/*
 * Copyright © 2014 Intel Corporation
 *
 * Permission is hereby granted, free of charge, to any person obtaining a
 * copy of this software and associated documentation files (the "Software"),
 * to deal in the Software without restriction, including without limitation
 * the rights to use, copy, modify, merge, publish, distribute, sublicense,
 * and/or sell copies of the Software, and to permit persons to whom the
 * Software is furnished to do so, subject to the following conditions:
 *
 * The above copyright notice and this permission notice (including the next
 * paragraph) shall be included in all copies or substantial portions of the
 * Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL
 * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
 * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
 * IN THE SOFTWARE.
 *
 * Authors:
 *    Jason Ekstrand (jason@jlekstrand.net)
 */

#include "nir.h"
#include "nir_worklist.h"
#include "nir_vla.h"

/*
 * Basic liveness analysis.  This works only in SSA form.
 *
 * This liveness pass treats phi nodes as being melded to the space between
 * blocks so that the destinations of a phi are in the livein of the block
 * in which it resides and the sources are in the liveout of the
 * corresponding block.  By formulating the liveness information in this
 * way, we ensure that the definition of any variable dominates its entire
 * live range.  This is true because the only way that the definition of an
 * SSA value may not dominate a use is if the use is in a phi node and the
 * uses in phi no are in the live-out of the corresponding predecessor
 * block but not in the live-in of the block containing the phi node.
 */

struct live_ssa_defs_state {
   unsigned num_ssa_defs;
   unsigned bitset_words;

   /* Used in propagate_across_edge() */
   BITSET_WORD *tmp_live;

   nir_block_worklist worklist;
};

static bool
index_ssa_def(nir_ssa_def *def, void *void_state)
{
   struct live_ssa_defs_state *state = void_state;

   if (def->parent_instr->type == nir_instr_type_ssa_undef)
      def->live_index = 0;
   else
      def->live_index = state->num_ssa_defs++;

   return true;
}

/* Initialize the liveness data to zero and add the given block to the
 * worklist.
 */
static bool
init_liveness_block(nir_block *block,
                    struct live_ssa_defs_state *state)
{
   block->live_in = reralloc(block, block->live_in, BITSET_WORD,
                             state->bitset_words);
   memset(block->live_in, 0, state->bitset_words * sizeof(BITSET_WORD));

   block->live_out = reralloc(block, block->live_out, BITSET_WORD,
                              state->bitset_words);
   memset(block->live_out, 0, state->bitset_words * sizeof(BITSET_WORD));

   nir_block_worklist_push_head(&state->worklist, block);

   return true;
}

static bool
set_src_live(nir_src *src, void *void_live)
{
   BITSET_WORD *live = void_live;

   if (!src->is_ssa)
      return true;

   if (src->ssa->live_index == 0)
      return true;   /* undefined variables are never live */

   BITSET_SET(live, src->ssa->live_index);

   return true;
}

static bool
set_ssa_def_dead(nir_ssa_def *def, void *void_live)
{
   BITSET_WORD *live = void_live;

   BITSET_CLEAR(live, def->live_index);

   return true;
}

/** Propagates the live in of succ across the edge to the live out of pred
 *
 * Phi nodes exist "between" blocks and all the phi nodes at the start of a
 * block act "in parallel".  When we propagate from the live_in of one
 * block to the live out of the other, we have to kill any writes from phis
 * and make live any sources.
 *
 * Returns true if updating live out of pred added anything
 */
static bool
propagate_across_edge(nir_block *pred, nir_block *succ,
                      struct live_ssa_defs_state *state)
{
   BITSET_WORD *live = state->tmp_live;
   memcpy(live, succ->live_in, state->bitset_words * sizeof *live);

   nir_foreach_instr(instr, succ) {
      if (instr->type != nir_instr_type_phi)
         break;
      nir_phi_instr *phi = nir_instr_as_phi(instr);

      assert(phi->dest.is_ssa);
      set_ssa_def_dead(&phi->dest.ssa, live);
   }

   nir_foreach_instr(instr, succ) {
      if (instr->type != nir_instr_type_phi)
         break;
      nir_phi_instr *phi = nir_instr_as_phi(instr);

      nir_foreach_phi_src(src, phi) {
         if (src->pred == pred) {
            set_src_live(&src->src, live);
            break;
         }
      }
   }

   BITSET_WORD progress = 0;
   for (unsigned i = 0; i < state->bitset_words; ++i) {
      progress |= live[i] & ~pred->live_out[i];
      pred->live_out[i] |= live[i];
   }
   return progress != 0;
}

void
nir_live_ssa_defs_impl(nir_function_impl *impl)
{
   struct live_ssa_defs_state state;

   /* We start at 1 because we reserve the index value of 0 for ssa_undef
    * instructions.  Those are never live, so their liveness information
    * can be compacted into a single bit.
    */
   state.num_ssa_defs = 1;
   nir_foreach_block(block, impl) {
      nir_foreach_instr(instr, block)
         nir_foreach_ssa_def(instr, index_ssa_def, &state);
   }

   nir_block_worklist_init(&state.worklist, impl->num_blocks, NULL);

   /* We now know how many unique ssa definitions we have and we can go
    * ahead and allocate live_in and live_out sets and add all of the
    * blocks to the worklist.
    */
   state.bitset_words = BITSET_WORDS(state.num_ssa_defs);
   state.tmp_live = rzalloc_array(impl, BITSET_WORD, state.bitset_words);
   nir_foreach_block(block, impl) {
      init_liveness_block(block, &state);
   }


   /* We're now ready to work through the worklist and update the liveness
    * sets of each of the blocks.  By the time we get to this point, every
    * block in the function implementation has been pushed onto the
    * worklist in reverse order.  As long as we keep the worklist
    * up-to-date as we go, everything will get covered.
    */
   while (!nir_block_worklist_is_empty(&state.worklist)) {
      /* We pop them off in the reverse order we pushed them on.  This way
       * the first walk of the instructions is backwards so we only walk
       * once in the case of no control flow.
       */
      nir_block *block = nir_block_worklist_pop_head(&state.worklist);

      memcpy(block->live_in, block->live_out,
             state.bitset_words * sizeof(BITSET_WORD));

      nir_if *following_if = nir_block_get_following_if(block);
      if (following_if)
         set_src_live(&following_if->condition, block->live_in);

      nir_foreach_instr_reverse(instr, block) {
         /* Phi nodes are handled seperately so we want to skip them.  Since
          * we are going backwards and they are at the beginning, we can just
          * break as soon as we see one.
          */
         if (instr->type == nir_instr_type_phi)
            break;

         nir_foreach_ssa_def(instr, set_ssa_def_dead, block->live_in);
         nir_foreach_src(instr, set_src_live, block->live_in);
      }

      /* Walk over all of the predecessors of the current block updating
       * their live in with the live out of this one.  If anything has
       * changed, add the predecessor to the work list so that we ensure
       * that the new information is used.
       */
      set_foreach(block->predecessors, entry) {
         nir_block *pred = (nir_block *)entry->key;
         if (propagate_across_edge(pred, block, &state))
            nir_block_worklist_push_tail(&state.worklist, pred);
      }
   }

   ralloc_free(state.tmp_live);
   nir_block_worklist_fini(&state.worklist);
}

static bool
src_does_not_use_def(nir_src *src, void *def)
{
   return !src->is_ssa || src->ssa != (nir_ssa_def *)def;
}

static bool
search_for_use_after_instr(nir_instr *start, nir_ssa_def *def)
{
   /* Only look for a use strictly after the given instruction */
   struct exec_node *node = start->node.next;
   while (!exec_node_is_tail_sentinel(node)) {
      nir_instr *instr = exec_node_data(nir_instr, node, node);
      if (!nir_foreach_src(instr, src_does_not_use_def, def))
         return true;
      node = node->next;
   }
   return false;
}

/* Returns true if def is live at instr assuming that def comes before
 * instr in a pre DFS search of the dominance tree.
 */
static bool
nir_ssa_def_is_live_at(nir_ssa_def *def, nir_instr *instr)
{
   if (BITSET_TEST(instr->block->live_out, def->live_index)) {
      /* Since def dominates instr, if def is in the liveout of the block,
       * it's live at instr
       */
      return true;
   } else {
      if (BITSET_TEST(instr->block->live_in, def->live_index) ||
          def->parent_instr->block == instr->block) {
         /* In this case it is either live coming into instr's block or it
          * is defined in the same block.  In this case, we simply need to
          * see if it is used after instr.
          */
         return search_for_use_after_instr(instr, def);
      } else {
         return false;
      }
   }
}

bool
nir_ssa_defs_interfere(nir_ssa_def *a, nir_ssa_def *b)
{
   if (a->parent_instr == b->parent_instr) {
      /* Two variables defined at the same time interfere assuming at
       * least one isn't dead.
       */
      return true;
   } else if (a->live_index == 0 || b->live_index == 0) {
      /* If either variable is an ssa_undef, then there's no interference */
      return false;
   } else if (a->live_index < b->live_index) {
      return nir_ssa_def_is_live_at(a, b->parent_instr);
   } else {
      return nir_ssa_def_is_live_at(b, a->parent_instr);
   }
}