Documentation/kvm/ppc-pv.txt - kernel/msm-4.9 - Gitiles

 The PPC KVM paravirtual interface
 =================================

 The basic execution principle by which KVM on PowerPC works is to run all kernel
 space code in PR=1 which is user space. This way we trap all privileged
 instructions and can emulate them accordingly.

 Unfortunately that is also the downfall. There are quite some privileged
 instructions that needlessly return us to the hypervisor even though they
 could be handled differently.

 This is what the PPC PV interface helps with. It takes privileged instructions
 and transforms them into unprivileged ones with some help from the hypervisor.
 This cuts down virtualization costs by about 50% on some of my benchmarks.

 The code for that interface can be found in arch/powerpc/kernel/kvm*

 Querying for existence
 ======================

 To find out if we're running on KVM or not, we leverage the device tree. When
 Linux is running on KVM, a node /hypervisor exists. That node contains a
 compatible property with the value "linux,kvm".

 Once you determined you're running under a PV capable KVM, you can now use
 hypercalls as described below.

 KVM hypercalls
 ==============

 Inside the device tree's /hypervisor node there's a property called
 'hypercall-instructions'. This property contains at most 4 opcodes that make
 up the hypercall. To call a hypercall, just call these instructions.

 The parameters are as follows:

 	Register	IN			OUT

 	r0		-			volatile
 	r3		1st parameter		Return code
 	r4		2nd parameter		1st output value
 	r5		3rd parameter		2nd output value
 	r6		4th parameter		3rd output value
 	r7		5th parameter		4th output value
 	r8		6th parameter		5th output value
 	r9		7th parameter		6th output value
 	r10		8th parameter		7th output value
 	r11		hypercall number	8th output value
 	r12		-			volatile

 Hypercall definitions are shared in generic code, so the same hypercall numbers
 apply for x86 and powerpc alike with the exception that each KVM hypercall
 also needs to be ORed with the KVM vendor code which is (42 << 16).

 Return codes can be as follows:

 	Code		Meaning

 	0		Success
 	12		Hypercall not implemented
 	<0		Error

 The magic page
 ==============

 To enable communication between the hypervisor and guest there is a new shared
 page that contains parts of supervisor visible register state. The guest can
 map this shared page using the KVM hypercall KVM_HC_PPC_MAP_MAGIC_PAGE.

 With this hypercall issued the guest always gets the magic page mapped at the
 desired location in effective and physical address space. For now, we always
 map the page to -4096. This way we can access it using absolute load and store
 functions. The following instruction reads the first field of the magic page:

 	ld	rX, -4096(0)

 The interface is designed to be extensible should there be need later to add
 additional registers to the magic page. If you add fields to the magic page,
 also define a new hypercall feature to indicate that the host can give you more
 registers. Only if the host supports the additional features, make use of them.

 The magic page has the following layout as described in
 arch/powerpc/include/asm/kvm_para.h:

 struct kvm_vcpu_arch_shared {
 	__u64 scratch1;
 	__u64 scratch2;
 	__u64 scratch3;
 	__u64 critical;		/* Guest may not get interrupts if == r1 */
 	__u64 sprg0;
 	__u64 sprg1;
 	__u64 sprg2;
 	__u64 sprg3;
 	__u64 srr0;
 	__u64 srr1;
 	__u64 dar;
 	__u64 msr;
 	__u32 dsisr;
 	__u32 int_pending;	/* Tells the guest if we have an interrupt */
 };

 Additions to the page must only occur at the end. Struct fields are always 32
 or 64 bit aligned, depending on them being 32 or 64 bit wide respectively.

 Magic page features
 ===================

 When mapping the magic page using the KVM hypercall KVM_HC_PPC_MAP_MAGIC_PAGE,
 a second return value is passed to the guest. This second return value contains
 a bitmap of available features inside the magic page.

 The following enhancements to the magic page are currently available:

   KVM_MAGIC_FEAT_SR		Maps SR registers r/w in the magic page

 For enhanced features in the magic page, please check for the existence of the
 feature before using them!

 MSR bits
 ========

 The MSR contains bits that require hypervisor intervention and bits that do
 not require direct hypervisor intervention because they only get interpreted
 when entering the guest or don't have any impact on the hypervisor's behavior.

 The following bits are safe to be set inside the guest:

   MSR_EE
   MSR_RI
   MSR_CR
   MSR_ME

 If any other bit changes in the MSR, please still use mtmsr(d).

 Patched instructions
 ====================

 The "ld" and "std" instructions are transormed to "lwz" and "stw" instructions
 respectively on 32 bit systems with an added offset of 4 to accomodate for big
 endianness.

 The following is a list of mapping the Linux kernel performs when running as
 guest. Implementing any of those mappings is optional, as the instruction traps
 also act on the shared page. So calling privileged instructions still works as
 before.

 From			To
 ====			==

 mfmsr	rX		ld	rX, magic_page->msr
 mfsprg	rX, 0		ld	rX, magic_page->sprg0
 mfsprg	rX, 1		ld	rX, magic_page->sprg1
 mfsprg	rX, 2		ld	rX, magic_page->sprg2
 mfsprg	rX, 3		ld	rX, magic_page->sprg3
 mfsrr0	rX		ld	rX, magic_page->srr0
 mfsrr1	rX		ld	rX, magic_page->srr1
 mfdar	rX		ld	rX, magic_page->dar
 mfdsisr	rX		lwz	rX, magic_page->dsisr

 mtmsr	rX		std	rX, magic_page->msr
 mtsprg	0, rX		std	rX, magic_page->sprg0
 mtsprg	1, rX		std	rX, magic_page->sprg1
 mtsprg	2, rX		std	rX, magic_page->sprg2
 mtsprg	3, rX		std	rX, magic_page->sprg3
 mtsrr0	rX		std	rX, magic_page->srr0
 mtsrr1	rX		std	rX, magic_page->srr1
 mtdar	rX		std	rX, magic_page->dar
 mtdsisr	rX		stw	rX, magic_page->dsisr

 tlbsync			nop

 mtmsrd	rX, 0		b	<special mtmsr section>
 mtmsr	rX		b	<special mtmsr section>

 mtmsrd	rX, 1		b	<special mtmsrd section>

 [Book3S only]
 mtsrin	rX, rY		b	<special mtsrin section>

 [BookE only]
 wrteei	[0|1]		b	<special wrteei section>


 Some instructions require more logic to determine what's going on than a load
 or store instruction can deliver. To enable patching of those, we keep some
 RAM around where we can live translate instructions to. What happens is the
 following:

 	1) copy emulation code to memory
 	2) patch that code to fit the emulated instruction
 	3) patch that code to return to the original pc + 4
 	4) patch the original instruction to branch to the new code

 That way we can inject an arbitrary amount of code as replacement for a single
 instruction. This allows us to check for pending interrupts when setting EE=1
 for example.
	The PPC KVM paravirtual interface
	=================================

	The basic execution principle by which KVM on PowerPC works is to run all kernel
	space code in PR=1 which is user space. This way we trap all privileged
	instructions and can emulate them accordingly.

	Unfortunately that is also the downfall. There are quite some privileged
	instructions that needlessly return us to the hypervisor even though they
	could be handled differently.

	This is what the PPC PV interface helps with. It takes privileged instructions
	and transforms them into unprivileged ones with some help from the hypervisor.
	This cuts down virtualization costs by about 50% on some of my benchmarks.

	The code for that interface can be found in arch/powerpc/kernel/kvm*

	Querying for existence
	======================

	To find out if we're running on KVM or not, we leverage the device tree. When
	Linux is running on KVM, a node /hypervisor exists. That node contains a
	compatible property with the value "linux,kvm".

	Once you determined you're running under a PV capable KVM, you can now use
	hypercalls as described below.

	KVM hypercalls
	==============

	Inside the device tree's /hypervisor node there's a property called
	'hypercall-instructions'. This property contains at most 4 opcodes that make
	up the hypercall. To call a hypercall, just call these instructions.

	The parameters are as follows:

	Register IN OUT

	r0 - volatile
	r3 1st parameter Return code
	r4 2nd parameter 1st output value
	r5 3rd parameter 2nd output value
	r6 4th parameter 3rd output value
	r7 5th parameter 4th output value
	r8 6th parameter 5th output value
	r9 7th parameter 6th output value
	r10 8th parameter 7th output value
	r11 hypercall number 8th output value
	r12 - volatile

	Hypercall definitions are shared in generic code, so the same hypercall numbers
	apply for x86 and powerpc alike with the exception that each KVM hypercall
	also needs to be ORed with the KVM vendor code which is (42 << 16).

	Return codes can be as follows:

	Code Meaning

	0 Success
	12 Hypercall not implemented
	<0 Error

	The magic page
	==============

	To enable communication between the hypervisor and guest there is a new shared
	page that contains parts of supervisor visible register state. The guest can
	map this shared page using the KVM hypercall KVM_HC_PPC_MAP_MAGIC_PAGE.

	With this hypercall issued the guest always gets the magic page mapped at the
	desired location in effective and physical address space. For now, we always
	map the page to -4096. This way we can access it using absolute load and store
	functions. The following instruction reads the first field of the magic page:

	ld rX, -4096(0)

	The interface is designed to be extensible should there be need later to add
	additional registers to the magic page. If you add fields to the magic page,
	also define a new hypercall feature to indicate that the host can give you more
	registers. Only if the host supports the additional features, make use of them.

	The magic page has the following layout as described in
	arch/powerpc/include/asm/kvm_para.h:

	struct kvm_vcpu_arch_shared {
	__u64 scratch1;
	__u64 scratch2;
	__u64 scratch3;
	__u64 critical; /* Guest may not get interrupts if == r1 */
	__u64 sprg0;
	__u64 sprg1;
	__u64 sprg2;
	__u64 sprg3;
	__u64 srr0;
	__u64 srr1;
	__u64 dar;
	__u64 msr;
	__u32 dsisr;
	__u32 int_pending; /* Tells the guest if we have an interrupt */
	};

	Additions to the page must only occur at the end. Struct fields are always 32
	or 64 bit aligned, depending on them being 32 or 64 bit wide respectively.

	Magic page features
	===================

	When mapping the magic page using the KVM hypercall KVM_HC_PPC_MAP_MAGIC_PAGE,
	a second return value is passed to the guest. This second return value contains
	a bitmap of available features inside the magic page.

	The following enhancements to the magic page are currently available:

	KVM_MAGIC_FEAT_SR Maps SR registers r/w in the magic page

	For enhanced features in the magic page, please check for the existence of the
	feature before using them!

	MSR bits
	========

	The MSR contains bits that require hypervisor intervention and bits that do
	not require direct hypervisor intervention because they only get interpreted
	when entering the guest or don't have any impact on the hypervisor's behavior.

	The following bits are safe to be set inside the guest:

	MSR_EE
	MSR_RI
	MSR_CR
	MSR_ME

	If any other bit changes in the MSR, please still use mtmsr(d).

	Patched instructions
	====================

	The "ld" and "std" instructions are transormed to "lwz" and "stw" instructions
	respectively on 32 bit systems with an added offset of 4 to accomodate for big
	endianness.

	The following is a list of mapping the Linux kernel performs when running as
	guest. Implementing any of those mappings is optional, as the instruction traps
	also act on the shared page. So calling privileged instructions still works as
	before.

	From To
	==== ==

	mfmsr rX ld rX, magic_page->msr
	mfsprg rX, 0 ld rX, magic_page->sprg0
	mfsprg rX, 1 ld rX, magic_page->sprg1
	mfsprg rX, 2 ld rX, magic_page->sprg2
	mfsprg rX, 3 ld rX, magic_page->sprg3
	mfsrr0 rX ld rX, magic_page->srr0
	mfsrr1 rX ld rX, magic_page->srr1
	mfdar rX ld rX, magic_page->dar
	mfdsisr rX lwz rX, magic_page->dsisr

	mtmsr rX std rX, magic_page->msr
	mtsprg 0, rX std rX, magic_page->sprg0
	mtsprg 1, rX std rX, magic_page->sprg1
	mtsprg 2, rX std rX, magic_page->sprg2
	mtsprg 3, rX std rX, magic_page->sprg3
	mtsrr0 rX std rX, magic_page->srr0
	mtsrr1 rX std rX, magic_page->srr1
	mtdar rX std rX, magic_page->dar
	mtdsisr rX stw rX, magic_page->dsisr

	tlbsync nop

	mtmsrd rX, 0 b <special mtmsr section>
	mtmsr rX b <special mtmsr section>

	mtmsrd rX, 1 b <special mtmsrd section>

	[Book3S only]
	mtsrin rX, rY b <special mtsrin section>

	[BookE only]
	wrteei [0\|1] b <special wrteei section>


	Some instructions require more logic to determine what's going on than a load
	or store instruction can deliver. To enable patching of those, we keep some
	RAM around where we can live translate instructions to. What happens is the
	following:

	1) copy emulation code to memory
	2) patch that code to fit the emulated instruction
	3) patch that code to return to the original pc + 4
	4) patch the original instruction to branch to the new code

	That way we can inject an arbitrary amount of code as replacement for a single
	instruction. This allows us to check for pending interrupts when setting EE=1
	for example.