be: Simplify places, which still assumed, that Projs are scheduled.

[libfirm] / ir / be / bemain.c

/*
 * Copyright (C) 1995-2011 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       Main Backend driver.
 * @author      Sebastian Hack
 * @date        25.11.2004
 */
#include "config.h"

#include <stdarg.h>
#include <stdio.h>

#include "lc_opts.h"
#include "lc_opts_enum.h"

#include "obst.h"
#include "bitset.h"
#include "statev.h"
#include "irprog.h"
#include "irgopt.h"
#include "irgraph.h"
#include "irdump.h"
#include "irdom_t.h"
#include "iredges_t.h"
#include "irloop_t.h"
#include "irtools.h"
#include "irverify.h"
#include "irprintf.h"
#include "iroptimize.h"
#include "firmstat.h"
#include "execfreq_t.h"
#include "irprofile.h"
#include "irpass_t.h"
#include "ircons.h"

#include "bearch.h"
#include "be_t.h"
#include "bemodule.h"
#include "beutil.h"
#include "benode.h"
#include "beirgmod.h"
#include "besched.h"
#include "belistsched.h"
#include "belive_t.h"
#include "bera.h"
#include "bechordal_t.h"
#include "beifg.h"
#include "becopyopt.h"
#include "becopystat.h"
#include "bessadestr.h"
#include "beabi.h"
#include "belower.h"
#include "bestat.h"
#include "beverify.h"
#include "beirg.h"
#include "bestack.h"
#include "beemitter.h"

#define NEW_ID(s) new_id_from_chars(s, sizeof(s) - 1)

/* options visible for anyone */
be_options_t be_options = {
        DUMP_NONE,                         /* dump flags */
        BE_TIME_OFF,                       /* no timing */
        false,                             /* profile_generate */
        false,                             /* profile_use */
        0,                                 /* try to omit frame pointer */
        0,                                 /* create PIC code */
        BE_VERIFY_WARN,                    /* verification level: warn */
        "",                                /* ilp server */
        "",                                /* ilp solver */
        0,                                 /* enable statistic event dumping */
        "",                                /* print stat events */
        1,                                 /* verbose assembler output */
};

/* back end instruction set architecture to use */
static const arch_isa_if_t *isa_if = NULL;

/* possible dumping options */
static const lc_opt_enum_mask_items_t dump_items[] = {
        { "none",       DUMP_NONE },
        { "initial",    DUMP_INITIAL },
        { "abi",        DUMP_ABI    },
        { "sched",      DUMP_SCHED  },
        { "prepared",   DUMP_PREPARED },
        { "regalloc",   DUMP_RA },
        { "final",      DUMP_FINAL },
        { "be",         DUMP_BE },
        { "all",        2 * DUMP_BE - 1 },
        { NULL,         0 }
};

/* verify options. */
static const lc_opt_enum_int_items_t verify_items[] = {
        { "off",    BE_VERIFY_OFF    },
        { "warn",   BE_VERIFY_WARN   },
        { "assert", BE_VERIFY_ASSERT },
        { NULL,     0 }
};

static lc_opt_enum_mask_var_t dump_var = {
        &be_options.dump_flags, dump_items
};

static lc_opt_enum_int_var_t verify_var = {
        &be_options.verify_option, verify_items
};

static const lc_opt_table_entry_t be_main_options[] = {
        LC_OPT_ENT_ENUM_MASK("dump",       "dump irg on several occasions",                       &dump_var),
        LC_OPT_ENT_BOOL     ("omitfp",     "omit frame pointer",                                  &be_options.omit_fp),
        LC_OPT_ENT_BOOL     ("pic",        "create PIC code",                                     &be_options.pic),
        LC_OPT_ENT_ENUM_INT ("verify",     "verify the backend irg",                              &verify_var),
        LC_OPT_ENT_BOOL     ("time",       "get backend timing statistics",                       &be_options.timing),
        LC_OPT_ENT_BOOL     ("profilegenerate", "instrument the code for execution count profiling",   &be_options.opt_profile_generate),
        LC_OPT_ENT_BOOL     ("profileuse",      "use existing profile data",                           &be_options.opt_profile_use),
        LC_OPT_ENT_BOOL     ("statev",     "dump statistic events",                               &be_options.statev),
        LC_OPT_ENT_STR      ("filtev",     "filter for stat events (regex if support is active",   be_options.filtev),
        LC_OPT_ENT_BOOL     ("verboseasm", "enable verbose assembler output",                     &be_options.verbose_asm),

        LC_OPT_ENT_STR("ilp.server", "the ilp server name", be_options.ilp_server),
        LC_OPT_ENT_STR("ilp.solver", "the ilp solver name", be_options.ilp_solver),
        LC_OPT_LAST
};

static be_module_list_entry_t *isa_ifs         = NULL;
static bool                    isa_initialized = false;

asm_constraint_flags_t asm_constraint_flags[256];

static void initialize_isa(void)
{
        if (isa_initialized)
                return;
        isa_if->init();
        isa_initialized = true;
}

static void finish_isa(void)
{
        if (isa_initialized) {
                isa_if->finish();
                isa_initialized = false;
        }
}

void be_init_default_asm_constraint_flags(void)
{
        asm_constraint_flags['?'] = ASM_CONSTRAINT_FLAG_NO_SUPPORT;
        asm_constraint_flags['!'] = ASM_CONSTRAINT_FLAG_NO_SUPPORT;
        asm_constraint_flags['&'] = ASM_CONSTRAINT_FLAG_NO_SUPPORT
                | ASM_CONSTRAINT_FLAG_MODIFIER_EARLYCLOBBER;
        asm_constraint_flags['%'] = ASM_CONSTRAINT_FLAG_NO_SUPPORT
                | ASM_CONSTRAINT_FLAG_MODIFIER_COMMUTATIVE;
        asm_constraint_flags['!'] = ASM_CONSTRAINT_FLAG_NO_SUPPORT;

        asm_constraint_flags['='] = ASM_CONSTRAINT_FLAG_MODIFIER_WRITE
                | ASM_CONSTRAINT_FLAG_MODIFIER_NO_READ;
        asm_constraint_flags['+'] = ASM_CONSTRAINT_FLAG_MODIFIER_READ
                | ASM_CONSTRAINT_FLAG_MODIFIER_WRITE;

        asm_constraint_flags['i'] = ASM_CONSTRAINT_FLAG_SUPPORTS_IMMEDIATE;
        asm_constraint_flags['s'] = ASM_CONSTRAINT_FLAG_SUPPORTS_IMMEDIATE;
        asm_constraint_flags['E'] = ASM_CONSTRAINT_FLAG_SUPPORTS_IMMEDIATE;
        asm_constraint_flags['F'] = ASM_CONSTRAINT_FLAG_SUPPORTS_IMMEDIATE;
        asm_constraint_flags['G'] = ASM_CONSTRAINT_FLAG_SUPPORTS_IMMEDIATE;
        asm_constraint_flags['H'] = ASM_CONSTRAINT_FLAG_SUPPORTS_IMMEDIATE;
        asm_constraint_flags['I'] = ASM_CONSTRAINT_FLAG_SUPPORTS_IMMEDIATE;
        asm_constraint_flags['J'] = ASM_CONSTRAINT_FLAG_SUPPORTS_IMMEDIATE;
        asm_constraint_flags['K'] = ASM_CONSTRAINT_FLAG_SUPPORTS_IMMEDIATE;
        asm_constraint_flags['L'] = ASM_CONSTRAINT_FLAG_SUPPORTS_IMMEDIATE;
        asm_constraint_flags['M'] = ASM_CONSTRAINT_FLAG_SUPPORTS_IMMEDIATE;
        asm_constraint_flags['N'] = ASM_CONSTRAINT_FLAG_SUPPORTS_IMMEDIATE;
        asm_constraint_flags['O'] = ASM_CONSTRAINT_FLAG_SUPPORTS_IMMEDIATE;
        asm_constraint_flags['P'] = ASM_CONSTRAINT_FLAG_SUPPORTS_IMMEDIATE;

        asm_constraint_flags['m'] = ASM_CONSTRAINT_FLAG_SUPPORTS_MEMOP;
        asm_constraint_flags['o'] = ASM_CONSTRAINT_FLAG_SUPPORTS_MEMOP;
        asm_constraint_flags['V'] = ASM_CONSTRAINT_FLAG_SUPPORTS_MEMOP;
        asm_constraint_flags['<'] = ASM_CONSTRAINT_FLAG_SUPPORTS_MEMOP;
        asm_constraint_flags['>'] = ASM_CONSTRAINT_FLAG_SUPPORTS_MEMOP;

        asm_constraint_flags['p'] = ASM_CONSTRAINT_FLAG_SUPPORTS_REGISTER;
        asm_constraint_flags['0'] = ASM_CONSTRAINT_FLAG_SUPPORTS_REGISTER;
        asm_constraint_flags['1'] = ASM_CONSTRAINT_FLAG_SUPPORTS_REGISTER;
        asm_constraint_flags['2'] = ASM_CONSTRAINT_FLAG_SUPPORTS_REGISTER;
        asm_constraint_flags['3'] = ASM_CONSTRAINT_FLAG_SUPPORTS_REGISTER;
        asm_constraint_flags['4'] = ASM_CONSTRAINT_FLAG_SUPPORTS_REGISTER;
        asm_constraint_flags['5'] = ASM_CONSTRAINT_FLAG_SUPPORTS_REGISTER;
        asm_constraint_flags['6'] = ASM_CONSTRAINT_FLAG_SUPPORTS_REGISTER;
        asm_constraint_flags['7'] = ASM_CONSTRAINT_FLAG_SUPPORTS_REGISTER;
        asm_constraint_flags['8'] = ASM_CONSTRAINT_FLAG_SUPPORTS_REGISTER;
        asm_constraint_flags['9'] = ASM_CONSTRAINT_FLAG_SUPPORTS_REGISTER;

        asm_constraint_flags['X'] = ASM_CONSTRAINT_FLAG_SUPPORTS_REGISTER
                | ASM_CONSTRAINT_FLAG_SUPPORTS_MEMOP
                | ASM_CONSTRAINT_FLAG_SUPPORTS_IMMEDIATE;

        /* these should have been catched by the parsing code already */
        asm_constraint_flags['#']  = ASM_CONSTRAINT_FLAG_NO_SUPPORT;
        asm_constraint_flags['*']  = ASM_CONSTRAINT_FLAG_NO_SUPPORT;
        asm_constraint_flags[' ']  = ASM_CONSTRAINT_FLAG_NO_SUPPORT;
        asm_constraint_flags['\t'] = ASM_CONSTRAINT_FLAG_NO_SUPPORT;
        asm_constraint_flags['\n'] = ASM_CONSTRAINT_FLAG_NO_SUPPORT;
        asm_constraint_flags['\r'] = ASM_CONSTRAINT_FLAG_NO_SUPPORT;
}

asm_constraint_flags_t be_parse_asm_constraints(const char *constraint)
{
        asm_constraint_flags_t  flags = ASM_CONSTRAINT_FLAG_NONE;
        const char             *c;
        asm_constraint_flags_t  tflags;

        initialize_isa();

        for (c = constraint; *c != '\0'; ++c) {
                switch (*c) {
                case '#':
                        /* 'comment' stuff */
                        while (*c != 0 && *c != ',')
                                ++c;
                        break;
                case '*':
                        /* 'comment' character */
                        ++c;
                        break;
                case ' ':
                case '\t':
                case '\n':
                case '\r':
                        break;
                default:
                        tflags = asm_constraint_flags[(int) *c];
                        if (tflags != 0) {
                                flags |= tflags;
                        } else {
                                flags |= isa_if->parse_asm_constraint(&c);
                        }
                        break;
                }
        }

        if ((
                flags & ASM_CONSTRAINT_FLAG_MODIFIER_WRITE &&
                flags & ASM_CONSTRAINT_FLAG_MODIFIER_NO_WRITE
            ) || (
                flags & ASM_CONSTRAINT_FLAG_MODIFIER_READ &&
                flags & ASM_CONSTRAINT_FLAG_MODIFIER_NO_READ
            )) {
                flags |= ASM_CONSTRAINT_FLAG_INVALID;
        }
        if (!(flags & (ASM_CONSTRAINT_FLAG_MODIFIER_READ     |
                       ASM_CONSTRAINT_FLAG_MODIFIER_WRITE    |
                       ASM_CONSTRAINT_FLAG_MODIFIER_NO_WRITE |
                       ASM_CONSTRAINT_FLAG_MODIFIER_NO_READ)
            )) {
                flags |= ASM_CONSTRAINT_FLAG_MODIFIER_READ;
        }

        return flags;
}

int be_is_valid_clobber(const char *clobber)
{
        initialize_isa();

        /* memory is a valid clobber. (the frontend has to detect this case too,
         * because it has to add memory edges to the asm) */
        if (strcmp(clobber, "memory") == 0)
                return 1;
        /* cc (condition code) is always valid */
        if (strcmp(clobber, "cc") == 0)
                return 1;

        return isa_if->is_valid_clobber(clobber);
}

void be_register_isa_if(const char *name, const arch_isa_if_t *isa)
{
        if (isa_if == NULL)
                isa_if = isa;

        be_add_module_to_list(&isa_ifs, name, (void*) isa);
}

static void be_opt_register(void)
{
        lc_opt_entry_t *be_grp;
        static int run_once = 0;

        if (run_once)
                return;
        run_once = 1;

        be_grp = lc_opt_get_grp(firm_opt_get_root(), "be");
        lc_opt_add_table(be_grp, be_main_options);

        be_add_module_list_opt(be_grp, "isa", "the instruction set architecture",
                               &isa_ifs, (void**) &isa_if);

        be_init_modules();
}

/* Parse one argument. */
int be_parse_arg(const char *arg)
{
        lc_opt_entry_t *be_grp = lc_opt_get_grp(firm_opt_get_root(), "be");
        if (strcmp(arg, "help") == 0 || (arg[0] == '?' && arg[1] == '\0')) {
                lc_opt_print_help_for_entry(be_grp, '-', stdout);
                return -1;
        }
        return lc_opt_from_single_arg(be_grp, NULL, arg, NULL);
}

/* Perform schedule verification if requested. */
static void be_sched_verify(ir_graph *irg, int verify_opt)
{
        if (verify_opt == BE_VERIFY_WARN) {
                be_verify_schedule(irg);
        } else if (verify_opt == BE_VERIFY_ASSERT) {
                assert(be_verify_schedule(irg) && "Schedule verification failed.");
        }
}

/* Initialize the Firm backend. Must be run first in init_firm()! */
void firm_be_init(void)
{
        be_opt_register();
        be_init_modules();
}

/* Finalize the Firm backend. */
void firm_be_finish(void)
{
        finish_isa();
        be_quit_modules();
}

/* Returns the backend parameter */
const backend_params *be_get_backend_param(void)
{
        initialize_isa();
        return isa_if->get_params();
}

int be_is_big_endian(void)
{
        return be_get_backend_param()->byte_order_big_endian;
}

unsigned be_get_machine_size(void)
{
        return be_get_backend_param()->machine_size;
}

ir_mode *be_get_mode_float_arithmetic(void)
{
        return be_get_backend_param()->mode_float_arithmetic;
}

ir_type *be_get_type_long_long(void)
{
        return be_get_backend_param()->type_long_long;
}

ir_type *be_get_type_unsigned_long_long(void)
{
        return be_get_backend_param()->type_unsigned_long_long;
}

ir_type *be_get_type_long_double(void)
{
        return be_get_backend_param()->type_long_double;
}

/**
 * Initializes the main environment for the backend.
 *
 * @param env          an empty environment
 * @param file_handle  the file handle where the output will be written to
 */
static be_main_env_t *be_init_env(be_main_env_t *env, FILE *file_handle,
                                  const char *compilation_unit_name)
{
        memset(env, 0, sizeof(*env));
        env->file_handle          = file_handle;
        env->ent_trampoline_map   = pmap_create();
        env->pic_trampolines_type = new_type_class(NEW_ID("$PIC_TRAMPOLINE_TYPE"));
        env->ent_pic_symbol_map   = pmap_create();
        env->pic_symbols_type     = new_type_struct(NEW_ID("$PIC_SYMBOLS_TYPE"));
        env->cup_name             = compilation_unit_name;

        set_class_final(env->pic_trampolines_type, 1);

        memset(asm_constraint_flags, 0, sizeof(asm_constraint_flags));
        env->arch_env = arch_env_begin_codegeneration(isa_if, env);

        return env;
}

/**
 * Called when the be_main_env_t can be destroyed.
 */
static void be_done_env(be_main_env_t *env)
{
        pmap_destroy(env->ent_trampoline_map);
        pmap_destroy(env->ent_pic_symbol_map);
        free_type(env->pic_trampolines_type);
        free_type(env->pic_symbols_type);
}

/**
 * A wrapper around a firm dumper. Dumps only, if
 * flags are enabled.
 *
 * @param mask    a bitmask containing the reason what will be dumped
 * @param irg     the IR graph to dump
 * @param suffix  the suffix for the dumper
 * @param dumper  the dumper to be called
 */
static void dump(int mask, ir_graph *irg, const char *suffix)
{
        if (be_options.dump_flags & mask)
                dump_ir_graph(irg, suffix);
}

/**
 * Prepare a backend graph for code generation and initialize its irg
 */
static void initialize_birg(be_irg_t *birg, ir_graph *irg, be_main_env_t *env)
{
        /* don't duplicate locals in backend when dumping... */
        ir_remove_dump_flags(ir_dump_flag_consts_local);

        dump(DUMP_INITIAL, irg, "begin");

        irg->be_data = birg;

        memset(birg, 0, sizeof(*birg));
        birg->main_env = env;
        obstack_init(&birg->obst);
        birg->lv = be_liveness_new(irg);

        edges_deactivate(irg);
        edges_activate(irg);

        /* set the current graph (this is important for several firm functions) */
        current_ir_graph = irg;

        /* we do this before critical edge split. As this produces less returns,
           because sometimes (= 164.gzip) multiple returns are slower */
        normalize_n_returns(irg);

        /* Remove critical edges */
        remove_critical_cf_edges_ex(irg, /*ignore_exception_edges=*/0);

        /* For code generation all unreachable code and Bad nodes should be gone */
        remove_unreachable_code(irg);
        remove_bads(irg);

        /* Ensure, that the ir_edges are computed. */
        assure_edges(irg);

        be_info_init_irg(irg);

        dump(DUMP_INITIAL, irg, "prepared");
}

int be_timing;

static const char *get_timer_name(be_timer_id_t id)
{
        switch (id) {
        case T_ABI:            return "abi";
        case T_CODEGEN:        return "codegen";
        case T_RA_PREPARATION: return "ra_preparation";
        case T_SCHED:          return "sched";
        case T_CONSTR:         return "constr";
        case T_FINISH:         return "finish";
        case T_EMIT:           return "emit";
        case T_VERIFY:         return "verify";
        case T_OTHER:          return "other";
        case T_HEIGHTS:        return "heights";
        case T_LIVE:           return "live";
        case T_EXECFREQ:       return "execfreq";
        case T_SSA_CONSTR:     return "ssa_constr";
        case T_RA_EPILOG:      return "ra_epilog";
        case T_RA_CONSTR:      return "ra_constr";
        case T_RA_SPILL:       return "ra_spill";
        case T_RA_SPILL_APPLY: return "ra_spill_apply";
        case T_RA_COLOR:       return "ra_color";
        case T_RA_IFG:         return "ra_ifg";
        case T_RA_COPYMIN:     return "ra_copymin";
        case T_RA_SSA:         return "ra_ssa";
        case T_RA_OTHER:       return "ra_other";
        }
        return "unknown";
}
ir_timer_t *be_timers[T_LAST+1];

void be_lower_for_target(void)
{
        size_t i;

        initialize_isa();

        isa_if->lower_for_target();
        /* set the phase to low */
        for (i = get_irp_n_irgs(); i > 0;) {
                ir_graph *irg = get_irp_irg(--i);
                assert(!irg_is_constrained(irg, IR_GRAPH_CONSTRAINT_TARGET_LOWERED));
                add_irg_constraints(irg, IR_GRAPH_CONSTRAINT_TARGET_LOWERED);
        }
}

/**
 * The Firm backend main loop.
 * Do architecture specific lowering for all graphs
 * and call the architecture specific code generator.
 *
 * @param file_handle   the file handle the output will be written to
 * @param cup_name      name of the compilation unit
 */
static void be_main_loop(FILE *file_handle, const char *cup_name)
{
        static const char suffix[] = ".prof";

        size_t        i;
        size_t        num_irgs;
        size_t        num_birgs;
        be_main_env_t env;
        char          prof_filename[256];
        be_irg_t      *birgs;
        arch_env_t    *arch_env;

        be_timing = (be_options.timing == BE_TIME_ON);

        /* perform target lowering if it didn't happen yet */
        if (get_irp_n_irgs() > 0 && !irg_is_constrained(get_irp_irg(0), IR_GRAPH_CONSTRAINT_TARGET_LOWERED))
                be_lower_for_target();

        if (be_timing) {
                for (i = 0; i < T_LAST+1; ++i) {
                        be_timers[i] = ir_timer_new();
                }
        }

        be_init_env(&env, file_handle, cup_name);

        arch_env = env.arch_env;

        /* we might need 1 birg more for instrumentation constructor */
        num_irgs = get_irp_n_irgs();
        birgs    = ALLOCAN(be_irg_t, num_irgs + 1);

        be_info_init();

        /* First: initialize all birgs */
        num_birgs = 0;
        for (i = 0; i < num_irgs; ++i) {
                ir_graph  *irg    = get_irp_irg(i);
                ir_entity *entity = get_irg_entity(irg);
                if (get_entity_linkage(entity) & IR_LINKAGE_NO_CODEGEN)
                        continue;
                initialize_birg(&birgs[num_birgs++], irg, &env);
        }
        arch_env_handle_intrinsics(arch_env);

        /*
                Get the filename for the profiling data.
                Beware: '\0' is already included in sizeof(suffix)
        */
        sprintf(prof_filename, "%.*s%s",
                (int)(sizeof(prof_filename) - sizeof(suffix)), cup_name, suffix);

        bool have_profile = false;
        if (be_options.opt_profile_use) {
                bool res = ir_profile_read(prof_filename);
                if (!res) {
                        fprintf(stderr, "Warning: Couldn't read profile data '%s'\n",
                                prof_filename);
                } else {
                        ir_create_execfreqs_from_profile();
                        ir_profile_free();
                        have_profile = true;
                }
        }

        if (num_birgs > 0 && be_options.opt_profile_generate) {
                ir_graph *const prof_init_irg = ir_profile_instrument(prof_filename);
                assert(prof_init_irg->be_data == NULL);
                initialize_birg(&birgs[num_birgs], prof_init_irg, &env);
                num_birgs++;
                num_irgs++;
                assert(num_irgs == get_irp_n_irgs());
        }

        for (be_timer_id_t t = T_FIRST; t < T_LAST+1; ++t) {
                ir_timer_init_parent(be_timers[t]);
        }
        if (!have_profile) {
                be_timer_push(T_EXECFREQ);
                for (i = 0; i < num_irgs; ++i) {
                        ir_graph *irg = get_irp_irg(i);
                        ir_estimate_execfreq(irg);
                }
                be_timer_pop(T_EXECFREQ);
        }

        /* For all graphs */
        for (i = 0; i < num_irgs; ++i) {
                ir_graph  *const irg    = get_irp_irg(i);
                ir_entity *const entity = get_irg_entity(irg);
                if (get_entity_linkage(entity) & IR_LINKAGE_NO_CODEGEN)
                        continue;

                /* set the current graph (this is important for several firm functions) */
                current_ir_graph = irg;

                if (stat_ev_enabled) {
                        stat_ev_ctx_push_fmt("bemain_irg", "%+F", irg);
                        stat_ev_ull("bemain_insns_start", be_count_insns(irg));
                        stat_ev_ull("bemain_blocks_start", be_count_blocks(irg));
                }

                /* stop and reset timers */
                be_timer_push(T_OTHER);

                /* Verify the initial graph */
                be_timer_push(T_VERIFY);
                if (be_options.verify_option == BE_VERIFY_WARN) {
                        irg_verify(irg, VERIFY_ENFORCE_SSA);
                } else if (be_options.verify_option == BE_VERIFY_ASSERT) {
                        assert(irg_verify(irg, VERIFY_ENFORCE_SSA) && "irg verification failed");
                }
                be_timer_pop(T_VERIFY);

                /* get a code generator for this graph. */
                if (arch_env->impl->init_graph)
                        arch_env->impl->init_graph(irg);

                /* some transformations need to be done before abi introduce */
                if (arch_env->impl->before_abi != NULL)
                        arch_env->impl->before_abi(irg);

                /* implement the ABI conventions. */
                if (!arch_env->custom_abi) {
                        be_timer_push(T_ABI);
                        be_abi_introduce(irg);
                        be_timer_pop(T_ABI);
                        dump(DUMP_ABI, irg, "abi");
                }

                /* We can't have Bad-blocks or critical edges in the backend.
                 * Before removing Bads, we remove unreachable code. */
                optimize_graph_df(irg);
                remove_critical_cf_edges(irg);
                remove_bads(irg);

                /* We often have dead code reachable through out-edges here. So for
                 * now we rebuild edges (as we need correct user count for code
                 * selection) */
                edges_deactivate(irg);
                edges_activate(irg);

                dump(DUMP_PREPARED, irg, "before-code-selection");

                /* perform codeselection */
                be_timer_push(T_CODEGEN);
                if (arch_env->impl->prepare_graph != NULL)
                        arch_env->impl->prepare_graph(irg);
                be_timer_pop(T_CODEGEN);

                dump(DUMP_PREPARED, irg, "code-selection");

                /* disabled for now, fails for EmptyFor.c and XXEndless.c */
                /* be_live_chk_compare(irg); */

                /* schedule the irg */
                be_timer_push(T_SCHED);
                be_schedule_graph(irg);
                be_timer_pop(T_SCHED);

                dump(DUMP_SCHED, irg, "sched");

                /* check schedule */
                be_timer_push(T_VERIFY);
                be_sched_verify(irg, be_options.verify_option);
                be_timer_pop(T_VERIFY);

                /* introduce patterns to assure constraints */
                be_timer_push(T_CONSTR);
                /* we switch off optimizations here, because they might cause trouble */
                optimization_state_t state;
                save_optimization_state(&state);
                set_optimize(0);
                set_opt_cse(0);

                /* add Keeps for should_be_different constrained nodes  */
                /* beware: needs schedule due to usage of be_ssa_constr */
                assure_constraints(irg);
                be_timer_pop(T_CONSTR);

                dump(DUMP_SCHED, irg, "assured");

                /* stuff needs to be done after scheduling but before register allocation */
                be_timer_push(T_RA_PREPARATION);
                if (arch_env->impl->before_ra != NULL)
                        arch_env->impl->before_ra(irg);
                be_timer_pop(T_RA_PREPARATION);

                /* connect all stack modifying nodes together (see beabi.c) */
                be_timer_push(T_ABI);
                be_abi_fix_stack_nodes(irg);
                be_timer_pop(T_ABI);

                dump(DUMP_SCHED, irg, "fix_stack");

                /* check schedule */
                be_timer_push(T_VERIFY);
                be_sched_verify(irg, be_options.verify_option);
                be_timer_pop(T_VERIFY);

                if (stat_ev_enabled) {
                        stat_ev_dbl("bemain_costs_before_ra", be_estimate_irg_costs(irg));
                        stat_ev_ull("bemain_insns_before_ra", be_count_insns(irg));
                        stat_ev_ull("bemain_blocks_before_ra", be_count_blocks(irg));
                }

                /* Do register allocation */
                be_allocate_registers(irg);

                stat_ev_dbl("bemain_costs_before_ra", be_estimate_irg_costs(irg));

                dump(DUMP_RA, irg, "ra");

                be_timer_push(T_FINISH);
                if (arch_env->impl->finish_graph != NULL)
                        arch_env->impl->finish_graph(irg);
                be_timer_pop(T_FINISH);

                dump(DUMP_FINAL, irg, "finish");

                if (stat_ev_enabled) {
                        stat_ev_ull("bemain_insns_finish", be_count_insns(irg));
                        stat_ev_ull("bemain_blocks_finish", be_count_blocks(irg));
                }

                /* check schedule and register allocation */
                be_timer_push(T_VERIFY);
                if (be_options.verify_option == BE_VERIFY_WARN) {
                        irg_verify(irg, VERIFY_ENFORCE_SSA);
                        be_verify_schedule(irg);
                        be_verify_register_allocation(irg);
                } else if (be_options.verify_option == BE_VERIFY_ASSERT) {
                        assert(irg_verify(irg, VERIFY_ENFORCE_SSA) && "irg verification failed");
                        assert(be_verify_schedule(irg) && "Schedule verification failed");
                        assert(be_verify_register_allocation(irg)
                               && "register allocation verification failed");

                }
                be_timer_pop(T_VERIFY);

                /* emit assembler code */
                be_timer_push(T_EMIT);
                if (arch_env->impl->emit != NULL)
                        arch_env->impl->emit(irg);
                be_timer_pop(T_EMIT);

                dump(DUMP_FINAL, irg, "end");

                restore_optimization_state(&state);

                be_timer_pop(T_OTHER);

                if (be_timing) {
                        be_timer_id_t t;
                        if (stat_ev_enabled) {
                                for (t = T_FIRST; t < T_LAST+1; ++t) {
                                        char buf[128];
                                        snprintf(buf, sizeof(buf), "bemain_time_%s",
                                                 get_timer_name(t));
                                        stat_ev_dbl(buf, ir_timer_elapsed_usec(be_timers[i]));
                                }
                        } else {
                                printf("==>> IRG %s <<==\n",
                                       get_entity_name(get_irg_entity(irg)));
                                for (t = T_FIRST; t < T_LAST+1; ++t) {
                                        double val = ir_timer_elapsed_usec(be_timers[t]) / 1000.0;
                                        printf("%-20s: %10.3f msec\n", get_timer_name(t), val);
                                }
                        }
                        for (t = T_FIRST; t < T_LAST+1; ++t) {
                                ir_timer_reset(be_timers[t]);
                        }
                }

                be_free_birg(irg);
                stat_ev_ctx_pop("bemain_irg");
        }

        arch_env_end_codegeneration(arch_env);

        be_done_env(&env);

        be_info_free();
}

/* Main interface to the frontend. */
void be_main(FILE *file_handle, const char *cup_name)
{
        ir_timer_t *t = NULL;

        if (be_options.timing == BE_TIME_ON) {
                t = ir_timer_new();

                if (ir_timer_enter_high_priority()) {
                        fprintf(stderr, "Warning: Could not enter high priority mode.\n");
                }

                ir_timer_reset_and_start(t);
        }

        if (be_options.statev) {
                const char *dot = strrchr(cup_name, '.');
                const char *pos = dot ? dot : cup_name + strlen(cup_name);
                char       *buf = ALLOCAN(char, pos - cup_name + 1);
                strncpy(buf, cup_name, pos - cup_name);
                buf[pos - cup_name] = '\0';

                be_options.statev = 1;
                stat_ev_begin(buf, be_options.filtev);
                stat_ev_ctx_push_str("bemain_compilation_unit", cup_name);
        }

        be_main_loop(file_handle, cup_name);

        if (be_options.timing == BE_TIME_ON) {
                ir_timer_stop(t);
                ir_timer_leave_high_priority();
                if (stat_ev_enabled) {
                        stat_ev_dbl("bemain_backend_time", ir_timer_elapsed_msec(t));
                } else {
                        double val = ir_timer_elapsed_usec(t) / 1000.0;
                        printf("%-20s: %10.3f msec\n", "BEMAINLOOP", val);
                }
        }

        if (be_options.statev) {
                stat_ev_ctx_pop("bemain_compilation_unit");
                stat_ev_end();
        }
}

static int do_lower_for_target(ir_prog *irp, void *context)
{
        be_lower_for_target();
        (void) context;
        (void) irp;
        return 0;
}

ir_prog_pass_t *lower_for_target_pass(const char *name)
{
        ir_prog_pass_t *pass = XMALLOCZ(ir_prog_pass_t);
        return def_prog_pass_constructor(pass,
                                         name ? name : "lower_for_target",
                                         do_lower_for_target);
}