/** * \file libyasm/expr.h * \brief YASM expression interface. * * \rcs * $Id: expr.h 2130 2008-10-07 05:38:11Z peter $ * \endrcs * * \license * Copyright (C) 2001-2007 Michael Urman, Peter Johnson * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * - Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * - Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND OTHER CONTRIBUTORS ``AS IS'' * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR OTHER CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. * \endlicense */ #ifndef YASM_EXPR_H #define YASM_EXPR_H #ifndef YASM_LIB_DECL #define YASM_LIB_DECL #endif /** Type of an expression item. Types are listed in canonical sorting order. * See expr_order_terms(). * Note #YASM_EXPR_PRECBC must be used carefully (in a-b pairs), as only * symrecs can become the relative term in a #yasm_value. */ typedef enum yasm_expr__type { YASM_EXPR_NONE = 0, /**< Nothing */ YASM_EXPR_REG = 1<<0, /**< Register */ YASM_EXPR_INT = 1<<1, /**< Integer value */ YASM_EXPR_SUBST = 1<<2, /**< Substitution placeholder */ YASM_EXPR_FLOAT = 1<<3, /**< Floating point value */ YASM_EXPR_SYM = 1<<4, /**< Symbol */ YASM_EXPR_PRECBC = 1<<5,/**< Direct bytecode ref (rather than via sym) */ YASM_EXPR_EXPR = 1<<6 /**< Subexpression */ } yasm_expr__type; /** Expression item. */ typedef struct yasm_expr__item { yasm_expr__type type; /**< Type */ /** Expression item data. Correct value depends on type. */ union { yasm_bytecode *precbc; /**< Direct bytecode ref (YASM_EXPR_PRECBC) */ yasm_symrec *sym; /**< Symbol (YASM_EXPR_SYM) */ yasm_expr *expn; /**< Subexpression (YASM_EXPR_EXPR) */ yasm_intnum *intn; /**< Integer value (YASM_EXPR_INT) */ yasm_floatnum *flt; /**< Floating point value (YASM_EXPR_FLOAT) */ uintptr_t reg; /**< Register (YASM_EXPR_REG) */ unsigned int subst; /**< Subst placeholder (YASM_EXPR_SUBST) */ } data; } yasm_expr__item; /** Expression. */ struct yasm_expr { yasm_expr_op op; /**< Operation. */ unsigned long line; /**< Line number where expression was defined. */ int numterms; /**< Number of terms in the expression. */ /** Terms of the expression. Structure may be extended to include more * terms, as some operations may allow more than two operand terms * (ADD, MUL, OR, AND, XOR). */ yasm_expr__item terms[2]; }; /** Create a new expression e=a op b. * \param op operation * \param a expression item a * \param b expression item b (optional depending on op) * \param line virtual line (where expression defined) * \return Newly allocated expression. */ YASM_LIB_DECL /*@only@*/ yasm_expr *yasm_expr_create (yasm_expr_op op, /*@only@*/ yasm_expr__item *a, /*@only@*/ /*@null@*/ yasm_expr__item *b, unsigned long line); /** Create a new preceding-bytecode expression item. * \param precbc preceding bytecode * \return Newly allocated expression item. */ YASM_LIB_DECL /*@only@*/ yasm_expr__item *yasm_expr_precbc(/*@keep@*/ yasm_bytecode *precbc); /** Create a new symbol expression item. * \param sym symbol * \return Newly allocated expression item. */ YASM_LIB_DECL /*@only@*/ yasm_expr__item *yasm_expr_sym(/*@keep@*/ yasm_symrec *sym); /** Create a new expression expression item. * \param e expression * \return Newly allocated expression item. */ YASM_LIB_DECL /*@only@*/ yasm_expr__item *yasm_expr_expr(/*@keep@*/ yasm_expr *e); /** Create a new intnum expression item. * \param intn intnum * \return Newly allocated expression item. */ YASM_LIB_DECL /*@only@*/ yasm_expr__item *yasm_expr_int(/*@keep@*/ yasm_intnum *intn); /** Create a new floatnum expression item. * \param flt floatnum * \return Newly allocated expression item. */ YASM_LIB_DECL /*@only@*/ yasm_expr__item *yasm_expr_float(/*@keep@*/ yasm_floatnum *flt); /** Create a new register expression item. * \param reg register * \return Newly allocated expression item. */ YASM_LIB_DECL /*@only@*/ yasm_expr__item *yasm_expr_reg(uintptr_t reg); /** Create a new expression tree e=l op r. * \param l expression for left side of new expression * \param o operation * \param r expression for right side of new expression * \param i line index * \return Newly allocated expression. */ #define yasm_expr_create_tree(l,o,r,i) \ yasm_expr_create ((o), yasm_expr_expr(l), yasm_expr_expr(r), i) /** Create a new expression branch e=op r. * \param o operation * \param r expression for right side of new expression * \param i line index * \return Newly allocated expression. */ #define yasm_expr_create_branch(o,r,i) \ yasm_expr_create ((o), yasm_expr_expr(r), (yasm_expr__item *)NULL, i) /** Create a new expression identity e=r. * \param r expression for identity within new expression * \param i line index * \return Newly allocated expression. */ #define yasm_expr_create_ident(r,i) \ yasm_expr_create (YASM_EXPR_IDENT, (r), (yasm_expr__item *)NULL, i) /** Duplicate an expression. * \param e expression * \return Newly allocated expression identical to e. */ yasm_expr *yasm_expr_copy(const yasm_expr *e); #ifndef YASM_DOXYGEN #define yasm_expr_copy(e) yasm_expr__copy_except(e, -1) #endif /** Destroy (free allocated memory for) an expression. * \param e expression */ YASM_LIB_DECL void yasm_expr_destroy(/*@only@*/ /*@null@*/ yasm_expr *e); /** Determine if an expression is a specified operation (at the top level). * \param e expression * \param op operator * \return Nonzero if the expression was the specified operation at the top * level, zero otherwise. */ YASM_LIB_DECL int yasm_expr_is_op(const yasm_expr *e, yasm_expr_op op); /** Extra transformation function for yasm_expr__level_tree(). * \param e expression being simplified * \param d data provided as expr_xform_extra_data to * yasm_expr__level_tree() * \return Transformed e. */ typedef /*@only@*/ yasm_expr * (*yasm_expr_xform_func) (/*@returned@*/ /*@only@*/ yasm_expr *e, /*@null@*/ void *d); /** Level an entire expression tree. * \internal * \param e expression * \param fold_const enable constant folding if nonzero * \param simplify_ident simplify identities * \param simplify_reg_mul simplify REG*1 identities * \param calc_bc_dist nonzero if distances between bytecodes should be * calculated, 0 if they should be left intact * \param expr_xform_extra extra transformation function * \param expr_xform_extra_data data to pass to expr_xform_extra * \return Leveled expression. */ YASM_LIB_DECL /*@only@*/ /*@null@*/ yasm_expr *yasm_expr__level_tree (/*@returned@*/ /*@only@*/ /*@null@*/ yasm_expr *e, int fold_const, int simplify_ident, int simplify_reg_mul, int calc_bc_dist, /*@null@*/ yasm_expr_xform_func expr_xform_extra, /*@null@*/ void *expr_xform_extra_data); /** Simplify an expression as much as possible. Eliminates extraneous * branches and simplifies integer-only subexpressions. Simplified version * of yasm_expr__level_tree(). * \param e expression * \param cbd if distance between bytecodes should be calculated * \return Simplified expression. */ #define yasm_expr_simplify(e, cbd) \ yasm_expr__level_tree(e, 1, 1, 1, cbd, NULL, NULL) /** Extract the segment portion of an expression containing SEG:OFF, leaving * the offset. * \param ep expression (pointer to) * \return NULL if unable to extract a segment (expr does not contain a * YASM_EXPR_SEGOFF operator), otherwise the segment expression. * The input expression is modified such that on return, it's the * offset expression. */ YASM_LIB_DECL /*@only@*/ /*@null@*/ yasm_expr *yasm_expr_extract_deep_segoff(yasm_expr **ep); /** Extract the segment portion of a SEG:OFF expression, leaving the offset. * \param ep expression (pointer to) * \return NULL if unable to extract a segment (YASM_EXPR_SEGOFF not the * top-level operator), otherwise the segment expression. The input * expression is modified such that on return, it's the offset * expression. */ YASM_LIB_DECL /*@only@*/ /*@null@*/ yasm_expr *yasm_expr_extract_segoff(yasm_expr **ep); /** Extract the right portion (y) of a x WRT y expression, leaving the left * portion (x). * \param ep expression (pointer to) * \return NULL if unable to extract (YASM_EXPR_WRT not the top-level * operator), otherwise the right side of the WRT expression. The * input expression is modified such that on return, it's the left side * of the WRT expression. */ YASM_LIB_DECL /*@only@*/ /*@null@*/ yasm_expr *yasm_expr_extract_wrt(yasm_expr **ep); /** Get the integer value of an expression if it's just an integer. * \param ep expression (pointer to) * \param calc_bc_dist nonzero if distances between bytecodes should be * calculated, 0 if NULL should be returned in this case * \return NULL if the expression is too complex (contains anything other than * integers, ie floats, non-valued labels, registers); otherwise the * intnum value of the expression. */ YASM_LIB_DECL /*@dependent@*/ /*@null@*/ yasm_intnum *yasm_expr_get_intnum (yasm_expr **ep, int calc_bc_dist); /** Get the symbol value of an expression if it's just a symbol. * \param ep expression (pointer to) * \param simplify if nonzero, simplify the expression first * \return NULL if the expression is too complex; otherwise the symbol value of * the expression. */ YASM_LIB_DECL /*@dependent@*/ /*@null@*/ const yasm_symrec *yasm_expr_get_symrec (yasm_expr **ep, int simplify); /** Get the register value of an expression if it's just a register. * \param ep expression (pointer to) * \param simplify if nonzero, simplify the expression first * \return NULL if the expression is too complex; otherwise the register value * of the expression. */ YASM_LIB_DECL /*@dependent@*/ /*@null@*/ const uintptr_t *yasm_expr_get_reg (yasm_expr **ep, int simplify); /** Print an expression. For debugging purposes. * \param e expression * \param f file */ YASM_LIB_DECL void yasm_expr_print(/*@null@*/ const yasm_expr *e, FILE *f); /** Return the size of an expression, if the user provided it * \param e expression */ unsigned int yasm_expr_size(const yasm_expr *e); /** Return the segment of an expression, if the user provided it * \param e expression */ const char *yasm_expr_segment(const yasm_expr *e); /** Traverse over expression tree in order (const version). * Calls func for each leaf (non-operation). * \param e expression * \param d data passed to each call to func * \param func callback function * \return Stops early (and returns 1) if func returns 1. * Otherwise returns 0. */ YASM_LIB_DECL int yasm_expr__traverse_leaves_in_const (const yasm_expr *e, /*@null@*/ void *d, int (*func) (/*@null@*/ const yasm_expr__item *ei, /*@null@*/ void *d)); /** Traverse over expression tree in order. * Calls func for each leaf (non-operation). * \param e expression * \param d data passed to each call to func * \param func callback function * \return Stops early (and returns 1) if func returns 1. * Otherwise returns 0. */ YASM_LIB_DECL int yasm_expr__traverse_leaves_in (yasm_expr *e, /*@null@*/ void *d, int (*func) (/*@null@*/ yasm_expr__item *ei, /*@null@*/ void *d)); /** Reorder terms of e into canonical order. Only reorders if reordering * doesn't change meaning of expression. (eg, doesn't reorder SUB). * Canonical order: REG, INT, FLOAT, SYM, EXPR. * Multiple terms of a single type are kept in the same order as in * the original expression. * \param e expression * \note Only performs reordering on *one* level (no recursion). */ YASM_LIB_DECL void yasm_expr__order_terms(yasm_expr *e); /** Copy entire expression EXCEPT for index "except" at *top level only*. * \param e expression * \param except term index not to copy; -1 to copy all terms * \return Newly allocated copy of expression. */ YASM_LIB_DECL yasm_expr *yasm_expr__copy_except(const yasm_expr *e, int except); /** Test if expression contains an item. Searches recursively into * subexpressions. * \param e expression * \param t type of item to look for * \return Nonzero if expression contains an item of type t, zero if not. */ YASM_LIB_DECL int yasm_expr__contains(const yasm_expr *e, yasm_expr__type t); /** Transform symrec-symrec terms in expression into #YASM_EXPR_SUBST items. * Calls the callback function for each symrec-symrec term. * \param ep expression (pointer to) * \param cbd callback data passed to callback function * \param callback callback function: given subst index for bytecode * pair, bytecode pair (bc2-bc1), and cbd (callback data) * \return Number of transformations made. */ YASM_LIB_DECL int yasm_expr__bc_dist_subst(yasm_expr **ep, void *cbd, void (*callback) (unsigned int subst, yasm_bytecode *precbc, yasm_bytecode *precbc2, void *cbd)); /** Substitute items into expr YASM_EXPR_SUBST items (by index). Items are * copied, so caller is responsible for freeing array of items. * \param e expression * \param num_items number of items in items array * \param items items array * \return 1 on error (index out of range). */ YASM_LIB_DECL int yasm_expr__subst(yasm_expr *e, unsigned int num_items, const yasm_expr__item *items); #endif