Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Jarkko Sakkinen | 481 | 96.20% | 1 | 50.00% |
Sean Christopherson | 19 | 3.80% | 1 | 50.00% |
Total | 500 | 2 |
/* SPDX-License-Identifier: GPL-2.0 */ #ifndef _X86_ENCLS_H #define _X86_ENCLS_H #include <linux/bitops.h> #include <linux/err.h> #include <linux/io.h> #include <linux/rwsem.h> #include <linux/types.h> #include <asm/asm.h> #include <asm/traps.h> #include "sgx.h" /** * ENCLS_FAULT_FLAG - flag signifying an ENCLS return code is a trapnr * * ENCLS has its own (positive value) error codes and also generates * ENCLS specific #GP and #PF faults. And the ENCLS values get munged * with system error codes as everything percolates back up the stack. * Unfortunately (for us), we need to precisely identify each unique * error code, e.g. the action taken if EWB fails varies based on the * type of fault and on the exact SGX error code, i.e. we can't simply * convert all faults to -EFAULT. * * To make all three error types coexist, we set bit 30 to identify an * ENCLS fault. Bit 31 (technically bits N:31) is used to differentiate * between positive (faults and SGX error codes) and negative (system * error codes) values. */ #define ENCLS_FAULT_FLAG 0x40000000 /* Retrieve the encoded trapnr from the specified return code. */ #define ENCLS_TRAPNR(r) ((r) & ~ENCLS_FAULT_FLAG) /* Issue a WARN() about an ENCLS function. */ #define ENCLS_WARN(r, name) { \ do { \ int _r = (r); \ WARN_ONCE(_r, "%s returned %d (0x%x)\n", (name), _r, _r); \ } while (0); \ } /* * encls_faulted() - Check if an ENCLS leaf faulted given an error code * @ret: the return value of an ENCLS leaf function call * * Return: * - true: ENCLS leaf faulted. * - false: Otherwise. */ static inline bool encls_faulted(int ret) { return ret & ENCLS_FAULT_FLAG; } /** * encls_failed() - Check if an ENCLS function failed * @ret: the return value of an ENCLS function call * * Check if an ENCLS function failed. This happens when the function causes a * fault that is not caused by an EPCM conflict or when the function returns a * non-zero value. */ static inline bool encls_failed(int ret) { if (encls_faulted(ret)) return ENCLS_TRAPNR(ret) != X86_TRAP_PF; return !!ret; } /** * __encls_ret_N - encode an ENCLS function that returns an error code in EAX * @rax: function number * @inputs: asm inputs for the function * * Emit assembly for an ENCLS function that returns an error code, e.g. EREMOVE. * And because SGX isn't complex enough as it is, function that return an error * code also modify flags. * * Return: * 0 on success, * SGX error code on failure */ #define __encls_ret_N(rax, inputs...) \ ({ \ int ret; \ asm volatile( \ "1: .byte 0x0f, 0x01, 0xcf;\n\t" \ "2:\n" \ ".section .fixup,\"ax\"\n" \ "3: orl $"__stringify(ENCLS_FAULT_FLAG)",%%eax\n" \ " jmp 2b\n" \ ".previous\n" \ _ASM_EXTABLE_FAULT(1b, 3b) \ : "=a"(ret) \ : "a"(rax), inputs \ : "memory", "cc"); \ ret; \ }) #define __encls_ret_1(rax, rcx) \ ({ \ __encls_ret_N(rax, "c"(rcx)); \ }) #define __encls_ret_2(rax, rbx, rcx) \ ({ \ __encls_ret_N(rax, "b"(rbx), "c"(rcx)); \ }) #define __encls_ret_3(rax, rbx, rcx, rdx) \ ({ \ __encls_ret_N(rax, "b"(rbx), "c"(rcx), "d"(rdx)); \ }) /** * __encls_N - encode an ENCLS function that doesn't return an error code * @rax: function number * @rbx_out: optional output variable * @inputs: asm inputs for the function * * Emit assembly for an ENCLS function that does not return an error code, e.g. * ECREATE. Leaves without error codes either succeed or fault. @rbx_out is an * optional parameter for use by EDGBRD, which returns the requested value in * RBX. * * Return: * 0 on success, * trapnr with ENCLS_FAULT_FLAG set on fault */ #define __encls_N(rax, rbx_out, inputs...) \ ({ \ int ret; \ asm volatile( \ "1: .byte 0x0f, 0x01, 0xcf;\n\t" \ " xor %%eax,%%eax;\n" \ "2:\n" \ ".section .fixup,\"ax\"\n" \ "3: orl $"__stringify(ENCLS_FAULT_FLAG)",%%eax\n" \ " jmp 2b\n" \ ".previous\n" \ _ASM_EXTABLE_FAULT(1b, 3b) \ : "=a"(ret), "=b"(rbx_out) \ : "a"(rax), inputs \ : "memory"); \ ret; \ }) #define __encls_2(rax, rbx, rcx) \ ({ \ unsigned long ign_rbx_out; \ __encls_N(rax, ign_rbx_out, "b"(rbx), "c"(rcx)); \ }) #define __encls_1_1(rax, data, rcx) \ ({ \ unsigned long rbx_out; \ int ret = __encls_N(rax, rbx_out, "c"(rcx)); \ if (!ret) \ data = rbx_out; \ ret; \ }) static inline int __ecreate(struct sgx_pageinfo *pginfo, void *secs) { return __encls_2(ECREATE, pginfo, secs); } static inline int __eextend(void *secs, void *addr) { return __encls_2(EEXTEND, secs, addr); } static inline int __eadd(struct sgx_pageinfo *pginfo, void *addr) { return __encls_2(EADD, pginfo, addr); } static inline int __einit(void *sigstruct, void *token, void *secs) { return __encls_ret_3(EINIT, sigstruct, secs, token); } static inline int __eremove(void *addr) { return __encls_ret_1(EREMOVE, addr); } static inline int __edbgwr(void *addr, unsigned long *data) { return __encls_2(EDGBWR, *data, addr); } static inline int __edbgrd(void *addr, unsigned long *data) { return __encls_1_1(EDGBRD, *data, addr); } static inline int __etrack(void *addr) { return __encls_ret_1(ETRACK, addr); } static inline int __eldu(struct sgx_pageinfo *pginfo, void *addr, void *va) { return __encls_ret_3(ELDU, pginfo, addr, va); } static inline int __eblock(void *addr) { return __encls_ret_1(EBLOCK, addr); } static inline int __epa(void *addr) { unsigned long rbx = SGX_PAGE_TYPE_VA; return __encls_2(EPA, rbx, addr); } static inline int __ewb(struct sgx_pageinfo *pginfo, void *addr, void *va) { return __encls_ret_3(EWB, pginfo, addr, va); } #endif /* _X86_ENCLS_H */
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