/* * Libbacktrace * Copyright 2015 Stephen Street * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at https://www.mozilla.org/en-US/MPL/2.0/ * * This library was modified, some bugs fixed, stack address validated * and adapted to be used in Marlin 3D printer firmware as backtracer * for exceptions for debugging purposes in 2018 by Eduardo José Tagle. */ #if defined(__arm__) || defined(__thumb__) #include "unwarmbytab.h" #include #include /* These symbols point to the unwind index and should be provide by the linker script */ extern "C" const UnwTabEntry __exidx_start[]; extern "C" const UnwTabEntry __exidx_end[]; /* This prevents the linking of libgcc unwinder code */ void __aeabi_unwind_cpp_pr0() {}; void __aeabi_unwind_cpp_pr1() {}; void __aeabi_unwind_cpp_pr2() {}; static inline __attribute__((always_inline)) uint32_t prel31_to_addr(const uint32_t *prel31) { uint32_t offset = (((uint32_t)(*prel31)) << 1) >> 1; return ((uint32_t)prel31 + offset) & 0x7FFFFFFF; } static const UnwTabEntry *UnwTabSearchIndex(const UnwTabEntry *start, const UnwTabEntry *end, uint32_t ip) { const UnwTabEntry *middle; /* Perform a binary search of the unwind index */ while (start < end - 1) { middle = start + ((end - start + 1) >> 1); if (ip < prel31_to_addr(&middle->addr_offset)) end = middle; else start = middle; } return start; } /* * Get the function name or nullptr if not found */ static const char *UnwTabGetFunctionName(const UnwindCallbacks *cb, uint32_t address) { uint32_t flag_word = 0; if (!cb->readW(address-4,&flag_word)) return nullptr; if ((flag_word & 0xFF000000) == 0xFF000000) { return (const char *)(address - 4 - (flag_word & 0x00FFFFFF)); } return nullptr; } /** * Get the next frame unwinding instruction * * Return either the instruction or -1 to signal no more instructions * are available */ static int UnwTabGetNextInstruction(const UnwindCallbacks *cb, UnwTabState *ucb) { int instruction; /* Are there more instructions */ if (ucb->remaining == 0) return -1; /* Extract the current instruction */ uint32_t v = 0; if (!cb->readW(ucb->current, &v)) return -1; instruction = (v >> (ucb->byte << 3)) & 0xFF; /* Move the next byte */ --ucb->byte; if (ucb->byte < 0) { ucb->current += 4; ucb->byte = 3; } --ucb->remaining; return instruction; } /** * Initialize the frame unwinding state */ static UnwResult UnwTabStateInit(const UnwindCallbacks *cb, UnwTabState *ucb, uint32_t instructions, const UnwindFrame *frame) { /* Initialize control block */ memset(ucb, 0, sizeof(UnwTabState)); ucb->current = instructions; /* Is a short unwind description */ uint32_t v = 0; if (!cb->readW(instructions, &v)) return UNWIND_DREAD_W_FAIL; if ((v & 0xFF000000) == 0x80000000) { ucb->remaining = 3; ucb->byte = 2; /* Is a long unwind description */ } else if ((v & 0xFF000000) == 0x81000000) { ucb->remaining = ((v & 0x00FF0000) >> 14) + 2; ucb->byte = 1; } else return UNWIND_UNSUPPORTED_DWARF_PERSONALITY; /* Initialize the virtual register set */ ucb->vrs[7] = frame->fp; ucb->vrs[13] = frame->sp; ucb->vrs[14] = frame->lr; ucb->vrs[15] = 0; /* All good */ return UNWIND_SUCCESS; } /* * Execute unwinding instructions */ static UnwResult UnwTabExecuteInstructions(const UnwindCallbacks *cb, UnwTabState *ucb) { int instruction; uint32_t mask, reg, vsp; /* Consume all instruction byte */ while ((instruction = UnwTabGetNextInstruction(cb, ucb)) != -1) { if ((instruction & 0xC0) == 0x00) { // ARM_EXIDX_CMD_DATA_POP /* vsp = vsp + (xxxxxx << 2) + 4 */ ucb->vrs[13] += ((instruction & 0x3F) << 2) + 4; } else if ((instruction & 0xC0) == 0x40) { // ARM_EXIDX_CMD_DATA_PUSH /* vsp = vsp - (xxxxxx << 2) - 4 */ ucb->vrs[13] -= ((instruction & 0x3F) << 2) - 4; } else if ((instruction & 0xF0) == 0x80) { /* pop under mask {r15-r12},{r11-r4} or refuse to unwind */ instruction = instruction << 8 | UnwTabGetNextInstruction(cb, ucb); /* Check for refuse to unwind */ if (instruction == 0x8000) // ARM_EXIDX_CMD_REFUSED return UNWIND_REFUSED; /* Pop registers using mask */ // ARM_EXIDX_CMD_REG_POP vsp = ucb->vrs[13]; mask = instruction & 0xFFF; reg = 4; while (mask) { if ((mask & 1) != 0) { uint32_t v; if (!cb->readW(vsp,&v)) return UNWIND_DREAD_W_FAIL; ucb->vrs[reg] = v; v += 4; } mask >>= 1; ++reg; } /* Patch up the vrs sp if it was in the mask */ if (instruction & (1 << (13 - 4))) ucb->vrs[13] = vsp; } else if ((instruction & 0xF0) == 0x90 // ARM_EXIDX_CMD_REG_TO_SP && instruction != 0x9D && instruction != 0x9F ) { /* vsp = r[nnnn] */ ucb->vrs[13] = ucb->vrs[instruction & 0x0F]; } else if ((instruction & 0xF0) == 0xA0) { // ARM_EXIDX_CMD_REG_POP /* pop r4-r[4+nnn] or pop r4-r[4+nnn], r14*/ vsp = ucb->vrs[13]; for (reg = 4; reg <= uint32_t((instruction & 0x07) + 4); ++reg) { uint32_t v; if (!cb->readW(vsp,&v)) return UNWIND_DREAD_W_FAIL; ucb->vrs[reg] = v; vsp += 4; } if (instruction & 0x08) { // ARM_EXIDX_CMD_REG_POP uint32_t v; if (!cb->readW(vsp,&v)) return UNWIND_DREAD_W_FAIL; ucb->vrs[14] = v; vsp += 4; } ucb->vrs[13] = vsp; } else if (instruction == 0xB0) { // ARM_EXIDX_CMD_FINISH /* finished */ if (ucb->vrs[15] == 0) ucb->vrs[15] = ucb->vrs[14]; /* All done unwinding */ return UNWIND_SUCCESS; } else if (instruction == 0xB1) { // ARM_EXIDX_CMD_REG_POP /* pop register under mask {r3,r2,r1,r0} */ vsp = ucb->vrs[13]; mask = UnwTabGetNextInstruction(cb, ucb); reg = 0; while (mask) { if ((mask & 1) != 0) { uint32_t v; if (!cb->readW(vsp,&v)) return UNWIND_DREAD_W_FAIL; ucb->vrs[reg] = v; vsp += 4; } mask >>= 1; ++reg; } ucb->vrs[13] = (uint32_t)vsp; } else if (instruction == 0xB2) { // ARM_EXIDX_CMD_DATA_POP /* vps = vsp + 0x204 + (uleb128 << 2) */ ucb->vrs[13] += 0x204 + (UnwTabGetNextInstruction(cb, ucb) << 2); } else if (instruction == 0xB3 // ARM_EXIDX_CMD_VFP_POP || instruction == 0xC8 || instruction == 0xC9 ) { /* pop VFP double-precision registers */ vsp = ucb->vrs[13]; /* D[ssss]-D[ssss+cccc] */ uint32_t v; if (!cb->readW(vsp,&v)) return UNWIND_DREAD_W_FAIL; ucb->vrs[14] = v; vsp += 4; if (instruction == 0xC8) { /* D[16+sssss]-D[16+ssss+cccc] */ ucb->vrs[14] |= 1 << 16; } if (instruction != 0xB3) { /* D[sssss]-D[ssss+cccc] */ ucb->vrs[14] |= 1 << 17; } ucb->vrs[13] = vsp; } else if ((instruction & 0xF8) == 0xB8 || (instruction & 0xF8) == 0xD0) { /* Pop VFP double precision registers D[8]-D[8+nnn] */ ucb->vrs[14] = 0x80 | (instruction & 0x07); if ((instruction & 0xF8) == 0xD0) ucb->vrs[14] = 1 << 17; } else return UNWIND_UNSUPPORTED_DWARF_INSTR; } return UNWIND_SUCCESS; } static inline __attribute__((always_inline)) uint32_t read_psp() { /* Read the current PSP and return its value as a pointer */ uint32_t psp; __asm__ volatile ( " mrs %0, psp \n" : "=r" (psp) : : ); return psp; } /* * Unwind the specified frame and goto the previous one */ static UnwResult UnwTabUnwindFrame(const UnwindCallbacks *cb, UnwindFrame *frame) { UnwResult err; UnwTabState ucb; const UnwTabEntry *index; uint32_t instructions; /* Search the unwind index for the matching unwind table */ index = UnwTabSearchIndex(__exidx_start, __exidx_end, frame->pc); /* Make sure we can unwind this frame */ if (index->insn == 0x00000001) return UNWIND_SUCCESS; /* Get the pointer to the first unwind instruction */ if (index->insn & 0x80000000) instructions = (uint32_t)&index->insn; else instructions = prel31_to_addr(&index->insn); /* Initialize the unwind control block */ if ((err = UnwTabStateInit(cb, &ucb, instructions, frame)) < 0) return err; /* Execute the unwind instructions */ err = UnwTabExecuteInstructions(cb, &ucb); if (err < 0) return err; /* Set the virtual pc to the virtual lr if this is the first unwind */ if (ucb.vrs[15] == 0) ucb.vrs[15] = ucb.vrs[14]; /* Check for exception return */ /* TODO Test with other ARM processors to verify this method. */ if ((ucb.vrs[15] & 0xF0000000) == 0xF0000000) { /* According to the Cortex Programming Manual (p.44), the stack address is always 8-byte aligned (Cortex-M7). Depending on where the exception came from (MSP or PSP), we need the right SP value to work with. ucb.vrs[7] contains the right value, so take it and align it by 8 bytes, store it as the current SP to work with (ucb.vrs[13]) which is then saved as the current (virtual) frame's SP. */ uint32_t stack; ucb.vrs[13] = (ucb.vrs[7] & ~7); /* If we need to start from the MSP, we need to go down X words to find the PC, where: X=2 if it was a non-floating-point exception X=20 if it was a floating-point (VFP) exception If we need to start from the PSP, we need to go up exactly 6 words to find the PC. See the ARMv7-M Architecture Reference Manual p.594 and Cortex-M7 Processor Programming Manual p.44/p.45 for details. */ if ((ucb.vrs[15] & 0xC) == 0) { /* Return to Handler Mode: MSP (0xFFFFFF-1) */ stack = ucb.vrs[13]; /* The PC is always 2 words down from the MSP, if it was a non-floating-point exception */ stack -= 2*4; /* If there was a VFP exception (0xFFFFFFE1), the PC is located another 18 words down */ if ((ucb.vrs[15] & 0xF0) == 0xE0) { stack -= 18*4; } } else { /* Return to Thread Mode: PSP (0xFFFFFF-d) */ stack = read_psp(); /* The PC is always 6 words up from the PSP */ stack += 6*4; } /* Store the PC */ uint32_t v; if (!cb->readW(stack,&v)) return UNWIND_DREAD_W_FAIL; ucb.vrs[15] = v; stack -= 4; /* Store the LR */ if (!cb->readW(stack,&v)) return UNWIND_DREAD_W_FAIL; ucb.vrs[14] = v; stack -= 4; } /* We are done if current frame pc is equal to the virtual pc, prevent infinite loop */ if (frame->pc == ucb.vrs[15]) return UNWIND_SUCCESS; /* Update the frame */ frame->fp = ucb.vrs[7]; frame->sp = ucb.vrs[13]; frame->lr = ucb.vrs[14]; frame->pc = ucb.vrs[15]; /* All good - Continue unwinding */ return UNWIND_MORE_AVAILABLE; } UnwResult UnwindByTableStart(UnwindFrame* frame, const UnwindCallbacks *cb, void *data) { UnwResult err = UNWIND_SUCCESS; UnwReport entry; /* Use DWARF unwind information to unwind frames */ do { if (frame->pc == 0) { /* Reached __exidx_end. */ break; } if (frame->pc == 0x00000001) { /* Reached .cantunwind instruction. */ break; } /* Find the unwind index of the current frame pc */ const UnwTabEntry *index = UnwTabSearchIndex(__exidx_start, __exidx_end, frame->pc); /* Clear last bit (Thumb indicator) */ frame->pc &= 0xFFFFFFFEU; /* Generate the backtrace information */ entry.address = frame->pc; entry.function = prel31_to_addr(&index->addr_offset); entry.name = UnwTabGetFunctionName(cb, entry.function); if (!cb->report(data,&entry)) break; /* Unwind frame and repeat */ } while ((err = UnwTabUnwindFrame(cb, frame)) == UNWIND_MORE_AVAILABLE); /* All done */ return err; } #endif // __arm__ || __thumb__