#include "oakdsp.hpp" #include #include int data_id; //-------------------------------------------------------------------------- static const char *const register_names[] = { "r0", "r1", "r2", "r3", "r4", "r5", // DAAU Registers "rb", // Base Register "y", // Input Register "st0", "st1", "st2", // Status Registers "p", // Output Register "pc", // Program Counter "sp", // Software Stack Pointer "cfgi", "cfgj", // DAAU Configuration Registers "b0h", "b1h", "b0l", "b1l", // Accumulator B "ext0","ext1", "ext2", "ext3", // External registers "a0", "a1", "a0l", "a1l", "a0h", "a1h", // Accumulator A "lc", // Loop Counter "sv", // Shift Value Register "x", // Input Register "dvm", // Data Value Match Register "mixp", // Minimal/Maximal Pointer Register "icr", // Internal Configuration Register "ps", // Product Shifter Control "repc", // Internal Repeat Counter "b0", "b1", // Accumulator B "modi", "modj", // Modulo Modifier "stepi","stepj", // Linear (Step) Modifier "page", // Short Direct Addressing Mode Page "cs","ds", // virtual registers for code and data segments }; //-------------------------------------------------------------------------- static const uchar retcode_0[] = { 0x45, 0xc0 }; static const uchar retcode_1[] = { 0x45, 0xd0 }; static const uchar retcode_2[] = { 0x45, 0x80 }; static const bytes_t retcodes[] = { { sizeof(retcode_0), retcode_0 }, { sizeof(retcode_1), retcode_1 }, { sizeof(retcode_2), retcode_2 }, { 0, NULL } }; //----------------------------------------------------------------------- // Dsp Group OAK DSP Assembler //----------------------------------------------------------------------- static const asm_t oakasm = { ASH_HEXF4 // $34 |ASD_DECF0 // 34 |ASB_BINF2 // %01010 |ASO_OCTF1 // 0123 |AS_COLON |AS_N2CHR |AS_NCMAS |AS_ONEDUP, 0, "Dsp Group OAK DSP Assembler", 0, NULL, // header lines "org", // org "end", // end ";", // comment string '"', // string delimiter '\'', // char delimiter "\"'", // special symbols in char and string constants "dc", // ascii string directive "dcb", // byte directive "dc", // word directive NULL, // double words NULL, // qwords NULL, // oword (16 bytes) NULL, // float (4 bytes) NULL, // double (8 bytes) NULL, // tbyte (10/12 bytes) NULL, // packed decimal real "bs#s(c,) #d, #v", // arrays (#h,#d,#v,#s(...) "ds %s", // uninited arrays "equ", // equ NULL, // 'seg' prefix (example: push seg seg001) "*", // current IP (instruction pointer) NULL, // func_header NULL, // func_footer "global", // "public" name keyword NULL, // "weak" name keyword "xref", // "extrn" name keyword // .extern directive requires an explicit object size NULL, // "comm" (communal variable) NULL, // const char *(*get_type_name)(int32 flag,uint32 id); NULL, // "align" keyword '(', ')', // lbrace, rbrace "%", // mod "&", // and "|", // or "^", // xor "~", // not "<<", // shl ">>", // shr NULL, // sizeof AS2_BYTE1CHAR,// One symbol per processor byte }; //----------------------------------------------------------------------- // GNU ASM //----------------------------------------------------------------------- static const asm_t gas = { AS_ASCIIC |ASH_HEXF4 // $34 |ASD_DECF0 // 34 |ASB_BINF3 // 0b01010 |ASO_OCTF1 // 0123 |AS_COLON |AS_N2CHR |AS_NCMAS |AS_ONEDUP, UAS_GNU, "GNU-like hypothetical assembler", 0, NULL, // header lines ".org", // org NULL, // end ";", // comment string '"', // string delimiter '\'', // char delimiter "\"'", // special symbols in char and string constants ".string", // ascii string directive ".byte", // byte directive ".short", // word directive ".long", // double words NULL, // qwords NULL, // oword (16 bytes) NULL, // float (4 bytes) NULL, // double (8 bytes) NULL, // tbyte (10/12 bytes) NULL, // packed decimal real ".ds.#s(b,w,l,d) #d, #v", // arrays (#h,#d,#v,#s(...) ".space %s", // uninited arrays "=", // equ NULL, // 'seg' prefix (example: push seg seg001) ".", // current IP (instruction pointer) NULL, // func_header NULL, // func_footer ".global", // "public" name keyword NULL, // "weak" name keyword ".extern", // "extrn" name keyword // .extern directive requires an explicit object size ".comm", // "comm" (communal variable) NULL, // const char *(*get_type_name)(int32 flag,uint32 id); ".align", // "align" keyword '(', ')', // lbrace, rbrace "mod", // mod "and", // and "or", // or "xor", // xor "not", // not "shl", // shl "shr", // shr NULL, // sizeof AS2_BYTE1CHAR,// One symbol per processor byte NULL, // cmnt2 NULL, // low8 NULL, // high8 NULL, // low16 NULL, // high16 "#include \"%s\"", // a_include_fmt }; static const asm_t *const asms[] = { &oakasm, &gas, NULL }; //---------------------------------------------------------------------- ea_t oakdsp_t::add_data_segm(size_t size, int offset, const char *name) const { segment_t s; s.start_ea = free_chunk(0x1000000, size, 0xF); s.end_ea = s.start_ea + size; s.sel = allocate_selector((s.start_ea-offset) >> 4); s.type = SEG_DATA; s.bitness = ph.dnbits > 16; add_segm_ex(&s, name, "DATA", ADDSEG_NOSREG|ADDSEG_OR_DIE); return s.start_ea - offset; } inline ea_t get_start(const segment_t *s) { return s ? s->start_ea : BADADDR; } //-------------------------------------------------------------------------- const char *oakdsp_iohandler_t::iocallback(const ioports_t &lports, const char *line) { int size; if ( qsscanf(line, "XMEMSIZE = %i", &size) == 1 ) { pm.xmemsize = size; pm.ioh.deviceparams.sprnt("XMEM=0x%X", pm.xmemsize); return NULL; } return standard_callback(lports, line); } const ioport_t *oakdsp_t::find_port(ea_t address) { return find_ioport(ioh.ports, address); } //-------------------------------------------------------------------------- void oakdsp_t::create_xmem(void) { if ( xmem == BADADDR ) xmem = add_data_segm(xmemsize, 0, "XMEM"); } //-------------------------------------------------------------------------- void oakdsp_t::select_device(const char *dname, int lrespect_info) { ioh.set_device_name(dname, lrespect_info); create_xmem(); for ( int i=0; i < ioh.ports.size(); i++ ) { const ioport_t &p = ioh.ports[i]; ea_t ea = xmem + p.address; const char *name = p.name.c_str(); ea_t nameea = get_name_ea(BADADDR, name); if ( nameea != ea ) { set_name(nameea, ""); if ( !set_name(ea, name, SN_NOCHECK|SN_NOWARN|SN_NODUMMY) ) set_cmt(ea, name, 0); } } } //-------------------------------------------------------------------------- const char *oakdsp_t::set_idp_options( const char *keyword, int /*value_type*/, const void * /*value*/, bool /*idb_loaded*/) { if ( keyword != NULL ) return IDPOPT_BADKEY; char cfgfile[QMAXFILE]; ioh.get_cfg_filename(cfgfile, sizeof(cfgfile)); if ( choose_ioport_device(&ioh.device, cfgfile) ) select_device(ioh.device.c_str(), IORESP_INT); return IDPOPT_OK; } //----------------------------------------------------------------------- // We always return "yes" because of the messy problem that // there are additional operands with a wrong operand number (always 1) static bool idaapi can_have_type(const op_t &) { return true; } //---------------------------------------------------------------------- // This old-style callback only returns the processor module object. static ssize_t idaapi notify(void *, int msgid, va_list) { if ( msgid == processor_t::ev_get_procmod ) return size_t(SET_MODULE_DATA(oakdsp_t)); return 0; } //-------------------------------------------------------------------------- void oakdsp_t::load_from_idb() { xmem = get_start(get_segm_by_name("XMEM")); char dev[MAXSTR]; char *pdev = helper.supstr(-1, dev, sizeof(dev)) > 0 ? dev : NULL; select_device(pdev, IORESP_NONE); } //-------------------------------------------------------------------------- ssize_t idaapi oakdsp_t::on_event(ssize_t msgid, va_list va) { int code = 0; switch ( msgid ) { case processor_t::ev_init: helper.create(PROCMOD_NODE_NAME); init_emu(); break; case processor_t::ev_term: ioh.ports.clear(); clr_module_data(data_id); break; case processor_t::ev_newfile: // new file loaded { char cfgfile[QMAXFILE]; ioh.get_cfg_filename(cfgfile, sizeof(cfgfile)); iohandler_t::parse_area_line0_t cb(ioh); if ( choose_ioport_device2(&ioh.device, cfgfile, &cb) ) select_device(ioh.device.c_str(), IORESP_AREA|IORESP_INT); else create_xmem(); segment_t *s0 = get_first_seg(); if ( s0 != NULL ) { segment_t *s1 = get_next_seg(s0->start_ea); for ( int i = PAGE; i <= vDS; i++ ) { set_default_sreg_value(s0, i, BADSEL); set_default_sreg_value(s1, i, BADSEL); } } } break; case processor_t::ev_ending_undo: procnum = ph.get_proc_index(); //fall through case processor_t::ev_oldfile: // old file loaded load_from_idb(); break; case processor_t::ev_newprc: // new processor type { int n = va_arg(va, int); // bool keep_cfg = va_argi(va, bool); if ( procnum == -1 ) { procnum = n; } else if ( procnum != n ) // can't change the processor type { // after the initial set up warning("Sorry, processor type cannot be changed after loading"); code = -1; break; } } break; case processor_t::ev_is_sane_insn: { const insn_t *insn = va_arg(va, insn_t *); int nocrefs = va_arg(va, int); return is_sane_insn(*insn, nocrefs) == 1 ? 1 : -1; } case processor_t::ev_may_be_func: // can a function start here? // arg: instruction // returns: probability 0..100 { const insn_t *insn = va_arg(va, insn_t *); return may_be_func(*insn); } case processor_t::ev_out_header: { outctx_t *ctx = va_arg(va, outctx_t *); oakdsp_header(*ctx); return 1; } case processor_t::ev_out_footer: { outctx_t *ctx = va_arg(va, outctx_t *); oakdsp_footer(*ctx); return 1; } case processor_t::ev_out_segstart: { outctx_t *ctx = va_arg(va, outctx_t *); segment_t *seg = va_arg(va, segment_t *); oakdsp_segstart(*ctx, seg); return 1; } case processor_t::ev_out_segend: { outctx_t *ctx = va_arg(va, outctx_t *); segment_t *seg = va_arg(va, segment_t *); oakdsp_segend(*ctx, seg); return 1; } case processor_t::ev_out_assumes: { outctx_t *ctx = va_arg(va, outctx_t *); oakdsp_assumes(*ctx); return 1; } case processor_t::ev_ana_insn: { insn_t *out = va_arg(va, insn_t *); return ana(out); } case processor_t::ev_emu_insn: { const insn_t *insn = va_arg(va, const insn_t *); return emu(*insn) ? 1 : -1; } case processor_t::ev_out_insn: { outctx_t *ctx = va_arg(va, outctx_t *); out_insn(*ctx); return 1; } case processor_t::ev_out_operand: { outctx_t *ctx = va_arg(va, outctx_t *); const op_t *_op = va_arg(va, const op_t *); return out_opnd(*ctx, *_op) ? 1 : -1; } case processor_t::ev_can_have_type: { const op_t *_op = va_arg(va, const op_t *); return can_have_type(*_op) ? 1 : -1; } case processor_t::ev_is_sp_based: { int *mode = va_arg(va, int *); const insn_t *insn = va_arg(va, const insn_t *); const op_t *_op = va_arg(va, const op_t *); *mode = is_sp_based(*insn, *_op); return 1; } case processor_t::ev_create_func_frame: { func_t *pfn = va_arg(va, func_t *); create_func_frame(pfn); return 1; } case processor_t::ev_get_frame_retsize: { int *frsize = va_arg(va, int *); const func_t *pfn = va_arg(va, const func_t *); *frsize = OAK_get_frame_retsize(pfn); return 1; } case processor_t::ev_gen_stkvar_def: { outctx_t *ctx = va_arg(va, outctx_t *); const member_t *mptr = va_arg(va, const member_t *); sval_t v = va_arg(va, sval_t); gen_stkvar_def(*ctx, mptr, v); return 1; } case processor_t::ev_set_idp_options: { const char *keyword = va_arg(va, const char *); int value_type = va_arg(va, int); const char *value = va_arg(va, const char *); const char **errmsg = va_arg(va, const char **); bool idb_loaded = va_argi(va, bool); const char *ret = set_idp_options(keyword, value_type, value, idb_loaded); if ( ret == IDPOPT_OK ) return 1; if ( errmsg != NULL ) *errmsg = ret; return -1; } case processor_t::ev_is_align_insn: { ea_t ea = va_arg(va, ea_t); return is_align_insn(ea); } default: break; } return code; } //----------------------------------------------------------------------- #define FAMILY "Atmel OAK DSP:" static const char *const shnames[] = { "oakdsp", NULL }; static const char *const lnames[] = { FAMILY"Dsp Group OAK DSP", NULL }; //----------------------------------------------------------------------- // Processor Definition //----------------------------------------------------------------------- processor_t LPH = { IDP_INTERFACE_VERSION, // version PLFM_OAKDSP, // id // flag PRN_HEX | PR_SEGS // has segment registers | PR_ALIGN // data items must be aligned | PR_BINMEM // module knows about memory organization | PR_ALIGN_INSN, // allow align instructions // flag2 PR2_IDP_OPTS, // the module has processor-specific configuration options 16, // 16 bits in a byte for code segments 16, // 16 bits in a byte for other segments shnames, lnames, asms, notify, register_names, // Register names qnumber(register_names), // Number of registers PAGE, // first vDS, // last 1, // size of a segment register vCS, vDS, NULL, // No known code start sequences retcodes, OAK_Dsp_null, OAK_Dsp_last, Instructions, // instruc 0, // int tbyte_size; -- doesn't exist { 0, 7, 15, 0 }, // char real_width[4]; // number of symbols after decimal point // 2byte float (0-does not exist) // normal float // normal double // long double OAK_Dsp_ret, // Icode of return instruction. It is ok to give any of possible return instructions };