Let foreach_out_edge_kind() and foreach_out_edge_kind_safe() declare their iterator...

[libfirm] / ir / be / beabihelper.c

/*
 * Copyright (C) 1995-2008 University of Karlsruhe.  All right reserved.
 *
 * This file is part of libFirm.
 *
 * This file may be distributed and/or modified under the terms of the
 * GNU General Public License version 2 as published by the Free Software
 * Foundation and appearing in the file LICENSE.GPL included in the
 * packaging of this file.
 *
 * Licensees holding valid libFirm Professional Edition licenses may use
 * this file in accordance with the libFirm Commercial License.
 * Agreement provided with the Software.
 *
 * This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE
 * WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 * PURPOSE.
 */

/**
 * @file
 * @brief       Helper functions for handling ABI constraints in the code
 *              selection phase.
 * @author      Matthias Braun
 */
#include "config.h"

#include "beabihelper.h"
#include "bearch.h"
#include "benode.h"
#include "besched.h"
#include "ircons.h"
#include "iredges.h"
#include "irgwalk.h"
#include "irnodemap.h"
#include "irtools.h"
#include "heights.h"

/**
 * An entry in the register state map.
 */
typedef struct reg_flag_t {
        const arch_register_t *reg;     /**< register at an input position.
                                             may be NULL in case of memory input */
        arch_register_req_type_t flags; /**< requirement flags for this register. */
} reg_flag_t;

/**
 * A register state mapping keeps track of the symbol values (=firm nodes)
 * to registers. This is useful when constructing straight line code
 * like the function prolog or epilog in some architectures.
 */
typedef struct register_state_mapping_t {
        ir_node   **value_map;     /**< mapping of state indices to values */
        size_t    **reg_index_map; /**< mapping of regclass,regnum to an index
                                        into the value_map */
        reg_flag_t *regs;          /**< registers (and memory values) that form a
                                        state */
} register_state_mapping_t;

/**
 * The environment for all helper functions.
 */
struct beabi_helper_env_t {
        ir_graph                 *irg;         /**< the graph we operate on */
        register_state_mapping_t  prolog;      /**< the register state map for the prolog */
        register_state_mapping_t  epilog;      /**< the register state map for the epilog */
};

/**
 * Create a new empty register state map for the given
 * architecture.
 *
 * @param rsm       the register state map to be initialized
 * @param arch_env  the architecture environment
 *
 * After this call, the register map is initialized to empty.
 */
static void prepare_rsm(register_state_mapping_t *rsm,
                        const arch_env_t *arch_env)
{
        unsigned   n_reg_classes = arch_env->n_register_classes;
        unsigned   c;
        reg_flag_t memory = { NULL, arch_register_req_type_none };

        rsm->regs = NEW_ARR_F(reg_flag_t, 0);
        /* memory input at 0 */
        ARR_APP1(reg_flag_t, rsm->regs, memory);

        rsm->value_map     = NULL;
        rsm->reg_index_map = XMALLOCN(size_t*, n_reg_classes);
        for (c = 0; c < n_reg_classes; ++c) {
                const arch_register_class_t *cls    = &arch_env->register_classes[c];
                unsigned                     n_regs = arch_register_class_n_regs(cls);
                unsigned                     r;

                rsm->reg_index_map[c] = XMALLOCN(size_t, n_regs);
                for (r = 0; r < n_regs; ++r) {
                        rsm->reg_index_map[c][r] = (size_t)-1;
                }
        }
}

/**
 * Destroy a register state map for the given
 * architecture.
 *
 * @param rsm       the register state map to be destroyed
 * @param arch_env  the architecture environment
 *
 * After this call, the register map is initialized to empty.
 */
static void free_rsm(register_state_mapping_t *rsm, const arch_env_t *arch_env)
{
        unsigned n_reg_classes = arch_env->n_register_classes;
        unsigned c;

        for (c = 0; c < n_reg_classes; ++c) {
                free(rsm->reg_index_map[c]);
        }

        free(rsm->reg_index_map);
        if (rsm->value_map != NULL)
                DEL_ARR_F(rsm->value_map);
        DEL_ARR_F(rsm->regs);

        rsm->regs          = NULL;
        rsm->reg_index_map = NULL;
        rsm->value_map     = NULL;
}

/**
 * Remove all registers from a register state map.
 *
 * @param rsm       the register state map to be destroyed
 * @param arch_env  the architecture environment
 */
static void rsm_clear_regs(register_state_mapping_t *rsm,
                           const arch_env_t *arch_env)
{
        unsigned   n_reg_classes = arch_env->n_register_classes;
        unsigned   c;
        reg_flag_t memory = { NULL, arch_register_req_type_none };

        for (c = 0; c < n_reg_classes; ++c) {
                const arch_register_class_t *cls    = &arch_env->register_classes[c];
                unsigned                     n_regs = arch_register_class_n_regs(cls);
                unsigned                     r;

                for (r = 0; r < n_regs; ++r) {
                        rsm->reg_index_map[c][r] = (size_t)-1;
                }
        }
        ARR_RESIZE(reg_flag_t, rsm->regs, 0);
        ARR_APP1(reg_flag_t, rsm->regs, memory);

        if (rsm->value_map != NULL) {
                DEL_ARR_F(rsm->value_map);
                rsm->value_map = NULL;
        }
}

/**
 * Add a register and its constraint flags to a register state map
 * and return its index inside the map.
 */
static size_t rsm_add_reg(register_state_mapping_t *rsm,
                          const arch_register_t *reg,
                           arch_register_req_type_t flags)
{
        size_t     input_idx = ARR_LEN(rsm->regs);
        int        cls_idx   = reg->reg_class->index;
        int        reg_idx   = reg->index;
        reg_flag_t regflag   = { reg, flags };

        /* we must not have used get_value yet */
        assert(rsm->reg_index_map[cls_idx][reg_idx] == (size_t)-1);
        rsm->reg_index_map[cls_idx][reg_idx] = input_idx;
        ARR_APP1(reg_flag_t, rsm->regs, regflag);

        if (rsm->value_map != NULL) {
                ARR_APP1(ir_node*, rsm->value_map, NULL);
                assert(ARR_LEN(rsm->value_map) == ARR_LEN(rsm->regs));
        }
        return input_idx;
}

/**
 * Retrieve the ir_node stored at the given index in the register state map.
 */
static ir_node *rsm_get_value(register_state_mapping_t *rsm, size_t index)
{
        assert(index < ARR_LEN(rsm->value_map));
        return rsm->value_map[index];
}

/**
 * Retrieve the ir_node occupying the given register in the register state map.
 */
static ir_node *rsm_get_reg_value(register_state_mapping_t *rsm,
                                  const arch_register_t *reg)
{
        int    cls_idx   = reg->reg_class->index;
        int    reg_idx   = reg->index;
        size_t input_idx = rsm->reg_index_map[cls_idx][reg_idx];

        return rsm_get_value(rsm, input_idx);
}

/**
 * Enter a ir_node at the given index in the register state map.
 */
static void rsm_set_value(register_state_mapping_t *rsm, size_t index,
                          ir_node *value)
{
        assert(index < ARR_LEN(rsm->value_map));
        rsm->value_map[index] = value;
}

/**
 * Enter a ir_node at the given register in the register state map.
 */
static void rsm_set_reg_value(register_state_mapping_t *rsm,
                              const arch_register_t *reg, ir_node *value)
{
        int    cls_idx   = reg->reg_class->index;
        int    reg_idx   = reg->index;
        size_t input_idx = rsm->reg_index_map[cls_idx][reg_idx];
        rsm_set_value(rsm, input_idx, value);
}


beabi_helper_env_t *be_abihelper_prepare(ir_graph *irg)
{
        const arch_env_t   *arch_env = be_get_irg_arch_env(irg);
        beabi_helper_env_t *env      = XMALLOCZ(beabi_helper_env_t);

        env->irg = irg;
        prepare_rsm(&env->prolog, arch_env);
        prepare_rsm(&env->epilog, arch_env);

        return env;
}

void be_abihelper_finish(beabi_helper_env_t *env)
{
        const arch_env_t *arch_env = be_get_irg_arch_env(env->irg);

        free_rsm(&env->prolog, arch_env);
        if (env->epilog.reg_index_map != NULL) {
                free_rsm(&env->epilog, arch_env);
        }
        xfree(env);
}

void be_prolog_add_reg(beabi_helper_env_t *env, const arch_register_t *reg,
                       arch_register_req_type_t flags)
{
        rsm_add_reg(&env->prolog, reg, flags);
}

ir_node *be_prolog_create_start(beabi_helper_env_t *env, dbg_info *dbgi,
                                ir_node *block)
{
        int      n_start_outs = ARR_LEN(env->prolog.regs);
        ir_node *start        = be_new_Start(dbgi, block, n_start_outs);
        int      o;

        assert(env->prolog.value_map == NULL);
        env->prolog.value_map = NEW_ARR_F(ir_node*, n_start_outs);

        for (o = 0; o < n_start_outs; ++o) {
                const reg_flag_t      *regflag = &env->prolog.regs[o];
                const arch_register_t *reg     = regflag->reg;
                ir_node               *proj;
                if (reg == NULL) {
                        arch_set_irn_register_req_out(start, o, arch_no_register_req);
                        proj = new_r_Proj(start, mode_M, o);
                } else {
                        be_set_constr_single_reg_out(start, o, regflag->reg,
                                                     regflag->flags);
                        arch_set_irn_register_out(start, o, regflag->reg);
                        proj = new_r_Proj(start, reg->reg_class->mode, o);
                }
                env->prolog.value_map[o] = proj;
        }

        return start;
}

ir_node *be_prolog_get_reg_value(beabi_helper_env_t *env,
                                 const arch_register_t *reg)
{
        return rsm_get_reg_value(&env->prolog, reg);
}

ir_node *be_prolog_get_memory(beabi_helper_env_t *env)
{
        return rsm_get_value(&env->prolog, 0);
}

void be_prolog_set_reg_value(beabi_helper_env_t *env,
                             const arch_register_t *reg, ir_node *value)
{
        rsm_set_reg_value(&env->prolog, reg, value);
}

void be_prolog_set_memory(beabi_helper_env_t *env, ir_node *value)
{
        rsm_set_value(&env->prolog, 0, value);
}



void be_epilog_begin(beabi_helper_env_t *env)
{
        const arch_env_t *arch_env = be_get_irg_arch_env(env->irg);
        rsm_clear_regs(&env->epilog, arch_env);
        env->epilog.value_map    = NEW_ARR_F(ir_node*, 1);
        env->epilog.value_map[0] = NULL;
}

void be_epilog_add_reg(beabi_helper_env_t *env, const arch_register_t *reg,
                       arch_register_req_type_t flags, ir_node *value)
{
        size_t index = rsm_add_reg(&env->epilog, reg, flags);
        rsm_set_value(&env->epilog, index, value);
}

void be_epilog_set_reg_value(beabi_helper_env_t *env,
                             const arch_register_t *reg, ir_node *value)
{
        rsm_set_reg_value(&env->epilog, reg, value);
}

void be_epilog_set_memory(beabi_helper_env_t *env, ir_node *value)
{
        rsm_set_value(&env->epilog, 0, value);
}

ir_node *be_epilog_get_reg_value(beabi_helper_env_t *env,
                                 const arch_register_t *reg)
{
        return rsm_get_reg_value(&env->epilog, reg);
}

ir_node *be_epilog_get_memory(beabi_helper_env_t *env)
{
        return rsm_get_value(&env->epilog, 0);
}

ir_node *be_epilog_create_return(beabi_helper_env_t *env, dbg_info *dbgi,
                                 ir_node *block)
{
        size_t    n_return_in = ARR_LEN(env->epilog.regs);
        ir_node **in          = env->epilog.value_map;
        int       n_res       = 1; /* TODO */
        unsigned  pop         = 0; /* TODO */
        size_t    i;
        ir_node  *ret;

        assert(ARR_LEN(env->epilog.value_map) == n_return_in);

        ret = be_new_Return(dbgi, get_irn_irg(block), block, n_res, pop,
                            n_return_in, in);
        for (i = 0; i < n_return_in; ++i) {
                const reg_flag_t      *regflag = &env->epilog.regs[i];
                const arch_register_t *reg     = regflag->reg;
                if (reg != NULL) {
                        be_set_constr_single_reg_in(ret, i, reg,
                                                    arch_register_req_type_none);
                }
        }

        rsm_clear_regs(&env->epilog, be_get_irg_arch_env(env->irg));

        return ret;
}

/**
 * Tests whether a node has a real user and is not just kept by the End or
 * Anchor node
 */
static bool has_real_user(const ir_node *node)
{
        foreach_out_edge(node, edge) {
                ir_node *user = get_edge_src_irn(edge);
                if (!is_End(user) && !is_Anchor(user))
                        return true;
        }
        return false;
}

static ir_node *add_to_keep(ir_node *last_keep,
                            const arch_register_class_t *cls, ir_node *node)
{
        if (last_keep != NULL) {
                be_Keep_add_node(last_keep, cls, node);
        } else {
                ir_node *in[1] = { node };
                ir_node *block = get_nodes_block(node);
                ir_node *schedpoint;
                last_keep = be_new_Keep(block, 1, in);

                schedpoint = skip_Proj(node);
                if (sched_is_scheduled(schedpoint)) {
                        sched_add_after(schedpoint, last_keep);
                }
        }
        return last_keep;
}

void be_add_missing_keeps_node(ir_node *node)
{
        int       n_outs, i;
        unsigned *found_projs;
        ir_mode  *mode = get_irn_mode(node);
        ir_node  *last_keep;
        ir_node **existing_projs;

        if (mode != mode_T) {
                if (!has_real_user(node)) {
                        const arch_register_req_t   *req = arch_get_irn_register_req(node);
                        const arch_register_class_t *cls = req->cls;
                        if (cls == NULL
                                        || (cls->flags & arch_register_class_flag_manual_ra)) {
                                return;
                        }

                        add_to_keep(NULL, cls, node);
                }
                return;
        }

        n_outs = arch_get_irn_n_outs(node);
        if (n_outs <= 0)
                return;

        rbitset_alloca(found_projs, n_outs);
        existing_projs = ALLOCANZ(ir_node*, n_outs);
        foreach_out_edge(node, edge) {
                ir_node *succ = get_edge_src_irn(edge);
                ir_mode *mode = get_irn_mode(succ);
                int      pn;

                /* The node could be kept */
                if (is_End(succ) || is_Anchor(succ))
                        continue;
                if (mode == mode_M || mode == mode_X)
                        continue;
                pn                 = get_Proj_proj(succ);
                existing_projs[pn] = succ;
                if (!has_real_user(succ))
                        continue;

                assert(pn < n_outs);
                rbitset_set(found_projs, pn);
        }

        /* are keeps missing? */
        last_keep = NULL;
        for (i = 0; i < n_outs; ++i) {
                ir_node                     *value;
                const arch_register_req_t   *req;
                const arch_register_class_t *cls;

                if (rbitset_is_set(found_projs, i)) {
                        continue;
                }

                req = arch_get_irn_register_req_out(node, i);
                cls = req->cls;
                if (cls == NULL || (cls->flags & arch_register_class_flag_manual_ra)) {
                        continue;
                }

                value = existing_projs[i];
                if (value == NULL)
                        value = new_r_Proj(node, arch_register_class_mode(cls), i);
                last_keep = add_to_keep(last_keep, cls, value);
        }
}

static void add_missing_keep_walker(ir_node *node, void *data)
{
        (void)data;
        be_add_missing_keeps_node(node);
}

void be_add_missing_keeps(ir_graph *irg)
{
        irg_walk_graph(irg, add_missing_keep_walker, NULL, NULL);
}


/**
 * Link the node into its block list as a new head.
 */
static void collect_node(ir_node *node)
{
        ir_node *block = get_nodes_block(node);
        ir_node *old   = (ir_node*)get_irn_link(block);

        set_irn_link(node, old);
        set_irn_link(block, node);
}

/**
 * Post-walker: link all nodes that probably access the stack into lists of their block.
 */
static void link_ops_in_block_walker(ir_node *node, void *data)
{
        (void) data;

        switch (get_irn_opcode(node)) {
        case iro_Return:
        case iro_Call:
                collect_node(node);
                break;
        case iro_Alloc:
                /** all non-stack alloc nodes should be lowered before the backend */
                assert(get_Alloc_where(node) == stack_alloc);
                collect_node(node);
                break;
        case iro_Free:
                assert(get_Free_where(node) == stack_alloc);
                collect_node(node);
                break;
        case iro_Builtin:
                if (get_Builtin_kind(node) == ir_bk_return_address) {
                        ir_node   *param = get_Builtin_param(node, 0);
                        ir_tarval *tv    = get_Const_tarval(param); /* must be Const */
                        long       value = get_tarval_long(tv);
                        if (value > 0) {
                                /* not the return address of the current function:
                                 * we need the stack pointer for the frame climbing */
                                collect_node(node);
                        }
                }
                break;
        default:
                break;
        }
}

static ir_heights_t *heights;

/**
 * Check if a node is somehow data dependent on another one.
 * both nodes must be in the same basic block.
 * @param n1 The first node.
 * @param n2 The second node.
 * @return 1, if n1 is data dependent (transitively) on n2, 0 if not.
 */
static int dependent_on(const ir_node *n1, const ir_node *n2)
{
        assert(get_nodes_block(n1) == get_nodes_block(n2));

        return heights_reachable_in_block(heights, n1, n2);
}

/**
 * Classical qsort() comparison function behavior:
 *
 * 0  if both elements are equal, no node depend on the other
 * +1 if first depends on second (first is greater)
 * -1 if second depends on first (second is greater)
*/
static int cmp_call_dependency(const void *c1, const void *c2)
{
        const ir_node *n1 = *(const ir_node **) c1;
        const ir_node *n2 = *(const ir_node **) c2;
        unsigned h1, h2;

        if (dependent_on(n1, n2))
                return 1;

        if (dependent_on(n2, n1))
                return -1;

        /* The nodes have no depth order, but we need a total order because qsort()
         * is not stable.
         *
         * Additionally, we need to respect transitive dependencies. Consider a
         * Call a depending on Call b and an independent Call c.
         * We MUST NOT order c > a and b > c. */
        h1 = get_irn_height(heights, n1);
        h2 = get_irn_height(heights, n2);
        if (h1 < h2) return  1;
        if (h1 > h2) return -1;
        /* Same height, so use a random (but stable) order */
        return get_irn_idx(n2) - get_irn_idx(n1);
}

/**
 * Block-walker: sorts dependencies and remember them into a phase
 */
static void process_ops_in_block(ir_node *block, void *data)
{
        ir_nodemap *map = (ir_nodemap*)data;
        unsigned    n;
        unsigned    n_nodes;
        ir_node    *node;
        ir_node   **nodes;

        n_nodes = 0;
        for (node = (ir_node*)get_irn_link(block); node != NULL;
             node = (ir_node*)get_irn_link(node)) {
                ++n_nodes;
        }

        if (n_nodes == 0)
                return;

        nodes = XMALLOCN(ir_node*, n_nodes);
        n = 0;
        for (node = (ir_node*)get_irn_link(block); node != NULL;
             node = (ir_node*)get_irn_link(node)) {
                nodes[n++] = node;
        }
        assert(n == n_nodes);

        /* order nodes according to their data dependencies */
        qsort(nodes, n_nodes, sizeof(nodes[0]), cmp_call_dependency);

        /* remember the calculated dependency into a phase */
        for (n = n_nodes-1; n > 0; --n) {
                ir_node *node = nodes[n];
                ir_node *pred = nodes[n-1];

                ir_nodemap_insert(map, node, pred);
        }
        xfree(nodes);
}



struct be_stackorder_t {
        ir_nodemap stack_order; /**< a phase to handle stack dependencies. */
};

be_stackorder_t *be_collect_stacknodes(ir_graph *irg)
{
        be_stackorder_t *env = XMALLOCZ(be_stackorder_t);

        ir_reserve_resources(irg, IR_RESOURCE_IRN_LINK);

        /* collect all potential^stack accessing nodes */
        irg_walk_graph(irg, firm_clear_link, link_ops_in_block_walker, NULL);

        ir_nodemap_init(&env->stack_order, irg);

        /* use heights to create a total order for those nodes: this order is stored
         * in the created phase */
        heights = heights_new(irg);
        irg_block_walk_graph(irg, NULL, process_ops_in_block, &env->stack_order);
        heights_free(heights);

        ir_free_resources(irg, IR_RESOURCE_IRN_LINK);

        return env;
}

ir_node *be_get_stack_pred(const be_stackorder_t *env, const ir_node *node)
{
        return ir_nodemap_get(ir_node, &env->stack_order, node);
}

void be_free_stackorder(be_stackorder_t *env)
{
        ir_nodemap_destroy(&env->stack_order);
        free(env);
}

static void create_stores_for_type(ir_graph *irg, ir_type *type)
{
        size_t   n           = get_compound_n_members(type);
        ir_node *frame       = get_irg_frame(irg);
        ir_node *initial_mem = get_irg_initial_mem(irg);
        ir_node *mem         = initial_mem;
        ir_node *first_store = NULL;
        ir_node *start_block = get_irg_start_block(irg);
        ir_node *args        = get_irg_args(irg);
        size_t   i;

        /* all parameter entities left in the frame type require stores.
         * (The ones passed on the stack have been moved to the arg type) */
        for (i = 0; i < n; ++i) {
                ir_entity *entity = get_compound_member(type, i);
                ir_node   *addr;
                size_t     arg;
                if (!is_parameter_entity(entity))
                        continue;

                arg = get_entity_parameter_number(entity);
                if (arg == IR_VA_START_PARAMETER_NUMBER)
                        continue;

                addr = new_r_Sel(start_block, mem, frame, 0, NULL, entity);
                if (entity->attr.parameter.doubleword_low_mode != NULL) {
                        ir_mode *mode      = entity->attr.parameter.doubleword_low_mode;
                        ir_node *val0      = new_r_Proj(args, mode, arg);
                        ir_node *val1      = new_r_Proj(args, mode, arg+1);
                        ir_node *store0    = new_r_Store(start_block, mem, addr, val0,
                                                         cons_none);
                        ir_node *mem0      = new_r_Proj(store0, mode_M, pn_Store_M);
                        size_t   offset    = get_mode_size_bits(mode)/8;
                        ir_mode *addr_mode = get_irn_mode(addr);
                        ir_node *cnst      = new_r_Const_long(irg, addr_mode, offset);
                        ir_node *next_addr = new_r_Add(start_block, addr, cnst, addr_mode);
                        ir_node *store1    = new_r_Store(start_block, mem0, next_addr, val1,
                                                         cons_none);
                        mem = new_r_Proj(store1, mode_M, pn_Store_M);
                        if (first_store == NULL)
                                first_store = store0;
                } else {
                        ir_type *tp    = get_entity_type(entity);
                        ir_mode *mode  = is_compound_type(tp) ? mode_P : get_type_mode(tp);
                        ir_node *val   = new_r_Proj(args, mode, arg);
                        ir_node *store = new_r_Store(start_block, mem, addr, val, cons_none);
                        mem = new_r_Proj(store, mode_M, pn_Store_M);
                        if (first_store == NULL)
                                first_store = store;
                }
        }

        if (mem != initial_mem) {
                edges_reroute(initial_mem, mem);
                set_Store_mem(first_store, initial_mem);
        }
}

void be_add_parameter_entity_stores(ir_graph *irg)
{
        ir_type           *frame_type   = get_irg_frame_type(irg);
        be_stack_layout_t *layout       = be_get_irg_stack_layout(irg);
        ir_type           *between_type = layout->between_type;

        create_stores_for_type(irg, frame_type);
        if (between_type != NULL) {
                create_stores_for_type(irg, between_type);
        }
}