/* * UnSSA - translate the SSA back to normal form. * * For now it's done by replacing to set of copies: * 1) For each phi-node, replace all their phisrc by copies to a common * temporary. * 2) Replace all the phi-nodes by copies of the temporaries to the phi-node target. * This is node to preserve the semantic of the phi-node (they should all "execute" * simultaneously on entry in the basic block in which they belong). * * This is similar to the "Sreedhar method I" except that the copies to the * temporaries are not placed at the end of the predecessor basic blocks, but * at the place where the phi-node operands are defined (the same place where the * phisrc were present). * Is this a problem? * * While very simple this method create a lot more copies that really necessary. * Ideally, "Sreedhar method III" should be used: * "Translating Out of Static Single Assignment Form", V. C. Sreedhar, R. D.-C. Ju, * D. M. Gillies and V. Santhanam. SAS'99, Vol. 1694 of Lecture Notes in Computer * Science, Springer-Verlag, pp. 194-210, 1999. * * Copyright (C) 2005 Luc Van Oostenryck */ #include "lib.h" #include "linearize.h" #include "allocate.h" #include "flow.h" #include static void remove_phisrc_defines(struct instruction *phisrc) { struct instruction *phi; struct basic_block *bb = phisrc->bb; FOR_EACH_PTR(phisrc->phi_users, phi) { remove_pseudo(&bb->defines, phi->target); } END_FOR_EACH_PTR(phi); } static void replace_phi_node(struct instruction *phi) { pseudo_t tmp; tmp = alloc_pseudo(NULL); tmp->type = phi->target->type; tmp->ident = phi->target->ident; tmp->def = NULL; // defined by all the phisrc // update the current liveness remove_pseudo(&phi->bb->needs, phi->target); add_pseudo(&phi->bb->needs, tmp); track_phi_uses(phi); phi->opcode = OP_COPY; phi->src = tmp; // FIXME: free phi->phi_list; } static void rewrite_phi_bb(struct basic_block *bb) { struct instruction *insn; // Replace all the phi-nodes by copies of a temporary // (which represent the set of all the %phi that feed them). // The target pseudo doesn't change. FOR_EACH_PTR(bb->insns, insn) { if (!insn->bb) continue; if (insn->opcode != OP_PHI) continue; replace_phi_node(insn); } END_FOR_EACH_PTR(insn); } static void rewrite_phisrc_bb(struct basic_block *bb) { struct instruction *insn; // Replace all the phisrc by one or several copies to // the temporaries associated to each phi-node it defines. FOR_EACH_PTR_REVERSE(bb->insns, insn) { struct instruction *phi; int i; if (!insn->bb) continue; if (insn->opcode != OP_PHISOURCE) continue; i = 0; FOR_EACH_PTR(insn->phi_users, phi) { pseudo_t tmp = phi->src; pseudo_t src = insn->phi_src; if (i == 0) { // first phi: we overwrite the phisrc insn->opcode = OP_COPY; insn->target = tmp; insn->src = src; } else { struct instruction *copy = __alloc_instruction(0); copy->bb = bb; copy->opcode = OP_COPY; copy->size = insn->size; copy->pos = insn->pos; copy->target = tmp; copy->src = src; INSERT_CURRENT(copy, insn); } // update the liveness info remove_phisrc_defines(insn); // FIXME: should really something like add_pseudo_exclusive() add_pseudo(&bb->defines, tmp); i++; } END_FOR_EACH_PTR(phi); } END_FOR_EACH_PTR_REVERSE(insn); } int unssa(struct entrypoint *ep) { struct basic_block *bb; FOR_EACH_PTR(ep->bbs, bb) { rewrite_phi_bb(bb); } END_FOR_EACH_PTR(bb); FOR_EACH_PTR(ep->bbs, bb) { rewrite_phisrc_bb(bb); } END_FOR_EACH_PTR(bb); return 0; }