Mercurial > hg > CbC > CbC_gcc
view gcc/tree-flow-inline.h @ 12:ab98828ce7a7
refactor cbc_finish_labeled_goto, cbc_finish_nested_function.
| author | kent <kent@cr.ie.u-ryukyu.ac.jp> |
|---|---|
| date | Fri, 11 Sep 2009 14:52:24 +0900 |
| parents | a06113de4d67 |
| children | 77e2b8dfacca |
line wrap: on
line source
/* Inline functions for tree-flow.h Copyright (C) 2001, 2003, 2005, 2006, 2007, 2008 Free Software Foundation, Inc. Contributed by Diego Novillo <dnovillo@redhat.com> This file is part of GCC. GCC is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. GCC is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GCC; see the file COPYING3. If not see <http://www.gnu.org/licenses/>. */ #ifndef _TREE_FLOW_INLINE_H #define _TREE_FLOW_INLINE_H 1 /* Inline functions for manipulating various data structures defined in tree-flow.h. See tree-flow.h for documentation. */ /* Return true when gimple SSA form was built. gimple_in_ssa_p is queried by gimplifier in various early stages before SSA infrastructure is initialized. Check for presence of the datastructures at first place. */ static inline bool gimple_in_ssa_p (const struct function *fun) { return fun && fun->gimple_df && fun->gimple_df->in_ssa_p; } /* 'true' after aliases have been computed (see compute_may_aliases). */ static inline bool gimple_aliases_computed_p (const struct function *fun) { gcc_assert (fun && fun->gimple_df); return fun->gimple_df->aliases_computed_p; } /* Addressable variables in the function. If bit I is set, then REFERENCED_VARS (I) has had its address taken. Note that CALL_CLOBBERED_VARS and ADDRESSABLE_VARS are not related. An addressable variable is not necessarily call-clobbered (e.g., a local addressable whose address does not escape) and not all call-clobbered variables are addressable (e.g., a local static variable). */ static inline bitmap gimple_addressable_vars (const struct function *fun) { gcc_assert (fun && fun->gimple_df); return fun->gimple_df->addressable_vars; } /* Call clobbered variables in the function. If bit I is set, then REFERENCED_VARS (I) is call-clobbered. */ static inline bitmap gimple_call_clobbered_vars (const struct function *fun) { gcc_assert (fun && fun->gimple_df); return fun->gimple_df->call_clobbered_vars; } /* Call-used variables in the function. If bit I is set, then REFERENCED_VARS (I) is call-used at pure function call-sites. */ static inline bitmap gimple_call_used_vars (const struct function *fun) { gcc_assert (fun && fun->gimple_df); return fun->gimple_df->call_used_vars; } /* Array of all variables referenced in the function. */ static inline htab_t gimple_referenced_vars (const struct function *fun) { if (!fun->gimple_df) return NULL; return fun->gimple_df->referenced_vars; } /* Artificial variable used to model the effects of function calls. */ static inline tree gimple_global_var (const struct function *fun) { gcc_assert (fun && fun->gimple_df); return fun->gimple_df->global_var; } /* Artificial variable used to model the effects of nonlocal variables. */ static inline tree gimple_nonlocal_all (const struct function *fun) { gcc_assert (fun && fun->gimple_df); return fun->gimple_df->nonlocal_all; } /* Initialize the hashtable iterator HTI to point to hashtable TABLE */ static inline void * first_htab_element (htab_iterator *hti, htab_t table) { hti->htab = table; hti->slot = table->entries; hti->limit = hti->slot + htab_size (table); do { PTR x = *(hti->slot); if (x != HTAB_EMPTY_ENTRY && x != HTAB_DELETED_ENTRY) break; } while (++(hti->slot) < hti->limit); if (hti->slot < hti->limit) return *(hti->slot); return NULL; } /* Return current non-empty/deleted slot of the hashtable pointed to by HTI, or NULL if we have reached the end. */ static inline bool end_htab_p (const htab_iterator *hti) { if (hti->slot >= hti->limit) return true; return false; } /* Advance the hashtable iterator pointed to by HTI to the next element of the hashtable. */ static inline void * next_htab_element (htab_iterator *hti) { while (++(hti->slot) < hti->limit) { PTR x = *(hti->slot); if (x != HTAB_EMPTY_ENTRY && x != HTAB_DELETED_ENTRY) return x; }; return NULL; } /* Initialize ITER to point to the first referenced variable in the referenced_vars hashtable, and return that variable. */ static inline tree first_referenced_var (referenced_var_iterator *iter) { return (tree) first_htab_element (&iter->hti, gimple_referenced_vars (cfun)); } /* Return true if we have hit the end of the referenced variables ITER is iterating through. */ static inline bool end_referenced_vars_p (const referenced_var_iterator *iter) { return end_htab_p (&iter->hti); } /* Make ITER point to the next referenced_var in the referenced_var hashtable, and return that variable. */ static inline tree next_referenced_var (referenced_var_iterator *iter) { return (tree) next_htab_element (&iter->hti); } /* Fill up VEC with the variables in the referenced vars hashtable. */ static inline void fill_referenced_var_vec (VEC (tree, heap) **vec) { referenced_var_iterator rvi; tree var; *vec = NULL; FOR_EACH_REFERENCED_VAR (var, rvi) VEC_safe_push (tree, heap, *vec, var); } /* Return the variable annotation for T, which must be a _DECL node. Return NULL if the variable annotation doesn't already exist. */ static inline var_ann_t var_ann (const_tree t) { var_ann_t ann; if (!t->base.ann) return NULL; ann = (var_ann_t) t->base.ann; gcc_assert (ann->common.type == VAR_ANN); return ann; } /* Return the variable annotation for T, which must be a _DECL node. Create the variable annotation if it doesn't exist. */ static inline var_ann_t get_var_ann (tree var) { var_ann_t ann = var_ann (var); return (ann) ? ann : create_var_ann (var); } /* Return the function annotation for T, which must be a FUNCTION_DECL node. Return NULL if the function annotation doesn't already exist. */ static inline function_ann_t function_ann (const_tree t) { gcc_assert (t); gcc_assert (TREE_CODE (t) == FUNCTION_DECL); gcc_assert (!t->base.ann || t->base.ann->common.type == FUNCTION_ANN); return (function_ann_t) t->base.ann; } /* Return the function annotation for T, which must be a FUNCTION_DECL node. Create the function annotation if it doesn't exist. */ static inline function_ann_t get_function_ann (tree var) { function_ann_t ann = function_ann (var); gcc_assert (!var->base.ann || var->base.ann->common.type == FUNCTION_ANN); return (ann) ? ann : create_function_ann (var); } /* Get the number of the next statement uid to be allocated. */ static inline unsigned int gimple_stmt_max_uid (struct function *fn) { return fn->last_stmt_uid; } /* Set the number of the next statement uid to be allocated. */ static inline void set_gimple_stmt_max_uid (struct function *fn, unsigned int maxid) { fn->last_stmt_uid = maxid; } /* Set the number of the next statement uid to be allocated. */ static inline unsigned int inc_gimple_stmt_max_uid (struct function *fn) { return fn->last_stmt_uid++; } /* Return the annotation type for annotation ANN. */ static inline enum tree_ann_type ann_type (tree_ann_t ann) { return ann->common.type; } /* Return the may_aliases bitmap for variable VAR, or NULL if it has no may aliases. */ static inline bitmap may_aliases (const_tree var) { return MTAG_ALIASES (var); } /* Return the line number for EXPR, or return -1 if we have no line number information for it. */ static inline int get_lineno (const_gimple stmt) { location_t loc; if (!stmt) return -1; loc = gimple_location (stmt); if (loc != UNKNOWN_LOCATION) return -1; return LOCATION_LINE (loc); } /* Delink an immediate_uses node from its chain. */ static inline void delink_imm_use (ssa_use_operand_t *linknode) { /* Return if this node is not in a list. */ if (linknode->prev == NULL) return; linknode->prev->next = linknode->next; linknode->next->prev = linknode->prev; linknode->prev = NULL; linknode->next = NULL; } /* Link ssa_imm_use node LINKNODE into the chain for LIST. */ static inline void link_imm_use_to_list (ssa_use_operand_t *linknode, ssa_use_operand_t *list) { /* Link the new node at the head of the list. If we are in the process of traversing the list, we won't visit any new nodes added to it. */ linknode->prev = list; linknode->next = list->next; list->next->prev = linknode; list->next = linknode; } /* Link ssa_imm_use node LINKNODE into the chain for DEF. */ static inline void link_imm_use (ssa_use_operand_t *linknode, tree def) { ssa_use_operand_t *root; if (!def || TREE_CODE (def) != SSA_NAME) linknode->prev = NULL; else { root = &(SSA_NAME_IMM_USE_NODE (def)); #ifdef ENABLE_CHECKING if (linknode->use) gcc_assert (*(linknode->use) == def); #endif link_imm_use_to_list (linknode, root); } } /* Set the value of a use pointed to by USE to VAL. */ static inline void set_ssa_use_from_ptr (use_operand_p use, tree val) { delink_imm_use (use); *(use->use) = val; link_imm_use (use, val); } /* Link ssa_imm_use node LINKNODE into the chain for DEF, with use occurring in STMT. */ static inline void link_imm_use_stmt (ssa_use_operand_t *linknode, tree def, gimple stmt) { if (stmt) link_imm_use (linknode, def); else link_imm_use (linknode, NULL); linknode->loc.stmt = stmt; } /* Relink a new node in place of an old node in the list. */ static inline void relink_imm_use (ssa_use_operand_t *node, ssa_use_operand_t *old) { /* The node one had better be in the same list. */ gcc_assert (*(old->use) == *(node->use)); node->prev = old->prev; node->next = old->next; if (old->prev) { old->prev->next = node; old->next->prev = node; /* Remove the old node from the list. */ old->prev = NULL; } } /* Relink ssa_imm_use node LINKNODE into the chain for OLD, with use occurring in STMT. */ static inline void relink_imm_use_stmt (ssa_use_operand_t *linknode, ssa_use_operand_t *old, gimple stmt) { if (stmt) relink_imm_use (linknode, old); else link_imm_use (linknode, NULL); linknode->loc.stmt = stmt; } /* Return true is IMM has reached the end of the immediate use list. */ static inline bool end_readonly_imm_use_p (const imm_use_iterator *imm) { return (imm->imm_use == imm->end_p); } /* Initialize iterator IMM to process the list for VAR. */ static inline use_operand_p first_readonly_imm_use (imm_use_iterator *imm, tree var) { gcc_assert (TREE_CODE (var) == SSA_NAME); imm->end_p = &(SSA_NAME_IMM_USE_NODE (var)); imm->imm_use = imm->end_p->next; #ifdef ENABLE_CHECKING imm->iter_node.next = imm->imm_use->next; #endif if (end_readonly_imm_use_p (imm)) return NULL_USE_OPERAND_P; return imm->imm_use; } /* Bump IMM to the next use in the list. */ static inline use_operand_p next_readonly_imm_use (imm_use_iterator *imm) { use_operand_p old = imm->imm_use; #ifdef ENABLE_CHECKING /* If this assertion fails, it indicates the 'next' pointer has changed since the last bump. This indicates that the list is being modified via stmt changes, or SET_USE, or somesuch thing, and you need to be using the SAFE version of the iterator. */ gcc_assert (imm->iter_node.next == old->next); imm->iter_node.next = old->next->next; #endif imm->imm_use = old->next; if (end_readonly_imm_use_p (imm)) return NULL_USE_OPERAND_P; return imm->imm_use; } /* Return true if VAR has no uses. */ static inline bool has_zero_uses (const_tree var) { const ssa_use_operand_t *const ptr = &(SSA_NAME_IMM_USE_NODE (var)); /* A single use means there is no items in the list. */ return (ptr == ptr->next); } /* Return true if VAR has a single use. */ static inline bool has_single_use (const_tree var) { const ssa_use_operand_t *const ptr = &(SSA_NAME_IMM_USE_NODE (var)); /* A single use means there is one item in the list. */ return (ptr != ptr->next && ptr == ptr->next->next); } /* If VAR has only a single immediate use, return true, and set USE_P and STMT to the use pointer and stmt of occurrence. */ static inline bool single_imm_use (const_tree var, use_operand_p *use_p, gimple *stmt) { const ssa_use_operand_t *const ptr = &(SSA_NAME_IMM_USE_NODE (var)); if (ptr != ptr->next && ptr == ptr->next->next) { *use_p = ptr->next; *stmt = ptr->next->loc.stmt; return true; } *use_p = NULL_USE_OPERAND_P; *stmt = NULL; return false; } /* Return the number of immediate uses of VAR. */ static inline unsigned int num_imm_uses (const_tree var) { const ssa_use_operand_t *const start = &(SSA_NAME_IMM_USE_NODE (var)); const ssa_use_operand_t *ptr; unsigned int num = 0; for (ptr = start->next; ptr != start; ptr = ptr->next) num++; return num; } /* Return the tree pointed-to by USE. */ static inline tree get_use_from_ptr (use_operand_p use) { return *(use->use); } /* Return the tree pointed-to by DEF. */ static inline tree get_def_from_ptr (def_operand_p def) { return *def; } /* Return a use_operand_p pointer for argument I of PHI node GS. */ static inline use_operand_p gimple_phi_arg_imm_use_ptr (gimple gs, int i) { return &gimple_phi_arg (gs, i)->imm_use; } /* Return the tree operand for argument I of PHI node GS. */ static inline tree gimple_phi_arg_def (gimple gs, size_t index) { struct phi_arg_d *pd = gimple_phi_arg (gs, index); return get_use_from_ptr (&pd->imm_use); } /* Return a pointer to the tree operand for argument I of PHI node GS. */ static inline tree * gimple_phi_arg_def_ptr (gimple gs, size_t index) { return &gimple_phi_arg (gs, index)->def; } /* Return the edge associated with argument I of phi node GS. */ static inline edge gimple_phi_arg_edge (gimple gs, size_t i) { return EDGE_PRED (gimple_bb (gs), i); } /* Return the PHI nodes for basic block BB, or NULL if there are no PHI nodes. */ static inline gimple_seq phi_nodes (const_basic_block bb) { gcc_assert (!(bb->flags & BB_RTL)); if (!bb->il.gimple) return NULL; return bb->il.gimple->phi_nodes; } /* Set PHI nodes of a basic block BB to SEQ. */ static inline void set_phi_nodes (basic_block bb, gimple_seq seq) { gimple_stmt_iterator i; gcc_assert (!(bb->flags & BB_RTL)); bb->il.gimple->phi_nodes = seq; if (seq) for (i = gsi_start (seq); !gsi_end_p (i); gsi_next (&i)) gimple_set_bb (gsi_stmt (i), bb); } /* Return the phi argument which contains the specified use. */ static inline int phi_arg_index_from_use (use_operand_p use) { struct phi_arg_d *element, *root; size_t index; gimple phi; /* Since the use is the first thing in a PHI argument element, we can calculate its index based on casting it to an argument, and performing pointer arithmetic. */ phi = USE_STMT (use); gcc_assert (gimple_code (phi) == GIMPLE_PHI); element = (struct phi_arg_d *)use; root = gimple_phi_arg (phi, 0); index = element - root; #ifdef ENABLE_CHECKING /* Make sure the calculation doesn't have any leftover bytes. If it does, then imm_use is likely not the first element in phi_arg_d. */ gcc_assert ( (((char *)element - (char *)root) % sizeof (struct phi_arg_d)) == 0); gcc_assert (index < gimple_phi_capacity (phi)); #endif return index; } /* Mark VAR as used, so that it'll be preserved during rtl expansion. */ static inline void set_is_used (tree var) { var_ann_t ann = get_var_ann (var); ann->used = 1; } /* Return true if T (assumed to be a DECL) is a global variable. */ static inline bool is_global_var (const_tree t) { if (MTAG_P (t)) return MTAG_GLOBAL (t); else return (TREE_STATIC (t) || DECL_EXTERNAL (t)); } /* PHI nodes should contain only ssa_names and invariants. A test for ssa_name is definitely simpler; don't let invalid contents slip in in the meantime. */ static inline bool phi_ssa_name_p (const_tree t) { if (TREE_CODE (t) == SSA_NAME) return true; #ifdef ENABLE_CHECKING gcc_assert (is_gimple_min_invariant (t)); #endif return false; } /* Returns the loop of the statement STMT. */ static inline struct loop * loop_containing_stmt (gimple stmt) { basic_block bb = gimple_bb (stmt); if (!bb) return NULL; return bb->loop_father; } /* Return the memory partition tag associated with symbol SYM. */ static inline tree memory_partition (tree sym) { tree tag; /* MPTs belong to their own partition. */ if (TREE_CODE (sym) == MEMORY_PARTITION_TAG) return sym; gcc_assert (!is_gimple_reg (sym)); /* Autoparallelization moves statements from the original function (which has aliases computed) to the new one (which does not). When rebuilding operands for the statement in the new function, we do not want to record the memory partition tags of the original function. */ if (!gimple_aliases_computed_p (cfun)) return NULL_TREE; tag = get_var_ann (sym)->mpt; #if defined ENABLE_CHECKING if (tag) gcc_assert (TREE_CODE (tag) == MEMORY_PARTITION_TAG); #endif return tag; } /* Return true if NAME is a memory factoring SSA name (i.e., an SSA name for a memory partition. */ static inline bool factoring_name_p (const_tree name) { return TREE_CODE (SSA_NAME_VAR (name)) == MEMORY_PARTITION_TAG; } /* Return true if VAR is used by function calls. */ static inline bool is_call_used (const_tree var) { return (var_ann (var)->call_clobbered || bitmap_bit_p (gimple_call_used_vars (cfun), DECL_UID (var))); } /* Return true if VAR is clobbered by function calls. */ static inline bool is_call_clobbered (const_tree var) { return var_ann (var)->call_clobbered; } /* Mark variable VAR as being clobbered by function calls. */ static inline void mark_call_clobbered (tree var, unsigned int escape_type) { var_ann (var)->escape_mask |= escape_type; var_ann (var)->call_clobbered = true; bitmap_set_bit (gimple_call_clobbered_vars (cfun), DECL_UID (var)); } /* Clear the call-clobbered attribute from variable VAR. */ static inline void clear_call_clobbered (tree var) { var_ann_t ann = var_ann (var); ann->escape_mask = 0; if (MTAG_P (var)) MTAG_GLOBAL (var) = 0; var_ann (var)->call_clobbered = false; bitmap_clear_bit (gimple_call_clobbered_vars (cfun), DECL_UID (var)); } /* Return the common annotation for T. Return NULL if the annotation doesn't already exist. */ static inline tree_ann_common_t tree_common_ann (const_tree t) { /* Watch out static variables with unshared annotations. */ if (DECL_P (t) && TREE_CODE (t) == VAR_DECL) return &var_ann (t)->common; return &t->base.ann->common; } /* Return a common annotation for T. Create the constant annotation if it doesn't exist. */ static inline tree_ann_common_t get_tree_common_ann (tree t) { tree_ann_common_t ann = tree_common_ann (t); return (ann) ? ann : create_tree_common_ann (t); } /* ----------------------------------------------------------------------- */ /* The following set of routines are used to iterator over various type of SSA operands. */ /* Return true if PTR is finished iterating. */ static inline bool op_iter_done (const ssa_op_iter *ptr) { return ptr->done; } /* Get the next iterator use value for PTR. */ static inline use_operand_p op_iter_next_use (ssa_op_iter *ptr) { use_operand_p use_p; #ifdef ENABLE_CHECKING gcc_assert (ptr->iter_type == ssa_op_iter_use); #endif if (ptr->uses) { use_p = USE_OP_PTR (ptr->uses); ptr->uses = ptr->uses->next; return use_p; } if (ptr->vuses) { use_p = VUSE_OP_PTR (ptr->vuses, ptr->vuse_index); if (++(ptr->vuse_index) >= VUSE_NUM (ptr->vuses)) { ptr->vuse_index = 0; ptr->vuses = ptr->vuses->next; } return use_p; } if (ptr->mayuses) { use_p = VDEF_OP_PTR (ptr->mayuses, ptr->mayuse_index); if (++(ptr->mayuse_index) >= VDEF_NUM (ptr->mayuses)) { ptr->mayuse_index = 0; ptr->mayuses = ptr->mayuses->next; } return use_p; } if (ptr->phi_i < ptr->num_phi) { return PHI_ARG_DEF_PTR (ptr->phi_stmt, (ptr->phi_i)++); } ptr->done = true; return NULL_USE_OPERAND_P; } /* Get the next iterator def value for PTR. */ static inline def_operand_p op_iter_next_def (ssa_op_iter *ptr) { def_operand_p def_p; #ifdef ENABLE_CHECKING gcc_assert (ptr->iter_type == ssa_op_iter_def); #endif if (ptr->defs) { def_p = DEF_OP_PTR (ptr->defs); ptr->defs = ptr->defs->next; return def_p; } if (ptr->vdefs) { def_p = VDEF_RESULT_PTR (ptr->vdefs); ptr->vdefs = ptr->vdefs->next; return def_p; } ptr->done = true; return NULL_DEF_OPERAND_P; } /* Get the next iterator tree value for PTR. */ static inline tree op_iter_next_tree (ssa_op_iter *ptr) { tree val; #ifdef ENABLE_CHECKING gcc_assert (ptr->iter_type == ssa_op_iter_tree); #endif if (ptr->uses) { val = USE_OP (ptr->uses); ptr->uses = ptr->uses->next; return val; } if (ptr->vuses) { val = VUSE_OP (ptr->vuses, ptr->vuse_index); if (++(ptr->vuse_index) >= VUSE_NUM (ptr->vuses)) { ptr->vuse_index = 0; ptr->vuses = ptr->vuses->next; } return val; } if (ptr->mayuses) { val = VDEF_OP (ptr->mayuses, ptr->mayuse_index); if (++(ptr->mayuse_index) >= VDEF_NUM (ptr->mayuses)) { ptr->mayuse_index = 0; ptr->mayuses = ptr->mayuses->next; } return val; } if (ptr->defs) { val = DEF_OP (ptr->defs); ptr->defs = ptr->defs->next; return val; } if (ptr->vdefs) { val = VDEF_RESULT (ptr->vdefs); ptr->vdefs = ptr->vdefs->next; return val; } ptr->done = true; return NULL_TREE; } /* This functions clears the iterator PTR, and marks it done. This is normally used to prevent warnings in the compile about might be uninitialized components. */ static inline void clear_and_done_ssa_iter (ssa_op_iter *ptr) { ptr->defs = NULL; ptr->uses = NULL; ptr->vuses = NULL; ptr->vdefs = NULL; ptr->mayuses = NULL; ptr->iter_type = ssa_op_iter_none; ptr->phi_i = 0; ptr->num_phi = 0; ptr->phi_stmt = NULL; ptr->done = true; ptr->vuse_index = 0; ptr->mayuse_index = 0; } /* Initialize the iterator PTR to the virtual defs in STMT. */ static inline void op_iter_init (ssa_op_iter *ptr, gimple stmt, int flags) { ptr->defs = (flags & SSA_OP_DEF) ? gimple_def_ops (stmt) : NULL; ptr->uses = (flags & SSA_OP_USE) ? gimple_use_ops (stmt) : NULL; ptr->vuses = (flags & SSA_OP_VUSE) ? gimple_vuse_ops (stmt) : NULL; ptr->vdefs = (flags & SSA_OP_VDEF) ? gimple_vdef_ops (stmt) : NULL; ptr->mayuses = (flags & SSA_OP_VMAYUSE) ? gimple_vdef_ops (stmt) : NULL; ptr->done = false; ptr->phi_i = 0; ptr->num_phi = 0; ptr->phi_stmt = NULL; ptr->vuse_index = 0; ptr->mayuse_index = 0; } /* Initialize iterator PTR to the use operands in STMT based on FLAGS. Return the first use. */ static inline use_operand_p op_iter_init_use (ssa_op_iter *ptr, gimple stmt, int flags) { gcc_assert ((flags & SSA_OP_ALL_DEFS) == 0); op_iter_init (ptr, stmt, flags); ptr->iter_type = ssa_op_iter_use; return op_iter_next_use (ptr); } /* Initialize iterator PTR to the def operands in STMT based on FLAGS. Return the first def. */ static inline def_operand_p op_iter_init_def (ssa_op_iter *ptr, gimple stmt, int flags) { gcc_assert ((flags & SSA_OP_ALL_USES) == 0); op_iter_init (ptr, stmt, flags); ptr->iter_type = ssa_op_iter_def; return op_iter_next_def (ptr); } /* Initialize iterator PTR to the operands in STMT based on FLAGS. Return the first operand as a tree. */ static inline tree op_iter_init_tree (ssa_op_iter *ptr, gimple stmt, int flags) { op_iter_init (ptr, stmt, flags); ptr->iter_type = ssa_op_iter_tree; return op_iter_next_tree (ptr); } /* Get the next iterator mustdef value for PTR, returning the mustdef values in KILL and DEF. */ static inline void op_iter_next_vdef (vuse_vec_p *use, def_operand_p *def, ssa_op_iter *ptr) { #ifdef ENABLE_CHECKING gcc_assert (ptr->iter_type == ssa_op_iter_vdef); #endif if (ptr->mayuses) { *def = VDEF_RESULT_PTR (ptr->mayuses); *use = VDEF_VECT (ptr->mayuses); ptr->mayuses = ptr->mayuses->next; return; } *def = NULL_DEF_OPERAND_P; *use = NULL; ptr->done = true; return; } static inline void op_iter_next_mustdef (use_operand_p *use, def_operand_p *def, ssa_op_iter *ptr) { vuse_vec_p vp; op_iter_next_vdef (&vp, def, ptr); if (vp != NULL) { gcc_assert (VUSE_VECT_NUM_ELEM (*vp) == 1); *use = VUSE_ELEMENT_PTR (*vp, 0); } else *use = NULL_USE_OPERAND_P; } /* Initialize iterator PTR to the operands in STMT. Return the first operands in USE and DEF. */ static inline void op_iter_init_vdef (ssa_op_iter *ptr, gimple stmt, vuse_vec_p *use, def_operand_p *def) { gcc_assert (gimple_code (stmt) != GIMPLE_PHI); op_iter_init (ptr, stmt, SSA_OP_VMAYUSE); ptr->iter_type = ssa_op_iter_vdef; op_iter_next_vdef (use, def, ptr); } /* If there is a single operand in STMT matching FLAGS, return it. Otherwise return NULL. */ static inline tree single_ssa_tree_operand (gimple stmt, int flags) { tree var; ssa_op_iter iter; var = op_iter_init_tree (&iter, stmt, flags); if (op_iter_done (&iter)) return NULL_TREE; op_iter_next_tree (&iter); if (op_iter_done (&iter)) return var; return NULL_TREE; } /* If there is a single operand in STMT matching FLAGS, return it. Otherwise return NULL. */ static inline use_operand_p single_ssa_use_operand (gimple stmt, int flags) { use_operand_p var; ssa_op_iter iter; var = op_iter_init_use (&iter, stmt, flags); if (op_iter_done (&iter)) return NULL_USE_OPERAND_P; op_iter_next_use (&iter); if (op_iter_done (&iter)) return var; return NULL_USE_OPERAND_P; } /* If there is a single operand in STMT matching FLAGS, return it. Otherwise return NULL. */ static inline def_operand_p single_ssa_def_operand (gimple stmt, int flags) { def_operand_p var; ssa_op_iter iter; var = op_iter_init_def (&iter, stmt, flags); if (op_iter_done (&iter)) return NULL_DEF_OPERAND_P; op_iter_next_def (&iter); if (op_iter_done (&iter)) return var; return NULL_DEF_OPERAND_P; } /* Return true if there are zero operands in STMT matching the type given in FLAGS. */ static inline bool zero_ssa_operands (gimple stmt, int flags) { ssa_op_iter iter; op_iter_init_tree (&iter, stmt, flags); return op_iter_done (&iter); } /* Return the number of operands matching FLAGS in STMT. */ static inline int num_ssa_operands (gimple stmt, int flags) { ssa_op_iter iter; tree t; int num = 0; FOR_EACH_SSA_TREE_OPERAND (t, stmt, iter, flags) num++; return num; } /* Delink all immediate_use information for STMT. */ static inline void delink_stmt_imm_use (gimple stmt) { ssa_op_iter iter; use_operand_p use_p; if (ssa_operands_active ()) FOR_EACH_SSA_USE_OPERAND (use_p, stmt, iter, SSA_OP_ALL_USES) delink_imm_use (use_p); } /* This routine will compare all the operands matching FLAGS in STMT1 to those in STMT2. TRUE is returned if they are the same. STMTs can be NULL. */ static inline bool compare_ssa_operands_equal (gimple stmt1, gimple stmt2, int flags) { ssa_op_iter iter1, iter2; tree op1 = NULL_TREE; tree op2 = NULL_TREE; bool look1, look2; if (stmt1 == stmt2) return true; look1 = stmt1 != NULL; look2 = stmt2 != NULL; if (look1) { op1 = op_iter_init_tree (&iter1, stmt1, flags); if (!look2) return op_iter_done (&iter1); } else clear_and_done_ssa_iter (&iter1); if (look2) { op2 = op_iter_init_tree (&iter2, stmt2, flags); if (!look1) return op_iter_done (&iter2); } else clear_and_done_ssa_iter (&iter2); while (!op_iter_done (&iter1) && !op_iter_done (&iter2)) { if (op1 != op2) return false; op1 = op_iter_next_tree (&iter1); op2 = op_iter_next_tree (&iter2); } return (op_iter_done (&iter1) && op_iter_done (&iter2)); } /* If there is a single DEF in the PHI node which matches FLAG, return it. Otherwise return NULL_DEF_OPERAND_P. */ static inline tree single_phi_def (gimple stmt, int flags) { tree def = PHI_RESULT (stmt); if ((flags & SSA_OP_DEF) && is_gimple_reg (def)) return def; if ((flags & SSA_OP_VIRTUAL_DEFS) && !is_gimple_reg (def)) return def; return NULL_TREE; } /* Initialize the iterator PTR for uses matching FLAGS in PHI. FLAGS should be either SSA_OP_USES or SSA_OP_VIRTUAL_USES. */ static inline use_operand_p op_iter_init_phiuse (ssa_op_iter *ptr, gimple phi, int flags) { tree phi_def = gimple_phi_result (phi); int comp; clear_and_done_ssa_iter (ptr); ptr->done = false; gcc_assert ((flags & (SSA_OP_USE | SSA_OP_VIRTUAL_USES)) != 0); comp = (is_gimple_reg (phi_def) ? SSA_OP_USE : SSA_OP_VIRTUAL_USES); /* If the PHI node doesn't the operand type we care about, we're done. */ if ((flags & comp) == 0) { ptr->done = true; return NULL_USE_OPERAND_P; } ptr->phi_stmt = phi; ptr->num_phi = gimple_phi_num_args (phi); ptr->iter_type = ssa_op_iter_use; return op_iter_next_use (ptr); } /* Start an iterator for a PHI definition. */ static inline def_operand_p op_iter_init_phidef (ssa_op_iter *ptr, gimple phi, int flags) { tree phi_def = PHI_RESULT (phi); int comp; clear_and_done_ssa_iter (ptr); ptr->done = false; gcc_assert ((flags & (SSA_OP_DEF | SSA_OP_VIRTUAL_DEFS)) != 0); comp = (is_gimple_reg (phi_def) ? SSA_OP_DEF : SSA_OP_VIRTUAL_DEFS); /* If the PHI node doesn't the operand type we care about, we're done. */ if ((flags & comp) == 0) { ptr->done = true; return NULL_USE_OPERAND_P; } ptr->iter_type = ssa_op_iter_def; /* The first call to op_iter_next_def will terminate the iterator since all the fields are NULL. Simply return the result here as the first and therefore only result. */ return PHI_RESULT_PTR (phi); } /* Return true is IMM has reached the end of the immediate use stmt list. */ static inline bool end_imm_use_stmt_p (const imm_use_iterator *imm) { return (imm->imm_use == imm->end_p); } /* Finished the traverse of an immediate use stmt list IMM by removing the placeholder node from the list. */ static inline void end_imm_use_stmt_traverse (imm_use_iterator *imm) { delink_imm_use (&(imm->iter_node)); } /* Immediate use traversal of uses within a stmt require that all the uses on a stmt be sequentially listed. This routine is used to build up this sequential list by adding USE_P to the end of the current list currently delimited by HEAD and LAST_P. The new LAST_P value is returned. */ static inline use_operand_p move_use_after_head (use_operand_p use_p, use_operand_p head, use_operand_p last_p) { gcc_assert (USE_FROM_PTR (use_p) == USE_FROM_PTR (head)); /* Skip head when we find it. */ if (use_p != head) { /* If use_p is already linked in after last_p, continue. */ if (last_p->next == use_p) last_p = use_p; else { /* Delink from current location, and link in at last_p. */ delink_imm_use (use_p); link_imm_use_to_list (use_p, last_p); last_p = use_p; } } return last_p; } /* This routine will relink all uses with the same stmt as HEAD into the list immediately following HEAD for iterator IMM. */ static inline void link_use_stmts_after (use_operand_p head, imm_use_iterator *imm) { use_operand_p use_p; use_operand_p last_p = head; gimple head_stmt = USE_STMT (head); tree use = USE_FROM_PTR (head); ssa_op_iter op_iter; int flag; /* Only look at virtual or real uses, depending on the type of HEAD. */ flag = (is_gimple_reg (use) ? SSA_OP_USE : SSA_OP_VIRTUAL_USES); if (gimple_code (head_stmt) == GIMPLE_PHI) { FOR_EACH_PHI_ARG (use_p, head_stmt, op_iter, flag) if (USE_FROM_PTR (use_p) == use) last_p = move_use_after_head (use_p, head, last_p); } else { FOR_EACH_SSA_USE_OPERAND (use_p, head_stmt, op_iter, flag) if (USE_FROM_PTR (use_p) == use) last_p = move_use_after_head (use_p, head, last_p); } /* Link iter node in after last_p. */ if (imm->iter_node.prev != NULL) delink_imm_use (&imm->iter_node); link_imm_use_to_list (&(imm->iter_node), last_p); } /* Initialize IMM to traverse over uses of VAR. Return the first statement. */ static inline gimple first_imm_use_stmt (imm_use_iterator *imm, tree var) { gcc_assert (TREE_CODE (var) == SSA_NAME); imm->end_p = &(SSA_NAME_IMM_USE_NODE (var)); imm->imm_use = imm->end_p->next; imm->next_imm_name = NULL_USE_OPERAND_P; /* iter_node is used as a marker within the immediate use list to indicate where the end of the current stmt's uses are. Initialize it to NULL stmt and use, which indicates a marker node. */ imm->iter_node.prev = NULL_USE_OPERAND_P; imm->iter_node.next = NULL_USE_OPERAND_P; imm->iter_node.loc.stmt = NULL; imm->iter_node.use = NULL_USE_OPERAND_P; if (end_imm_use_stmt_p (imm)) return NULL; link_use_stmts_after (imm->imm_use, imm); return USE_STMT (imm->imm_use); } /* Bump IMM to the next stmt which has a use of var. */ static inline gimple next_imm_use_stmt (imm_use_iterator *imm) { imm->imm_use = imm->iter_node.next; if (end_imm_use_stmt_p (imm)) { if (imm->iter_node.prev != NULL) delink_imm_use (&imm->iter_node); return NULL; } link_use_stmts_after (imm->imm_use, imm); return USE_STMT (imm->imm_use); } /* This routine will return the first use on the stmt IMM currently refers to. */ static inline use_operand_p first_imm_use_on_stmt (imm_use_iterator *imm) { imm->next_imm_name = imm->imm_use->next; return imm->imm_use; } /* Return TRUE if the last use on the stmt IMM refers to has been visited. */ static inline bool end_imm_use_on_stmt_p (const imm_use_iterator *imm) { return (imm->imm_use == &(imm->iter_node)); } /* Bump to the next use on the stmt IMM refers to, return NULL if done. */ static inline use_operand_p next_imm_use_on_stmt (imm_use_iterator *imm) { imm->imm_use = imm->next_imm_name; if (end_imm_use_on_stmt_p (imm)) return NULL_USE_OPERAND_P; else { imm->next_imm_name = imm->imm_use->next; return imm->imm_use; } } /* Return true if VAR cannot be modified by the program. */ static inline bool unmodifiable_var_p (const_tree var) { if (TREE_CODE (var) == SSA_NAME) var = SSA_NAME_VAR (var); if (MTAG_P (var)) return false; return TREE_READONLY (var) && (TREE_STATIC (var) || DECL_EXTERNAL (var)); } /* Return true if REF, an ARRAY_REF, has an INDIRECT_REF somewhere in it. */ static inline bool array_ref_contains_indirect_ref (const_tree ref) { gcc_assert (TREE_CODE (ref) == ARRAY_REF); do { ref = TREE_OPERAND (ref, 0); } while (handled_component_p (ref)); return TREE_CODE (ref) == INDIRECT_REF; } /* Return true if REF, a handled component reference, has an ARRAY_REF somewhere in it. */ static inline bool ref_contains_array_ref (const_tree ref) { gcc_assert (handled_component_p (ref)); do { if (TREE_CODE (ref) == ARRAY_REF) return true; ref = TREE_OPERAND (ref, 0); } while (handled_component_p (ref)); return false; } /* Return true, if the two ranges [POS1, SIZE1] and [POS2, SIZE2] overlap. SIZE1 and/or SIZE2 can be (unsigned)-1 in which case the range is open-ended. Otherwise return false. */ static inline bool ranges_overlap_p (unsigned HOST_WIDE_INT pos1, unsigned HOST_WIDE_INT size1, unsigned HOST_WIDE_INT pos2, unsigned HOST_WIDE_INT size2) { if (pos1 >= pos2 && (size2 == (unsigned HOST_WIDE_INT)-1 || pos1 < (pos2 + size2))) return true; if (pos2 >= pos1 && (size1 == (unsigned HOST_WIDE_INT)-1 || pos2 < (pos1 + size1))) return true; return false; } /* Return the memory tag associated with symbol SYM. */ static inline tree symbol_mem_tag (tree sym) { tree tag = get_var_ann (sym)->symbol_mem_tag; #if defined ENABLE_CHECKING if (tag) gcc_assert (TREE_CODE (tag) == SYMBOL_MEMORY_TAG); #endif return tag; } /* Set the memory tag associated with symbol SYM. */ static inline void set_symbol_mem_tag (tree sym, tree tag) { #if defined ENABLE_CHECKING if (tag) gcc_assert (TREE_CODE (tag) == SYMBOL_MEMORY_TAG); #endif get_var_ann (sym)->symbol_mem_tag = tag; } /* Accessor to tree-ssa-operands.c caches. */ static inline struct ssa_operands * gimple_ssa_operands (const struct function *fun) { return &fun->gimple_df->ssa_operands; } /* Map describing reference statistics for function FN. */ static inline struct mem_ref_stats_d * gimple_mem_ref_stats (const struct function *fn) { return &fn->gimple_df->mem_ref_stats; } /* Given an edge_var_map V, return the PHI arg definition. */ static inline tree redirect_edge_var_map_def (edge_var_map *v) { return v->def; } /* Given an edge_var_map V, return the PHI result. */ static inline tree redirect_edge_var_map_result (edge_var_map *v) { return v->result; } /* Return an SSA_NAME node for variable VAR defined in statement STMT in function cfun. */ static inline tree make_ssa_name (tree var, gimple stmt) { return make_ssa_name_fn (cfun, var, stmt); } #endif /* _TREE_FLOW_INLINE_H */