Merge branch 'master' into greedy2

[pachi.git] / uct / slave.c

/* This is the slave specific part of the distributed engine.
 * See introduction at top of distributed/distributed.c.
 * The slave maintains a hash table of nodes received from the
 * master. When receiving stats the hash table gives a pointer to the
 * tree node to update. When sending stats we remember in the tree
 * what was previously sent so that only the incremental part has to
 * be sent.  The incremental part is smaller and can be compressed.
 * The compression is not yet done in this version. */

/* Similarly the master only sends stats increments.
 * They include only contributions from other slaves. */

/* The keys for the hash table are coordinate paths from
 * a root child to a given node. See distributed/distributed.h
 * for the encoding of a path to a 64 bit integer. */

/* To allow the master to select the best move, slaves also send
 * absolute playout counts for the best top level nodes (children
 * of the root node), including contributions from other slaves. */

/* Pass me arguments like a=b,c=d,...
 * Slave specific arguments (see uct.c for the other uct arguments
 * and distributed.c for the port arguments) :
 *  slave                   required to indicate slave mode
 *  max_nodes=MAX_NODES     default 80K
 *  stats_hbits=STATS_HBITS default 24. 2^stats_bits = hash table size
 */

#include <assert.h>
#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>

#define MAX_VERBOSE_LOGS 1000
#define DEBUG

#include "debug.h"
#include "board.h"
#include "fbook.h"
#include "gtp.h"
#include "move.h"
#include "timeinfo.h"
#include "uct/internal.h"
#include "uct/search.h"
#include "uct/slave.h"
#include "uct/tree.h"


/* UCT infrastructure for a distributed engine slave. */

/* For debugging only. */
static struct hash_counts h_counts;
static long parent_not_found = 0;
static long parent_leaf = 0;
static long node_not_found = 0;

/* Hash table entry mapping path to node. */
struct tree_hash {
        path_t coord_path;
        struct tree_node *node;
};

void *
uct_htable_alloc(int hbits)
{
        return calloc2(1 << hbits, sizeof(struct tree_hash));
}

/* Clear the hash table. Used only when running as slave for the distributed engine. */
void uct_htable_reset(struct tree *t)
{
        if (!t->htable) return;
        double start = time_now();
        memset(t->htable, 0, (1 << t->hbits) * sizeof(t->htable[0]));
        if (DEBUGL(3))
                fprintf(stderr, "tree occupied %ld %.1f%% inserts %ld collisions %ld/%ld %.1f%% clear %.3fms\n"
                        "parent_not_found %.1f%% parent_leaf %.1f%% node_not_found %.1f%%\n",
                        h_counts.occupied, h_counts.occupied * 100.0 / (1 << t->hbits),
                        h_counts.inserts, h_counts.collisions, h_counts.lookups,
                        h_counts.collisions * 100.0 / (h_counts.lookups + 1),
                        (time_now() - start)*1000,
                        parent_not_found * 100.0 / (h_counts.lookups + 1),
                        parent_leaf * 100.0 / (h_counts.lookups + 1),
                        node_not_found * 100.0 / (h_counts.lookups + 1));
        if (DEBUG_MODE) h_counts.occupied = 0;
}

/* Find a node given its coord path from root. Insert it in the
 * hash table if it is not already there.
 * Return the tree node, or NULL if the node cannot be found.
 * The tree is modified in background while this function is running.
 * prev is only used to optimize the tree search, given that calls to
 * tree_find_node are made with sorted coordinates (increasing levels
 * and increasing coord within a level). */
static struct tree_node *
tree_find_node(struct tree *t, struct incr_stats *is, struct tree_node *prev)
{
        assert(t && t->htable);
        path_t path = is->coord_path;
        /* pass and resign must never be inserted in the hash table. */
        assert(path > 0);

        int hash, parent_hash;
        bool found;
        find_hash(hash, t->htable, t->hbits, path, found, h_counts);
        struct tree_hash *hnode = &t->htable[hash];

        if (DEBUGVV(7))
                fprintf(stderr,
                        "find_node %"PRIpath" %s found %d hash %d playouts %d node %p\n", path,
                        path2sstr(path, t->board), found, hash, is->incr.playouts, hnode->node);

        if (found) return hnode->node;

        /* The master sends parents before children so the parent should
         * already be in the hash table. */
        path_t parent_p = parent_path(path, t->board);
        struct tree_node *parent;
        if (parent_p) {
                find_hash(parent_hash, t->htable, t->hbits,
                          parent_p, found, h_counts);
                parent = t->htable[parent_hash].node;
        } else {
                parent = t->root;
        }
        struct tree_node *node = NULL;
        if (parent) {
                /* Search for the node in parent's children. */
                coord_t leaf = leaf_coord(path, t->board);
                node = (prev && prev->parent == parent ? prev->sibling : parent->children);
                while (node && node_coord(node) != leaf) node = node->sibling;

                if (DEBUG_MODE) parent_leaf += !parent->is_expanded;
        } else {
                if (DEBUG_MODE) parent_not_found++;
                if (DEBUGVV(7))
                        fprintf(stderr, "parent of %"PRIpath" %s not found\n",
                                path, path2sstr(path, t->board));
        }

        /* Insert the node in the hash table. */
        hnode->node = node;
        if (DEBUG_MODE) h_counts.inserts++, h_counts.occupied++;
        if (DEBUGVV(7))
                fprintf(stderr, "insert path %"PRIpath" %s hash %d playouts %d node %p\n",
                        path, path2sstr(path, t->board), hash, is->incr.playouts, node);

        if (DEBUG_MODE && !node) node_not_found++;

        hnode->coord_path = path;
        return node;
}


/* Read and discard any binary arguments. The number of
 * bytes to be skipped is given by @size in the command. */
static void
discard_bin_args(char *args)
{
        char *s = strchr(args, '@');
        int size = 0;
        if (s) size = atoi(s+1);
        while (size) {
                char buf[64*1024];
                int len = sizeof(buf);
                if (len > size) len = size;
                len = fread(buf, 1, len, stdin);
                if (len <= 0) break;
                size -= len;
        }
}

enum parse_code
uct_notify(struct engine *e, struct board *b, int id, char *cmd, char *args, char **reply)
{
        struct uct *u = e->data;

        static bool board_resized = false;
        if (is_gamestart(cmd)) {
                board_resized = true;
                uct_pondering_stop(u);
        }

        /* Force resending the whole command history if we are out of sync
         * but do it only once, not if already getting the history. */
        if ((move_number(id) != b->moves || !board_resized)
            && !reply_disabled(id) && !is_reset(cmd)) {
                static char buf[128];
                snprintf(buf, sizeof(buf), "Out of sync, %d %s, move %d expected", id, cmd, b->moves);
                if (UDEBUGL(0))
                        fprintf(stderr, "%s\n", buf); 
                discard_bin_args(args);

                *reply = buf;
                /* Let gtp_parse() complain about invalid commands. */
                if (!gtp_is_valid(cmd) && !is_repeated(cmd)) return P_OK;
                return P_DONE_ERROR;
        }
        return reply_disabled(id) ? P_NOREPLY : P_OK;
}


/* Read the move stats sent by the master, as a binary array of
 * incr_stats structs. The stats come sorted by increasing coord path.
 * To simplify the code, we assume that master and slave have the same
 * architecture (store values identically).
 * Keep this code in sync with distributed/merge.c:output_stats()
 * Return true if ok, false if error. */
static bool
receive_stats(struct uct *u, int size)
{
        if (size % sizeof(struct incr_stats)) return false;
        int nodes = size / sizeof(struct incr_stats);
        if (nodes > (1 << u->stats_hbits)) return false;

        struct tree *t = u->t;
        assert(nodes && t->htable);
        struct tree_node *prev = NULL;
        double start_time = time_now();

        for (int n = 0; n < nodes; n++) {
                struct incr_stats is;
                if (fread(&is, sizeof(struct incr_stats), 1, stdin) != 1)
                        return false;

                if (UDEBUGL(7))
                        fprintf(stderr, "read %5d/%d %6d %.3f %"PRIpath" %s\n", n, nodes,
                                is.incr.playouts, is.incr.value, is.coord_path,
                                path2sstr(is.coord_path, t->board));

                struct tree_node *node = tree_find_node(t, &is, prev);
                if (!node) continue;

                /* node_total += others_incr */
                stats_add_result(&node->u, is.incr.value, is.incr.playouts);

                /* last_total += others_incr */
                stats_add_result(&node->pu, is.incr.value, is.incr.playouts);

                prev = node;
        }
        if (DEBUGVV(2))
                fprintf(stderr, "read args for %d nodes in %.4fms\n", nodes,
                        (time_now() - start_time)*1000);
        return true;
}

/* A tree traversal fills this array, then the nodes with most increments are sent. */
struct stats_candidate {
        path_t coord_path;
        int playout_incr;
        struct tree_node *node;
};

/* We maintain counts per bucket to avoid sorting stats_queue.
 * All nodes with n updates since last send go to bucket n.
 * If we put all nodes above 1023 updates in the top bucket,
 * we get at most 27 nodes in this bucket. So we can select
 * exactly the best shared_nodes nodes if shared_nodes >= 27. */
#define MAX_BUCKETS 1024
static int bucket_count[MAX_BUCKETS];

/* Traverse the tree rooted at node, and append incremental stats
 * for children to stats_queue. start_path is the coordinate path
 * for the top node. Stats for a node are only appended if enough playouts
 * have been made since the last send, and the level is not too deep.
 * Return the updated stats count. */
static int
append_stats(struct stats_candidate *stats_queue, struct tree_node *node, int stats_count,
             int max_count, path_t start_path, path_t max_path, int min_increment, struct board *b)
{
        /* The children field is set only after all children are created
         * so we can traverse the the tree while it is updated. */
        for (struct tree_node *ni = node->children; ni; ni = ni->sibling) {

                if (is_pass(node_coord(ni))) continue;
                if (ni->hints & TREE_HINT_INVALID) continue;

                int incr = ni->u.playouts - ni->pu.playouts;
                if (incr < min_increment) continue;

                /* min_increment should be tuned to avoid overflow. */
                if (stats_count >= max_count) {
                        if (DEBUGL(0))
                                fprintf(stderr, "*** stats overflow %d nodes\n", stats_count);
                        return stats_count;
                }
                path_t child_path = append_child(start_path, node_coord(ni), b);
                stats_queue[stats_count].playout_incr = incr;
                stats_queue[stats_count].coord_path = child_path;
                stats_queue[stats_count++].node = ni;

                if (incr >= MAX_BUCKETS) incr = MAX_BUCKETS - 1;
                bucket_count[incr]++;

                /* Do not recurse if level deep enough. */
                if (child_path >= max_path) continue;

                stats_count = append_stats(stats_queue, ni, stats_count, max_count,
                                           child_path, max_path, min_increment, b);
        }
        return stats_count;
}

/* Used to sort by coord path the incremental stats to be sent. */
static int
coord_cmp(const void *p1, const void *p2)
{
        path_t diff = ((struct incr_stats *)p1)->coord_path
                    - ((struct incr_stats *)p2)->coord_path;
        return (int)(diff >> 32) | !!(int)diff;
}

/* Select from stats_queue at most shared_nodes candidates with
 * biggest increments. Return a binary array sorted by coord path. */
static struct incr_stats *
select_best_stats(struct stats_candidate *stats_queue, int stats_count,
                  int shared_nodes, int *byte_size)
{
        static struct incr_stats *out_stats = NULL;
        if (!out_stats)
                out_stats = malloc2(shared_nodes * sizeof(*out_stats));

        /* Find the minimum increment to send. The bucket with minimum
         * increment may be sent only partially. */
        int out_count = 0;
        int min_incr = MAX_BUCKETS;
        do {
                out_count += bucket_count[--min_incr];
        } while (min_incr > 1 && out_count < shared_nodes);

        /* Send all all increments > min_incr plus whatever we can at min_incr. */
        int min_count = bucket_count[min_incr] - (out_count - shared_nodes);
        struct incr_stats *os = out_stats;
        out_count = 0;
        for (int count = 0; count < stats_count; count++) {
                int delta = stats_queue[count].playout_incr - min_incr;
                if (delta < 0 || (delta == 0 && --min_count < 0)) continue;

                struct tree_node *node = stats_queue[count].node;
                os->incr = node->u;
                stats_rm_result(&os->incr, node->pu.value, node->pu.playouts);

                /* With virtual loss os->incr.playouts might be <= 0; we only
                 * send positive increments to other slaves so a virtual loss
                 * can be propagated to other machines (good). The undo of the
                 * virtual loss will be propagated later when node->u gets
                 * above node->pu. */
                if (os->incr.playouts > 0) {
                        node->pu = node->u;
                        os->coord_path = stats_queue[count].coord_path;
                        assert(os->coord_path > 0);
                        os++;
                        out_count++;
                }
                assert (out_count <= shared_nodes);
        }
        *byte_size = (char *)os - (char *)out_stats;

        /* Sort the increments by increasing coord path (required by master).
         * Can be done in linear time with radix sort if qsort is too slow. */
        qsort(out_stats, out_count, sizeof(*os), coord_cmp);
        return out_stats;
}

/* Get incremental stats updates for the distributed engine.
 * Return a binary array of incr_stats structs in coordinate order
 * (increasing levels and increasing coordinates within a level).
 * This function is called only by the main thread, but may be
 * called while the tree is updated by the worker threads. Keep this
 * code in sync with distributed/merge.c:merge_new_stats(). */
static void *
report_incr_stats(struct uct *u, int *stats_size)
{
        double start_time = time_now();

        struct tree_node *root = u->t->root;
        struct board *b = u->t->board;

        /* The factor 3 below has experimentally been found to be
         * sufficient. At worst if we fill stats_queue we will
         * discard some stats updates but this is rare. */
        int max_nodes = 3 * u->shared_nodes;
        static struct stats_candidate *stats_queue = NULL;
        if (!stats_queue) stats_queue = malloc2(max_nodes * sizeof(*stats_queue));

        memset(bucket_count, 0, sizeof(bucket_count));

        /* Try to fill the output buffer with the most important
         * nodes (highest increments), while still traversing
         * as little of the tree as possible. If we set min_increment
         * too low we waste time. If we set it too high we can't
         * fill the output buffer with the desired number of nodes.
         * The best min_increment results in stats_count just above 
         * shared_nodes. However perfect tuning is not necessary:
         * if we send too few nodes we just send shorter buffers
         * more frequently. */
        static int min_increment = 1;
        static int stats_count = 0;
        if (stats_count > 2 * u->shared_nodes) {
                min_increment++;
        } else if (stats_count < u->shared_nodes / 2 && min_increment > 1) {
                min_increment--;
        }

        stats_count = append_stats(stats_queue, root, 0, max_nodes, 0,
                                   max_parent_path(u, b), min_increment, b);

        void *buf = select_best_stats(stats_queue, stats_count, u->shared_nodes, stats_size);

        if (DEBUGVV(2))
                fprintf(stderr,
                        "min_incr %d games %d stats_queue %d/%d sending %d/%d in %.3fms\n",
                        min_increment, root->u.playouts - root->pu.playouts, stats_count,
                        max_nodes, *stats_size / (int)sizeof(struct incr_stats), u->shared_nodes,
                        (time_now() - start_time)*1000);
        root->pu = root->u;
        return buf;
}

/* Get stats for the distributed engine. Return a buffer with one
 * line "played_own root_playouts threads keep_looking @size", then
 * a list of lines "coord playouts value" with absolute counts for
 * children of the root node (including contributions from other
 * slaves). The last line must not end with \n.
 * If c is non-zero, add this move with a large weight.
 * This function is called only by the main thread, but may be
 * called while the tree is updated by the worker threads. Keep this
 * code in sync with distributed/distributed.c:select_best_move(). */
static char *
report_stats(struct uct *u, struct board *b, coord_t c,
             bool keep_looking, int bin_size)
{
        static char reply[10240];
        char *r = reply;
        char *end = reply + sizeof(reply);
        struct tree_node *root = u->t->root;
        r += snprintf(r, end - r, "%d %d %d %d @%d", u->played_own, root->u.playouts,
                      u->threads, keep_looking, bin_size);
        int min_playouts = root->u.playouts / 100;
        int max_playouts = 1;

        /* We rely on the fact that root->children is set only
         * after all children are created. */
        for (struct tree_node *ni = root->children; ni; ni = ni->sibling) {

                if (is_pass(node_coord(ni))) continue;
                assert(node_coord(ni) > 0 && node_coord(ni) < board_size2(b));

                if (ni->u.playouts > max_playouts)
                        max_playouts = ni->u.playouts;
                if (ni->u.playouts <= min_playouts || ni->hints & TREE_HINT_INVALID)
                        continue;
                /* A book move is only added at the end: */
                if (node_coord(ni) == c) continue;

                char buf[4];
                /* We return the values as stored in the tree, so from black's view. */
                r += snprintf(r, end - r, "\n%s %d %.16f", coord2bstr(buf, node_coord(ni), b),
                              ni->u.playouts, ni->u.value);
        }
        /* Give a large but not infinite weight to pass, resign or book move, to avoid
         * forcing resign if other slaves don't like it. */
        if (c) {
                double resign_value = u->t->root_color == S_WHITE ? 0.0 : 1.0;
                double c_value = is_resign(c) ? resign_value : 1.0 - resign_value;
                r += snprintf(r, end - r, "\n%s %d %.1f", coord2sstr(c, b),
                              2 * max_playouts, c_value);
        }
        return reply;
}

/* genmoves is issued by the distributed engine master to all slaves, to:
 * 1. Start a MCTS search if not running yet
 * 2. Report current move statistics of the on-going search.
 * The MCTS search is left running on the background when uct_genmoves()
 * returns. It is stopped by receiving a play GTP command, triggering
 * uct_pondering_stop(). */
/* genmoves gets in the args parameter
 * "played_games nodes main_time byoyomi_time byoyomi_periods byoyomi_stones @size"
 * and reads a binary array of coord, playouts, value to get stats of other slaves,
 * except possibly for the first call at a given move number.
 * See report_stats() for the description of the return value. */
char *
uct_genmoves(struct engine *e, struct board *b, struct time_info *ti, enum stone color,
             char *args, bool pass_all_alive, void **stats_buf, int *stats_size)
{
        struct uct *u = e->data;
        assert(u->slave);

        /* Prepare the state if the search is not already running.
         * We must do this first since we tweak the state below
         * based on instructions from the master. */
        if (!thread_manager_running)
                uct_genmove_setup(u, b, color);

        /* Get playouts and time information from master. Keep this code
         * in sync with distibuted/distributed.c:distributed_genmove(). */
        if ((ti->dim == TD_WALLTIME
             && sscanf(args, "%d %lf %lf %d %d", &u->played_all,
                       &ti->len.t.main_time, &ti->len.t.byoyomi_time,
                       &ti->len.t.byoyomi_periods, &ti->len.t.byoyomi_stones) != 5)

            || (ti->dim == TD_GAMES && sscanf(args, "%d", &u->played_all) != 1)) {
                return NULL;
        }

        static struct uct_search_state s;
        if (!thread_manager_running) {
                /* This is the first genmoves issue, start the MCTS
                 * now and let it run while we receive stats. */
                memset(&s, 0, sizeof(s));
                uct_search_start(u, b, color, u->t, ti, &s);
        }

        /* Read binary incremental stats if present, otherwise
         * wait a bit to populate the statistics. */
        int size = 0;
        char *sizep = strchr(args, '@');
        if (sizep) size = atoi(sizep+1);
        if (!size) {
                time_sleep(u->stats_delay);
        } else if (!receive_stats(u, size)) {
                return NULL;
        }

        /* Check the state of the Monte Carlo Tree Search. */

        int played_games = uct_search_games(&s);
        uct_search_progress(u, b, color, u->t, ti, &s, played_games);
        u->played_own = played_games - s.base_playouts;

        *stats_size = 0;
        bool keep_looking = false;
        coord_t best_coord = pass;
        if (b->fbook)
                best_coord = fbook_check(b);
        if (best_coord == pass) {
                keep_looking = !uct_search_check_stop(u, b, color, u->t, ti, &s, played_games);
                uct_search_result(u, b, color, pass_all_alive, played_games, s.base_playouts, &best_coord);
                /* Give heavy weight only to pass, resign and book move: */
                if (best_coord > 0) best_coord = 0; 

                if (u->shared_levels) {
                        *stats_buf = report_incr_stats(u, stats_size);
                }
        }
        char *reply = report_stats(u, b, best_coord, keep_looking, *stats_size);
        return reply;
}