/* Disassembler code for CR16. Copyright (C) 2007-2014 Free Software Foundation, Inc. Contributed by M R Swami Reddy (MR.Swami.Reddy@nsc.com). This file is part of GAS, GDB and the GNU binutils. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street - Fifth Floor, Boston, MA 02110-1301, USA. */ #include "sysdep.h" #include "dis-asm.h" #include "opcode/cr16.h" #include "libiberty.h" /* String to print when opcode was not matched. */ #define ILLEGAL "illegal" /* Escape to 16-bit immediate. */ #define ESCAPE_16_BIT 0xB /* Extract 'n_bits' from 'a' starting from offset 'offs'. */ #define EXTRACT(a, offs, n_bits) \ (n_bits == 32 ? (((a) >> (offs)) & 0xffffffffL) \ : (((a) >> (offs)) & ((1 << (n_bits)) -1))) /* Set Bit Mask - a mask to set all bits starting from offset 'offs'. */ #define SBM(offs) ((((1 << (32 - offs)) -1) << (offs))) typedef struct { dwordU val; int nbits; } parameter; /* Structure to map valid 'cinv' instruction options. */ typedef struct { /* Cinv printed string. */ char *istr; /* Value corresponding to the string. */ char *ostr; } cinv_entry; /* CR16 'cinv' options mapping. */ const cinv_entry cr16_cinvs[] = { {"cinv[i]", "cinv [i]"}, {"cinv[i,u]", "cinv [i,u]"}, {"cinv[d]", "cinv [d]"}, {"cinv[d,u]", "cinv [d,u]"}, {"cinv[d,i]", "cinv [d,i]"}, {"cinv[d,i,u]", "cinv [d,i,u]"} }; /* Number of valid 'cinv' instruction options. */ static int NUMCINVS = ARRAY_SIZE (cr16_cinvs); /* Enum to distinguish different registers argument types. */ typedef enum REG_ARG_TYPE { /* General purpose register (r<N>). */ REG_ARG = 0, /*Processor register */ P_ARG, } REG_ARG_TYPE; /* Current opcode table entry we're disassembling. */ const inst *instruction; /* Current instruction we're disassembling. */ ins cr16_currInsn; /* The current instruction is read into 3 consecutive words. */ wordU cr16_words[3]; /* Contains all words in appropriate order. */ ULONGLONG cr16_allWords; /* Holds the current processed argument number. */ int processing_argument_number; /* Nonzero means a IMM4 instruction. */ int imm4flag; /* Nonzero means the instruction's original size is incremented (escape sequence is used). */ int size_changed; /* Print the constant expression length. */ static char * print_exp_len (int size) { switch (size) { case 4: case 5: case 6: case 8: case 14: case 16: return ":s"; case 20: case 24: case 32: return ":m"; case 48: return ":l"; default: return ""; } } /* Retrieve the number of operands for the current assembled instruction. */ static int get_number_of_operands (void) { int i; for (i = 0; instruction->operands[i].op_type && i < MAX_OPERANDS; i++) ; return i; } /* Return the bit size for a given operand. */ static int getbits (operand_type op) { if (op < MAX_OPRD) return cr16_optab[op].bit_size; return 0; } /* Return the argument type of a given operand. */ static argtype getargtype (operand_type op) { if (op < MAX_OPRD) return cr16_optab[op].arg_type; return nullargs; } /* Given a 'CC' instruction constant operand, return its corresponding string. This routine is used when disassembling the 'CC' instruction. */ static char * getccstring (unsigned cc_insn) { return (char *) cr16_b_cond_tab[cc_insn]; } /* Given a 'cinv' instruction constant operand, return its corresponding string. This routine is used when disassembling the 'cinv' instruction. */ static char * getcinvstring (const char *str) { const cinv_entry *cinv; for (cinv = cr16_cinvs; cinv < (cr16_cinvs + NUMCINVS); cinv++) if (strcmp (cinv->istr, str) == 0) return cinv->ostr; return ILLEGAL; } /* Given the trap index in dispatch table, return its name. This routine is used when disassembling the 'excp' instruction. */ static char * gettrapstring (unsigned int trap_index) { const trap_entry *trap; for (trap = cr16_traps; trap < cr16_traps + NUMTRAPS; trap++) if (trap->entry == trap_index) return trap->name; return ILLEGAL; } /* Given a register enum value, retrieve its name. */ static char * getregname (reg r) { const reg_entry * regentry = cr16_regtab + r; if (regentry->type != CR16_R_REGTYPE) return ILLEGAL; return regentry->name; } /* Given a register pair enum value, retrieve its name. */ static char * getregpname (reg r) { const reg_entry * regentry = cr16_regptab + r; if (regentry->type != CR16_RP_REGTYPE) return ILLEGAL; return regentry->name; } /* Given a index register pair enum value, retrieve its name. */ static char * getidxregpname (reg r) { const reg_entry * regentry; switch (r) { case 0: r = 0; break; case 1: r = 2; break; case 2: r = 4; break; case 3: r = 6; break; case 4: r = 8; break; case 5: r = 10; break; case 6: r = 3; break; case 7: r = 5; break; default: break; } regentry = cr16_regptab + r; if (regentry->type != CR16_RP_REGTYPE) return ILLEGAL; return regentry->name; } /* Getting a processor register name. */ static char * getprocregname (int reg_index) { const reg_entry *r; for (r = cr16_pregtab; r < cr16_pregtab + NUMPREGS; r++) if (r->image == reg_index) return r->name; return "ILLEGAL REGISTER"; } /* Getting a processor register name - 32 bit size. */ static char * getprocpregname (int reg_index) { const reg_entry *r; for (r = cr16_pregptab; r < cr16_pregptab + NUMPREGPS; r++) if (r->image == reg_index) return r->name; return "ILLEGAL REGISTER"; } /* START and END are relating 'cr16_allWords' struct, which is 48 bits size. START|--------|END +---------+---------+---------+---------+ | | V | A | L | +---------+---------+---------+---------+ 0 16 32 48 words [0] [1] [2] */ static parameter makelongparameter (ULONGLONG val, int start, int end) { parameter p; p.val = (dwordU) EXTRACT (val, 48 - end, end - start); p.nbits = end - start; return p; } /* Build a mask of the instruction's 'constant' opcode, based on the instruction's printing flags. */ static unsigned long build_mask (void) { unsigned long mask = SBM (instruction->match_bits); /* Adjust mask for bcond with 32-bit size instruction. */ if ((IS_INSN_MNEMONIC("b") && instruction->size == 2)) mask = 0xff0f0000; return mask; } /* Search for a matching opcode. Return 1 for success, 0 for failure. */ int cr16_match_opcode (void) { unsigned long mask; /* The instruction 'constant' opcode doesn't exceed 32 bits. */ unsigned long doubleWord = (cr16_words[1] + (cr16_words[0] << 16)) & 0xffffffff; /* Start searching from end of instruction table. */ instruction = &cr16_instruction[NUMOPCODES - 2]; /* Loop over instruction table until a full match is found. */ while (instruction >= cr16_instruction) { mask = build_mask (); /* Adjust mask for bcond with 32-bit size instruction */ if ((IS_INSN_MNEMONIC("b") && instruction->size == 2)) mask = 0xff0f0000; if ((doubleWord & mask) == BIN (instruction->match, instruction->match_bits)) return 1; else instruction--; } return 0; } /* Set the proper parameter value for different type of arguments. */ static void make_argument (argument * a, int start_bits) { int inst_bit_size; parameter p; if ((instruction->size == 3) && a->size >= 16) inst_bit_size = 48; else inst_bit_size = 32; switch (a->type) { case arg_r: p = makelongparameter (cr16_allWords, inst_bit_size - (start_bits + a->size), inst_bit_size - start_bits); a->r = p.val; break; case arg_rp: p = makelongparameter (cr16_allWords, inst_bit_size - (start_bits + a->size), inst_bit_size - start_bits); a->rp = p.val; break; case arg_pr: p = makelongparameter (cr16_allWords, inst_bit_size - (start_bits + a->size), inst_bit_size - start_bits); a->pr = p.val; break; case arg_prp: p = makelongparameter (cr16_allWords, inst_bit_size - (start_bits + a->size), inst_bit_size - start_bits); a->prp = p.val; break; case arg_ic: p = makelongparameter (cr16_allWords, inst_bit_size - (start_bits + a->size), inst_bit_size - start_bits); a->constant = p.val; break; case arg_cc: p = makelongparameter (cr16_allWords, inst_bit_size - (start_bits + a->size), inst_bit_size - start_bits); a->cc = p.val; break; case arg_idxr: if ((IS_INSN_MNEMONIC ("cbitb")) || (IS_INSN_MNEMONIC ("sbitb")) || (IS_INSN_MNEMONIC ("tbitb"))) p = makelongparameter (cr16_allWords, 8, 9); else p = makelongparameter (cr16_allWords, 9, 10); a->i_r = p.val; p = makelongparameter (cr16_allWords, inst_bit_size - a->size, inst_bit_size); a->constant = p.val; break; case arg_idxrp: p = makelongparameter (cr16_allWords, start_bits + 12, start_bits + 13); a->i_r = p.val; p = makelongparameter (cr16_allWords, start_bits + 13, start_bits + 16); a->rp = p.val; if (inst_bit_size > 32) { p = makelongparameter (cr16_allWords, inst_bit_size - start_bits - 12, inst_bit_size); a->constant = ((p.val & 0xffff) | (p.val >> 8 & 0xf0000)); } else if (instruction->size == 2) { p = makelongparameter (cr16_allWords, inst_bit_size - 22, inst_bit_size); a->constant = (p.val & 0xf) | (((p.val >>20) & 0x3) << 4) | ((p.val >>14 & 0x3) << 6) | (((p.val >>7) & 0x1f) <<7); } else if (instruction->size == 1 && a->size == 0) a->constant = 0; break; case arg_rbase: p = makelongparameter (cr16_allWords, inst_bit_size, inst_bit_size); a->constant = p.val; p = makelongparameter (cr16_allWords, inst_bit_size - (start_bits + 4), inst_bit_size - start_bits); a->r = p.val; break; case arg_cr: p = makelongparameter (cr16_allWords, start_bits + 12, start_bits + 16); a->r = p.val; p = makelongparameter (cr16_allWords, inst_bit_size - 16, inst_bit_size); a->constant = p.val; break; case arg_crp: if (instruction->size == 1) p = makelongparameter (cr16_allWords, 12, 16); else p = makelongparameter (cr16_allWords, start_bits + 12, start_bits + 16); a->rp = p.val; if (inst_bit_size > 32) { p = makelongparameter (cr16_allWords, inst_bit_size - start_bits - 12, inst_bit_size); a->constant = ((p.val & 0xffff) | (p.val >> 8 & 0xf0000)); } else if (instruction->size == 2) { p = makelongparameter (cr16_allWords, inst_bit_size - 16, inst_bit_size); a->constant = p.val; } else if (instruction->size == 1 && a->size != 0) { p = makelongparameter (cr16_allWords, 4, 8); if (IS_INSN_MNEMONIC ("loadw") || IS_INSN_MNEMONIC ("loadd") || IS_INSN_MNEMONIC ("storw") || IS_INSN_MNEMONIC ("stord")) a->constant = (p.val * 2); else a->constant = p.val; } else /* below case for 0x0(reg pair) */ a->constant = 0; break; case arg_c: if ((IS_INSN_TYPE (BRANCH_INS)) || (IS_INSN_MNEMONIC ("bal")) || (IS_INSN_TYPE (CSTBIT_INS)) || (IS_INSN_TYPE (LD_STOR_INS))) { switch (a->size) { case 8 : p = makelongparameter (cr16_allWords, 0, start_bits); a->constant = ((((p.val&0xf00)>>4)) | (p.val&0xf)); break; case 24: if (instruction->size == 3) { p = makelongparameter (cr16_allWords, 16, inst_bit_size); a->constant = ((((p.val>>16)&0xf) << 20) | (((p.val>>24)&0xf) << 16) | (p.val & 0xffff)); } else if (instruction->size == 2) { p = makelongparameter (cr16_allWords, 8, inst_bit_size); a->constant = p.val; } break; default: p = makelongparameter (cr16_allWords, inst_bit_size - (start_bits + a->size), inst_bit_size - start_bits); a->constant = p.val; break; } } else { p = makelongparameter (cr16_allWords, inst_bit_size - (start_bits + a->size), inst_bit_size - start_bits); a->constant = p.val; } break; default: break; } } /* Print a single argument. */ static void print_arg (argument *a, bfd_vma memaddr, struct disassemble_info *info) { LONGLONG longdisp, mask; int sign_flag = 0; int relative = 0; bfd_vma number; PTR stream = info->stream; fprintf_ftype func = info->fprintf_func; switch (a->type) { case arg_r: func (stream, "%s", getregname (a->r)); break; case arg_rp: func (stream, "%s", getregpname (a->rp)); break; case arg_pr: func (stream, "%s", getprocregname (a->pr)); break; case arg_prp: func (stream, "%s", getprocpregname (a->prp)); break; case arg_cc: func (stream, "%s", getccstring (a->cc)); func (stream, "%s", "\t"); break; case arg_ic: if (IS_INSN_MNEMONIC ("excp")) { func (stream, "%s", gettrapstring (a->constant)); break; } else if ((IS_INSN_TYPE (ARITH_INS) || IS_INSN_TYPE (ARITH_BYTE_INS)) && ((instruction->size == 1) && (a->constant == 9))) func (stream, "$%d", -1); else if (INST_HAS_REG_LIST) func (stream, "$0x%lx", a->constant +1); else if (IS_INSN_TYPE (SHIFT_INS)) { longdisp = a->constant; mask = ((LONGLONG)1 << a->size) - 1; if (longdisp & ((LONGLONG)1 << (a->size -1))) { sign_flag = 1; longdisp = ~(longdisp) + 1; } a->constant = (unsigned long int) (longdisp & mask); func (stream, "$%d", ((int)(sign_flag ? -a->constant : a->constant))); } else func (stream, "$0x%lx", a->constant); switch (a->size) { case 4 : case 5 : case 6 : case 8 : func (stream, "%s", ":s"); break; case 16 : case 20 : func (stream, "%s", ":m"); break; case 24 : case 32 : func (stream, "%s", ":l"); break; default: break; } break; case arg_idxr: if (a->i_r == 0) func (stream, "[r12]"); if (a->i_r == 1) func (stream, "[r13]"); func (stream, "0x%lx", a->constant); func (stream, "%s", print_exp_len (instruction->size * 16)); break; case arg_idxrp: if (a->i_r == 0) func (stream, "[r12]"); if (a->i_r == 1) func (stream, "[r13]"); func (stream, "0x%lx", a->constant); func (stream, "%s", print_exp_len (instruction->size * 16)); func (stream, "%s", getidxregpname (a->rp)); break; case arg_rbase: func (stream, "(%s)", getregname (a->r)); break; case arg_cr: func (stream, "0x%lx", a->constant); func (stream, "%s", print_exp_len (instruction->size * 16)); func (stream, "(%s)", getregname (a->r)); break; case arg_crp: func (stream, "0x%lx", a->constant); func (stream, "%s", print_exp_len (instruction->size * 16)); func (stream, "%s", getregpname (a->rp)); break; case arg_c: /*Removed the *2 part as because implicit zeros are no more required. Have to fix this as this needs a bit of extension in terms of branch instructions. */ if (IS_INSN_TYPE (BRANCH_INS) || IS_INSN_MNEMONIC ("bal")) { relative = 1; longdisp = a->constant; /* REVISIT: To sync with WinIDEA and CR16 4.1tools, the below line commented */ /* longdisp <<= 1; */ mask = ((LONGLONG)1 << a->size) - 1; switch (a->size) { case 8 : { longdisp <<= 1; if (longdisp & ((LONGLONG)1 << a->size)) { sign_flag = 1; longdisp = ~(longdisp) + 1; } break; } case 16 : case 24 : { if (longdisp & 1) { sign_flag = 1; longdisp = ~(longdisp) + 1; } break; } default: func (stream, "Wrong offset used in branch/bal instruction"); break; } a->constant = (unsigned long int) (longdisp & mask); } /* For branch Neq instruction it is 2*offset + 2. */ else if (IS_INSN_TYPE (BRANCH_NEQ_INS)) a->constant = 2 * a->constant + 2; if ((!IS_INSN_TYPE (CSTBIT_INS)) && (!IS_INSN_TYPE (LD_STOR_INS))) (sign_flag) ? func (stream, "%s", "*-"): func (stream, "%s","*+"); /* PR 10173: Avoid printing the 0x prefix twice. */ if (info->symtab_size > 0) func (stream, "%s", "0x"); number = ((relative ? memaddr : 0) + (sign_flag ? ((- a->constant) & 0xffffffe) : a->constant)); (*info->print_address_func) ((number & ((1 << 24) - 1)), info); func (stream, "%s", print_exp_len (instruction->size * 16)); break; default: break; } } /* Print all the arguments of CURRINSN instruction. */ static void print_arguments (ins *currentInsn, bfd_vma memaddr, struct disassemble_info *info) { int i; /* For "pop/push/popret RA instruction only. */ if ((IS_INSN_MNEMONIC ("pop") || (IS_INSN_MNEMONIC ("popret") || (IS_INSN_MNEMONIC ("push")))) && currentInsn->nargs == 1) { info->fprintf_func (info->stream, "RA"); return; } for (i = 0; i < currentInsn->nargs; i++) { processing_argument_number = i; /* For "bal (ra), disp17" instruction only. */ if ((IS_INSN_MNEMONIC ("bal")) && (i == 0) && instruction->size == 2) { info->fprintf_func (info->stream, "(ra),"); continue; } if ((INST_HAS_REG_LIST) && (i == 2)) info->fprintf_func (info->stream, "RA"); else print_arg (¤tInsn->arg[i], memaddr, info); if ((i != currentInsn->nargs - 1) && (!IS_INSN_MNEMONIC ("b"))) info->fprintf_func (info->stream, ","); } } /* Build the instruction's arguments. */ void cr16_make_instruction (void) { int i; unsigned int shift; for (i = 0; i < cr16_currInsn.nargs; i++) { argument a; memset (&a, 0, sizeof (a)); a.type = getargtype (instruction->operands[i].op_type); a.size = getbits (instruction->operands[i].op_type); shift = instruction->operands[i].shift; make_argument (&a, shift); cr16_currInsn.arg[i] = a; } /* Calculate instruction size (in bytes). */ cr16_currInsn.size = instruction->size + (size_changed ? 1 : 0); /* Now in bits. */ cr16_currInsn.size *= 2; } /* Retrieve a single word from a given memory address. */ static wordU get_word_at_PC (bfd_vma memaddr, struct disassemble_info *info) { bfd_byte buffer[4]; int status; wordU insn = 0; status = info->read_memory_func (memaddr, buffer, 2, info); if (status == 0) insn = (wordU) bfd_getl16 (buffer); return insn; } /* Retrieve multiple words (3) from a given memory address. */ static void get_words_at_PC (bfd_vma memaddr, struct disassemble_info *info) { int i; bfd_vma mem; for (i = 0, mem = memaddr; i < 3; i++, mem += 2) cr16_words[i] = get_word_at_PC (mem, info); cr16_allWords = ((ULONGLONG) cr16_words[0] << 32) + ((unsigned long) cr16_words[1] << 16) + cr16_words[2]; } /* Prints the instruction by calling print_arguments after proper matching. */ int print_insn_cr16 (bfd_vma memaddr, struct disassemble_info *info) { int is_decoded; /* Nonzero means instruction has a match. */ /* Initialize global variables. */ imm4flag = 0; size_changed = 0; /* Retrieve the encoding from current memory location. */ get_words_at_PC (memaddr, info); /* Find a matching opcode in table. */ is_decoded = cr16_match_opcode (); /* If found, print the instruction's mnemonic and arguments. */ if (is_decoded > 0 && (cr16_words[0] << 16 || cr16_words[1]) != 0) { if (strneq (instruction->mnemonic, "cinv", 4)) info->fprintf_func (info->stream,"%s", getcinvstring (instruction->mnemonic)); else info->fprintf_func (info->stream, "%s", instruction->mnemonic); if (((cr16_currInsn.nargs = get_number_of_operands ()) != 0) && ! (IS_INSN_MNEMONIC ("b"))) info->fprintf_func (info->stream, "\t"); cr16_make_instruction (); /* For push/pop/pushrtn with RA instructions. */ if ((INST_HAS_REG_LIST) && ((cr16_words[0] >> 7) & 0x1)) cr16_currInsn.nargs +=1; print_arguments (&cr16_currInsn, memaddr, info); return cr16_currInsn.size; } /* No match found. */ info->fprintf_func (info->stream,"%s ",ILLEGAL); return 2; }