src/internal/cpu/cpu_riscv64_linux.go - go - Git at Google

 // Copyright 2024 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 //go:build riscv64 && linux

 package cpu

 import _ "unsafe"

 // RISC-V extension discovery code for Linux.
 //
 // A note on detection of the Vector extension using HWCAP.
 //
 // Support for the Vector extension version 1.0 was added to the Linux kernel in release 6.5.
 // Support for the riscv_hwprobe syscall was added in 6.4. It follows that if the riscv_hwprobe
 // syscall is not available then neither is the Vector extension (which needs kernel support).
 // The riscv_hwprobe syscall should then be all we need to detect the Vector extension.
 // However, some RISC-V board manufacturers ship boards with an older kernel on top of which
 // they have back-ported various versions of the Vector extension patches but not the riscv_hwprobe
 // patches. These kernels advertise support for the Vector extension using HWCAP. Falling
 // back to HWCAP to detect the Vector extension, if riscv_hwprobe is not available, or simply not
 // bothering with riscv_hwprobe at all and just using HWCAP may then seem like an attractive option.
 //
 // Unfortunately, simply checking the 'V' bit in AT_HWCAP will not work as this bit is used by
 // RISC-V board and cloud instance providers to mean different things. The Lichee Pi 4A board
 // and the Scaleway RV1 cloud instances use the 'V' bit to advertise their support for the unratified
 // 0.7.1 version of the Vector Specification. The Banana Pi BPI-F3 and the CanMV-K230 board use
 // it to advertise support for 1.0 of the Vector extension. Versions 0.7.1 and 1.0 of the Vector
 // extension are binary incompatible. HWCAP can then not be used in isolation to populate the
 // HasV field as this field indicates that the underlying CPU is compatible with RVV 1.0.
 // Go will only support the ratified versions >= 1.0 and so any vector code it might generate
 // would crash on a Scaleway RV1 instance or a Lichee Pi 4a, if allowed to run.
 //
 // There is a way at runtime to distinguish between versions 0.7.1 and 1.0 of the Vector
 // specification by issuing a RVV 1.0 vsetvli instruction and checking the vill bit of the vtype
 // register. This check would allow us to safely detect version 1.0 of the Vector extension
 // with HWCAP, if riscv_hwprobe were not available. However, the check cannot
 // be added until the assembler supports the Vector instructions.
 //
 // Note the riscv_hwprobe syscall does not suffer from these ambiguities by design as all of the
 // extensions it advertises support for are explicitly versioned. It's also worth noting that
 // the riscv_hwprobe syscall is the only way to detect multi-letter RISC-V extensions, e.g., Zvbb.
 // These cannot be detected using HWCAP and so riscv_hwprobe must be used to detect the majority
 // of RISC-V extensions.
 //
 // Please see https://docs.kernel.org/arch/riscv/hwprobe.html for more information.

 const (
 	// Copied from golang.org/x/sys/unix/ztypes_linux_riscv64.go.
 	riscv_HWPROBE_KEY_IMA_EXT_0   = 0x4
 	riscv_HWPROBE_IMA_V           = 0x4
 	riscv_HWPROBE_EXT_ZBB         = 0x10
 	riscv_HWPROBE_KEY_CPUPERF_0   = 0x5
 	riscv_HWPROBE_MISALIGNED_FAST = 0x3
 	riscv_HWPROBE_MISALIGNED_MASK = 0x7
 )

 // riscvHWProbePairs is copied from golang.org/x/sys/unix/ztypes_linux_riscv64.go.
 type riscvHWProbePairs struct {
 	key   int64
 	value uint64
 }

 //go:linkname riscvHWProbe
 func riscvHWProbe(pairs []riscvHWProbePairs, flags uint) bool

 func osInit() {
 	// A slice of key/value pair structures is passed to the RISCVHWProbe syscall. The key
 	// field should be initialised with one of the key constants defined above, e.g.,
 	// RISCV_HWPROBE_KEY_IMA_EXT_0. The syscall will set the value field to the appropriate value.
 	// If the kernel does not recognise a key it will set the key field to -1 and the value field to 0.

 	pairs := []riscvHWProbePairs{
 		{riscv_HWPROBE_KEY_IMA_EXT_0, 0},
 		{riscv_HWPROBE_KEY_CPUPERF_0, 0},
 	}

 	// This call only indicates that extensions are supported if they are implemented on all cores.
 	if !riscvHWProbe(pairs, 0) {
 		return
 	}

 	if pairs[0].key != -1 {
 		v := uint(pairs[0].value)
 		RISCV64.HasV = isSet(v, riscv_HWPROBE_IMA_V)
 		RISCV64.HasZbb = isSet(v, riscv_HWPROBE_EXT_ZBB)
 	}
 	if pairs[1].key != -1 {
 		v := pairs[1].value & riscv_HWPROBE_MISALIGNED_MASK
 		RISCV64.HasFastMisaligned = v == riscv_HWPROBE_MISALIGNED_FAST
 	}
 }
	// Copyright 2024 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	//go:build riscv64 && linux

	package cpu

	import _ "unsafe"

	// RISC-V extension discovery code for Linux.
	//
	// A note on detection of the Vector extension using HWCAP.
	//
	// Support for the Vector extension version 1.0 was added to the Linux kernel in release 6.5.
	// Support for the riscv_hwprobe syscall was added in 6.4. It follows that if the riscv_hwprobe
	// syscall is not available then neither is the Vector extension (which needs kernel support).
	// The riscv_hwprobe syscall should then be all we need to detect the Vector extension.
	// However, some RISC-V board manufacturers ship boards with an older kernel on top of which
	// they have back-ported various versions of the Vector extension patches but not the riscv_hwprobe
	// patches. These kernels advertise support for the Vector extension using HWCAP. Falling
	// back to HWCAP to detect the Vector extension, if riscv_hwprobe is not available, or simply not
	// bothering with riscv_hwprobe at all and just using HWCAP may then seem like an attractive option.
	//
	// Unfortunately, simply checking the 'V' bit in AT_HWCAP will not work as this bit is used by
	// RISC-V board and cloud instance providers to mean different things. The Lichee Pi 4A board
	// and the Scaleway RV1 cloud instances use the 'V' bit to advertise their support for the unratified
	// 0.7.1 version of the Vector Specification. The Banana Pi BPI-F3 and the CanMV-K230 board use
	// it to advertise support for 1.0 of the Vector extension. Versions 0.7.1 and 1.0 of the Vector
	// extension are binary incompatible. HWCAP can then not be used in isolation to populate the
	// HasV field as this field indicates that the underlying CPU is compatible with RVV 1.0.
	// Go will only support the ratified versions >= 1.0 and so any vector code it might generate
	// would crash on a Scaleway RV1 instance or a Lichee Pi 4a, if allowed to run.
	//
	// There is a way at runtime to distinguish between versions 0.7.1 and 1.0 of the Vector
	// specification by issuing a RVV 1.0 vsetvli instruction and checking the vill bit of the vtype
	// register. This check would allow us to safely detect version 1.0 of the Vector extension
	// with HWCAP, if riscv_hwprobe were not available. However, the check cannot
	// be added until the assembler supports the Vector instructions.
	//
	// Note the riscv_hwprobe syscall does not suffer from these ambiguities by design as all of the
	// extensions it advertises support for are explicitly versioned. It's also worth noting that
	// the riscv_hwprobe syscall is the only way to detect multi-letter RISC-V extensions, e.g., Zvbb.
	// These cannot be detected using HWCAP and so riscv_hwprobe must be used to detect the majority
	// of RISC-V extensions.
	//
	// Please see https://docs.kernel.org/arch/riscv/hwprobe.html for more information.

	const (
	// Copied from golang.org/x/sys/unix/ztypes_linux_riscv64.go.
	riscv_HWPROBE_KEY_IMA_EXT_0 = 0x4
	riscv_HWPROBE_IMA_V = 0x4
	riscv_HWPROBE_EXT_ZBB = 0x10
	riscv_HWPROBE_KEY_CPUPERF_0 = 0x5
	riscv_HWPROBE_MISALIGNED_FAST = 0x3
	riscv_HWPROBE_MISALIGNED_MASK = 0x7
	)

	// riscvHWProbePairs is copied from golang.org/x/sys/unix/ztypes_linux_riscv64.go.
	type riscvHWProbePairs struct {
	key int64
	value uint64
	}

	//go:linkname riscvHWProbe
	func riscvHWProbe(pairs []riscvHWProbePairs, flags uint) bool

	func osInit() {
	// A slice of key/value pair structures is passed to the RISCVHWProbe syscall. The key
	// field should be initialised with one of the key constants defined above, e.g.,
	// RISCV_HWPROBE_KEY_IMA_EXT_0. The syscall will set the value field to the appropriate value.
	// If the kernel does not recognise a key it will set the key field to -1 and the value field to 0.

	pairs := []riscvHWProbePairs{
	{riscv_HWPROBE_KEY_IMA_EXT_0, 0},
	{riscv_HWPROBE_KEY_CPUPERF_0, 0},
	}

	// This call only indicates that extensions are supported if they are implemented on all cores.
	if !riscvHWProbe(pairs, 0) {
	return
	}

	if pairs[0].key != -1 {
	v := uint(pairs[0].value)
	RISCV64.HasV = isSet(v, riscv_HWPROBE_IMA_V)
	RISCV64.HasZbb = isSet(v, riscv_HWPROBE_EXT_ZBB)
	}
	if pairs[1].key != -1 {
	v := pairs[1].value & riscv_HWPROBE_MISALIGNED_MASK
	RISCV64.HasFastMisaligned = v == riscv_HWPROBE_MISALIGNED_FAST
	}
	}