#include #include #include #include #include "misc.h" #include "machine.h" #include "asmthumb.h" #define UNSIGNED_FIT8(x) (((x) & 0xffffff00) == 0) #define UNSIGNED_FIT16(x) (((x) & 0xffff0000) == 0) #define SIGNED_FIT8(x) (((x) & 0xffffff80) == 0) || (((x) & 0xffffff80) == 0xffffff80) #define SIGNED_FIT9(x) (((x) & 0xffffff00) == 0) || (((x) & 0xffffff00) == 0xffffff00) #define SIGNED_FIT12(x) (((x) & 0xfffff800) == 0) || (((x) & 0xfffff800) == 0xfffff800) struct _asm_thumb_t { int pass; uint code_offset; uint code_size; byte *code_base; byte dummy_data[8]; int next_label; int max_num_labels; int *label_offsets; int num_locals; uint push_reglist; uint stack_adjust; }; asm_thumb_t *asm_thumb_new(uint max_num_labels) { asm_thumb_t *as; as = m_new(asm_thumb_t, 1); as->pass = 0; as->code_offset = 0; as->code_size = 0; as->code_base = NULL; as->max_num_labels = max_num_labels; as->label_offsets = m_new(int, max_num_labels); as->num_locals = 0; return as; } void asm_thumb_free(asm_thumb_t *as, bool free_code) { if (free_code) { m_free(as->code_base); } /* if (as->label != NULL) { int i; for (i = 0; i < as->label->len; ++i) { Label *lab = &g_array_index(as->label, Label, i); if (lab->unresolved != NULL) g_array_free(lab->unresolved, true); } g_array_free(as->label, true); } */ m_free(as); } void asm_thumb_start_pass(asm_thumb_t *as, int pass) { as->pass = pass; as->code_offset = 0; as->next_label = 1; if (pass == ASM_THUMB_PASS_2) { memset(as->label_offsets, -1, as->max_num_labels * sizeof(int)); } } void asm_thumb_end_pass(asm_thumb_t *as) { if (as->pass == ASM_THUMB_PASS_2) { // calculate size of code in bytes as->code_size = as->code_offset; as->code_base = m_new(byte, as->code_size); printf("code_size: %u\n", as->code_size); } /* // check labels are resolved if (as->label != NULL) { int i; for (i = 0; i < as->label->len; ++i) if (g_array_index(as->label, Label, i).unresolved != NULL) return false; } */ } // all functions must go through this one to emit bytes static byte *asm_thumb_get_cur_to_write_bytes(asm_thumb_t *as, int num_bytes_to_write) { //printf("emit %d\n", num_bytes_to_write); if (as->pass < ASM_THUMB_PASS_3) { as->code_offset += num_bytes_to_write; return as->dummy_data; } else { assert(as->code_offset + num_bytes_to_write <= as->code_size); byte *c = as->code_base + as->code_offset; as->code_offset += num_bytes_to_write; return c; } } uint asm_thumb_get_code_size(asm_thumb_t *as) { return as->code_size; } void *asm_thumb_get_code(asm_thumb_t *as) { // need to set low bit to indicate that it's thumb code return (void *)(((machine_uint_t)as->code_base) | 1); } /* static void asm_thumb_write_byte_1(asm_thumb_t *as, byte b1) { byte *c = asm_thumb_get_cur_to_write_bytes(as, 1); c[0] = b1; } */ static void asm_thumb_write_op16(asm_thumb_t *as, uint op) { byte *c = asm_thumb_get_cur_to_write_bytes(as, 2); // little endian c[0] = op; c[1] = op >> 8; } static void asm_thumb_write_op32(asm_thumb_t *as, uint op1, uint op2) { byte *c = asm_thumb_get_cur_to_write_bytes(as, 4); // little endian, op1 then op2 c[0] = op1; c[1] = op1 >> 8; c[2] = op2; c[3] = op2 >> 8; } /* #define IMM32_L0(x) ((x) & 0xff) #define IMM32_L1(x) (((x) >> 8) & 0xff) #define IMM32_L2(x) (((x) >> 16) & 0xff) #define IMM32_L3(x) (((x) >> 24) & 0xff) static void asm_thumb_write_word32(asm_thumb_t *as, int w32) { byte *c = asm_thumb_get_cur_to_write_bytes(as, 4); c[0] = IMM32_L0(w32); c[1] = IMM32_L1(w32); c[2] = IMM32_L2(w32); c[3] = IMM32_L3(w32); } */ // rlolist is a bit map indicating desired lo-registers #define OP_PUSH_RLIST(rlolist) (0xb400 | (rlolist)) #define OP_PUSH_RLIST_LR(rlolist) (0xb400 | 0x0100 | (rlolist)) #define OP_POP_RLIST(rlolist) (0xbc00 | (rlolist)) #define OP_POP_RLIST_PC(rlolist) (0xbc00 | 0x0100 | (rlolist)) #define OP_ADD_SP(num_words) (0xb000 | (num_words)) #define OP_SUB_SP(num_words) (0xb080 | (num_words)) void asm_thumb_entry(asm_thumb_t *as, int num_locals) { // work out what to push and how many extra space to reserve on stack // so that we have enough for all locals and it's aligned an 8-byte boundary uint reglist; uint stack_adjust; if (num_locals < 0) { num_locals = 0; } // don't ppop r0 because it's used for return value switch (num_locals) { case 0: reglist = 0xf2; stack_adjust = 0; break; case 1: reglist = 0xf2; stack_adjust = 0; break; case 2: reglist = 0xfe; stack_adjust = 0; break; case 3: reglist = 0xfe; stack_adjust = 0; break; default: reglist = 0xfe; stack_adjust = ((num_locals - 3) + 1) & (~1); break; } asm_thumb_write_op16(as, OP_PUSH_RLIST_LR(reglist)); if (stack_adjust > 0) { asm_thumb_write_op16(as, OP_SUB_SP(stack_adjust)); } as->push_reglist = reglist; as->stack_adjust = stack_adjust; as->num_locals = num_locals; } void asm_thumb_exit(asm_thumb_t *as) { if (as->stack_adjust > 0) { asm_thumb_write_op16(as, OP_ADD_SP(as->stack_adjust)); } asm_thumb_write_op16(as, OP_POP_RLIST_PC(as->push_reglist)); } int asm_thumb_label_new(asm_thumb_t *as) { return as->next_label++; } void asm_thumb_label_assign(asm_thumb_t *as, int label) { assert(label < as->max_num_labels); if (as->pass == ASM_THUMB_PASS_2) { // assign label offset assert(as->label_offsets[label] == -1); as->label_offsets[label] = as->code_offset; } else if (as->pass == ASM_THUMB_PASS_3) { // ensure label offset has not changed from PASS_2 to PASS_3 //printf("l%d: (at %d=%ld)\n", label, as->label_offsets[label], as->code_offset); assert(as->label_offsets[label] == as->code_offset); } } static int get_label_dest(asm_thumb_t *as, int label) { assert(label < as->max_num_labels); return as->label_offsets[label]; } // the i8 value will be zero extended into the r32 register! void asm_thumb_mov_reg_i8(asm_thumb_t *as, uint rlo_dest, int i8) { assert(rlo_dest < REG_R8); // movs rlo_dest, #i8 asm_thumb_write_op16(as, 0x2000 | (rlo_dest << 8) | i8); } // if loading lo half, the i16 value will be zero extended into the r32 register! void asm_thumb_mov_i16_to_reg(asm_thumb_t *as, int i16, uint reg_dest, bool load_hi_half) { assert(reg_dest < REG_R15); uint op; if (load_hi_half) { // movt reg_dest, #i16 op = 0xf2c0; } else { // movw reg_dest, #i16 op = 0xf240; } asm_thumb_write_op32(as, op | ((i16 >> 1) & 0x0400) | ((i16 >> 12) & 0xf), ((i16 << 4) & 0x7000) | (reg_dest << 8) | (i16 & 0xff)); } void asm_thumb_mov_reg_i32(asm_thumb_t *as, uint reg_dest, machine_uint_t i32) { // movw, movt does it in 8 bytes // ldr [pc, #], dw does it in 6 bytes, but we might not reach to end of code for dw asm_thumb_mov_i16_to_reg(as, i32, reg_dest, false); asm_thumb_mov_i16_to_reg(as, i32 >> 16, reg_dest, true); } void asm_thumb_mov_reg_i32_optimised(asm_thumb_t *as, uint reg_dest, int i32) { if (reg_dest < 8 && UNSIGNED_FIT8(i32)) { asm_thumb_mov_reg_i8(as, reg_dest, i32); } else if (UNSIGNED_FIT16(i32)) { asm_thumb_mov_i16_to_reg(as, i32, reg_dest, false); } else { asm_thumb_mov_reg_i32(as, reg_dest, i32); } } void asm_thumb_mov_reg_reg(asm_thumb_t *as, uint reg_dest, uint reg_src) { uint op_lo; if (reg_src < 8) { op_lo = reg_src << 3; } else { op_lo = 0x40 | ((reg_src - 8) << 3); } if (reg_dest < 8) { op_lo |= reg_dest; } else { op_lo |= 0x80 | (reg_dest - 8); } asm_thumb_write_op16(as, 0x4600 | op_lo); } #define OP_STR_TO_SP_OFFSET(rlo_dest, word_offset) (0x9000 | ((rlo_dest) << 8) | ((word_offset) & 0x00ff)) #define OP_LDR_FROM_SP_OFFSET(rlo_dest, word_offset) (0x9800 | ((rlo_dest) << 8) | ((word_offset) & 0x00ff)) void asm_thumb_mov_local_reg(asm_thumb_t *as, int local_num, uint rlo_src) { assert(rlo_src < REG_R8); int word_offset = as->num_locals - local_num - 1; assert(as->pass < ASM_THUMB_PASS_3 || word_offset >= 0); asm_thumb_write_op16(as, OP_STR_TO_SP_OFFSET(rlo_src, word_offset)); } void asm_thumb_mov_reg_local(asm_thumb_t *as, uint rlo_dest, int local_num) { assert(rlo_dest < REG_R8); int word_offset = as->num_locals - local_num - 1; assert(as->pass < ASM_THUMB_PASS_3 || word_offset >= 0); asm_thumb_write_op16(as, OP_LDR_FROM_SP_OFFSET(rlo_dest, word_offset)); } void asm_thumb_mov_reg_local_addr(asm_thumb_t *as, uint reg_dest, int local_num) { assert(0); // see format 12, load address asm_thumb_write_op16(as, 0x0000); } #define OP_ADD_REG_REG_REG(rlo_dest, rlo_src_a, rlo_src_b) (0x1800 | ((rlo_src_b) << 6) | ((rlo_src_a) << 3) | (rlo_dest)) void asm_thumb_add_reg_reg_reg(asm_thumb_t *as, uint rlo_dest, uint rlo_src_a, uint rlo_src_b) { asm_thumb_write_op16(as, OP_ADD_REG_REG_REG(rlo_dest, rlo_src_a, rlo_src_b)); } #define OP_CMP_REG_REG(rlo_a, rlo_b) (0x4280 | ((rlo_b) << 3) | (rlo_a)) void asm_thumb_cmp_reg_reg(asm_thumb_t *as, uint rlo_a, uint rlo_b) { asm_thumb_write_op16(as, OP_CMP_REG_REG(rlo_a, rlo_b)); } void asm_thumb_ite_ge(asm_thumb_t *as) { asm_thumb_write_op16(as, 0xbfac); } #define OP_B(byte_offset) (0xe000 | (((byte_offset) >> 1) & 0x07ff)) // this could be wrong, because it should have a range of +/- 16MiB... #define OP_BW_HI(byte_offset) (0xf000 | (((byte_offset) >> 12) & 0x07ff)) #define OP_BW_LO(byte_offset) (0xb800 | (((byte_offset) >> 1) & 0x07ff)) void asm_thumb_b_label(asm_thumb_t *as, int label) { int dest = get_label_dest(as, label); int rel = dest - as->code_offset; rel -= 4; // account for instruction prefetch, PC is 4 bytes ahead of this instruction if (dest >= 0 && rel <= -4) { // is a backwards jump, so we know the size of the jump on the first pass // calculate rel assuming 12 bit relative jump if (SIGNED_FIT12(rel)) { asm_thumb_write_op16(as, OP_B(rel)); } else { goto large_jump; } } else { // is a forwards jump, so need to assume it's large large_jump: asm_thumb_write_op32(as, OP_BW_HI(rel), OP_BW_LO(rel)); } } #define OP_CMP_REG_IMM(rlo, i8) (0x2800 | ((rlo) << 8) | (i8)) // all these bit arithmetics need coverage testing! #define OP_BEQ(byte_offset) (0xd000 | (((byte_offset) >> 1) & 0x00ff)) #define OP_BEQW_HI(byte_offset) (0xf000 | (((byte_offset) >> 10) & 0x0400) | (((byte_offset) >> 14) & 0x003f)) #define OP_BEQW_LO(byte_offset) (0x8000 | ((byte_offset) & 0x2000) | (((byte_offset) >> 1) & 0x0fff)) void asm_thumb_cmp_reg_bz_label(asm_thumb_t *as, uint rlo, int label) { assert(rlo < REG_R8); // compare reg with 0 asm_thumb_write_op16(as, OP_CMP_REG_IMM(rlo, 0)); // branch if equal int dest = get_label_dest(as, label); int rel = dest - as->code_offset; rel -= 4; // account for instruction prefetch, PC is 4 bytes ahead of this instruction if (dest >= 0 && rel <= -4) { // is a backwards jump, so we know the size of the jump on the first pass // calculate rel assuming 12 bit relative jump if (SIGNED_FIT9(rel)) { asm_thumb_write_op16(as, OP_BEQ(rel)); } else { goto large_jump; } } else { // is a forwards jump, so need to assume it's large large_jump: asm_thumb_write_op32(as, OP_BEQW_HI(rel), OP_BEQW_LO(rel)); } } #define OP_BLX(reg) (0x4780 | ((reg) << 3)) #define OP_SVC(arg) (0xdf00 | (arg)) #define OP_LDR_FROM_BASE_OFFSET(rlo_dest, rlo_base, word_offset) (0x6800 | (((word_offset) << 6) & 0x07c0) | ((rlo_base) << 3) | (rlo_dest)) void asm_thumb_bl_ind(asm_thumb_t *as, void *fun_ptr, uint fun_id, uint reg_temp) { /* TODO make this use less bytes uint rlo_base = REG_R3; uint rlo_dest = REG_R7; uint word_offset = 4; asm_thumb_write_op16(as, 0x0000); asm_thumb_write_op16(as, 0x6800 | (word_offset << 6) | (rlo_base << 3) | rlo_dest); // ldr rlo_dest, [rlo_base, #offset] asm_thumb_write_op16(as, 0x4780 | (REG_R9 << 3)); // blx reg */ if (0) { // load ptr to function into register using immediate, then branch // not relocatable asm_thumb_mov_reg_i32(as, reg_temp, (machine_uint_t)fun_ptr); asm_thumb_write_op16(as, OP_BLX(reg_temp)); } else if (1) { asm_thumb_write_op16(as, OP_LDR_FROM_BASE_OFFSET(reg_temp, REG_R7, fun_id)); asm_thumb_write_op16(as, OP_BLX(reg_temp)); } else { // use SVC asm_thumb_write_op16(as, OP_SVC(fun_id)); } }