/* -*- mode: c; c-file-style: "bsd" -*- */ /* preproc.c macro preprocessor for the Netwide Assembler * * The Netwide Assembler is copyright (C) 1996 Simon Tatham and * Julian Hall. All rights reserved. The software is * redistributable under the licence given in the file "Licence" * distributed in the NASM archive. * * initial version 18/iii/97 by Simon Tatham */ /* Typical flow of text through preproc * * pp_getline gets tokenised lines, either * * from a macro expansion * * or * { * read_line gets raw text from stdmacpos, or predef, or current input file * tokenise converts to tokens * } * * expand_mmac_params is used to expand %1 etc., unless a macro is being * defined or a false conditional is being processed * (%0, %1, %+1, %-1, %%foo * * do_directive checks for directives * * expand_smacro is used to expand single line macros * * expand_mmacro is used to expand multi-line macros * * detoken is used to convert the line back to text */ #include #include #include #include #include #include #include #include #include #include "nasm.h" #include "nasmlib.h" #include "nasm-pp.h" typedef struct SMacro SMacro; typedef struct MMacro MMacro; typedef struct Context Context; typedef struct Token Token; typedef struct Blocks Blocks; typedef struct Line Line; typedef struct Include Include; typedef struct Cond Cond; /* * Store the definition of a single-line macro. */ struct SMacro { SMacro *next; char *name; int level; int casesense; int nparam; int in_progress; Token *expansion; }; /* * Store the definition of a multi-line macro. This is also used to * store the interiors of `%rep...%endrep' blocks, which are * effectively self-re-invoking multi-line macros which simply * don't have a name or bother to appear in the hash tables. %rep * blocks are signified by having a NULL `name' field. * * In a MMacro describing a `%rep' block, the `in_progress' field * isn't merely boolean, but gives the number of repeats left to * run. * * The `next' field is used for storing MMacros in hash tables; the * `next_active' field is for stacking them on istk entries. * * When a MMacro is being expanded, `params', `iline', `nparam', * `paramlen', `rotate' and `unique' are local to the invocation. */ struct MMacro { MMacro *next; char *name; int casesense; long nparam_min, nparam_max; int plus; /* is the last parameter greedy? */ int nolist; /* is this macro listing-inhibited? */ int in_progress; Token *dlist; /* All defaults as one list */ Token **defaults; /* Parameter default pointers */ int ndefs; /* number of default parameters */ Line *expansion; MMacro *next_active; MMacro *rep_nest; /* used for nesting %rep */ Token **params; /* actual parameters */ Token *iline; /* invocation line */ long nparam, rotate, *paramlen; unsigned long unique; int lineno; /* Current line number on expansion */ }; /* * The context stack is composed of a linked list of these. */ struct Context { Context *next; SMacro *localmac; char *name; unsigned long number; }; /* * This is the internal form which we break input lines up into. * Typically stored in linked lists. * * Note that `type' serves a double meaning: TOK_SMAC_PARAM is not * necessarily used as-is, but is intended to denote the number of * the substituted parameter. So in the definition * * %define a(x,y) ( (x) & ~(y) ) * * the token representing `x' will have its type changed to * TOK_SMAC_PARAM, but the one representing `y' will be * TOK_SMAC_PARAM+1. * * TOK_INTERNAL_STRING is a dirty hack: it's a single string token * which doesn't need quotes around it. Used in the pre-include * mechanism as an alternative to trying to find a sensible type of * quote to use on the filename we were passed. */ struct Token { Token *next; char *text; SMacro *mac; /* associated macro for TOK_SMAC_END */ int type; }; enum { TOK_WHITESPACE = 1, TOK_COMMENT, TOK_ID, TOK_PREPROC_ID, TOK_STRING, TOK_NUMBER, TOK_SMAC_END, TOK_OTHER, TOK_SMAC_PARAM, TOK_INTERNAL_STRING }; /* * Multi-line macro definitions are stored as a linked list of * these, which is essentially a container to allow several linked * lists of Tokens. * * Note that in this module, linked lists are treated as stacks * wherever possible. For this reason, Lines are _pushed_ on to the * `expansion' field in MMacro structures, so that the linked list, * if walked, would give the macro lines in reverse order; this * means that we can walk the list when expanding a macro, and thus * push the lines on to the `expansion' field in _istk_ in reverse * order (so that when popped back off they are in the right * order). It may seem cockeyed, and it relies on my design having * an even number of steps in, but it works... * * Some of these structures, rather than being actual lines, are * markers delimiting the end of the expansion of a given macro. * This is for use in the cycle-tracking and %rep-handling code. * Such structures have `finishes' non-NULL, and `first' NULL. All * others have `finishes' NULL, but `first' may still be NULL if * the line is blank. */ struct Line { Line *next; MMacro *finishes; Token *first; }; /* * To handle an arbitrary level of file inclusion, we maintain a * stack (ie linked list) of these things. */ struct Include { Include *next; FILE *fp; Cond *conds; Line *expansion; char *fname; int lineno, lineinc; MMacro *mstk; /* stack of active macros/reps */ }; /* * Conditional assembly: we maintain a separate stack of these for * each level of file inclusion. (The only reason we keep the * stacks separate is to ensure that a stray `%endif' in a file * included from within the true branch of a `%if' won't terminate * it and cause confusion: instead, rightly, it'll cause an error.) */ struct Cond { Cond *next; int state; }; enum { /* * These states are for use just after %if or %elif: IF_TRUE * means the condition has evaluated to truth so we are * currently emitting, whereas IF_FALSE means we are not * currently emitting but will start doing so if a %else comes * up. In these states, all directives are admissible: %elif, * %else and %endif. (And of course %if.) */ COND_IF_TRUE, COND_IF_FALSE, /* * These states come up after a %else: ELSE_TRUE means we're * emitting, and ELSE_FALSE means we're not. In ELSE_* states, * any %elif or %else will cause an error. */ COND_ELSE_TRUE, COND_ELSE_FALSE, /* * This state means that we're not emitting now, and also that * nothing until %endif will be emitted at all. It's for use in * two circumstances: (i) when we've had our moment of emission * and have now started seeing %elifs, and (ii) when the * condition construct in question is contained within a * non-emitting branch of a larger condition construct. */ COND_NEVER }; #define emitting(x) ( (x) == COND_IF_TRUE || (x) == COND_ELSE_TRUE ) /* * These defines are used as the possible return values for do_directive */ #define NO_DIRECTIVE_FOUND 0 #define DIRECTIVE_FOUND 1 /* * Condition codes. Note that we use c_ prefix not C_ because C_ is * used in nasm.h for the "real" condition codes. At _this_ level, * we treat CXZ and ECXZ as condition codes, albeit non-invertible * ones, so we need a different enum... */ static const char *conditions[] = { "a", "ae", "b", "be", "c", "cxz", "e", "ecxz", "g", "ge", "l", "le", "na", "nae", "nb", "nbe", "nc", "ne", "ng", "nge", "nl", "nle", "no", "np", "ns", "nz", "o", "p", "pe", "po", "s", "z" }; enum { c_A, c_AE, c_B, c_BE, c_C, c_CXZ, c_E, c_ECXZ, c_G, c_GE, c_L, c_LE, c_NA, c_NAE, c_NB, c_NBE, c_NC, c_NE, c_NG, c_NGE, c_NL, c_NLE, c_NO, c_NP, c_NS, c_NZ, c_O, c_P, c_PE, c_PO, c_S, c_Z }; static int inverse_ccs[] = { c_NA, c_NAE, c_NB, c_NBE, c_NC, -1, c_NE, -1, c_NG, c_NGE, c_NL, c_NLE, c_A, c_AE, c_B, c_BE, c_C, c_E, c_G, c_GE, c_L, c_LE, c_O, c_P, c_S, c_Z, c_NO, c_NP, c_PO, c_PE, c_NS, c_NZ }; /* * Directive names. */ static const char *directives[] = { "%arg", "%assign", "%clear", "%define", "%elif", "%elifctx", "%elifdef", "%elifid", "%elifidn", "%elifidni", "%elifmacro", "%elifnctx", "%elifndef", "%elifnid", "%elifnidn", "%elifnidni", "%elifnmacro", "%elifnnum", "%elifnstr", "%elifnum", "%elifstr", "%else", "%endif", "%endm", "%endmacro", "%endrep", "%endscope", "%error", "%exitrep", "%iassign", "%idefine", "%if", "%ifctx", "%ifdef", "%ifid", "%ifidn", "%ifidni", "%ifmacro", "%ifnctx", "%ifndef", "%ifnid", "%ifnidn", "%ifnidni", "%ifnmacro", "%ifnnum", "%ifnstr", "%ifnum", "%ifstr", "%imacro", "%include", "%ixdefine", "%line", "%local", "%macro", "%pop", "%push", "%rep", "%repl", "%rotate", "%scope", "%stacksize", "%strlen", "%substr", "%undef", "%xdefine" }; enum { PP_ARG, PP_ASSIGN, PP_CLEAR, PP_DEFINE, PP_ELIF, PP_ELIFCTX, PP_ELIFDEF, PP_ELIFID, PP_ELIFIDN, PP_ELIFIDNI, PP_ELIFMACRO, PP_ELIFNCTX, PP_ELIFNDEF, PP_ELIFNID, PP_ELIFNIDN, PP_ELIFNIDNI, PP_ELIFNMACRO, PP_ELIFNNUM, PP_ELIFNSTR, PP_ELIFNUM, PP_ELIFSTR, PP_ELSE, PP_ENDIF, PP_ENDM, PP_ENDMACRO, PP_ENDREP, PP_ENDSCOPE, PP_ERROR, PP_EXITREP, PP_IASSIGN, PP_IDEFINE, PP_IF, PP_IFCTX, PP_IFDEF, PP_IFID, PP_IFIDN, PP_IFIDNI, PP_IFMACRO, PP_IFNCTX, PP_IFNDEF, PP_IFNID, PP_IFNIDN, PP_IFNIDNI, PP_IFNMACRO, PP_IFNNUM, PP_IFNSTR, PP_IFNUM, PP_IFSTR, PP_IMACRO, PP_INCLUDE, PP_IXDEFINE, PP_LINE, PP_LOCAL, PP_MACRO, PP_POP, PP_PUSH, PP_REP, PP_REPL, PP_ROTATE, PP_SCOPE, PP_STACKSIZE, PP_STRLEN, PP_SUBSTR, PP_UNDEF, PP_XDEFINE }; /* If this is a an IF, ELIF, ELSE or ENDIF keyword */ static int is_condition(int arg) { return ((arg >= PP_ELIF) && (arg <= PP_ENDIF)) || ((arg >= PP_IF) && (arg <= PP_IFSTR)); } /* For TASM compatibility we need to be able to recognise TASM compatible * conditional compilation directives. Using the NASM pre-processor does * not work, so we look for them specifically from the following list and * then jam in the equivalent NASM directive into the input stream. */ #ifndef MAX # define MAX(a,b) ( ((a) > (b)) ? (a) : (b)) #endif enum { TM_ARG, TM_ELIF, TM_ELSE, TM_ENDIF, TM_IF, TM_IFDEF, TM_IFDIFI, TM_IFNDEF, TM_INCLUDE, TM_LOCAL, TM_REPT, TM_IRP, TM_MACRO, TM_STRUC, TM_SEGMENT }; static const char *tasm_directives[] = { "arg", "elif", "else", "endif", "if", "ifdef", "ifdifi", "ifndef", "include", "local" }; static int StackSize = 4; static const char *StackPointer = "ebp"; static int ArgOffset = 8; static int LocalOffset = 4; static int Level = 0; static Context *cstk; static Include *istk; static FILE *first_fp = NULL; static efunc _error; /* Pointer to client-provided error reporting function */ static evalfunc evaluate; static int pass; /* HACK: pass 0 = generate dependencies only */ static unsigned long unique; /* unique identifier numbers */ static Line *builtindef = NULL; static Line *stddef = NULL; static Line *predef = NULL; static int first_line = 1; static ListGen *list; /* * The number of hash values we use for the macro lookup tables. * FIXME: We should *really* be able to configure this at run time, * or even have the hash table automatically expanding when necessary. */ #define NHASH 31 /* * The current set of multi-line macros we have defined. */ static MMacro *mmacros[NHASH]; /* * The current set of single-line macros we have defined. */ static SMacro *smacros[NHASH]; /* * The multi-line macro we are currently defining, or the %rep * block we are currently reading, if any. */ static MMacro *defining; /* * The number of macro parameters to allocate space for at a time. */ #define PARAM_DELTA 16 /* * Macros to make NASM ignore some TASM directives before the first include * directive. */ static const char *tasm_compat_macros[] = { "%idefine IDEAL", "%idefine JUMPS", "%idefine END", "%idefine P8086 CPU 8086", "%idefine P186 CPU 186", "%idefine P286 CPU 286", "%idefine P286N CPU 286", "%idefine P286P CPU 286 Priv", "%idefine P386 CPU 386", "%idefine P386N CPU 386", "%idefine P386P CPU 386 Priv", "%idefine P486 CPU 486", "%idefine P586 CPU 586", "%idefine .8086 CPU 8086", "%idefine .186 CPU 186", "%idefine .286 CPU 286", "%idefine .286C CPU 286", "%idefine .286P CPU 286", "%idefine .386 CPU 386", "%idefine .386C CPU 386", "%idefine .386P CPU 386", "%idefine .486 CPU 486", "%idefine .486C CPU 486", "%idefine .486P CPU 486", "%idefine .586 CPU 586", "%idefine .586C CPU 586", "%idefine .586P CPU 586", "", "%imacro TITLE 1", "%endm", "%imacro NAME 1", "%endm", "", "%imacro EXTRN 1-*.nolist", "%rep %0", "[extern %1]", "%rotate 1", "%endrep", "%endmacro", "", "%imacro PUBLIC 1-*.nolist", "%rep %0", "[global %1]", "%rotate 1", "%endrep", "%endmacro", "", "; this is not needed", "%idefine PTR", NULL }; static int nested_mac_count, nested_rep_count; /* * Tokens are allocated in blocks to improve speed */ #define TOKEN_BLOCKSIZE 4096 static Token *freeTokens = NULL; struct Blocks { Blocks *next; void *chunk; }; static Blocks blocks = { NULL, NULL }; /* * Forward declarations. */ static Token *expand_mmac_params(Token * tline); static Token *expand_smacro(Token * tline); static Token *expand_id(Token * tline); static Context *get_ctx(char *name, int all_contexts); static void make_tok_num(Token * tok, yasm_intnum *val); static void error(int severity, const char *fmt, ...); static void *new_Block(size_t size); static void delete_Blocks(void); static Token *new_Token(Token * next, int type, const char *text, size_t txtlen); static Token *delete_Token(Token * t); static Token *tokenise(char *line); /* * Macros for safe checking of token pointers, avoid *(NULL) */ #define tok_type_(x,t) ((x) && (x)->type == (t)) #define skip_white_(x) if (tok_type_((x), TOK_WHITESPACE)) (x)=(x)->next #define tok_is_(x,v) (tok_type_((x), TOK_OTHER) && !strcmp((x)->text,(v))) #define tok_isnt_(x,v) ((x) && ((x)->type!=TOK_OTHER || strcmp((x)->text,(v)))) /* Handle TASM specific directives, which do not contain a % in * front of them. We do it here because I could not find any other * place to do it for the moment, and it is a hack (ideally it would * be nice to be able to use the NASM pre-processor to do it). */ typedef struct TMEndItem { int type; void *data; struct TMEndItem *next; } TMEndItem; static TMEndItem *EndmStack = NULL, *EndsStack = NULL; char **TMParameters; struct TStrucField { char *name; char *type; struct TStrucField *next; }; struct TStruc { char *name; struct TStrucField *fields, *lastField; struct TStruc *next; }; static struct TStruc *TStrucs = NULL; static int inTstruc = 0; struct TSegmentAssume { char *segreg; char *segment; }; struct TSegmentAssume *TAssumes; const char *tasm_get_segment_register(const char *segment) { struct TSegmentAssume *assume; if (!TAssumes) return NULL; for (assume = TAssumes; assume->segreg; assume++) { if (!strcmp(assume->segment, segment)) break; } return assume->segreg; } static char * check_tasm_directive(char *line) { int i, j, k, m; size_t len, len2; char *p, *oldline, oldchar, *q, oldchar2; TMEndItem *end; p = line; /* Skip whitespace */ while (isspace(*p) && *p != 0 && *p != ';') p++; /* Ignore nasm directives */ if (*p == '%') return line; /* Binary search for the directive name */ len = 0; while (!isspace(p[len]) && p[len] != 0 && p[len] != ';') len++; if (!len) return line; oldchar = p[len]; p[len] = 0; i = -1; j = elements(tasm_directives); while (j - i > 1) { k = (j + i) / 2; m = nasm_stricmp(p, tasm_directives[k]); if (m == 0) { /* We have found a directive, so jam a % in front of it * so that NASM will then recognise it as one if it's own. */ p[len] = oldchar; len = strlen(p); oldline = line; if (k == TM_IFDIFI) { /* NASM does not recognise IFDIFI, so we convert it to * %ifdef BOGUS. This is not used in NASM comaptible * code, but does need to parse for the TASM macro * package. */ line = nasm_malloc(13); strcpy(line, "%ifdef BOGUS"); } else if (k == TM_INCLUDE) { /* add double quotes around file name */ p += 7 + 1; while (isspace(*p) && *p) p++; len = strlen(p); line = nasm_malloc(1 + 7 + 1 + 1 + len + 1 + 1); sprintf(line, "%%include \"%s\"", p); } else { line = nasm_malloc(len + 2); line[0] = '%'; memcpy(line + 1, p, len + 1); } nasm_free(oldline); return line; } else if (m < 0) { j = k; } else i = k; } /* Not a simple directive */ if (!nasm_stricmp(p, "endm")) { /* handle end of endm directive */ char **parameter; end = EndmStack; /* undef parameters */ if (!end) { error(ERR_FATAL, "ENDM: not in an endm context"); return line; } EndmStack = EndmStack->next; nasm_free(line); switch (end->type) { case TM_MACRO: len = 0; for (parameter = end->data; *parameter; parameter++) len += 6 + 1 + strlen(*parameter) + 1; len += 5 + 1; line = nasm_malloc(len); p = line; for (parameter = end->data; *parameter; parameter++) { p += sprintf(p, "%%undef %s\n", *parameter); nasm_free(*parameter); } nasm_free(end->data); nasm_free(end); sprintf(p, "%%endm"); return line; case TM_REPT: nasm_free(end); return nasm_strdup("%endrep"); case TM_IRP: { char **data; const char *irp_format = "%%undef %s\n" "%%rotate 1\n" "%%endrep\n" "%%endm\n" "irp %s\n" "%%undef irp"; data = end->data; line = nasm_malloc(strlen(irp_format) - 4 + strlen(data[0]) + strlen(data[1])); sprintf(line, irp_format, data[0], data[1]); nasm_free(data[0]); nasm_free(data[1]); nasm_free(data); return line; } default: error(ERR_FATAL, "ENDM: bogus endm context type %d\n",end->type); return NULL; } } else if (!nasm_stricmp(p, "end")) { nasm_free(line); return nasm_strdup(""); } else if (!nasm_stricmp(p, "rept")) { /* handle repeat directive */ end = nasm_malloc(sizeof(*end)); end->type = TM_REPT; end->next = EndmStack; EndmStack = end; memcpy(p, "%rep", 4); p[len] = oldchar; return line; } else if (!nasm_stricmp(p, "locals")) { tasm_locals = 1; nasm_free(line); return nasm_strdup(""); } if (!oldchar) return line; /* handle two-words directives */ q = p + len + 1; /* Skip whitespaces */ while (isspace(*q) && *q) q++; len2 = 0; while (!isspace(q[len2]) && q[len2]!=',' && q[len2] != 0) len2++; oldchar2 = q[len2]; q[len2] = '\0'; if (!nasm_stricmp(p, "irp")) { /* handle indefinite repeat directive */ const char *irp_format = "%%imacro irp 0-*\n" "%%rep %%0\n" "%%define %s %%1\n"; char **data; data = malloc(2*sizeof(char*)); oldline = line; line = nasm_malloc(strlen(irp_format) - 2 + len2 + 1); sprintf(line,irp_format,q); data[0] = nasm_strdup(q); if (!oldchar2) error(ERR_FATAL, "%s: expected ", q + len2); p = strchr(q + len2 + 1, '<'); if (!p) error(ERR_FATAL, "%s: expected ", q + len2); p++; q = strchr(p, '>'); data[1] = nasm_strndup(p, q - p); end = nasm_malloc(sizeof(*end)); end->type = TM_IRP; end->next = EndmStack; end->data = data; EndmStack = end; nasm_free(oldline); return line; } else if (!nasm_stricmp(q, "macro")) { char *name = p; /* handle MACRO */ /* count parameters */ j = 1; i = 0; TMParameters = nasm_malloc(j*sizeof(*TMParameters)); len = 0; p = q + len2 + 1; /* Skip whitespaces */ while (isspace(*p) && *p) p++; while (*p) { /* Get parameter name */ for (q = p; !isspace(*q) && *q != ',' && *q; q++); len2 = q-p; if (len2 == 0) error(ERR_FATAL, "'%s': expected parameter name", p); TMParameters[i] = nasm_malloc(len2 + 1); memcpy(TMParameters[i], p, len2); TMParameters[i][len2] = '\0'; len += len2; i++; if (i + 1 > j) { j *= 2; TMParameters = nasm_realloc(TMParameters, j*sizeof(*TMParameters)); } if (i == 1000) error(ERR_FATAL, "too many parameters for macro %s", name); p = q; while (isspace(*p) && *p) p++; if (!*p) break; if (*p != ',') error(ERR_FATAL, "expected comma"); p++; while (isspace(*p) && *p) p++; } TMParameters[i] = NULL; TMParameters = nasm_realloc(TMParameters, (i+1)*sizeof(*TMParameters)); len += 1 + 6 + 1 + strlen(name) + 1 + 3; /* macro definition */ len += i * (1 + 9 + 1 + 1 + 1 + 3 + 2); /* macro parameter definition */ oldline = line; p = line = nasm_malloc(len + 1); p += sprintf(p, "%%imacro %s 0-*", name); nasm_free(oldline); for (j = 0; TMParameters[j]; j++) { p += sprintf(p, "\n%%idefine %s %%{%-u}", TMParameters[j], j + 1); } end = nasm_malloc(sizeof(*end)); end->type = TM_MACRO; end->next = EndmStack; end->data = TMParameters; EndmStack = end; return line; } else if (!nasm_stricmp(q, "proc")) { /* handle PROC */ oldline = line; line = nasm_malloc(2 + len + 1); sprintf(line, "..%s",p); nasm_free(oldline); return line; } else if (!nasm_stricmp(q, "struc")) { /* handle struc */ struct TStruc *struc; if (inTstruc) { error(ERR_FATAL, "STRUC: already in a struc context"); return line; } oldline = line; line = nasm_malloc(5 + 1 + len + 1); sprintf(line, "struc %s", p); struc = malloc(sizeof(*struc)); struc->name = nasm_strdup(p); struc->fields = NULL; struc->lastField = NULL; struc->next = TStrucs; TStrucs = struc; inTstruc = 1; nasm_free(oldline); end = nasm_malloc(sizeof(*end)); end->type = TM_STRUC; end->next = EndsStack; EndsStack = end; return line; } else if (!nasm_stricmp(q, "segment")) { /* handle SEGMENT */ oldline = line; line = nasm_strdup(oldchar2?q+len2+1:""); if (tasm_segment) { error(ERR_FATAL, "SEGMENT: already in a segment context"); return line; } tasm_segment = nasm_strdup(p); nasm_free(oldline); end = nasm_malloc(sizeof(*end)); end->type = TM_SEGMENT; end->next = EndsStack; EndsStack = end; return line; } else if (!nasm_stricmp(p, "ends") || !nasm_stricmp(q, "ends")) { /* handle end of ends directive */ end = EndsStack; /* undef parameters */ if (!end) { error(ERR_FATAL, "ENDS: not in an ends context"); return line; } EndsStack = EndsStack->next; nasm_free(line); switch (end->type) { case TM_STRUC: inTstruc = 0; return nasm_strdup("endstruc"); case TM_SEGMENT: /* XXX: yes, we leak memory here, but that permits labels * to avoid strduping... */ tasm_segment = NULL; return nasm_strdup(""); default: error(ERR_FATAL, "ENDS: bogus ends context type %d",end->type); return NULL; } } else if (!nasm_stricmp(p, "endp") || !nasm_stricmp(q, "endp")) { nasm_free(line); return nasm_strdup(""); } else if (!nasm_stricmp(p, "assume")) { struct TSegmentAssume *assume; /* handle ASSUME */ if (!TAssumes) { TAssumes = nasm_malloc(sizeof(*TAssumes)); TAssumes[0].segreg = NULL; } i = 0; q[len2] = oldchar2; /* Skip whitespaces */ while (isspace(*q) && *q) q++; while (*q && *q != ';') { p = q; for (; *q && *q != ';' && *q != ':' && !isspace(*q); q++); if (!*q || *q == ';') break; /* segment register name */ for (assume = TAssumes; assume->segreg; assume++) if (strlen(assume->segreg) == (size_t)(q-p) && !yasm__strncasecmp(assume->segreg, p, q-p)) break; if (!assume->segreg) { i = assume - TAssumes + 1; TAssumes = nasm_realloc(TAssumes, (i+1)*sizeof(*TAssumes)); assume = TAssumes + i - 1; assume->segreg = nasm_strndup(p, q-p); assume[1].segreg = NULL; } for (; *q && *q != ';' && *q != ':' && isspace(*q); q++); if (*q != ':') error(ERR_FATAL, "expected `:' instead of `%c'", *q); for (q++; *q && isspace(*q); q++); /* segment name */ p = q; for (; *q && *q != ';' && *q != ',' && !isspace(*q); q++); assume->segment = nasm_strndup(p, q-p); for (; *q && isspace(*q); q++); if (*q && *q != ';' && *q != ',') error(ERR_FATAL, "expected `,' instead of `%c'", *q); if (*q && *q != ';') q++; for (; *q && isspace(*q); q++); } TAssumes[i].segreg = NULL; TAssumes = nasm_realloc(TAssumes, (i+1)*sizeof(*TAssumes)); nasm_free(line); return nasm_strdup(""); } else if (inTstruc) { struct TStrucField *field; /* TODO: handle unnamed data */ field = nasm_malloc(sizeof(*field)); field->name = nasm_strdup(p); /* TODO: type struc ! */ field->type = nasm_strdup(q); field->next = NULL; if (!TStrucs->fields) TStrucs->fields = field; else if (TStrucs->lastField) TStrucs->lastField->next = field; TStrucs->lastField = field; if (!oldchar2) { error(ERR_FATAL, "Expected struc field initializer after %s %s", p, q); return line; } oldline = line; line = nasm_malloc(1 + len + 1 + len2 + 1 + strlen(q+len2+1) + 1); sprintf(line, ".%s %s %s", p, q, q+len2+1); nasm_free(oldline); return line; } { struct TStruc *struc; for (struc = TStrucs; struc; struc = struc->next) { if (!yasm__strcasecmp(q, struc->name)) { char *r = q + len2 + 1, *s, *t, tasm_param[6]; struct TStrucField *field = struc->fields; int size, n; if (!oldchar2) { error(ERR_FATAL, "Expected struc field initializer after %s %s", p, q); return line; } r = strchr(r, '<'); if (!r) { error(ERR_FATAL, "Expected < for struc field initializer in %s %s %s", p, q, r); return line; } t = strchr(r + 1, '>'); if (!t) { error(ERR_FATAL, "Expected > for struc field initializer in %s %s %s", p, q, r); return line; } *t = 0; oldline = line; size = len + len2 + 128; line = nasm_malloc(size); if (defining) for (n=0;TMParameters[n];n++) if (!strcmp(TMParameters[n],p)) { sprintf(tasm_param,"%%{%d}",n+1); p = tasm_param; break; } n = sprintf(line, "%s: istruc %s\n", p, q); /* use initialisers */ while ((s = strchr(r + 1, ','))) { if (!field) { error(ERR_FATAL, "Too many initializers in structure %s %s", p, q); return oldline; } *s = 0; m = strlen(p) + 1 + strlen(field->name)*2 + 8 + strlen(field->type) + 1 + strlen(r+1) + 2; size += m; line = nasm_realloc(line, size); sprintf(line + n, "%s.%s: at .%s, %s %s\n", p, field->name, field->name, field->type, r + 1); n += m-1; r = s; field = field->next; } /* complete with last initializer and '?' */ while(field) { m = strlen(p) + 1 + strlen(field->name)*2 + 8 + strlen(field->type) + 1 + (r ? strlen(r+1) : 1) + 2; size += m; line = nasm_realloc(line, size); sprintf(line + n, "%s.%s: at .%s, %s %s\n", p, field->name, field->name, field->type, r ? r + 1: "?"); n += m-1; r = NULL; field = field->next; } line = nasm_realloc(line, n + 5); sprintf(line + n, "iend"); nasm_free(oldline); return line; } } } q[len2] = oldchar2; p[len] = oldchar; return line; } static Token * tasm_join_tokens(Token *tline) { Token *t, *prev, *next; for (prev = NULL, t = tline; t; prev = t, t = next) { next = t->next; if (t->type == TOK_OTHER && !strcmp(t->text,"&")) { if (!prev) error(ERR_FATAL, "no token before &"); else if (!next) error(ERR_FATAL, "no token after &"); else if (prev->type != next->type) error(ERR_FATAL, "can't handle different types of token around &"); else if (!prev->text || !next->text) error(ERR_FATAL, "can't handle empty token around &"); else { int lenp = strlen(prev->text); int lenn = strlen(next->text); prev->text = nasm_realloc(prev->text, lenp + lenn + 1); strncpy(prev->text + lenp, next->text, lenn + 1); (void) delete_Token(t); prev->next = delete_Token(next); t = prev; next = t->next; } } } return tline; } /* * The pre-preprocessing stage... This function translates line * number indications as they emerge from GNU cpp (`# lineno "file" * flags') into NASM preprocessor line number indications (`%line * lineno file'). */ static char * prepreproc(char *line) { int lineno; size_t fnlen; char *fname, *oldline; char *c, *d, *ret; Line *l, **lp; if (line[0] == '#' && line[1] == ' ') { oldline = line; fname = oldline + 2; lineno = atoi(fname); fname += strspn(fname, "0123456789 "); if (*fname == '"') fname++; fnlen = strcspn(fname, "\""); line = nasm_malloc(20 + fnlen); sprintf(line, "%%line %d %.*s", lineno, (int)fnlen, fname); nasm_free(oldline); } if (tasm_compatible_mode) line = check_tasm_directive(line); if (!(c = strchr(line, '\n'))) return line; /* Turn multiline macros into several lines */ *c = '\0'; ret = nasm_strdup(line); lp = &istk->expansion; do { d = strchr(c+1, '\n'); if (d) *d = '\0'; l = malloc(sizeof(*l)); l -> first = tokenise(c+1); l -> finishes = NULL; l -> next = *lp; *lp = l; c = d; lp = &l -> next; } while (c); nasm_free(line); return ret; } /* * The hash function for macro lookups. Note that due to some * macros having case-insensitive names, the hash function must be * invariant under case changes. We implement this by applying a * perfectly normal hash function to the uppercase of the string. */ static int hash(char *s) { unsigned int h = 0; unsigned int i = 0; /* * Powers of three, mod 31. */ static const int multipliers[] = { 1, 3, 9, 27, 19, 26, 16, 17, 20, 29, 25, 13, 8, 24, 10, 30, 28, 22, 4, 12, 5, 15, 14, 11, 2, 6, 18, 23, 7, 21 }; while (*s) { h += multipliers[i] * (unsigned char) (toupper(*s)); s++; if (++i >= elements(multipliers)) i = 0; } h %= NHASH; return h; } /* * Free a linked list of tokens. */ static void free_tlist(Token * list_) { while (list_) { list_ = delete_Token(list_); } } /* * Free a linked list of lines. */ static void free_llist(Line * list_) { Line *l; while (list_) { l = list_; list_ = list_->next; free_tlist(l->first); nasm_free(l); } } /* * Free an MMacro */ static void free_mmacro(MMacro * m) { nasm_free(m->name); free_tlist(m->dlist); nasm_free(m->defaults); free_llist(m->expansion); nasm_free(m); } /* * Pop the context stack. */ static void ctx_pop(void) { Context *c = cstk; SMacro *smac, *s; cstk = cstk->next; smac = c->localmac; while (smac) { s = smac; smac = smac->next; nasm_free(s->name); free_tlist(s->expansion); nasm_free(s); } nasm_free(c->name); nasm_free(c); } #define BUF_DELTA 512 /* * Read a line from the top file in istk, handling multiple CR/LFs * at the end of the line read, and handling spurious ^Zs. Will * return lines from the standard macro set if this has not already * been done. */ static char * read_line(void) { char *buffer, *p, *q; int bufsize, continued_count; bufsize = BUF_DELTA; buffer = nasm_malloc(BUF_DELTA); p = buffer; continued_count = 0; while (1) { q = fgets(p, bufsize - (int)(p - buffer), istk->fp); if (!q) break; p += strlen(p); if (p > buffer && p[-1] == '\n') { /* Convert backslash-CRLF line continuation sequences into nothing at all (for DOS and Windows) */ if (((p - 2) > buffer) && (p[-3] == '\\') && (p[-2] == '\r')) { p -= 3; *p = 0; continued_count++; } /* Also convert backslash-LF line continuation sequences into nothing at all (for Unix) */ else if (((p - 1) > buffer) && (p[-2] == '\\')) { p -= 2; *p = 0; continued_count++; } else { break; } } if (p - buffer > bufsize - 10) { long offset = (long)(p - buffer); bufsize += BUF_DELTA; buffer = nasm_realloc(buffer, (size_t)bufsize); p = buffer + offset; /* prevent stale-pointer problems */ } } if (!q && p == buffer) { nasm_free(buffer); return NULL; } nasm_src_set_linnum(nasm_src_get_linnum() + istk->lineinc + (continued_count * istk->lineinc)); /* * Play safe: remove CRs as well as LFs, if any of either are * present at the end of the line. */ while (--p >= buffer && (*p == '\n' || *p == '\r')) *p = '\0'; /* * Handle spurious ^Z, which may be inserted into source files * by some file transfer utilities. */ buffer[strcspn(buffer, "\032")] = '\0'; list->line(LIST_READ, buffer); return buffer; } /* * Tokenise a line of text. This is a very simple process since we * don't need to parse the value out of e.g. numeric tokens: we * simply split one string into many. */ static Token * tokenise(char *line) { char *p = line; int type; Token *list_ = NULL; Token *t, **tail = &list_; while (*line) { p = line; if (*p == '%') { p++; if ( isdigit(*p) || ((*p == '-' || *p == '+') && isdigit(p[1])) || ((*p == '+') && (isspace(p[1]) || !p[1]))) { do { p++; } while (isdigit(*p)); type = TOK_PREPROC_ID; } else if (*p == '{') { p++; while (*p && *p != '}') { p[-1] = *p; p++; } p[-1] = '\0'; if (*p) p++; type = TOK_PREPROC_ID; } else if (isidchar(*p) || ((*p == '!' || *p == '%' || *p == '$') && isidchar(p[1]))) { do { p++; } while (isidchar(*p)); type = TOK_PREPROC_ID; } else { type = TOK_OTHER; if (*p == '%') p++; } } else if (isidstart(*p) || (*p == '$' && isidstart(p[1]))) { type = TOK_ID; p++; while (*p && isidchar(*p)) p++; } else if (*p == '\'' || *p == '"') { /* * A string token. */ char c = *p; p++; type = TOK_STRING; while (*p && *p != c) p++; if (*p) { p++; } else { error(ERR_WARNING, "unterminated string"); type = -1; } } else if (isnumstart(*p)) { /* * A number token. */ type = TOK_NUMBER; p++; while (*p && isnumchar(*p)) p++; } else if (isspace(*p)) { type = TOK_WHITESPACE; p++; while (*p && isspace(*p)) p++; /* * Whitespace just before end-of-line is discarded by * pretending it's a comment; whitespace just before a * comment gets lumped into the comment. */ if (!*p || *p == ';') { type = TOK_COMMENT; while (*p) p++; } } else if (*p == ';') { type = TOK_COMMENT; while (*p) p++; } else { /* * Anything else is an operator of some kind. We check * for all the double-character operators (>>, <<, //, * %%, <=, >=, ==, !=, <>, &&, ||, ^^), but anything * else is a single-character operator. */ type = TOK_OTHER; if ((p[0] == '>' && p[1] == '>') || (p[0] == '<' && p[1] == '<') || (p[0] == '/' && p[1] == '/') || (p[0] == '<' && p[1] == '=') || (p[0] == '>' && p[1] == '=') || (p[0] == '=' && p[1] == '=') || (p[0] == '!' && p[1] == '=') || (p[0] == '<' && p[1] == '>') || (p[0] == '&' && p[1] == '&') || (p[0] == '|' && p[1] == '|') || (p[0] == '^' && p[1] == '^')) { p++; } p++; } /* Handle unterminated string */ if (type == -1) { *tail = t = new_Token(NULL, TOK_STRING, line, (size_t)(p-line)+1); t->text[p-line] = *line; tail = &t->next; } else if (type != TOK_COMMENT) { *tail = t = new_Token(NULL, type, line, (size_t)(p - line)); tail = &t->next; } line = p; } return list_; } /* * this function allocates a new managed block of memory and * returns a pointer to the block. The managed blocks are * deleted only all at once by the delete_Blocks function. */ static void * new_Block(size_t size) { Blocks *b = &blocks; /* first, get to the end of the linked list */ while (b->next) b = b->next; /* now allocate the requested chunk */ b->chunk = nasm_malloc(size); /* now allocate a new block for the next request */ b->next = nasm_malloc(sizeof(Blocks)); /* and initialize the contents of the new block */ b->next->next = NULL; b->next->chunk = NULL; return b->chunk; } /* * this function deletes all managed blocks of memory */ static void delete_Blocks(void) { Blocks *a,*b = &blocks; /* * keep in mind that the first block, pointed to by blocks * is a static and not dynamically allocated, so we don't * free it. */ while (b) { if (b->chunk) nasm_free(b->chunk); a = b; b = b->next; if (a != &blocks) nasm_free(a); } } /* * this function creates a new Token and passes a pointer to it * back to the caller. It sets the type and text elements, and * also the mac and next elements to NULL. */ static Token * new_Token(Token * next, int type, const char *text, size_t txtlen) { Token *t; int i; if (freeTokens == NULL) { freeTokens = (Token *)new_Block(TOKEN_BLOCKSIZE * sizeof(Token)); for (i = 0; i < TOKEN_BLOCKSIZE - 1; i++) freeTokens[i].next = &freeTokens[i + 1]; freeTokens[i].next = NULL; } t = freeTokens; freeTokens = t->next; t->next = next; t->mac = NULL; t->type = type; if (type == TOK_WHITESPACE || text == NULL) { t->text = NULL; } else { if (txtlen == 0) txtlen = strlen(text); t->text = nasm_malloc(1 + txtlen); strncpy(t->text, text, txtlen); t->text[txtlen] = '\0'; } return t; } static Token * delete_Token(Token * t) { Token *next = t->next; nasm_free(t->text); t->next = freeTokens; freeTokens = t; return next; } /* * Convert a line of tokens back into text. * If expand_locals is not zero, identifiers of the form "%$*xxx" * will be transformed into ..@ctxnum.xxx */ static char * detoken(Token * tlist, int expand_locals) { Token *t; size_t len; char *line, *p; len = 0; for (t = tlist; t; t = t->next) { if (t->type == TOK_PREPROC_ID && t->text[1] == '!') { char *p2 = getenv(t->text + 2); nasm_free(t->text); if (p2) t->text = nasm_strdup(p2); else t->text = NULL; } /* Expand local macros here and not during preprocessing */ if (expand_locals && t->type == TOK_PREPROC_ID && t->text && t->text[0] == '%' && t->text[1] == '$') { Context *ctx = get_ctx(t->text, FALSE); if (ctx) { char buffer[40]; char *p2, *q = t->text + 2; q += strspn(q, "$"); sprintf(buffer, "..@%lu.", ctx->number); p2 = nasm_strcat(buffer, q); nasm_free(t->text); t->text = p2; } } if (t->type == TOK_WHITESPACE) { len++; } else if (t->text) { len += strlen(t->text); } } p = line = nasm_malloc(len + 1); for (t = tlist; t; t = t->next) { if (t->type == TOK_WHITESPACE) { *p = ' '; p++; *p = '\0'; } else if (t->text) { strcpy(p, t->text); p += strlen(p); } } *p = '\0'; return line; } /* * A scanner, suitable for use by the expression evaluator, which * operates on a line of Tokens. Expects a pointer to a pointer to * the first token in the line to be passed in as its private_data * field. */ static int ppscan(void *private_data, struct tokenval *tokval) { Token **tlineptr = private_data; Token *tline; do { tline = *tlineptr; *tlineptr = tline ? tline->next : NULL; } while (tline && (tline->type == TOK_WHITESPACE || tline->type == TOK_COMMENT)); if (!tline) return tokval->t_type = TOKEN_EOS; if (tline->text[0] == '$' && !tline->text[1]) return tokval->t_type = TOKEN_HERE; if (tline->text[0] == '$' && tline->text[1] == '$' && !tline->text[2]) return tokval->t_type = TOKEN_BASE; if (tline->type == TOK_ID) { tokval->t_charptr = tline->text; if (tline->text[0] == '$') { tokval->t_charptr++; return tokval->t_type = TOKEN_ID; } /* * This is the only special case we actually need to worry * about in this restricted context. */ if (!nasm_stricmp(tline->text, "seg")) return tokval->t_type = TOKEN_SEG; return tokval->t_type = TOKEN_ID; } if (tline->type == TOK_NUMBER) { int rn_error; tokval->t_integer = nasm_readnum(tline->text, &rn_error); if (rn_error) return tokval->t_type = TOKEN_ERRNUM; tokval->t_charptr = NULL; return tokval->t_type = TOKEN_NUM; } if (tline->type == TOK_STRING) { int rn_warn; char q, *r; size_t l; r = tline->text; q = *r++; l = strlen(r); if (l == 0 || r[l - 1] != q) return tokval->t_type = TOKEN_ERRNUM; tokval->t_integer = nasm_readstrnum(r, l - 1, &rn_warn); if (rn_warn) error(ERR_WARNING | ERR_PASS1, "character constant too long"); tokval->t_charptr = NULL; return tokval->t_type = TOKEN_NUM; } if (tline->type == TOK_OTHER) { if (!strcmp(tline->text, "<<")) return tokval->t_type = TOKEN_SHL; if (!strcmp(tline->text, ">>")) return tokval->t_type = TOKEN_SHR; if (!strcmp(tline->text, "//")) return tokval->t_type = TOKEN_SDIV; if (!strcmp(tline->text, "%%")) return tokval->t_type = TOKEN_SMOD; if (!strcmp(tline->text, "==")) return tokval->t_type = TOKEN_EQ; if (!strcmp(tline->text, "<>")) return tokval->t_type = TOKEN_NE; if (!strcmp(tline->text, "!=")) return tokval->t_type = TOKEN_NE; if (!strcmp(tline->text, "<=")) return tokval->t_type = TOKEN_LE; if (!strcmp(tline->text, ">=")) return tokval->t_type = TOKEN_GE; if (!strcmp(tline->text, "&&")) return tokval->t_type = TOKEN_DBL_AND; if (!strcmp(tline->text, "^^")) return tokval->t_type = TOKEN_DBL_XOR; if (!strcmp(tline->text, "||")) return tokval->t_type = TOKEN_DBL_OR; } /* * We have no other options: just return the first character of * the token text. */ return tokval->t_type = tline->text[0]; } /* * Compare a string to the name of an existing macro; this is a * simple wrapper which calls either strcmp or nasm_stricmp * depending on the value of the `casesense' parameter. */ static int mstrcmp(char *p, char *q, int casesense) { return casesense ? strcmp(p, q) : nasm_stricmp(p, q); } /* * Return the Context structure associated with a %$ token. Return * NULL, having _already_ reported an error condition, if the * context stack isn't deep enough for the supplied number of $ * signs. * If all_contexts == TRUE, contexts that enclose current are * also scanned for such smacro, until it is found; if not - * only the context that directly results from the number of $'s * in variable's name. */ static Context * get_ctx(char *name, int all_contexts) { Context *ctx; SMacro *m; size_t i; if (!name || name[0] != '%' || name[1] != '$') return NULL; if (!cstk) { error(ERR_NONFATAL, "`%s': context stack is empty", name); return NULL; } for (i = strspn(name + 2, "$"), ctx = cstk; (i > 0) && ctx; i--) { ctx = ctx->next; /* i--; Lino - 02/25/02 */ } if (!ctx) { error(ERR_NONFATAL, "`%s': context stack is only" " %d level%s deep", name, i - 1, (i == 2 ? "" : "s")); return NULL; } if (!all_contexts) return ctx; do { /* Search for this smacro in found context */ m = ctx->localmac; while (m) { if (!mstrcmp(m->name, name, m->casesense)) return ctx; m = m->next; } ctx = ctx->next; } while (ctx); return NULL; } /* * Open an include file. This routine must always return a valid * file pointer if it returns - it's responsible for throwing an * ERR_FATAL and bombing out completely if not. It should also try * the include path one by one until it finds the file or reaches * the end of the path. */ static FILE * inc_fopen(char *file, char **newname) { FILE *fp; char *combine = NULL, *c; char *pb, *p1, *p2, *file2 = NULL; /* Try to expand all %ENVVAR% in filename. Warn, and leave %string% * intact, if ENVVAR is not set in the environment. */ pb = file; p1 = pb; for (;;) { char *env; while (*p1 != '\0' && *p1 != '%') p1++; if (*p1 == '\0') break; p2 = p1+1; while (*p2 != '\0' && *p2 != '%') p2++; if (*p2 == '\0') break; /* Okay, we have a %...%, with p1 pointing to the first %, and p2 * pointing to the second %. */ *p2 = '\0'; env = getenv(p1+1); if (!env) { /* warn, restore %, and continue looking */ error(ERR_WARNING, "environment variable `%s' does not exist", p1+1); *p2 = '%'; p1 = p2+1; continue; } /* need to expand */ if (!file2) { file2 = nasm_malloc(strlen(file)+strlen(env)+1); file2[0] = '\0'; } else file2 = nasm_realloc(file2, strlen(file2)+strlen(env)+1); *p1 = '\0'; strcat(file2, pb); strcat(file2, env); pb = p2+1; p1 = pb; } /* add tail end; string is long enough that we don't need to realloc */ if (file2) strcat(file2, pb); fp = yasm_fopen_include(file2 ? file2 : file, nasm_src_get_fname(), "r", &combine); if (!fp && tasm_compatible_mode) { char *thefile = file2 ? file2 : file; /* try a few case combinations */ do { for (c = thefile; *c; c++) *c = toupper(*c); fp = yasm_fopen_include(thefile, nasm_src_get_fname(), "r", &combine); if (fp) break; *thefile = tolower(*thefile); fp = yasm_fopen_include(thefile, nasm_src_get_fname(), "r", &combine); if (fp) break; for (c = thefile; *c; c++) *c = tolower(*c); fp = yasm_fopen_include(thefile, nasm_src_get_fname(), "r", &combine); if (fp) break; *thefile = toupper(*thefile); fp = yasm_fopen_include(thefile, nasm_src_get_fname(), "r", &combine); if (fp) break; } while (0); } if (!fp) error(ERR_FATAL, "unable to open include file `%s'", file2 ? file2 : file); nasm_preproc_add_dep(combine); if (file2) nasm_free(file2); *newname = combine; return fp; } /* * Determine if we should warn on defining a single-line macro of * name `name', with `nparam' parameters. If nparam is 0 or -1, will * return TRUE if _any_ single-line macro of that name is defined. * Otherwise, will return TRUE if a single-line macro with either * `nparam' or no parameters is defined. * * If a macro with precisely the right number of parameters is * defined, or nparam is -1, the address of the definition structure * will be returned in `defn'; otherwise NULL will be returned. If `defn' * is NULL, no action will be taken regarding its contents, and no * error will occur. * * Note that this is also called with nparam zero to resolve * `ifdef'. * * If you already know which context macro belongs to, you can pass * the context pointer as first parameter; if you won't but name begins * with %$ the context will be automatically computed. If all_contexts * is true, macro will be searched in outer contexts as well. */ static int smacro_defined(Context * ctx, char *name, int nparam, SMacro ** defn, int nocase) { SMacro *m; int highest_level = -1; if (ctx) m = ctx->localmac; else if (name[0] == '%' && name[1] == '$') { if (cstk) ctx = get_ctx(name, FALSE); if (!ctx) return FALSE; /* got to return _something_ */ m = ctx->localmac; } else m = smacros[hash(name)]; while (m) { if (!mstrcmp(m->name, name, m->casesense && nocase) && (nparam <= 0 || m->nparam == 0 || nparam == m->nparam) && (highest_level < 0 || m->level > highest_level)) { highest_level = m->level; if (defn) { if (nparam == m->nparam || nparam == -1) *defn = m; else *defn = NULL; } } m = m->next; } return highest_level >= 0; } /* * Count and mark off the parameters in a multi-line macro call. * This is called both from within the multi-line macro expansion * code, and also to mark off the default parameters when provided * in a %macro definition line. */ static void count_mmac_params(Token * t, int *nparam, Token *** params) { int paramsize, brace; *nparam = paramsize = 0; *params = NULL; while (t) { if (*nparam+1 >= paramsize) { paramsize += PARAM_DELTA; *params = nasm_realloc(*params, sizeof(**params) * paramsize); } skip_white_(t); brace = FALSE; if (tok_is_(t, "{")) brace = TRUE; (*params)[(*nparam)++] = t; while (tok_isnt_(t, brace ? "}" : ",")) t = t->next; if (t) { /* got a comma/brace */ t = t->next; if (brace) { /* * Now we've found the closing brace, look further * for the comma. */ skip_white_(t); if (tok_isnt_(t, ",")) { error(ERR_NONFATAL, "braces do not enclose all of macro parameter"); while (tok_isnt_(t, ",")) t = t->next; } if (t) t = t->next; /* eat the comma */ } } } } /* * Determine whether one of the various `if' conditions is true or * not. * * We must free the tline we get passed. */ static int if_condition(Token * tline, int i) { int j, casesense; Token *t, *tt, **tptr, *origline; struct tokenval tokval; yasm_expr *evalresult; yasm_intnum *intn; origline = tline; switch (i) { case PP_IFCTX: case PP_ELIFCTX: case PP_IFNCTX: case PP_ELIFNCTX: j = FALSE; /* have we matched yet? */ while (cstk && tline) { skip_white_(tline); if (!tline || tline->type != TOK_ID) { error(ERR_NONFATAL, "`%s' expects context identifiers", directives[i]); free_tlist(origline); return -1; } if (!nasm_stricmp(tline->text, cstk->name)) j = TRUE; tline = tline->next; } if (i == PP_IFNCTX || i == PP_ELIFNCTX) j = !j; free_tlist(origline); return j; case PP_IFDEF: case PP_ELIFDEF: case PP_IFNDEF: case PP_ELIFNDEF: j = FALSE; /* have we matched yet? */ while (tline) { skip_white_(tline); if (!tline || (tline->type != TOK_ID && (tline->type != TOK_PREPROC_ID || tline->text[1] != '$'))) { error(ERR_NONFATAL, "`%s' expects macro identifiers", directives[i]); free_tlist(origline); return -1; } if (smacro_defined(NULL, tline->text, 0, NULL, 1)) j = TRUE; tline = tline->next; } if (i == PP_IFNDEF || i == PP_ELIFNDEF) j = !j; free_tlist(origline); return j; case PP_IFIDN: case PP_ELIFIDN: case PP_IFNIDN: case PP_ELIFNIDN: case PP_IFIDNI: case PP_ELIFIDNI: case PP_IFNIDNI: case PP_ELIFNIDNI: tline = expand_smacro(tline); t = tt = tline; while (tok_isnt_(tt, ",")) tt = tt->next; if (!tt) { error(ERR_NONFATAL, "`%s' expects two comma-separated arguments", directives[i]); free_tlist(tline); return -1; } tt = tt->next; casesense = (i == PP_IFIDN || i == PP_ELIFIDN || i == PP_IFNIDN || i == PP_ELIFNIDN); j = TRUE; /* assume equality unless proved not */ while ((t->type != TOK_OTHER || strcmp(t->text, ",")) && tt) { if (tt->type == TOK_OTHER && !strcmp(tt->text, ",")) { error(ERR_NONFATAL, "`%s': more than one comma on line", directives[i]); free_tlist(tline); return -1; } if (t->type == TOK_WHITESPACE) { t = t->next; continue; } if (tt->type == TOK_WHITESPACE) { tt = tt->next; continue; } if (tt->type != t->type) { j = FALSE; /* found mismatching tokens */ break; } /* Unify surrounding quotes for strings */ if (t->type == TOK_STRING) { tt->text[0] = t->text[0]; tt->text[strlen(tt->text) - 1] = t->text[0]; } if (mstrcmp(tt->text, t->text, casesense) != 0) { j = FALSE; /* found mismatching tokens */ break; } t = t->next; tt = tt->next; } if ((t->type != TOK_OTHER || strcmp(t->text, ",")) || tt) j = FALSE; /* trailing gunk on one end or other */ if (i == PP_IFNIDN || i == PP_ELIFNIDN || i == PP_IFNIDNI || i == PP_ELIFNIDNI) j = !j; free_tlist(tline); return j; case PP_IFMACRO: case PP_ELIFMACRO: case PP_IFNMACRO: case PP_ELIFNMACRO: { int found = 0; MMacro searching, *mmac; tline = tline->next; skip_white_(tline); tline = expand_id(tline); if (!tok_type_(tline, TOK_ID)) { error(ERR_NONFATAL, "`%s' expects a macro name", directives[i]); return -1; } searching.name = nasm_strdup(tline->text); searching.casesense = (i == PP_MACRO); searching.plus = FALSE; searching.nolist = FALSE; searching.in_progress = FALSE; searching.rep_nest = NULL; searching.nparam_min = 0; searching.nparam_max = INT_MAX; tline = expand_smacro(tline->next); skip_white_(tline); if (!tline) { } else if (!tok_type_(tline, TOK_NUMBER)) { error(ERR_NONFATAL, "`%s' expects a parameter count or nothing", directives[i]); } else { intn = nasm_readnum(tline->text, &j); searching.nparam_min = searching.nparam_max = yasm_intnum_get_int(intn); yasm_intnum_destroy(intn); if (j) error(ERR_NONFATAL, "unable to parse parameter count `%s'", tline->text); } if (tline && tok_is_(tline->next, "-")) { tline = tline->next->next; if (tok_is_(tline, "*")) searching.nparam_max = INT_MAX; else if (!tok_type_(tline, TOK_NUMBER)) error(ERR_NONFATAL, "`%s' expects a parameter count after `-'", directives[i]); else { intn = nasm_readnum(tline->text, &j); searching.nparam_max = yasm_intnum_get_int(intn); yasm_intnum_destroy(intn); if (j) error(ERR_NONFATAL, "unable to parse parameter count `%s'", tline->text); if (searching.nparam_min > searching.nparam_max) error(ERR_NONFATAL, "minimum parameter count exceeds maximum"); } } if (tline && tok_is_(tline->next, "+")) { tline = tline->next; searching.plus = TRUE; } mmac = mmacros[hash(searching.name)]; while (mmac) { if (!strcmp(mmac->name, searching.name) && (mmac->nparam_min <= searching.nparam_max || searching.plus) && (searching.nparam_min <= mmac->nparam_max || mmac->plus)) { found = TRUE; break; } mmac = mmac->next; } nasm_free(searching.name); free_tlist(origline); if (i == PP_IFNMACRO || i == PP_ELIFNMACRO) found = !found; return found; } case PP_IFID: case PP_ELIFID: case PP_IFNID: case PP_ELIFNID: case PP_IFNUM: case PP_ELIFNUM: case PP_IFNNUM: case PP_ELIFNNUM: case PP_IFSTR: case PP_ELIFSTR: case PP_IFNSTR: case PP_ELIFNSTR: tline = expand_smacro(tline); t = tline; while (tok_type_(t, TOK_WHITESPACE)) t = t->next; j = FALSE; /* placate optimiser */ if (t) switch (i) { case PP_IFID: case PP_ELIFID: case PP_IFNID: case PP_ELIFNID: j = (t->type == TOK_ID); break; case PP_IFNUM: case PP_ELIFNUM: case PP_IFNNUM: case PP_ELIFNNUM: j = (t->type == TOK_NUMBER); break; case PP_IFSTR: case PP_ELIFSTR: case PP_IFNSTR: case PP_ELIFNSTR: j = (t->type == TOK_STRING); break; } if (i == PP_IFNID || i == PP_ELIFNID || i == PP_IFNNUM || i == PP_ELIFNNUM || i == PP_IFNSTR || i == PP_ELIFNSTR) j = !j; free_tlist(tline); return j; case PP_IF: case PP_ELIF: t = tline = expand_smacro(tline); tptr = &t; tokval.t_type = TOKEN_INVALID; evalresult = evaluate(ppscan, tptr, &tokval, pass | CRITICAL, error); free_tlist(tline); if (!evalresult) return -1; if (tokval.t_type) error(ERR_WARNING, "trailing garbage after expression ignored"); intn = yasm_expr_get_intnum(&evalresult, 0); if (!intn) { error(ERR_NONFATAL, "non-constant value given to `%s'", directives[i]); yasm_expr_destroy(evalresult); return -1; } j = !yasm_intnum_is_zero(intn); yasm_expr_destroy(evalresult); return j; default: error(ERR_FATAL, "preprocessor directive `%s' not yet implemented", directives[i]); free_tlist(origline); return -1; /* yeah, right */ } } /* * Expand macros in a string. Used in %error and %include directives. * First tokenise the string, apply "expand_smacro" and then de-tokenise back. * The returned variable should ALWAYS be freed after usage. */ static void expand_macros_in_string(char **p) { Token *line = tokenise(*p); line = expand_smacro(line); *p = detoken(line, FALSE); } /** * find and process preprocessor directive in passed line * Find out if a line contains a preprocessor directive, and deal * with it if so. * * If a directive _is_ found, it is the responsibility of this routine * (and not the caller) to free_tlist() the line. * * @param tline a pointer to the current tokeninzed line linked list * @return DIRECTIVE_FOUND or NO_DIRECTIVE_FOUND * */ static int do_directive(Token * tline) { int i, j, k, m, nparam, nolist; int offset; char *p, *mname, *newname; Include *inc; Context *ctx; Cond *cond; SMacro *smac, **smhead; MMacro *mmac; Token *t, *tt, *param_start, *macro_start, *last, **tptr, *origline; Line *l; struct tokenval tokval; yasm_expr *evalresult; MMacro *tmp_defining; /* Used when manipulating rep_nest */ yasm_intnum *intn; origline = tline; skip_white_(tline); if (!tok_type_(tline, TOK_PREPROC_ID) || (tline->text[1] == '%' || tline->text[1] == '$' || tline->text[1] == '!')) return NO_DIRECTIVE_FOUND; i = -1; j = elements(directives); while (j - i > 1) { k = (j + i) / 2; m = nasm_stricmp(tline->text, directives[k]); if (m == 0) { if (tasm_compatible_mode) { i = k; j = -2; } else if (k != PP_ARG && k != PP_LOCAL && k != PP_STACKSIZE) { i = k; j = -2; } break; } else if (m < 0) { j = k; } else i = k; } /* * If we're in a non-emitting branch of a condition construct, * or walking to the end of an already terminated %rep block, * we should ignore all directives except for condition * directives. */ if (((istk->conds && !emitting(istk->conds->state)) || (istk->mstk && !istk->mstk->in_progress)) && !is_condition(i)) { return NO_DIRECTIVE_FOUND; } /* * If we're defining a macro or reading a %rep block, we should * ignore all directives except for %macro/%imacro (which * generate an error), %endm/%endmacro, and (only if we're in a * %rep block) %endrep. If we're in a %rep block, another %rep * causes an error, so should be let through. */ if (defining && i != PP_MACRO && i != PP_IMACRO && i != PP_ENDMACRO && i != PP_ENDM && (defining->name || (i != PP_ENDREP && i != PP_REP))) { return NO_DIRECTIVE_FOUND; } if (defining) { if (i == PP_MACRO || i == PP_IMACRO) { nested_mac_count++; return NO_DIRECTIVE_FOUND; } else if (nested_mac_count > 0) { if (i == PP_ENDMACRO) { nested_mac_count--; return NO_DIRECTIVE_FOUND; } } if (!defining->name) { if (i == PP_REP) { nested_rep_count++; return NO_DIRECTIVE_FOUND; } else if (nested_rep_count > 0) { if (i == PP_ENDREP) { nested_rep_count--; return NO_DIRECTIVE_FOUND; } } } } if (j != -2) { error(ERR_NONFATAL, "unknown preprocessor directive `%s'", tline->text); return NO_DIRECTIVE_FOUND; /* didn't get it */ } switch (i) { case PP_STACKSIZE: /* Directive to tell NASM what the default stack size is. The * default is for a 16-bit stack, and this can be overriden with * %stacksize large. * the following form: * * ARG arg1:WORD, arg2:DWORD, arg4:QWORD */ tline = tline->next; if (tline && tline->type == TOK_WHITESPACE) tline = tline->next; if (!tline || tline->type != TOK_ID) { error(ERR_NONFATAL, "`%%stacksize' missing size parameter"); free_tlist(origline); return DIRECTIVE_FOUND; } if (nasm_stricmp(tline->text, "flat") == 0) { /* All subsequent ARG directives are for a 32-bit stack */ StackSize = 4; StackPointer = "ebp"; ArgOffset = 8; LocalOffset = 4; } else if (nasm_stricmp(tline->text, "large") == 0) { /* All subsequent ARG directives are for a 16-bit stack, * far function call. */ StackSize = 2; StackPointer = "bp"; ArgOffset = 4; LocalOffset = 2; } else if (nasm_stricmp(tline->text, "small") == 0) { /* All subsequent ARG directives are for a 16-bit stack, * far function call. We don't support near functions. */ StackSize = 2; StackPointer = "bp"; ArgOffset = 6; LocalOffset = 2; } else { error(ERR_NONFATAL, "`%%stacksize' invalid size type"); free_tlist(origline); return DIRECTIVE_FOUND; } free_tlist(origline); return DIRECTIVE_FOUND; case PP_ARG: /* TASM like ARG directive to define arguments to functions, in * the following form: * * ARG arg1:WORD, arg2:DWORD, arg4:QWORD */ offset = ArgOffset; do { char *arg, directive[256]; int size = StackSize; /* Find the argument name */ tline = tline->next; if (tline && tline->type == TOK_WHITESPACE) tline = tline->next; if (!tline || tline->type != TOK_ID) { error(ERR_NONFATAL, "`%%arg' missing argument parameter"); free_tlist(origline); return DIRECTIVE_FOUND; } arg = tline->text; /* Find the argument size type */ tline = tline->next; if (!tline || tline->type != TOK_OTHER || tline->text[0] != ':') { error(ERR_NONFATAL, "Syntax error processing `%%arg' directive"); free_tlist(origline); return DIRECTIVE_FOUND; } tline = tline->next; if (!tline || tline->type != TOK_ID) { error(ERR_NONFATAL, "`%%arg' missing size type parameter"); free_tlist(origline); return DIRECTIVE_FOUND; } /* Allow macro expansion of type parameter */ tt = tokenise(tline->text); tt = expand_smacro(tt); if (nasm_stricmp(tt->text, "byte") == 0) { size = MAX(StackSize, 1); } else if (nasm_stricmp(tt->text, "word") == 0) { size = MAX(StackSize, 2); } else if (nasm_stricmp(tt->text, "dword") == 0) { size = MAX(StackSize, 4); } else if (nasm_stricmp(tt->text, "qword") == 0) { size = MAX(StackSize, 8); } else if (nasm_stricmp(tt->text, "tword") == 0) { size = MAX(StackSize, 10); } else { error(ERR_NONFATAL, "Invalid size type for `%%arg' missing directive"); free_tlist(tt); free_tlist(origline); return DIRECTIVE_FOUND; } free_tlist(tt); /* Now define the macro for the argument */ sprintf(directive, "%%define %s (%s+%d)", arg, StackPointer, offset); do_directive(tokenise(directive)); offset += size; /* Move to the next argument in the list */ tline = tline->next; if (tline && tline->type == TOK_WHITESPACE) tline = tline->next; } while (tline && tline->type == TOK_OTHER && tline->text[0] == ','); free_tlist(origline); return DIRECTIVE_FOUND; case PP_LOCAL: /* TASM like LOCAL directive to define local variables for a * function, in the following form: * * LOCAL local1:WORD, local2:DWORD, local4:QWORD = LocalSize * * The '= LocalSize' at the end is ignored by NASM, but is * required by TASM to define the local parameter size (and used * by the TASM macro package). */ offset = LocalOffset; do { char *local, directive[256]; int size = StackSize; /* Find the argument name */ tline = tline->next; if (tline && tline->type == TOK_WHITESPACE) tline = tline->next; if (!tline || tline->type != TOK_ID) { error(ERR_NONFATAL, "`%%local' missing argument parameter"); free_tlist(origline); return DIRECTIVE_FOUND; } local = tline->text; /* Find the argument size type */ tline = tline->next; if (!tline || tline->type != TOK_OTHER || tline->text[0] != ':') { error(ERR_NONFATAL, "Syntax error processing `%%local' directive"); free_tlist(origline); return DIRECTIVE_FOUND; } tline = tline->next; if (!tline || tline->type != TOK_ID) { error(ERR_NONFATAL, "`%%local' missing size type parameter"); free_tlist(origline); return DIRECTIVE_FOUND; } /* Allow macro expansion of type parameter */ tt = tokenise(tline->text); tt = expand_smacro(tt); if (nasm_stricmp(tt->text, "byte") == 0) { size = MAX(StackSize, 1); } else if (nasm_stricmp(tt->text, "word") == 0) { size = MAX(StackSize, 2); } else if (nasm_stricmp(tt->text, "dword") == 0) { size = MAX(StackSize, 4); } else if (nasm_stricmp(tt->text, "qword") == 0) { size = MAX(StackSize, 8); } else if (nasm_stricmp(tt->text, "tword") == 0) { size = MAX(StackSize, 10); } else { error(ERR_NONFATAL, "Invalid size type for `%%local' missing directive"); free_tlist(tt); free_tlist(origline); return DIRECTIVE_FOUND; } free_tlist(tt); /* Now define the macro for the argument */ sprintf(directive, "%%define %s (%s-%d)", local, StackPointer, offset); do_directive(tokenise(directive)); offset += size; /* Now define the assign to setup the enter_c macro correctly */ sprintf(directive, "%%assign %%$localsize %%$localsize+%d", size); do_directive(tokenise(directive)); /* Move to the next argument in the list */ tline = tline->next; if (tline && tline->type == TOK_WHITESPACE) tline = tline->next; } while (tline && tline->type == TOK_OTHER && tline->text[0] == ','); free_tlist(origline); return DIRECTIVE_FOUND; case PP_CLEAR: if (tline->next) error(ERR_WARNING, "trailing garbage after `%%clear' ignored"); for (j = 0; j < NHASH; j++) { while (mmacros[j]) { MMacro *m2 = mmacros[j]; mmacros[j] = m2->next; free_mmacro(m2); } while (smacros[j]) { SMacro *s = smacros[j]; smacros[j] = smacros[j]->next; nasm_free(s->name); free_tlist(s->expansion); nasm_free(s); } } free_tlist(origline); return DIRECTIVE_FOUND; case PP_INCLUDE: tline = tline->next; skip_white_(tline); if (!tline || (tline->type != TOK_STRING && tline->type != TOK_INTERNAL_STRING)) { error(ERR_NONFATAL, "`%%include' expects a file name"); free_tlist(origline); return DIRECTIVE_FOUND; /* but we did _something_ */ } if (tline->next) error(ERR_WARNING, "trailing garbage after `%%include' ignored"); if (tline->type != TOK_INTERNAL_STRING) { p = tline->text + 1; /* point past the quote to the name */ p[strlen(p) - 1] = '\0'; /* remove the trailing quote */ } else p = tline->text; /* internal_string is easier */ expand_macros_in_string(&p); inc = nasm_malloc(sizeof(Include)); inc->next = istk; inc->conds = NULL; inc->fp = inc_fopen(p, &newname); inc->fname = nasm_src_set_fname(newname); inc->lineno = nasm_src_set_linnum(0); inc->lineinc = 1; inc->expansion = NULL; inc->mstk = NULL; istk = inc; list->uplevel(LIST_INCLUDE); free_tlist(origline); return DIRECTIVE_FOUND; case PP_PUSH: tline = tline->next; skip_white_(tline); tline = expand_id(tline); if (!tok_type_(tline, TOK_ID)) { error(ERR_NONFATAL, "`%%push' expects a context identifier"); free_tlist(origline); return DIRECTIVE_FOUND; /* but we did _something_ */ } if (tline->next) error(ERR_WARNING, "trailing garbage after `%%push' ignored"); ctx = nasm_malloc(sizeof(Context)); ctx->next = cstk; ctx->localmac = NULL; ctx->name = nasm_strdup(tline->text); ctx->number = unique++; cstk = ctx; free_tlist(origline); break; case PP_REPL: tline = tline->next; skip_white_(tline); tline = expand_id(tline); if (!tok_type_(tline, TOK_ID)) { error(ERR_NONFATAL, "`%%repl' expects a context identifier"); free_tlist(origline); return DIRECTIVE_FOUND; /* but we did _something_ */ } if (tline->next) error(ERR_WARNING, "trailing garbage after `%%repl' ignored"); if (!cstk) error(ERR_NONFATAL, "`%%repl': context stack is empty"); else { nasm_free(cstk->name); cstk->name = nasm_strdup(tline->text); } free_tlist(origline); break; case PP_POP: if (tline->next) error(ERR_WARNING, "trailing garbage after `%%pop' ignored"); if (!cstk) error(ERR_NONFATAL, "`%%pop': context stack is already empty"); else ctx_pop(); free_tlist(origline); break; case PP_SCOPE: if (tline->next) error(ERR_WARNING, "trailing garbage after `%%scope' ignored"); Level++; free_tlist(origline); break; case PP_ENDSCOPE: if (tline->next) error(ERR_WARNING, "trailing garbage after `%%endscope' ignored"); if (!Level) error(ERR_NONFATAL, "`%%endscope': already popped all levels"); else { for (k = 0; k < NHASH; k++) { SMacro **smlast = &smacros[k]; smac = smacros[k]; while (smac) { if (smac->level < Level) { smlast = &smac->next; smac = smac->next; } else { *smlast = smac->next; nasm_free(smac->name); free_tlist(smac->expansion); nasm_free(smac); smac = *smlast; } } } for (ctx = cstk; ctx; ctx = ctx->next) { SMacro **smlast = &ctx->localmac; smac = ctx->localmac; while (smac) { if (smac->level < Level) { smlast = &smac->next; smac = smac->next; } else { *smlast = smac->next; nasm_free(smac->name); free_tlist(smac->expansion); nasm_free(smac); smac = *smlast; } } } Level--; } free_tlist(origline); break; case PP_ERROR: tline->next = expand_smacro(tline->next); tline = tline->next; skip_white_(tline); if (tok_type_(tline, TOK_STRING)) { p = tline->text + 1; /* point past the quote to the name */ p[strlen(p) - 1] = '\0'; /* remove the trailing quote */ expand_macros_in_string(&p); error(ERR_NONFATAL, "%s", p); nasm_free(p); } else { p = detoken(tline, FALSE); error(ERR_WARNING, "%s", p); nasm_free(p); } free_tlist(origline); break; case PP_IF: case PP_IFCTX: case PP_IFDEF: case PP_IFID: case PP_IFIDN: case PP_IFIDNI: case PP_IFMACRO: case PP_IFNCTX: case PP_IFNDEF: case PP_IFNID: case PP_IFNIDN: case PP_IFNIDNI: case PP_IFNMACRO: case PP_IFNNUM: case PP_IFNSTR: case PP_IFNUM: case PP_IFSTR: if (istk->conds && !emitting(istk->conds->state)) j = COND_NEVER; else { j = if_condition(tline->next, i); tline->next = NULL; /* it got freed */ j = j < 0 ? COND_NEVER : j ? COND_IF_TRUE : COND_IF_FALSE; } free_tlist(origline); cond = nasm_malloc(sizeof(Cond)); cond->next = istk->conds; cond->state = j; istk->conds = cond; return DIRECTIVE_FOUND; case PP_ELIF: case PP_ELIFCTX: case PP_ELIFDEF: case PP_ELIFID: case PP_ELIFIDN: case PP_ELIFIDNI: case PP_ELIFMACRO: case PP_ELIFNCTX: case PP_ELIFNDEF: case PP_ELIFNID: case PP_ELIFNIDN: case PP_ELIFNIDNI: case PP_ELIFNMACRO: case PP_ELIFNNUM: case PP_ELIFNSTR: case PP_ELIFNUM: case PP_ELIFSTR: if (!istk->conds) error(ERR_FATAL, "`%s': no matching `%%if'", directives[i]); if (emitting(istk->conds->state) || istk->conds->state == COND_NEVER) istk->conds->state = COND_NEVER; else { /* * IMPORTANT: In the case of %if, we will already have * called expand_mmac_params(); however, if we're * processing an %elif we must have been in a * non-emitting mode, which would have inhibited * the normal invocation of expand_mmac_params(). Therefore, * we have to do it explicitly here. */ j = if_condition(expand_mmac_params(tline->next), i); tline->next = NULL; /* it got freed */ istk->conds->state = j < 0 ? COND_NEVER : j ? COND_IF_TRUE : COND_IF_FALSE; } free_tlist(origline); return DIRECTIVE_FOUND; case PP_ELSE: if (tline->next) error(ERR_WARNING, "trailing garbage after `%%else' ignored"); if (!istk->conds) error(ERR_FATAL, "`%%else': no matching `%%if'"); if (emitting(istk->conds->state) || istk->conds->state == COND_NEVER) istk->conds->state = COND_ELSE_FALSE; else istk->conds->state = COND_ELSE_TRUE; free_tlist(origline); return DIRECTIVE_FOUND; case PP_ENDIF: if (tline->next) error(ERR_WARNING, "trailing garbage after `%%endif' ignored"); if (!istk->conds) error(ERR_FATAL, "`%%endif': no matching `%%if'"); cond = istk->conds; istk->conds = cond->next; nasm_free(cond); free_tlist(origline); return DIRECTIVE_FOUND; case PP_MACRO: case PP_IMACRO: if (defining) error(ERR_FATAL, "`%%%smacro': already defining a macro", (i == PP_IMACRO ? "i" : "")); tline = tline->next; skip_white_(tline); tline = expand_id(tline); if (!tok_type_(tline, TOK_ID)) { error(ERR_NONFATAL, "`%%%smacro' expects a macro name", (i == PP_IMACRO ? "i" : "")); return DIRECTIVE_FOUND; } defining = nasm_malloc(sizeof(MMacro)); defining->name = nasm_strdup(tline->text); defining->casesense = (i == PP_MACRO); defining->plus = FALSE; defining->nolist = FALSE; defining->in_progress = FALSE; defining->rep_nest = NULL; tline = expand_smacro(tline->next); skip_white_(tline); if (!tok_type_(tline, TOK_NUMBER)) { error(ERR_NONFATAL, "`%%%smacro' expects a parameter count", (i == PP_IMACRO ? "i" : "")); defining->nparam_min = defining->nparam_max = 0; } else { intn = nasm_readnum(tline->text, &j); defining->nparam_min = defining->nparam_max = yasm_intnum_get_int(intn); yasm_intnum_destroy(intn); if (j) error(ERR_NONFATAL, "unable to parse parameter count `%s'", tline->text); } if (tline && tok_is_(tline->next, "-")) { tline = tline->next->next; if (tok_is_(tline, "*")) defining->nparam_max = INT_MAX; else if (!tok_type_(tline, TOK_NUMBER)) error(ERR_NONFATAL, "`%%%smacro' expects a parameter count after `-'", (i == PP_IMACRO ? "i" : "")); else { intn = nasm_readnum(tline->text, &j); defining->nparam_max = yasm_intnum_get_int(intn); yasm_intnum_destroy(intn); if (j) error(ERR_NONFATAL, "unable to parse parameter count `%s'", tline->text); if (defining->nparam_min > defining->nparam_max) error(ERR_NONFATAL, "minimum parameter count exceeds maximum"); } } if (tline && tok_is_(tline->next, "+")) { tline = tline->next; defining->plus = TRUE; } if (tline && tok_type_(tline->next, TOK_ID) && !nasm_stricmp(tline->next->text, ".nolist")) { tline = tline->next; defining->nolist = TRUE; } mmac = mmacros[hash(defining->name)]; while (mmac) { if (!strcmp(mmac->name, defining->name) && (mmac->nparam_min <= defining->nparam_max || defining->plus) && (defining->nparam_min <= mmac->nparam_max || mmac->plus)) { error(ERR_WARNING, "redefining multi-line macro `%s'", defining->name); break; } mmac = mmac->next; } /* * Handle default parameters. */ if (tline && tline->next) { defining->dlist = tline->next; tline->next = NULL; count_mmac_params(defining->dlist, &defining->ndefs, &defining->defaults); } else { defining->dlist = NULL; defining->defaults = NULL; } defining->expansion = NULL; free_tlist(origline); return DIRECTIVE_FOUND; case PP_ENDM: case PP_ENDMACRO: if (!defining) { error(ERR_NONFATAL, "`%s': not defining a macro", tline->text); return DIRECTIVE_FOUND; } k = hash(defining->name); defining->next = mmacros[k]; mmacros[k] = defining; defining = NULL; free_tlist(origline); return DIRECTIVE_FOUND; case PP_ROTATE: if (tline->next && tline->next->type == TOK_WHITESPACE) tline = tline->next; if (tline->next == NULL) { free_tlist(origline); error(ERR_NONFATAL, "`%%rotate' missing rotate count"); return DIRECTIVE_FOUND; } t = expand_smacro(tline->next); tline->next = NULL; free_tlist(origline); tline = t; tptr = &t; tokval.t_type = TOKEN_INVALID; evalresult = evaluate(ppscan, tptr, &tokval, pass, error); free_tlist(tline); if (!evalresult) return DIRECTIVE_FOUND; if (tokval.t_type) error(ERR_WARNING, "trailing garbage after expression ignored"); intn = yasm_expr_get_intnum(&evalresult, 0); if (!intn) { error(ERR_NONFATAL, "non-constant value given to `%%rotate'"); yasm_expr_destroy(evalresult); return DIRECTIVE_FOUND; } mmac = istk->mstk; while (mmac && !mmac->name) /* avoid mistaking %reps for macros */ mmac = mmac->next_active; if (!mmac) { error(ERR_NONFATAL, "`%%rotate' invoked outside a macro call"); } else if (mmac->nparam == 0) { error(ERR_NONFATAL, "`%%rotate' invoked within macro without parameters"); } else { mmac->rotate = mmac->rotate + yasm_intnum_get_int(intn); if (mmac->rotate < 0) mmac->rotate = mmac->nparam - (-mmac->rotate) % mmac->nparam; mmac->rotate %= mmac->nparam; } yasm_expr_destroy(evalresult); return DIRECTIVE_FOUND; case PP_REP: nolist = FALSE; do { tline = tline->next; } while (tok_type_(tline, TOK_WHITESPACE)); if (tok_type_(tline, TOK_ID) && nasm_stricmp(tline->text, ".nolist") == 0) { nolist = TRUE; do { tline = tline->next; } while (tok_type_(tline, TOK_WHITESPACE)); } if (tline) { t = expand_smacro(tline); tptr = &t; tokval.t_type = TOKEN_INVALID; evalresult = evaluate(ppscan, tptr, &tokval, pass, error); if (!evalresult) { free_tlist(origline); return DIRECTIVE_FOUND; } if (tokval.t_type) error(ERR_WARNING, "trailing garbage after expression ignored"); intn = yasm_expr_get_intnum(&evalresult, 0); if (!intn) { error(ERR_NONFATAL, "non-constant value given to `%%rep'"); yasm_expr_destroy(evalresult); return DIRECTIVE_FOUND; } i = (int)yasm_intnum_get_int(intn) + 1; yasm_expr_destroy(evalresult); } else { error(ERR_NONFATAL, "`%%rep' expects a repeat count"); i = 0; } free_tlist(origline); tmp_defining = defining; defining = nasm_malloc(sizeof(MMacro)); defining->name = NULL; /* flags this macro as a %rep block */ defining->casesense = 0; defining->plus = FALSE; defining->nolist = nolist; defining->in_progress = i; defining->nparam_min = defining->nparam_max = 0; defining->defaults = NULL; defining->dlist = NULL; defining->expansion = NULL; defining->next_active = istk->mstk; defining->rep_nest = tmp_defining; return DIRECTIVE_FOUND; case PP_ENDREP: if (!defining || defining->name) { error(ERR_NONFATAL, "`%%endrep': no matching `%%rep'"); return DIRECTIVE_FOUND; } /* * Now we have a "macro" defined - although it has no name * and we won't be entering it in the hash tables - we must * push a macro-end marker for it on to istk->expansion. * After that, it will take care of propagating itself (a * macro-end marker line for a macro which is really a %rep * block will cause the macro to be re-expanded, complete * with another macro-end marker to ensure the process * continues) until the whole expansion is forcibly removed * from istk->expansion by a %exitrep. */ l = nasm_malloc(sizeof(Line)); l->next = istk->expansion; l->finishes = defining; l->first = NULL; istk->expansion = l; istk->mstk = defining; list->uplevel(defining->nolist ? LIST_MACRO_NOLIST : LIST_MACRO); tmp_defining = defining; defining = defining->rep_nest; free_tlist(origline); return DIRECTIVE_FOUND; case PP_EXITREP: /* * We must search along istk->expansion until we hit a * macro-end marker for a macro with no name. Then we set * its `in_progress' flag to 0. */ for (l = istk->expansion; l; l = l->next) if (l->finishes && !l->finishes->name) break; if (l) l->finishes->in_progress = 0; else error(ERR_NONFATAL, "`%%exitrep' not within `%%rep' block"); free_tlist(origline); return DIRECTIVE_FOUND; case PP_XDEFINE: case PP_IXDEFINE: case PP_DEFINE: case PP_IDEFINE: tline = tline->next; skip_white_(tline); tline = expand_id(tline); if (!tline || (tline->type != TOK_ID && (tline->type != TOK_PREPROC_ID || tline->text[1] != '$'))) { error(ERR_NONFATAL, "`%%%s%sdefine' expects a macro identifier", ((i == PP_IDEFINE || i == PP_IXDEFINE) ? "i" : ""), ((i == PP_XDEFINE || i == PP_IXDEFINE) ? "x" : "")); free_tlist(origline); return DIRECTIVE_FOUND; } ctx = get_ctx(tline->text, FALSE); if (!ctx) smhead = &smacros[hash(tline->text)]; else smhead = &ctx->localmac; mname = tline->text; last = tline; param_start = tline = tline->next; nparam = 0; /* Expand the macro definition now for %xdefine and %ixdefine */ if ((i == PP_XDEFINE) || (i == PP_IXDEFINE)) tline = expand_smacro(tline); if (tok_is_(tline, "(")) { /* * This macro has parameters. */ tline = tline->next; while (1) { skip_white_(tline); if (!tline) { error(ERR_NONFATAL, "parameter identifier expected"); free_tlist(origline); return DIRECTIVE_FOUND; } if (tline->type != TOK_ID) { error(ERR_NONFATAL, "`%s': parameter identifier expected", tline->text); free_tlist(origline); return DIRECTIVE_FOUND; } tline->type = TOK_SMAC_PARAM + nparam++; tline = tline->next; skip_white_(tline); if (tok_is_(tline, ",")) { tline = tline->next; continue; } if (!tok_is_(tline, ")")) { error(ERR_NONFATAL, "`)' expected to terminate macro template"); free_tlist(origline); return DIRECTIVE_FOUND; } break; } last = tline; tline = tline->next; } if (tok_type_(tline, TOK_WHITESPACE)) last = tline, tline = tline->next; macro_start = NULL; last->next = NULL; t = tline; while (t) { if (t->type == TOK_ID) { for (tt = param_start; tt; tt = tt->next) if (tt->type >= TOK_SMAC_PARAM && !strcmp(tt->text, t->text)) t->type = tt->type; } tt = t->next; t->next = macro_start; macro_start = t; t = tt; } /* * Good. We now have a macro name, a parameter count, and a * token list (in reverse order) for an expansion. We ought * to be OK just to create an SMacro, store it, and let * free_tlist have the rest of the line (which we have * carefully re-terminated after chopping off the expansion * from the end). */ if (smacro_defined(ctx, mname, nparam, &smac, i == PP_DEFINE)) { if (!smac) { error(ERR_WARNING, "single-line macro `%s' defined both with and" " without parameters", mname); free_tlist(origline); free_tlist(macro_start); return DIRECTIVE_FOUND; } else if (smac->level == Level) { /* * We're redefining in the same level, so we have to * take over an existing SMacro structure. This means * freeing what was already in it. */ nasm_free(smac->name); free_tlist(smac->expansion); } else { smac = nasm_malloc(sizeof(SMacro)); smac->next = *smhead; *smhead = smac; } } else { smac = nasm_malloc(sizeof(SMacro)); smac->next = *smhead; *smhead = smac; } smac->name = nasm_strdup(mname); smac->casesense = ((i == PP_DEFINE) || (i == PP_XDEFINE)); smac->nparam = nparam; smac->level = Level; smac->expansion = macro_start; smac->in_progress = FALSE; free_tlist(origline); return DIRECTIVE_FOUND; case PP_UNDEF: tline = tline->next; skip_white_(tline); tline = expand_id(tline); if (!tline || (tline->type != TOK_ID && (tline->type != TOK_PREPROC_ID || tline->text[1] != '$'))) { error(ERR_NONFATAL, "`%%undef' expects a macro identifier"); free_tlist(origline); return DIRECTIVE_FOUND; } if (tline->next) { error(ERR_WARNING, "trailing garbage after macro name ignored"); } /* Find the context that symbol belongs to */ ctx = get_ctx(tline->text, FALSE); if (!ctx) smhead = &smacros[hash(tline->text)]; else smhead = &ctx->localmac; mname = tline->text; /* * We now have a macro name... go hunt for it. */ while (smacro_defined(ctx, mname, -1, &smac, 1)) { /* Defined, so we need to find its predecessor and nuke it */ SMacro **s; for (s = smhead; *s && *s != smac; s = &(*s)->next); if (*s) { *s = smac->next; nasm_free(smac->name); free_tlist(smac->expansion); nasm_free(smac); } } free_tlist(origline); return DIRECTIVE_FOUND; case PP_STRLEN: tline = tline->next; skip_white_(tline); tline = expand_id(tline); if (!tline || (tline->type != TOK_ID && (tline->type != TOK_PREPROC_ID || tline->text[1] != '$'))) { error(ERR_NONFATAL, "`%%strlen' expects a macro identifier as first parameter"); free_tlist(origline); return DIRECTIVE_FOUND; } ctx = get_ctx(tline->text, FALSE); if (!ctx) smhead = &smacros[hash(tline->text)]; else smhead = &ctx->localmac; mname = tline->text; last = tline; tline = expand_smacro(tline->next); last->next = NULL; t = tline; while (tok_type_(t, TOK_WHITESPACE)) t = t->next; /* t should now point to the string */ if (t->type != TOK_STRING) { error(ERR_NONFATAL, "`%%strlen` requires string as second parameter"); free_tlist(tline); free_tlist(origline); return DIRECTIVE_FOUND; } macro_start = nasm_malloc(sizeof(*macro_start)); macro_start->next = NULL; make_tok_num(macro_start, yasm_intnum_create_uint((unsigned long)(strlen(t->text) - 2))); macro_start->mac = NULL; /* * We now have a macro name, an implicit parameter count of * zero, and a numeric token to use as an expansion. Create * and store an SMacro. */ if (smacro_defined(ctx, mname, 0, &smac, i == PP_STRLEN)) { if (!smac) error(ERR_WARNING, "single-line macro `%s' defined both with and" " without parameters", mname); else { /* * We're redefining, so we have to take over an * existing SMacro structure. This means freeing * what was already in it. */ nasm_free(smac->name); free_tlist(smac->expansion); } } else { smac = nasm_malloc(sizeof(SMacro)); smac->next = *smhead; *smhead = smac; } smac->name = nasm_strdup(mname); smac->casesense = (i == PP_STRLEN); smac->nparam = 0; smac->level = 0; smac->expansion = macro_start; smac->in_progress = FALSE; free_tlist(tline); free_tlist(origline); return DIRECTIVE_FOUND; case PP_SUBSTR: tline = tline->next; skip_white_(tline); tline = expand_id(tline); if (!tline || (tline->type != TOK_ID && (tline->type != TOK_PREPROC_ID || tline->text[1] != '$'))) { error(ERR_NONFATAL, "`%%substr' expects a macro identifier as first parameter"); free_tlist(origline); return DIRECTIVE_FOUND; } ctx = get_ctx(tline->text, FALSE); if (!ctx) smhead = &smacros[hash(tline->text)]; else smhead = &ctx->localmac; mname = tline->text; last = tline; tline = expand_smacro(tline->next); last->next = NULL; t = tline->next; while (tok_type_(t, TOK_WHITESPACE)) t = t->next; /* t should now point to the string */ if (t->type != TOK_STRING) { error(ERR_NONFATAL, "`%%substr` requires string as second parameter"); free_tlist(tline); free_tlist(origline); return DIRECTIVE_FOUND; } tt = t->next; tptr = &tt; tokval.t_type = TOKEN_INVALID; evalresult = evaluate(ppscan, tptr, &tokval, pass, error); if (!evalresult) { free_tlist(tline); free_tlist(origline); return DIRECTIVE_FOUND; } intn = yasm_expr_get_intnum(&evalresult, 0); if (!intn) { error(ERR_NONFATAL, "non-constant value given to `%%substr`"); free_tlist(tline); free_tlist(origline); yasm_expr_destroy(evalresult); return DIRECTIVE_FOUND; } macro_start = nasm_malloc(sizeof(*macro_start)); macro_start->next = NULL; macro_start->text = nasm_strdup("'''"); if (yasm_intnum_sign(intn) == 1 && yasm_intnum_get_uint(intn) < strlen(t->text) - 1) { macro_start->text[1] = t->text[yasm_intnum_get_uint(intn)]; } else { macro_start->text[2] = '\0'; } yasm_expr_destroy(evalresult); macro_start->type = TOK_STRING; macro_start->mac = NULL; /* * We now have a macro name, an implicit parameter count of * zero, and a numeric token to use as an expansion. Create * and store an SMacro. */ if (smacro_defined(ctx, mname, 0, &smac, i == PP_SUBSTR)) { if (!smac) error(ERR_WARNING, "single-line macro `%s' defined both with and" " without parameters", mname); else { /* * We're redefining, so we have to take over an * existing SMacro structure. This means freeing * what was already in it. */ nasm_free(smac->name); free_tlist(smac->expansion); } } else { smac = nasm_malloc(sizeof(SMacro)); smac->next = *smhead; *smhead = smac; } smac->name = nasm_strdup(mname); smac->casesense = (i == PP_SUBSTR); smac->nparam = 0; smac->level = 0; smac->expansion = macro_start; smac->in_progress = FALSE; free_tlist(tline); free_tlist(origline); return DIRECTIVE_FOUND; case PP_ASSIGN: case PP_IASSIGN: tline = tline->next; skip_white_(tline); tline = expand_id(tline); if (!tline || (tline->type != TOK_ID && (tline->type != TOK_PREPROC_ID || tline->text[1] != '$'))) { error(ERR_NONFATAL, "`%%%sassign' expects a macro identifier", (i == PP_IASSIGN ? "i" : "")); free_tlist(origline); return DIRECTIVE_FOUND; } ctx = get_ctx(tline->text, FALSE); if (!ctx) smhead = &smacros[hash(tline->text)]; else smhead = &ctx->localmac; mname = tline->text; last = tline; tline = expand_smacro(tline->next); last->next = NULL; t = tline; tptr = &t; tokval.t_type = TOKEN_INVALID; evalresult = evaluate(ppscan, tptr, &tokval, pass, error); free_tlist(tline); if (!evalresult) { free_tlist(origline); return DIRECTIVE_FOUND; } if (tokval.t_type) error(ERR_WARNING, "trailing garbage after expression ignored"); intn = yasm_expr_get_intnum(&evalresult, 0); if (!intn) { error(ERR_NONFATAL, "non-constant value given to `%%%sassign'", (i == PP_IASSIGN ? "i" : "")); free_tlist(origline); yasm_expr_destroy(evalresult); return DIRECTIVE_FOUND; } macro_start = nasm_malloc(sizeof(*macro_start)); macro_start->next = NULL; make_tok_num(macro_start, yasm_intnum_copy(intn)); yasm_expr_destroy(evalresult); macro_start->mac = NULL; /* * We now have a macro name, an implicit parameter count of * zero, and a numeric token to use as an expansion. Create * and store an SMacro. */ if (smacro_defined(ctx, mname, 0, &smac, i == PP_ASSIGN)) { if (!smac) error(ERR_WARNING, "single-line macro `%s' defined both with and" " without parameters", mname); else { /* * We're redefining, so we have to take over an * existing SMacro structure. This means freeing * what was already in it. */ nasm_free(smac->name); free_tlist(smac->expansion); } } else { smac = nasm_malloc(sizeof(SMacro)); smac->next = *smhead; *smhead = smac; } smac->name = nasm_strdup(mname); smac->casesense = (i == PP_ASSIGN); smac->nparam = 0; smac->level = 0; smac->expansion = macro_start; smac->in_progress = FALSE; free_tlist(origline); return DIRECTIVE_FOUND; case PP_LINE: /* * Syntax is `%line nnn[+mmm] [filename]' */ tline = tline->next; skip_white_(tline); if (!tok_type_(tline, TOK_NUMBER)) { error(ERR_NONFATAL, "`%%line' expects line number"); free_tlist(origline); return DIRECTIVE_FOUND; } intn = nasm_readnum(tline->text, &j); k = yasm_intnum_get_int(intn); yasm_intnum_destroy(intn); m = 1; tline = tline->next; if (tok_is_(tline, "+")) { tline = tline->next; if (!tok_type_(tline, TOK_NUMBER)) { error(ERR_NONFATAL, "`%%line' expects line increment"); free_tlist(origline); return DIRECTIVE_FOUND; } intn = nasm_readnum(tline->text, &j); m = yasm_intnum_get_int(intn); yasm_intnum_destroy(intn); tline = tline->next; } skip_white_(tline); nasm_src_set_linnum(k); istk->lineinc = m; if (tline) { nasm_free(nasm_src_set_fname(detoken(tline, FALSE))); } free_tlist(origline); return DIRECTIVE_FOUND; default: error(ERR_FATAL, "preprocessor directive `%s' not yet implemented", directives[i]); break; } return DIRECTIVE_FOUND; } /* * Ensure that a macro parameter contains a condition code and * nothing else. Return the condition code index if so, or -1 * otherwise. */ static int find_cc(Token * t) { Token *tt; int i, j, k, m; skip_white_(t); if (t->type != TOK_ID) return -1; tt = t->next; skip_white_(tt); if (tt && (tt->type != TOK_OTHER || strcmp(tt->text, ","))) return -1; i = -1; j = elements(conditions); while (j - i > 1) { k = (j + i) / 2; m = nasm_stricmp(t->text, conditions[k]); if (m == 0) { i = k; j = -2; break; } else if (m < 0) { j = k; } else i = k; } if (j != -2) return -1; return i; } /* * Expand MMacro-local things: parameter references (%0, %n, %+n, * %-n) and MMacro-local identifiers (%%foo). */ static Token * expand_mmac_params(Token * tline) { Token *t, *tt, **tail, *thead; tail = &thead; thead = NULL; while (tline) { if (tline->type == TOK_PREPROC_ID && (((tline->text[1] == '+' || tline->text[1] == '-') && tline->text[2]) || tline->text[1] == '%' || (tline->text[1] >= '0' && tline->text[1] <= '9'))) { char *text = NULL; int type = 0, cc; /* type = 0 to placate optimisers */ char tmpbuf[30]; char *second_text = NULL; int n, i; MMacro *mac; t = tline; tline = tline->next; second_text = strchr(t->text, ':'); mac = istk->mstk; while (mac && !mac->name) /* avoid mistaking %reps for macros */ mac = mac->next_active; if (!mac) error(ERR_NONFATAL, "`%s': not in a macro call", t->text); else { if (second_text) { int end = atoi(second_text+1)-1; int is_fst = 1; int k; n = atoi(t->text + 1)-1; if (end < 0) end += mac->nparam; for (k = n; k <= end; k++) { if (k >= mac->nparam) tt = NULL; else { if (mac->nparam > 1) k = (k + mac->rotate) % mac->nparam; tt = mac->params[k]; } if (tt) { if (!is_fst && mac->paramlen[k]) { *tail = new_Token(NULL, TOK_OTHER, ",", 0); tail = &(*tail)->next; } if (mac->paramlen[k]) is_fst = 0; for (i = 0; i < mac->paramlen[k]; i++) { *tail = new_Token(NULL, tt->type, tt->text, 0); tail = &(*tail)->next; tt = tt->next; } } text = NULL; /* we've done it here */ } } else { switch (t->text[1]) { /* * We have to make a substitution of one of the * forms %1, %-1, %+1, %%foo, %0. */ case '0': type = TOK_NUMBER; sprintf(tmpbuf, "%ld", mac->nparam); text = nasm_strdup(tmpbuf); break; case '%': type = TOK_ID; sprintf(tmpbuf, "..@%lu.", mac->unique); text = nasm_strcat(tmpbuf, t->text + 2); break; case '-': n = atoi(t->text + 2) - 1; if (n >= mac->nparam) tt = NULL; else { if (mac->nparam > 1) n = (n + mac->rotate) % mac->nparam; tt = mac->params[n]; } cc = find_cc(tt); if (cc == -1) { error(ERR_NONFATAL, "macro parameter %d is not a condition code", n + 1); text = NULL; } else { type = TOK_ID; if (inverse_ccs[cc] == -1) { error(ERR_NONFATAL, "condition code `%s' is not invertible", conditions[cc]); text = NULL; } else text = nasm_strdup(conditions[inverse_ccs [cc]]); } break; case '+': n = atoi(t->text + 2) - 1; if (n >= mac->nparam) tt = NULL; else { if (mac->nparam > 1) n = (n + mac->rotate) % mac->nparam; tt = mac->params[n]; } cc = find_cc(tt); if (cc == -1) { error(ERR_NONFATAL, "macro parameter %d is not a condition code", n + 1); text = NULL; } else { type = TOK_ID; text = nasm_strdup(conditions[cc]); } break; default: n = atoi(t->text + 1) - 1; if (n >= mac->nparam) tt = NULL; else { if (mac->nparam > 1) n = (n + mac->rotate) % mac->nparam; tt = mac->params[n]; } if (tt) { for (i = 0; i < mac->paramlen[n]; i++) { *tail = new_Token(NULL, tt->type, tt->text, 0); tail = &(*tail)->next; tt = tt->next; } } text = NULL; /* we've done it here */ break; } } } if (!text) { delete_Token(t); } else { *tail = t; tail = &t->next; t->type = type; nasm_free(t->text); t->text = text; t->mac = NULL; } continue; } else { t = *tail = tline; tline = tline->next; t->mac = NULL; tail = &t->next; } } *tail = NULL; t = thead; for (; t && (tt = t->next) != NULL; t = t->next) switch (t->type) { case TOK_WHITESPACE: if (tt->type == TOK_WHITESPACE) { t->next = delete_Token(tt); } break; case TOK_ID: if (tt->type == TOK_ID || tt->type == TOK_NUMBER) { char *tmp = nasm_strcat(t->text, tt->text); nasm_free(t->text); t->text = tmp; t->next = delete_Token(tt); } break; case TOK_NUMBER: if (tt->type == TOK_NUMBER) { char *tmp = nasm_strcat(t->text, tt->text); nasm_free(t->text); t->text = tmp; t->next = delete_Token(tt); } break; } return thead; } /* * Expand all single-line macro calls made in the given line. * Return the expanded version of the line. The original is deemed * to be destroyed in the process. (In reality we'll just move * Tokens from input to output a lot of the time, rather than * actually bothering to destroy and replicate.) */ static Token * expand_smacro(Token * tline) { Token *t, *tt, *mstart, **tail, *thead; SMacro *head = NULL, *m; Token **params; int *paramsize; int nparam, sparam, brackets, rescan; Token *org_tline = tline; Context *ctx; char *mname; /* * Trick: we should avoid changing the start token pointer since it can * be contained in "next" field of other token. Because of this * we allocate a copy of first token and work with it; at the end of * routine we copy it back */ if (org_tline) { tline = new_Token(org_tline->next, org_tline->type, org_tline->text, 0); tline->mac = org_tline->mac; nasm_free(org_tline->text); org_tline->text = NULL; } again: tail = &thead; thead = NULL; while (tline) { /* main token loop */ if ((mname = tline->text)) { /* if this token is a local macro, look in local context */ if (tline->type == TOK_ID || tline->type == TOK_PREPROC_ID) ctx = get_ctx(mname, TRUE); else ctx = NULL; if (!ctx) head = smacros[hash(mname)]; else head = ctx->localmac; /* * We've hit an identifier. As in is_mmacro below, we first * check whether the identifier is a single-line macro at * all, then think about checking for parameters if * necessary. */ for (m = head; m; m = m->next) if (!mstrcmp(m->name, mname, m->casesense)) break; if (m) { mstart = tline; params = NULL; paramsize = NULL; if (m->nparam == 0) { /* * Simple case: the macro is parameterless. Discard the * one token that the macro call took, and push the * expansion back on the to-do stack. */ if (!m->expansion) { if (!strcmp("__FILE__", m->name)) { long num = 0; nasm_src_get(&num, &(tline->text)); nasm_quote(&(tline->text)); tline->type = TOK_STRING; continue; } if (!strcmp("__LINE__", m->name)) { nasm_free(tline->text); make_tok_num(tline, yasm_intnum_create_int(nasm_src_get_linnum())); continue; } tline = delete_Token(tline); continue; } } else { /* * Complicated case: at least one macro with this name * exists and takes parameters. We must find the * parameters in the call, count them, find the SMacro * that corresponds to that form of the macro call, and * substitute for the parameters when we expand. What a * pain. */ /*tline = tline->next; skip_white_(tline);*/ do { t = tline->next; while (tok_type_(t, TOK_SMAC_END)) { t->mac->in_progress = FALSE; t->text = NULL; t = tline->next = delete_Token(t); } tline = t; } while (tok_type_(tline, TOK_WHITESPACE)); if (!tok_is_(tline, "(")) { /* * This macro wasn't called with parameters: ignore * the call. (Behaviour borrowed from gnu cpp.) */ tline = mstart; m = NULL; } else { int paren = 0; int white = 0; brackets = 0; nparam = 0; sparam = PARAM_DELTA; params = nasm_malloc(sparam * sizeof(Token *)); params[0] = tline->next; paramsize = nasm_malloc(sparam * sizeof(int)); paramsize[0] = 0; while (TRUE) { /* parameter loop */ /* * For some unusual expansions * which concatenates function call */ t = tline->next; while (tok_type_(t, TOK_SMAC_END)) { t->mac->in_progress = FALSE; t->text = NULL; t = tline->next = delete_Token(t); } tline = t; if (!tline) { error(ERR_NONFATAL, "macro call expects terminating `)'"); break; } if (tline->type == TOK_WHITESPACE && brackets <= 0) { if (paramsize[nparam]) white++; else params[nparam] = tline->next; continue; /* parameter loop */ } if (tline->type == TOK_OTHER && tline->text[1] == 0) { char ch = tline->text[0]; if (ch == ',' && !paren && brackets <= 0) { if (++nparam >= sparam) { sparam += PARAM_DELTA; params = nasm_realloc(params, sparam * sizeof(Token *)); paramsize = nasm_realloc(paramsize, sparam * sizeof(int)); } params[nparam] = tline->next; paramsize[nparam] = 0; white = 0; continue; /* parameter loop */ } if (ch == '{' && (brackets > 0 || (brackets == 0 && !paramsize[nparam]))) { if (!(brackets++)) { params[nparam] = tline->next; continue; /* parameter loop */ } } if (ch == '}' && brackets > 0) if (--brackets == 0) { brackets = -1; continue; /* parameter loop */ } if (ch == '(' && !brackets) paren++; if (ch == ')' && brackets <= 0) if (--paren < 0) break; } if (brackets < 0) { brackets = 0; error(ERR_NONFATAL, "braces do not " "enclose all of macro parameter"); } paramsize[nparam] += white + 1; white = 0; } /* parameter loop */ nparam++; while (m && (m->nparam != nparam || mstrcmp(m->name, mname, m->casesense))) m = m->next; if (!m) error(ERR_WARNING | ERR_WARN_MNP, "macro `%s' exists, " "but not taking %d parameters", mstart->text, nparam); } } if (m && m->in_progress) m = NULL; if (!m) /* in progess or didn't find '(' or wrong nparam */ { /* * Design question: should we handle !tline, which * indicates missing ')' here, or expand those * macros anyway, which requires the (t) test a few * lines down? */ nasm_free(params); nasm_free(paramsize); tline = mstart; } else { /* * Expand the macro: we are placed on the last token of the * call, so that we can easily split the call from the * following tokens. We also start by pushing an SMAC_END * token for the cycle removal. */ t = tline; if (t) { tline = t->next; t->next = NULL; } tt = new_Token(tline, TOK_SMAC_END, NULL, 0); tt->mac = m; m->in_progress = TRUE; tline = tt; for (t = m->expansion; t; t = t->next) { if (t->type >= TOK_SMAC_PARAM) { Token *pcopy = tline, **ptail = &pcopy; Token *ttt, *pt; int i; ttt = params[t->type - TOK_SMAC_PARAM]; for (i = paramsize[t->type - TOK_SMAC_PARAM]; --i >= 0;) { pt = *ptail = new_Token(tline, ttt->type, ttt->text, 0); ptail = &pt->next; ttt = ttt->next; } tline = pcopy; } else { tt = new_Token(tline, t->type, t->text, 0); tline = tt; } } /* * Having done that, get rid of the macro call, and clean * up the parameters. */ nasm_free(params); nasm_free(paramsize); free_tlist(mstart); continue; /* main token loop */ } } } if (tline->type == TOK_SMAC_END) { tline->mac->in_progress = FALSE; tline = delete_Token(tline); } else { t = *tail = tline; tline = tline->next; t->mac = NULL; t->next = NULL; tail = &t->next; } } /* * Now scan the entire line and look for successive TOK_IDs that resulted * after expansion (they can't be produced by tokenise()). The successive * TOK_IDs should be concatenated. * Also we look for %+ tokens and concatenate the tokens before and after * them (without white spaces in between). */ t = thead; rescan = 0; while (t) { while (t && t->type != TOK_ID && t->type != TOK_PREPROC_ID) t = t->next; if (!t || !t->next) break; if (t->next->type == TOK_ID || t->next->type == TOK_PREPROC_ID || t->next->type == TOK_NUMBER) { char *p = nasm_strcat(t->text, t->next->text); nasm_free(t->text); t->next = delete_Token(t->next); t->text = p; rescan = 1; } else if (t->next->type == TOK_WHITESPACE && t->next->next && t->next->next->type == TOK_PREPROC_ID && strcmp(t->next->next->text, "%+") == 0) { /* free the next whitespace, the %+ token and next whitespace */ int i; for (i = 1; i <= 3; i++) { if (!t->next || (i != 2 && t->next->type != TOK_WHITESPACE)) break; t->next = delete_Token(t->next); } /* endfor */ } else t = t->next; } /* If we concatenaded something, re-scan the line for macros */ if (rescan) { tline = thead; goto again; } if (org_tline) { if (thead) { *org_tline = *thead; /* since we just gave text to org_line, don't free it */ thead->text = NULL; delete_Token(thead); } else { /* the expression expanded to empty line; we can't return NULL for some reasons we just set the line to a single WHITESPACE token. */ memset(org_tline, 0, sizeof(*org_tline)); org_tline->text = NULL; org_tline->type = TOK_WHITESPACE; } thead = org_tline; } return thead; } /* * Similar to expand_smacro but used exclusively with macro identifiers * right before they are fetched in. The reason is that there can be * identifiers consisting of several subparts. We consider that if there * are more than one element forming the name, user wants a expansion, * otherwise it will be left as-is. Example: * * %define %$abc cde * * the identifier %$abc will be left as-is so that the handler for %define * will suck it and define the corresponding value. Other case: * * %define _%$abc cde * * In this case user wants name to be expanded *before* %define starts * working, so we'll expand %$abc into something (if it has a value; * otherwise it will be left as-is) then concatenate all successive * PP_IDs into one. */ static Token * expand_id(Token * tline) { Token *cur, *oldnext = NULL; if (!tline || !tline->next) return tline; cur = tline; while (cur->next && (cur->next->type == TOK_ID || cur->next->type == TOK_PREPROC_ID || cur->next->type == TOK_NUMBER)) cur = cur->next; /* If identifier consists of just one token, don't expand */ if (cur == tline) return tline; if (cur) { oldnext = cur->next; /* Detach the tail past identifier */ cur->next = NULL; /* so that expand_smacro stops here */ } tline = expand_smacro(tline); if (cur) { /* expand_smacro possibly changhed tline; re-scan for EOL */ cur = tline; while (cur && cur->next) cur = cur->next; if (cur) cur->next = oldnext; } return tline; } /* * Determine whether the given line constitutes a multi-line macro * call, and return the MMacro structure called if so. Doesn't have * to check for an initial label - that's taken care of in * expand_mmacro - but must check numbers of parameters. Guaranteed * to be called with tline->type == TOK_ID, so the putative macro * name is easy to find. */ static MMacro * is_mmacro(Token * tline, Token *** params_array) { MMacro *head, *m; Token **params; int nparam; head = mmacros[hash(tline->text)]; /* * Efficiency: first we see if any macro exists with the given * name. If not, we can return NULL immediately. _Then_ we * count the parameters, and then we look further along the * list if necessary to find the proper MMacro. */ for (m = head; m; m = m->next) if (!mstrcmp(m->name, tline->text, m->casesense)) break; if (!m) return NULL; /* * OK, we have a potential macro. Count and demarcate the * parameters. */ count_mmac_params(tline->next, &nparam, ¶ms); /* * So we know how many parameters we've got. Find the MMacro * structure that handles this number. */ while (m) { if (m->nparam_min <= nparam && (m->plus || nparam <= m->nparam_max)) { /* * This one is right. Just check if cycle removal * prohibits us using it before we actually celebrate... */ if (m->in_progress) { #if 0 error(ERR_NONFATAL, "self-reference in multi-line macro `%s'", m->name); #endif nasm_free(params); return NULL; } /* * It's right, and we can use it. Add its default * parameters to the end of our list if necessary. */ if (m->defaults && nparam < m->nparam_min + m->ndefs) { params = nasm_realloc(params, ((m->nparam_min + m->ndefs + 1) * sizeof(*params))); while (nparam < m->nparam_min + m->ndefs) { params[nparam] = m->defaults[nparam - m->nparam_min]; nparam++; } } /* * If we've gone over the maximum parameter count (and * we're in Plus mode), ignore parameters beyond * nparam_max. */ if (m->plus && nparam > m->nparam_max) nparam = m->nparam_max; /* * Then terminate the parameter list, and leave. */ if (!params) { /* need this special case */ params = nasm_malloc(sizeof(*params)); nparam = 0; } params[nparam] = NULL; *params_array = params; return m; } /* * This one wasn't right: look for the next one with the * same name. */ for (m = m->next; m; m = m->next) if (!mstrcmp(m->name, tline->text, m->casesense)) break; } /* * After all that, we didn't find one with the right number of * parameters. Issue a warning, and fail to expand the macro. */ error(ERR_WARNING | ERR_WARN_MNP, "macro `%s' exists, but not taking %d parameters", tline->text, nparam); nasm_free(params); return NULL; } /* * Expand the multi-line macro call made by the given line, if * there is one to be expanded. If there is, push the expansion on * istk->expansion and return 1. Otherwise return 0. */ static int expand_mmacro(Token * tline) { Token *startline = tline; Token *label = NULL; int dont_prepend = 0; Token **params, *t, *tt; MMacro *m; Line *l, *ll; int i, nparam; long *paramlen; t = tline; skip_white_(t); /* if (!tok_type_(t, TOK_ID)) Lino 02/25/02 */ if (!tok_type_(t, TOK_ID) && !tok_type_(t, TOK_PREPROC_ID)) return 0; m = is_mmacro(t, ¶ms); if (!m) { Token *last; /* * We have an id which isn't a macro call. We'll assume * it might be a label; we'll also check to see if a * colon follows it. Then, if there's another id after * that lot, we'll check it again for macro-hood. */ label = last = t; t = t->next; if (tok_type_(t, TOK_WHITESPACE)) last = t, t = t->next; if (tok_is_(t, ":")) { dont_prepend = 1; last = t, t = t->next; if (tok_type_(t, TOK_WHITESPACE)) last = t, t = t->next; } if (!tok_type_(t, TOK_ID) || (m = is_mmacro(t, ¶ms)) == NULL) return 0; last->next = NULL; tline = t; } /* * Fix up the parameters: this involves stripping leading and * trailing whitespace, then stripping braces if they are * present. */ for (nparam = 0; params[nparam]; nparam++) ; paramlen = nparam ? nasm_malloc(nparam * sizeof(*paramlen)) : NULL; for (i = 0; params[i]; i++) { int brace = FALSE; int comma = (!m->plus || i < nparam - 1); t = params[i]; skip_white_(t); if (tok_is_(t, "{")) t = t->next, brace = TRUE, comma = FALSE; params[i] = t; paramlen[i] = 0; while (t) { if (comma && t->type == TOK_OTHER && !strcmp(t->text, ",")) break; /* ... because we have hit a comma */ if (comma && t->type == TOK_WHITESPACE && tok_is_(t->next, ",")) break; /* ... or a space then a comma */ if (brace && t->type == TOK_OTHER && !strcmp(t->text, "}")) break; /* ... or a brace */ t = t->next; paramlen[i]++; } } /* * OK, we have a MMacro structure together with a set of * parameters. We must now go through the expansion and push * copies of each Line on to istk->expansion. Substitution of * parameter tokens and macro-local tokens doesn't get done * until the single-line macro substitution process; this is * because delaying them allows us to change the semantics * later through %rotate. * * First, push an end marker on to istk->expansion, mark this * macro as in progress, and set up its invocation-specific * variables. */ ll = nasm_malloc(sizeof(Line)); ll->next = istk->expansion; ll->finishes = m; ll->first = NULL; istk->expansion = ll; m->in_progress = TRUE; m->params = params; m->iline = tline; m->nparam = nparam; m->rotate = 0; m->paramlen = paramlen; m->unique = unique++; m->lineno = 0; m->next_active = istk->mstk; istk->mstk = m; for (l = m->expansion; l; l = l->next) { Token **tail; ll = nasm_malloc(sizeof(Line)); ll->finishes = NULL; ll->next = istk->expansion; istk->expansion = ll; tail = &ll->first; for (t = l->first; t; t = t->next) { Token *x = t; if (t->type == TOK_PREPROC_ID && t->text[1] == '0' && t->text[2] == '0') { dont_prepend = -1; x = label; if (!x) continue; } tt = *tail = new_Token(NULL, x->type, x->text, 0); tail = &tt->next; } *tail = NULL; } /* * If we had a label, push it on as the first line of * the macro expansion. */ if (label) { if (dont_prepend < 0) free_tlist(startline); else { ll = nasm_malloc(sizeof(Line)); ll->finishes = NULL; ll->next = istk->expansion; istk->expansion = ll; ll->first = startline; if (!dont_prepend) { while (label->next) label = label->next; label->next = tt = new_Token(NULL, TOK_OTHER, ":", 0); } } } list->uplevel(m->nolist ? LIST_MACRO_NOLIST : LIST_MACRO); return 1; } /* * Since preprocessor always operates only on the line that didn't * arrive yet, we should always use ERR_OFFBY1. Also since user * won't want to see same error twice (preprocessing is done once * per pass) we will want to show errors only during pass one. */ static void error(int severity, const char *fmt, ...) { va_list arg; char buff[1024]; /* If we're in a dead branch of IF or something like it, ignore the error */ if (istk && istk->conds && !emitting(istk->conds->state)) return; va_start(arg, fmt); #ifdef HAVE_VSNPRINTF vsnprintf(buff, sizeof(buff), fmt, arg); #else vsprintf(buff, fmt, arg); #endif va_end(arg); if (istk && istk->mstk && istk->mstk->name) _error(severity | ERR_PASS1, "(%s:%d) %s", istk->mstk->name, istk->mstk->lineno, buff); else _error(severity | ERR_PASS1, "%s", buff); } static void pp_reset(FILE *f, const char *file, int apass, efunc errfunc, evalfunc eval, ListGen * listgen) { int h; first_fp = f; _error = errfunc; cstk = NULL; istk = nasm_malloc(sizeof(Include)); istk->next = NULL; istk->conds = NULL; istk->expansion = NULL; istk->mstk = NULL; istk->fp = f; istk->fname = NULL; nasm_free(nasm_src_set_fname(nasm_strdup(file))); nasm_src_set_linnum(0); istk->lineinc = 1; defining = NULL; nested_mac_count = 0; nested_rep_count = 0; for (h = 0; h < NHASH; h++) { mmacros[h] = NULL; smacros[h] = NULL; } unique = 0; if (tasm_compatible_mode) { pp_extra_stdmac(tasm_compat_macros); } list = listgen; evaluate = eval; pass = apass; first_line = 1; } /* * Nasty hack: here we push the contents of `predef' on * to the top-level expansion stack, since this is the * most convenient way to implement the pre-include and * pre-define features. */ static void poke_predef(Line *predef_lines) { Line *pd, *l; Token *head, **tail, *t; for (pd = predef_lines; pd; pd = pd->next) { head = NULL; tail = &head; for (t = pd->first; t; t = t->next) { *tail = new_Token(NULL, t->type, t->text, 0); tail = &(*tail)->next; } l = nasm_malloc(sizeof(Line)); l->next = istk->expansion; l->first = head; l->finishes = FALSE; istk->expansion = l; } } static char * pp_getline(void) { char *line; Token *tline; while (1) { /* * Fetch a tokenised line, either from the macro-expansion * buffer or from the input file. */ tline = NULL; if (first_line) { /* Reverse order */ poke_predef(predef); poke_predef(stddef); poke_predef(builtindef); first_line = 0; } if (!istk) return NULL; while (istk->expansion && istk->expansion->finishes) { Line *l = istk->expansion; if (!l->finishes->name && l->finishes->in_progress > 1) { Line *ll; /* * This is a macro-end marker for a macro with no * name, which means it's not really a macro at all * but a %rep block, and the `in_progress' field is * more than 1, meaning that we still need to * repeat. (1 means the natural last repetition; 0 * means termination by %exitrep.) We have * therefore expanded up to the %endrep, and must * push the whole block on to the expansion buffer * again. We don't bother to remove the macro-end * marker: we'd only have to generate another one * if we did. */ l->finishes->in_progress--; for (l = l->finishes->expansion; l; l = l->next) { Token *t, *tt, **tail; ll = nasm_malloc(sizeof(Line)); ll->next = istk->expansion; ll->finishes = NULL; ll->first = NULL; tail = &ll->first; for (t = l->first; t; t = t->next) { if (t->text || t->type == TOK_WHITESPACE) { tt = *tail = new_Token(NULL, t->type, t->text, 0); tail = &tt->next; } } istk->expansion = ll; } } else { /* * Check whether a `%rep' was started and not ended * within this macro expansion. This can happen and * should be detected. It's a fatal error because * I'm too confused to work out how to recover * sensibly from it. */ if (defining) { if (defining->name) error(ERR_PANIC, "defining with name in expansion"); else if (istk->mstk->name) error(ERR_FATAL, "`%%rep' without `%%endrep' within" " expansion of macro `%s'", istk->mstk->name); } /* * FIXME: investigate the relationship at this point between * istk->mstk and l->finishes */ { MMacro *m = istk->mstk; istk->mstk = m->next_active; if (m->name) { /* * This was a real macro call, not a %rep, and * therefore the parameter information needs to * be freed. */ nasm_free(m->params); free_tlist(m->iline); nasm_free(m->paramlen); l->finishes->in_progress = FALSE; } else free_mmacro(m); } istk->expansion = l->next; nasm_free(l); list->downlevel(LIST_MACRO); } } while (1) { /* until we get a line we can use */ if (istk->expansion) { /* from a macro expansion */ char *p; Line *l = istk->expansion; if (istk->mstk) istk->mstk->lineno++; tline = l->first; istk->expansion = l->next; nasm_free(l); p = detoken(tline, FALSE); list->line(LIST_MACRO, p); nasm_free(p); break; } line = read_line(); if (line) { /* from the current input file */ line = prepreproc(line); tline = tokenise(line); nasm_free(line); break; } /* * The current file has ended; work down the istk */ { Include *i = istk; if (i->fp != first_fp) fclose(i->fp); if (i->conds) error(ERR_FATAL, "expected `%%endif' before end of file"); /* only set line and file name if there's a next node */ if (i->next) { nasm_src_set_linnum(i->lineno); nasm_free(nasm_src_set_fname(nasm_strdup(i->fname))); } istk = i->next; list->downlevel(LIST_INCLUDE); nasm_free(i); if (!istk) return NULL; if (istk->expansion && istk->expansion->finishes) break; } } /* * We must expand MMacro parameters and MMacro-local labels * _before_ we plunge into directive processing, to cope * with things like `%define something %1' such as STRUC * uses. Unless we're _defining_ a MMacro, in which case * those tokens should be left alone to go into the * definition; and unless we're in a non-emitting * condition, in which case we don't want to meddle with * anything. */ if (!defining && !(istk->conds && !emitting(istk->conds->state))) tline = expand_mmac_params(tline); /* * Check the line to see if it's a preprocessor directive. */ if (do_directive(tline) == DIRECTIVE_FOUND) { continue; } else if (defining) { /* * We're defining a multi-line macro. We emit nothing * at all, and just * shove the tokenised line on to the macro definition. */ Line *l = nasm_malloc(sizeof(Line)); l->next = defining->expansion; l->first = tline; l->finishes = FALSE; defining->expansion = l; continue; } else if (istk->conds && !emitting(istk->conds->state)) { /* * We're in a non-emitting branch of a condition block. * Emit nothing at all, not even a blank line: when we * emerge from the condition we'll give a line-number * directive so we keep our place correctly. */ free_tlist(tline); continue; } else if (istk->mstk && !istk->mstk->in_progress) { /* * We're in a %rep block which has been terminated, so * we're walking through to the %endrep without * emitting anything. Emit nothing at all, not even a * blank line: when we emerge from the %rep block we'll * give a line-number directive so we keep our place * correctly. */ free_tlist(tline); continue; } else { tline = expand_smacro(tline); if (!expand_mmacro(tline)) { /* * De-tokenise the line again, and emit it. */ if (tasm_compatible_mode) tline = tasm_join_tokens(tline); line = detoken(tline, TRUE); free_tlist(tline); break; } else { continue; /* expand_mmacro calls free_tlist */ } } } return line; } static void pp_cleanup(int pass_) { int h; if (pass_ == 1) { if (defining) { error(ERR_NONFATAL, "end of file while still defining macro `%s'", defining->name); free_mmacro(defining); } return; } while (cstk) ctx_pop(); for (h = 0; h < NHASH; h++) { while (mmacros[h]) { MMacro *m = mmacros[h]; mmacros[h] = mmacros[h]->next; free_mmacro(m); } while (smacros[h]) { SMacro *s = smacros[h]; smacros[h] = smacros[h]->next; nasm_free(s->name); free_tlist(s->expansion); nasm_free(s); } } while (istk) { Include *i = istk; istk = istk->next; if (i->fp != first_fp) fclose(i->fp); nasm_free(i->fname); nasm_free(i); } while (cstk) ctx_pop(); if (pass_ == 0) { free_llist(builtindef); free_llist(stddef); free_llist(predef); builtindef = NULL; stddef = NULL; predef = NULL; freeTokens = NULL; delete_Blocks(); blocks.next = NULL; blocks.chunk = NULL; } } void pp_pre_include(const char *fname) { Token *inc, *space, *name; Line *l; name = new_Token(NULL, TOK_INTERNAL_STRING, fname, 0); space = new_Token(name, TOK_WHITESPACE, NULL, 0); inc = new_Token(space, TOK_PREPROC_ID, "%include", 0); l = nasm_malloc(sizeof(Line)); l->next = predef; l->first = inc; l->finishes = FALSE; predef = l; } void pp_pre_define(char *definition) { Token *def, *space; Line *l; char *equals; equals = strchr(definition, '='); space = new_Token(NULL, TOK_WHITESPACE, NULL, 0); def = new_Token(space, TOK_PREPROC_ID, "%define", 0); if (equals) *equals = ' '; space->next = tokenise(definition); if (equals) *equals = '='; l = nasm_malloc(sizeof(Line)); l->next = predef; l->first = def; l->finishes = FALSE; predef = l; } void pp_pre_undefine(char *definition) { Token *def, *space; Line *l; space = new_Token(NULL, TOK_WHITESPACE, NULL, 0); def = new_Token(space, TOK_PREPROC_ID, "%undef", 0); space->next = tokenise(definition); l = nasm_malloc(sizeof(Line)); l->next = predef; l->first = def; l->finishes = FALSE; predef = l; } void pp_builtin_define(char *definition) { Token *def, *space; Line *l; char *equals; equals = strchr(definition, '='); space = new_Token(NULL, TOK_WHITESPACE, NULL, 0); def = new_Token(space, TOK_PREPROC_ID, "%define", 0); if (equals) *equals = ' '; space->next = tokenise(definition); if (equals) *equals = '='; l = nasm_malloc(sizeof(Line)); l->next = builtindef; l->first = def; l->finishes = FALSE; builtindef = l; } void pp_extra_stdmac(const char **macros) { const char **lp; for (lp=macros; *lp; lp++) { char *macro; Token *t; Line *l; macro = nasm_strdup(*lp); t = tokenise(macro); nasm_free(macro); l = nasm_malloc(sizeof(Line)); l->next = stddef; l->first = t; l->finishes = FALSE; stddef = l; } } static void make_tok_num(Token * tok, yasm_intnum *val) { tok->text = yasm_intnum_get_str(val); tok->type = TOK_NUMBER; } Preproc nasmpp = { pp_reset, pp_getline, pp_cleanup };