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//===-- LinuxPTraceDefines_arm64sve.h ------------------------- -*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#ifndef LLDB_SOURCE_PLUGINS_PROCESS_UTILITY_LINUXPTRACEDEFINES_ARM64SVE_H
#define LLDB_SOURCE_PLUGINS_PROCESS_UTILITY_LINUXPTRACEDEFINES_ARM64SVE_H
#include <stdint.h>
namespace lldb_private {
namespace sve {
/*
* The SVE architecture leaves space for future expansion of the
* vector length beyond its initial architectural limit of 2048 bits
* (16 quadwords).
*
* See <Linux kernel source tree>/Documentation/arm64/sve.rst for a description
* of the vl/vq terminology.
*/
const uint16_t vq_bytes = 16; /* number of bytes per quadword */
const uint16_t vq_min = 1;
const uint16_t vq_max = 512;
const uint16_t vl_min = vq_min * vq_bytes;
const uint16_t vl_max = vq_max * vq_bytes;
const uint16_t num_of_zregs = 32;
const uint16_t num_of_pregs = 16;
inline uint16_t vl_valid(uint16_t vl) {
return (vl % vq_bytes == 0 && vl >= vl_min && vl <= vl_max);
}
inline uint16_t vq_from_vl(uint16_t vl) { return vl / vq_bytes; }
inline uint16_t vl_from_vq(uint16_t vq) { return vq * vq_bytes; }
/* A new signal frame record sve_context encodes the SVE Registers on signal
* delivery. sve_context struct definition may be included in asm/sigcontext.h.
* We define sve_context_size which will be used by LLDB sve helper functions.
* More information on sve_context can be found in Linux kernel source tree at
* Documentation/arm64/sve.rst.
*/
const uint16_t sve_context_size = 16;
/*
* If the SVE registers are currently live for the thread at signal delivery,
* sve_context.head.size >=
* SigContextSize(vq_from_vl(sve_context.vl))
* and the register data may be accessed using the Sig*() functions.
*
* If sve_context.head.size <
* SigContextSize(vq_from_vl(sve_context.vl)),
* the SVE registers were not live for the thread and no register data
* is included: in this case, the Sig*() functions should not be
* used except for this check.
*
* The same convention applies when returning from a signal: a caller
* will need to remove or resize the sve_context block if it wants to
* make the SVE registers live when they were previously non-live or
* vice-versa. This may require the the caller to allocate fresh
* memory and/or move other context blocks in the signal frame.
*
* Changing the vector length during signal return is not permitted:
* sve_context.vl must equal the thread's current vector length when
* doing a sigreturn.
*
*
* Note: for all these functions, the "vq" argument denotes the SVE
* vector length in quadwords (i.e., units of 128 bits).
*
* The correct way to obtain vq is to use vq_from_vl(vl). The
* result is valid if and only if vl_valid(vl) is true. This is
* guaranteed for a struct sve_context written by the kernel.
*
*
* Additional functions describe the contents and layout of the payload.
* For each, Sig*Offset(args) is the start offset relative to
* the start of struct sve_context, and Sig*Size(args) is the
* size in bytes:
*
* x type description
* - ---- -----------
* REGS the entire SVE context
*
* ZREGS __uint128_t[num_of_zregs][vq] all Z-registers
* ZREG __uint128_t[vq] individual Z-register Zn
*
* PREGS uint16_t[num_of_pregs][vq] all P-registers
* PREG uint16_t[vq] individual P-register Pn
*
* FFR uint16_t[vq] first-fault status register
*
* Additional data might be appended in the future.
*/
inline uint16_t SigZRegSize(uint16_t vq) { return vq * vq_bytes; }
inline uint16_t SigPRegSize(uint16_t vq) { return vq * vq_bytes / 8; }
inline uint16_t SigFFRSize(uint16_t vq) { return SigPRegSize(vq); }
inline uint32_t SigRegsOffset() {
return (sve_context_size + vq_bytes - 1) / vq_bytes * vq_bytes;
}
inline uint32_t SigZRegsOffset() { return SigRegsOffset(); }
inline uint32_t SigZRegOffset(uint16_t vq, uint16_t n) {
return SigRegsOffset() + SigZRegSize(vq) * n;
}
inline uint32_t SigZRegsSize(uint16_t vq) {
return SigZRegOffset(vq, num_of_zregs) - SigRegsOffset();
}
inline uint32_t SigPRegsOffset(uint16_t vq) {
return SigRegsOffset() + SigZRegsSize(vq);
}
inline uint32_t SigPRegOffset(uint16_t vq, uint16_t n) {
return SigPRegsOffset(vq) + SigPRegSize(vq) * n;
}
inline uint32_t SigpRegsSize(uint16_t vq) {
return SigPRegOffset(vq, num_of_pregs) - SigPRegsOffset(vq);
}
inline uint32_t SigFFROffset(uint16_t vq) {
return SigPRegsOffset(vq) + SigpRegsSize(vq);
}
inline uint32_t SigRegsSize(uint16_t vq) {
return SigFFROffset(vq) + SigFFRSize(vq) - SigRegsOffset();
}
inline uint32_t SVESigContextSize(uint16_t vq) {
return SigRegsOffset() + SigRegsSize(vq);
}
struct user_sve_header {
uint32_t size; /* total meaningful regset content in bytes */
uint32_t max_size; /* maxmium possible size for this thread */
uint16_t vl; /* current vector length */
uint16_t max_vl; /* maximum possible vector length */
uint16_t flags;
uint16_t reserved;
};
/* Definitions for user_sve_header.flags: */
const uint16_t ptrace_regs_mask = 1 << 0;
const uint16_t ptrace_regs_fpsimd = 0;
const uint16_t ptrace_regs_sve = ptrace_regs_mask;
/*
* The remainder of the SVE state follows struct user_sve_header. The
* total size of the SVE state (including header) depends on the
* metadata in the header: PTraceSize(vq, flags) gives the total size
* of the state in bytes, including the header.
*
* Refer to <asm/sigcontext.h> for details of how to pass the correct
* "vq" argument to these macros.
*/
/* Offset from the start of struct user_sve_header to the register data */
inline uint16_t PTraceRegsOffset() {
return (sizeof(struct user_sve_header) + vq_bytes - 1) / vq_bytes * vq_bytes;
}
/*
* The register data content and layout depends on the value of the
* flags field.
*/
/*
* (flags & ptrace_regs_mask) == ptrace_regs_fpsimd case:
*
* The payload starts at offset PTraceFPSIMDOffset, and is of type
* struct user_fpsimd_state. Additional data might be appended in the
* future: use PTraceFPSIMDSize(vq, flags) to compute the total size.
* PTraceFPSIMDSize(vq, flags) will never be less than
* sizeof(struct user_fpsimd_state).
*/
const uint32_t ptrace_fpsimd_offset = PTraceRegsOffset();
/* Return size of struct user_fpsimd_state from asm/ptrace.h */
inline uint32_t PTraceFPSIMDSize(uint16_t vq, uint16_t flags) { return 528; }
/*
* (flags & ptrace_regs_mask) == ptrace_regs_sve case:
*
* The payload starts at offset PTraceSVEOffset, and is of size
* PTraceSVESize(vq, flags).
*
* Additional functions describe the contents and layout of the payload.
* For each, PTrace*X*Offset(args) is the start offset relative to
* the start of struct user_sve_header, and PTrace*X*Size(args) is
* the size in bytes:
*
* x type description
* - ---- -----------
* ZREGS \
* ZREG |
* PREGS | refer to <asm/sigcontext.h>
* PREG |
* FFR /
*
* FPSR uint32_t FPSR
* FPCR uint32_t FPCR
*
* Additional data might be appended in the future.
*/
inline uint32_t PTraceZRegSize(uint16_t vq) { return SigZRegSize(vq); }
inline uint32_t PTracePRegSize(uint16_t vq) { return SigPRegSize(vq); }
inline uint32_t PTraceFFRSize(uint16_t vq) { return SigFFRSize(vq); }
const uint32_t fpsr_size = sizeof(uint32_t);
const uint32_t fpcr_size = sizeof(uint32_t);
inline uint32_t SigToPTrace(uint32_t offset) {
return offset - SigRegsOffset() + PTraceRegsOffset();
}
const uint32_t ptrace_sve_offset = PTraceRegsOffset();
inline uint32_t PTraceZRegsOffset(uint16_t vq) {
return SigToPTrace(SigZRegsOffset());
}
inline uint32_t PTraceZRegOffset(uint16_t vq, uint16_t n) {
return SigToPTrace(SigZRegOffset(vq, n));
}
inline uint32_t PTraceZRegsSize(uint16_t vq) {
return PTraceZRegOffset(vq, num_of_zregs) - SigToPTrace(SigRegsOffset());
}
inline uint32_t PTracePRegsOffset(uint16_t vq) {
return SigToPTrace(SigPRegsOffset(vq));
}
inline uint32_t PTracePRegOffset(uint16_t vq, uint16_t n) {
return SigToPTrace(SigPRegOffset(vq, n));
}
inline uint32_t PTracePRegsSize(uint16_t vq) {
return PTracePRegOffset(vq, num_of_pregs) - PTracePRegsOffset(vq);
}
inline uint32_t PTraceFFROffset(uint16_t vq) {
return SigToPTrace(SigFFROffset(vq));
}
inline uint32_t PTraceFPSROffset(uint16_t vq) {
return (PTraceFFROffset(vq) + PTraceFFRSize(vq) + (vq_bytes - 1)) / vq_bytes *
vq_bytes;
}
inline uint32_t PTraceFPCROffset(uint16_t vq) {
return PTraceFPSROffset(vq) + fpsr_size;
}
/*
* Any future extension appended after FPCR must be aligned to the next
* 128-bit boundary.
*/
inline uint32_t PTraceSVESize(uint16_t vq, uint16_t flags) {
return (PTraceFPCROffset(vq) + fpcr_size - ptrace_sve_offset + vq_bytes - 1) /
vq_bytes * vq_bytes;
}
inline uint32_t PTraceSize(uint16_t vq, uint16_t flags) {
return (flags & ptrace_regs_mask) == ptrace_regs_sve
? ptrace_sve_offset + PTraceSVESize(vq, flags)
: ptrace_fpsimd_offset + PTraceFPSIMDSize(vq, flags);
}
} // namespace SVE
} // namespace lldb_private
#endif // LLDB_SOURCE_PLUGINS_PROCESS_UTILITY_LINUXPTRACEDEFINES_ARM64SVE_H
|
