <----> |            |  Hcall  |         |
+--+  DRC2  +------------+         +---------+

PAPR hypervisor terms shared hardware resources like PCI devices, NVDIMMs etc available for use by LPARs as Dynamic Resource (DR). When a DR is allocated to an LPAR, PHYP creates a data-structure called Dynamic Resource Connector (DRC) to manage LPAR access. An LPAR refers to a DRC via an opaque 32-bit number called DRC-Index. The DRC-index value is provided to the LPAR via device-tree where its present as an attribute in the device tree node associated with the DR.

HCALL Return-values

After servicing the hcall, hypervisor sets the return-value in r3 indicating success or failure of the hcall. In case of a failure an error code indicates the cause for error. These codes are defined and documented in arch specific header [4].

In some cases a hcall can potentially take a long time and need to be issued multiple times in order to be completely serviced. These hcalls will usually accept an opaque value continue-token within there argument list and a return value of H_CONTINUE indicates that hypervisor hasn’t still finished servicing the hcall yet.

To make such hcalls the guest need to set continue-token == 0 for the initial call and use the hypervisor returned value of continue-token for each subsequent hcall until hypervisor returns a non H_CONTINUE return value.

HCALL Op-codes

Below is a partial list of HCALLs that are supported by PHYP. For the corresponding opcode values please look into the arch specific header [4]:

H_SCM_READ_METADATA

Input: drcIndex, offset, buffer-address, numBytesToRead
Out: numBytesRead
Return Value: H_Success, H_Parameter, H_P2, H_P3, H_Hardware

Given a DRC Index of an NVDIMM, read N-bytes from the the metadata area associated with it, at a specified offset and copy it to provided buffer. The metadata area stores configuration information such as label information, bad-blocks etc. The metadata area is located out-of-band of NVDIMM storage area hence a separate access semantics is provided.

H_SCM_WRITE_METADATA

Input: drcIndex, offset, data, numBytesToWrite
Out: None
Return Value: H_Success, H_Parameter, H_P2, H_P4, H_Hardware

Given a DRC Index of an NVDIMM, write N-bytes to the metadata area associated with it, at the specified offset and from the provided buffer.

H_SCM_BIND_MEM

Input: drcIndex, startingScmBlockIndex, numScmBlocksToBind,
targetLogicalMemoryAddress, continue-token
Out: continue-token, targetLogicalMemoryAddress, numScmBlocksToBound
Return Value: H_Success, H_Parameter, H_P2, H_P3, H_P4, H_Overlap,
H_Too_Big, H_P5, H_Busy

Given a DRC-Index of an NVDIMM, map a continuous SCM blocks range (startingScmBlockIndex, startingScmBlockIndex+numScmBlocksToBind) to the guest at targetLogicalMemoryAddress within guest physical address space. In case targetLogicalMemoryAddress == 0xFFFFFFFF_FFFFFFFF then hypervisor assigns a target address to the guest. The HCALL can fail if the Guest has an active PTE entry to the SCM block being bound.

H_SCM_UNBIND_MEM | Input: drcIndex, startingScmLogicalMemoryAddress, numScmBlocksToUnbind | Out: numScmBlocksUnbound | Return Value: H_Success, H_Parameter, H_P2, H_P3, H_In_Use, H_Overlap, | H_Busy, H_LongBusyOrder1mSec, H_LongBusyOrder10mSec

Given a DRC-Index of an NVDimm, unmap numScmBlocksToUnbind SCM blocks starting at startingScmLogicalMemoryAddress from guest physical address space. The HCALL can fail if the Guest has an active PTE entry to the SCM block being unbound.

H_SCM_QUERY_BLOCK_MEM_BINDING

Input: drcIndex, scmBlockIndex
Out: Guest-Physical-Address
Return Value: H_Success, H_Parameter, H_P2, H_NotFound

Given a DRC-Index and an SCM Block index return the guest physical address to which the SCM block is mapped to.

H_SCM_QUERY_LOGICAL_MEM_BINDING

Input: Guest-Physical-Address
Out: drcIndex, scmBlockIndex
Return Value: H_Success, H_Parameter, H_P2, H_NotFound

Given a guest physical address return which DRC Index and SCM block is mapped to that address.

H_SCM_UNBIND_ALL

Input: scmTargetScope, drcIndex
Out: None
Return Value: H_Success, H_Parameter, H_P2, H_P3, H_In_Use, H_Busy,
H_LongBusyOrder1mSec, H_LongBusyOrder10mSec

Depending on the Target scope unmap all SCM blocks belonging to all NVDIMMs or all SCM blocks belonging to a single NVDIMM identified by its drcIndex from the LPAR memory.

H_SCM_HEALTH

Input: drcIndex
Out: health-bitmap, health-bit-valid-bitmap
Return Value: H_Success, H_Parameter, H_Hardware

Given a DRC Index return the info on predictive failure and overall health of the NVDIMM. The asserted bits in the health-bitmap indicate a single predictive failure and health-bit-valid-bitmap indicate which bits in health-bitmap are valid.

H_SCM_PERFORMANCE_STATS

Input: drcIndex, resultBuffer Addr
Out: None
Return Value: H_Success, H_Parameter, H_Unsupported, H_Hardware, H_Authority, H_Privilege

Given a DRC Index collect the performance statistics for NVDIMM and copy them to the resultBuffer.

References

[1]“Power Architecture Platform Reference” https://en.wikipedia.org/wiki/Power_Architecture_Platform_Reference
[2](1, 2) “Linux on Power Architecture Platform Reference” https://members.openpowerfoundation.org/document/dl/469
[3]“Definitions and Notation” Book III-Section 14.5.3 https://openpowerfoundation.org/?resource_lib=power-isa-version-3-0
[4](1, 2, 3) arch/powerpc/include/asm/hvcall.h
[5]“64-Bit ELF V2 ABI Specification: Power Architecture” https://openpowerfoundation.org/?resource_lib=64-bit-elf-v2-abi-specification-power-architecture