renamed exec_freq_t to ir_exec_freq

[libfirm] / ir / be / ia32 / ia32_emitter.c

/**
 * This file implements the node emitter.
 * @author Christian Wuerdig
 * $Id$
 */

#ifdef HAVE_CONFIG_H
#include "config.h"
#endif

#include <limits.h>

#include "xmalloc.h"
#include "tv.h"
#include "iredges.h"
#include "debug.h"
#include "irgwalk.h"
#include "irprintf.h"
#include "irop_t.h"
#include "irargs_t.h"
#include "irprog_t.h"
#include "iredges_t.h"
#include "execfreq.h"

#include "../besched_t.h"
#include "../benode_t.h"
#include "../beabi.h"
#include "../be_dbgout.h"

#include "ia32_emitter.h"
#include "gen_ia32_emitter.h"
#include "gen_ia32_regalloc_if.h"
#include "ia32_nodes_attr.h"
#include "ia32_new_nodes.h"
#include "ia32_map_regs.h"
#include "bearch_ia32_t.h"

#define BLOCK_PREFIX(x) ".L" x

#define SNPRINTF_BUF_LEN 128

/* global arch_env for lc_printf functions */
static const arch_env_t *arch_env = NULL;

/** by default, we generate assembler code for the Linux gas */
asm_flavour_t asm_flavour = ASM_LINUX_GAS;

/**
 * Switch to a new section
 */
void ia32_switch_section(FILE *F, section_t sec) {
        static section_t curr_sec = NO_SECTION;
        static const char *text[ASM_MAX][SECTION_MAX] = {
                {
                        ".section\t.text",
                        ".section\t.data",
                        ".section\t.rodata",
                        ".section\t.text",
                        ".section\t.tbss,\"awT\",@nobits",
                        ".section\t.ctors,\"aw\",@progbits"
                },
                {
                        ".section\t.text",
                        ".section\t.data",
                        ".section .rdata,\"dr\"",
                        ".section\t.text",
                        ".section\t.tbss,\"awT\",@nobits",
                        ".section\t.ctors,\"aw\",@progbits"
                }
        };

        if (curr_sec == sec)
                return;

        curr_sec = sec;
        switch (sec) {

        case NO_SECTION:
                break;

        case SECTION_TEXT:
        case SECTION_DATA:
        case SECTION_RODATA:
        case SECTION_COMMON:
        case SECTION_TLS:
        case SECTION_CTOR:
                fprintf(F, "\t%s\n", text[asm_flavour][sec]);
                break;

        default:
                break;
        }
}

static void ia32_dump_function_object(FILE *F, const char *name)
{
        switch (asm_flavour) {
        case ASM_LINUX_GAS:
                fprintf(F, "\t.type\t%s, @function\n", name);
                break;
        case ASM_MINGW_GAS:
                fprintf(F, "\t.def\t%s;\t.scl\t2;\t.type\t32;\t.endef\n", name);
                break;
        default:
                break;
        }
}

static void ia32_dump_function_size(FILE *F, const char *name)
{
        switch (asm_flavour) {
        case ASM_LINUX_GAS:
                fprintf(F, "\t.size\t%s, .-%s\n", name, name);
                break;
        default:
                break;
        }
}

/*************************************************************
 *             _       _    __   _          _
 *            (_)     | |  / _| | |        | |
 *  _ __  _ __ _ _ __ | |_| |_  | |__   ___| |_ __   ___ _ __
 * | '_ \| '__| | '_ \| __|  _| | '_ \ / _ \ | '_ \ / _ \ '__|
 * | |_) | |  | | | | | |_| |   | | | |  __/ | |_) |  __/ |
 * | .__/|_|  |_|_| |_|\__|_|   |_| |_|\___|_| .__/ \___|_|
 * | |                                       | |
 * |_|                                       |_|
 *************************************************************/

/**
 * returns true if a node has x87 registers
 */
static INLINE int has_x87_register(const ir_node *n) {
        return is_irn_machine_user(n, 0);
}

/* We always pass the ir_node which is a pointer. */
static int ia32_get_arg_type(const lc_arg_occ_t *occ) {
        return lc_arg_type_ptr;
}


/**
 * Returns the register at in position pos.
 */
static const arch_register_t *get_in_reg(const ir_node *irn, int pos) {
        ir_node                *op;
        const arch_register_t  *reg = NULL;

        assert(get_irn_arity(irn) > pos && "Invalid IN position");

        /* The out register of the operator at position pos is the
           in register we need. */
        op = get_irn_n(irn, pos);

        reg = arch_get_irn_register(arch_env, op);

        assert(reg && "no in register found");

        /* in case of a joker register: just return a valid register */
        if (arch_register_type_is(reg, joker)) {
                arch_register_req_t       req;
                const arch_register_req_t *p_req;

                /* ask for the requirements */
                p_req = arch_get_register_req(arch_env, &req, irn, pos);

                if (arch_register_req_is(p_req, limited)) {
                        /* in case of limited requirements: get the first allowed register */

                        bitset_t *bs = bitset_alloca(arch_register_class_n_regs(p_req->cls));
                        int      idx;

                        p_req->limited(p_req->limited_env, bs);
                        idx = bitset_next_set(bs, 0);
                        reg = arch_register_for_index(p_req->cls, idx);
                }
                else {
                        /* otherwise get first register in class */
                        reg = arch_register_for_index(p_req->cls, 0);
                }
        }

        return reg;
}

/**
 * Returns the register at out position pos.
 */
static const arch_register_t *get_out_reg(const ir_node *irn, int pos) {
        ir_node                *proj;
        const arch_register_t  *reg = NULL;

        /* 1st case: irn is not of mode_T, so it has only                 */
        /*           one OUT register -> good                             */
        /* 2nd case: irn is of mode_T -> collect all Projs and ask the    */
        /*           Proj with the corresponding projnum for the register */

        if (get_irn_mode(irn) != mode_T) {
                reg = arch_get_irn_register(arch_env, irn);
        }
        else if (is_ia32_irn(irn)) {
                reg = get_ia32_out_reg(irn, pos);
        }
        else {
                const ir_edge_t *edge;

                foreach_out_edge(irn, edge) {
                        proj = get_edge_src_irn(edge);
                        assert(is_Proj(proj) && "non-Proj from mode_T node");
                        if (get_Proj_proj(proj) == pos) {
                                reg = arch_get_irn_register(arch_env, proj);
                                break;
                        }
                }
        }

        assert(reg && "no out register found");
        return reg;
}

enum io_direction {
  IN_REG,
  OUT_REG
};

/**
 * Returns the name of the in register at position pos.
 */
static const char *get_ia32_reg_name(ir_node *irn, int pos, enum io_direction in_out) {
        const arch_register_t *reg;

        if (in_out == IN_REG) {
                reg = get_in_reg(irn, pos);

                if (reg->reg_class == &ia32_reg_classes[CLASS_ia32_vfp]) {
                        /* FIXME: works for binop only */
                        assert(2 <= pos && pos <= 3);
                        reg = get_ia32_attr(irn)->x87[pos - 2];
                }
        }
        else {
                /* destination address mode nodes don't have outputs */
                if (is_ia32_irn(irn) && get_ia32_op_type(irn) == ia32_AddrModeD) {
                        return "MEM";
                }

                reg = get_out_reg(irn, pos);
                if (reg->reg_class == &ia32_reg_classes[CLASS_ia32_vfp])
                        reg = get_ia32_attr(irn)->x87[pos + 2];
        }
        return arch_register_get_name(reg);
}

/**
 * Get the register name for a node.
 */
static int ia32_get_reg_name(lc_appendable_t *app,
    const lc_arg_occ_t *occ, const lc_arg_value_t *arg)
{
        const char *buf;
        ir_node    *irn = arg->v_ptr;
        int         nr = occ->width - 1;

        if (! irn)
                return lc_appendable_snadd(app, "(null)", 6);

        buf = get_ia32_reg_name(irn, nr, occ->conversion == 'S' ? IN_REG : OUT_REG);

        /* append the stupid % to register names */
        lc_appendable_chadd(app, '%');
        return lc_appendable_snadd(app, buf, strlen(buf));
}

/**
 * Get the x87 register name for a node.
 */
static int ia32_get_x87_name(lc_appendable_t *app,
    const lc_arg_occ_t *occ, const lc_arg_value_t *arg)
{
        const char *buf;
        ir_node     *irn = arg->v_ptr;
        int         nr = occ->width - 1;
        ia32_attr_t *attr;

        if (! irn)
                return lc_appendable_snadd(app, "(null)", 6);

        attr = get_ia32_attr(irn);
        buf = attr->x87[nr]->name;
        lc_appendable_chadd(app, '%');
        return lc_appendable_snadd(app, buf, strlen(buf));
}

/**
 * Returns the tarval, offset or scale of an ia32 as a string.
 */
static int ia32_const_to_str(lc_appendable_t *app,
    const lc_arg_occ_t *occ, const lc_arg_value_t *arg)
{
        const char *buf;
        ir_node    *irn = arg->v_ptr;

        if (! irn)
                return lc_arg_append(app, occ, "(null)", 6);

        if (occ->conversion == 'C') {
                buf = get_ia32_cnst(irn);
        }
        else { /* 'O' */
                buf = get_ia32_am_offs(irn);
        }

        return buf ? lc_appendable_snadd(app, buf, strlen(buf)) : 0;
}

/**
 * Determines the SSE suffix depending on the mode.
 */
static int ia32_get_mode_suffix(lc_appendable_t *app,
    const lc_arg_occ_t *occ, const lc_arg_value_t *arg)
{
        ir_node *irn  = arg->v_ptr;
        ir_mode *mode = get_irn_mode(irn);

        if (mode == mode_T) {
                mode = get_ia32_res_mode(irn);
                if (! mode)
                        mode = get_ia32_ls_mode(irn);
        }

        if (! irn)
                return lc_arg_append(app, occ, "(null)", 6);

        if (mode_is_float(mode)) {
                return lc_appendable_chadd(app, get_mode_size_bits(mode) == 32 ? 's' : 'd');
        }
        else {
                return lc_appendable_chadd(app, mode_is_signed(mode) ? 's' : 'z');
        }
}

/**
 * Return the ia32 printf arg environment.
 * We use the firm environment with some additional handlers.
 */
const lc_arg_env_t *ia32_get_arg_env(void) {
        static lc_arg_env_t *env = NULL;

        static const lc_arg_handler_t ia32_reg_handler   = { ia32_get_arg_type, ia32_get_reg_name };
        static const lc_arg_handler_t ia32_const_handler = { ia32_get_arg_type, ia32_const_to_str };
        static const lc_arg_handler_t ia32_mode_handler  = { ia32_get_arg_type, ia32_get_mode_suffix };
        static const lc_arg_handler_t ia32_x87_handler   = { ia32_get_arg_type, ia32_get_x87_name };

        if(env == NULL) {
                /* extend the firm printer */
                env = firm_get_arg_env();

                lc_arg_register(env, "ia32:sreg", 'S', &ia32_reg_handler);
                lc_arg_register(env, "ia32:dreg", 'D', &ia32_reg_handler);
                lc_arg_register(env, "ia32:cnst", 'C', &ia32_const_handler);
                lc_arg_register(env, "ia32:offs", 'O', &ia32_const_handler);
                lc_arg_register(env, "ia32:mode", 'M', &ia32_mode_handler);
                lc_arg_register(env, "ia32:x87",  'X', &ia32_x87_handler);
        }

        return env;
}

static const char *ia32_get_reg_name_for_mode(ia32_emit_env_t *env, ir_mode *mode, const arch_register_t *reg) {
        switch(get_mode_size_bits(mode)) {
                case 8:
                        return ia32_get_mapped_reg_name(env->isa->regs_8bit, reg);
                case 16:
                        return ia32_get_mapped_reg_name(env->isa->regs_16bit, reg);
                default:
                        return (char *)arch_register_get_name(reg);
        }
}

/**
 * Emits registers and/or address mode of a binary operation.
 */
const char *ia32_emit_binop(const ir_node *n, ia32_emit_env_t *env) {
        static char *buf = NULL;

        /* verify that this function is never called on non-AM supporting operations */
        //assert(get_ia32_am_support(n) != ia32_am_None && "emit binop expects addressmode support");

#define PRODUCES_RESULT(n)   \
        (!(is_ia32_St(n)      || \
        is_ia32_Store8Bit(n)  || \
        is_ia32_CondJmp(n)    || \
        is_ia32_xCondJmp(n)   || \
        is_ia32_CmpSet(n)     || \
        is_ia32_xCmpSet(n)    || \
        is_ia32_SwitchJmp(n)))

        if (! buf) {
                buf = xcalloc(1, SNPRINTF_BUF_LEN);
        }
        else {
                memset(buf, 0, SNPRINTF_BUF_LEN);
        }

        switch(get_ia32_op_type(n)) {
                case ia32_Normal:
                        if (is_ia32_ImmConst(n)) {
                                lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%3S, %s", n, get_ia32_cnst(n));
                        }
                        else if (is_ia32_ImmSymConst(n)) {
                                lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%3S, OFFSET FLAT:%s", n, get_ia32_cnst(n));
                        }
                        else {
                                const arch_register_t *in1 = get_in_reg(n, 2);
                                const arch_register_t *in2 = get_in_reg(n, 3);
                                const arch_register_t *out = PRODUCES_RESULT(n) ? get_out_reg(n, 0) : NULL;
                                const arch_register_t *in;
                                const char            *in_name;

                                in      = out ? (REGS_ARE_EQUAL(out, in2) ? in1 : in2) : in2;
                                out     = out ? out : in1;
                                in_name = arch_register_get_name(in);

                                if (is_ia32_emit_cl(n)) {
                                        assert(REGS_ARE_EQUAL(&ia32_gp_regs[REG_ECX], in) && "shift operation needs ecx");
                                        in_name = "cl";
                                }

                                snprintf(buf, SNPRINTF_BUF_LEN, "%%%s, %%%s", arch_register_get_name(out), in_name);
                        }
                        break;
                case ia32_AddrModeS:
                        if (is_ia32_ImmConst(n) || is_ia32_ImmSymConst(n)) {
                                assert(! PRODUCES_RESULT(n) && "Source AM with Const must not produce result");
                                snprintf(buf, SNPRINTF_BUF_LEN, "%s, %s", get_ia32_cnst(n), ia32_emit_am(n, env));
                        }
                        else {
                                if (PRODUCES_RESULT(n)) {
                                        lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%1D, %s", n, ia32_emit_am(n, env));
                                }
                                else {
                                        lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%3S, %s", n, ia32_emit_am(n, env));
                                }
                        }
                        break;
                case ia32_AddrModeD:
                        if (is_ia32_ImmConst(n) || is_ia32_ImmSymConst(n)) {
                                lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%s,%s%s",
                                        ia32_emit_am(n, env),
                                        is_ia32_ImmSymConst(n) ? " OFFSET FLAT:" : " ",  /* In case of a symconst we must add OFFSET to */
                                        get_ia32_cnst(n));                               /* tell the assembler to store it's address.   */
                        }
                        else {
                                const arch_register_t *in1 = get_in_reg(n, get_irn_arity(n) == 5 ? 3 : 2);
                                ir_mode               *mode = get_ia32_res_mode(n);
                                const char            *in_name;

                                mode    = mode ? mode : get_ia32_ls_mode(n);
                                in_name = ia32_get_reg_name_for_mode(env, mode, in1);

                                if (is_ia32_emit_cl(n)) {
                                        assert(REGS_ARE_EQUAL(&ia32_gp_regs[REG_ECX], in1) && "shift operation needs ecx");
                                        in_name = "cl";
                                }

                                lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%s, %%%s", ia32_emit_am(n, env), in_name);
                        }
                        break;
                default:
                        assert(0 && "unsupported op type");
        }

#undef PRODUCES_RESULT

        return buf;
}

/**
 * Returns the xxx PTR string for a given mode
 *
 * @param mode      the mode
 * @param x87_insn  if non-zero returns the string for a x87 instruction
 *                  else for a SSE instruction
 */
static const char *pointer_size(ir_mode *mode, int x87_insn)
{
        if (mode) {
                switch (get_mode_size_bits(mode)) {
                case 8:  return "BYTE PTR";
                case 16: return "WORD PTR";
                case 32: return "DWORD PTR";
                case 64:
                        if (x87_insn)
                                return "QWORD PTR";
                        return NULL;
                case 80:
                case 96: return "XWORD PTR";
                default: return NULL;
                }
        }
        return NULL;
}

/**
 * Emits registers and/or address mode of a binary operation.
 */
const char *ia32_emit_x87_binop(const ir_node *n, ia32_emit_env_t *env) {
        static char *buf = NULL;

        /* verify that this function is never called on non-AM supporting operations */
        //assert(get_ia32_am_support(n) != ia32_am_None && "emit binop expects addressmode support");

        if (! buf) {
                buf = xcalloc(1, SNPRINTF_BUF_LEN);
        }
        else {
                memset(buf, 0, SNPRINTF_BUF_LEN);
        }

        switch(get_ia32_op_type(n)) {
                case ia32_Normal:
                        if (is_ia32_ImmConst(n) || is_ia32_ImmSymConst(n)) {
                                ir_mode *mode = get_ia32_ls_mode(n);
                                const char *p = pointer_size(mode, 1);
                                lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%s %s", p, get_ia32_cnst(n));
                        }
                        else {
                                ia32_attr_t *attr = get_ia32_attr(n);
                                const arch_register_t *in1 = attr->x87[0];
                                const arch_register_t *in2 = attr->x87[1];
                                const arch_register_t *out = attr->x87[2];
                                const arch_register_t *in;
                                const char            *in_name;

                                in      = out ? (REGS_ARE_EQUAL(out, in2) ? in1 : in2) : in2;
                                out     = out ? out : in1;
                                in_name = arch_register_get_name(in);

                                snprintf(buf, SNPRINTF_BUF_LEN, "%%%s, %%%s", arch_register_get_name(out), in_name);
                        }
                        break;
                case ia32_AddrModeS:
                case ia32_AddrModeD:
                        lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%s", ia32_emit_am(n, env));
                        break;
                default:
                        assert(0 && "unsupported op type");
        }

        return buf;
}

/**
 * Emits registers and/or address mode of a unary operation.
 */
const char *ia32_emit_unop(const ir_node *n, ia32_emit_env_t *env) {
        static char *buf = NULL;

        if (! buf) {
                buf = xcalloc(1, SNPRINTF_BUF_LEN);
        }
        else {
                memset(buf, 0, SNPRINTF_BUF_LEN);
        }

        switch(get_ia32_op_type(n)) {
                case ia32_Normal:
                        if (is_ia32_ImmConst(n)) {
                                lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%C", n);
                        }
                        else if (is_ia32_ImmSymConst(n)) {
                                lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "OFFSET FLAT:%C", n);
                        }
                        else {
                                if (is_ia32_MulS(n) || is_ia32_Mulh(n)) {
                                        /* MulS and Mulh implicitly multiply by EAX */
                                        lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%4S", n);
                                } else if(is_ia32_Push(n)) {
                                        lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%3S", n);
                                } else {
                                        lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%1D", n);
                                }
                        }
                        break;
                case ia32_AddrModeD:
                        assert(!is_ia32_Push(n));
                        snprintf(buf, SNPRINTF_BUF_LEN, "%s", ia32_emit_am(n, env));
                        break;
                case ia32_AddrModeS:
                        /*
                                Mulh is emitted via emit_unop
                                imul [MEM]  means EDX:EAX <- EAX * [MEM]
                        */
                        assert((is_ia32_Mulh(n) || is_ia32_MulS(n) || is_ia32_Push(n)) && "Only MulS and Mulh can have AM source as unop");
                        lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%s", ia32_emit_am(n, env));
                        break;
                default:
                        assert(0 && "unsupported op type");
        }

        return buf;
}

/**
 * Emits address mode.
 */
const char *ia32_emit_am(const ir_node *n, ia32_emit_env_t *env) {
        ia32_am_flavour_t am_flav    = get_ia32_am_flavour(n);
        int               had_output = 0;
        char              *s;
        const char        *p;
        static struct obstack *obst  = NULL;
        ir_mode *mode = get_ia32_ls_mode(n);

        if (! is_ia32_Lea(n))
                assert(mode && "AM node must have ls_mode attribute set.");

        if (! obst) {
                obst = xcalloc(1, sizeof(*obst));
        }
        else {
                obstack_free(obst, NULL);
        }

        /* obstack_free with NULL results in an uninitialized obstack */
        obstack_init(obst);

        p = pointer_size(mode, has_x87_register(n) || is_ia32_GetST0(n) || is_ia32_SetST0(n));
        if (p)
                obstack_printf(obst, "%s ", p);

        /* emit address mode symconst */
        if (get_ia32_am_sc(n)) {
                if (is_ia32_am_sc_sign(n))
                        obstack_printf(obst, "-");
                obstack_printf(obst, "%s", get_id_str(get_ia32_am_sc(n)));
        }

        if (am_flav & ia32_B) {
                obstack_printf(obst, "[");
                lc_eoprintf(ia32_get_arg_env(), obst, "%1S", n);
                had_output = 1;
        }

        if (am_flav & ia32_I) {
                if (had_output) {
                        obstack_printf(obst, "+");
                }
                else {
                        obstack_printf(obst, "[");
                }

                lc_eoprintf(ia32_get_arg_env(), obst, "%2S", n);

                if (am_flav & ia32_S) {
                        obstack_printf(obst, "*%d", 1 << get_ia32_am_scale(n));
                }

                had_output = 1;
        }

        if (am_flav & ia32_O) {
                int offs = get_ia32_am_offs_int(n);

                if (offs != 0) {
                        /* omit explicit + if there was no base or index */
                        if (! had_output) {
                                obstack_printf(obst, "[%d", offs);
                        } else {
                                obstack_printf(obst, "%+d", offs);
                        }

                        had_output = 1;
                }
        }

        if (had_output)
                obstack_printf(obst, "] ");

        obstack_1grow(obst, '\0');
        s = obstack_finish(obst);

        return s;
}

/**
 * emit an address
 */
const char *ia32_emit_adr(const ir_node *irn, ia32_emit_env_t *env)
{
        static char buf[SNPRINTF_BUF_LEN];
        ir_mode    *mode = get_ia32_ls_mode(irn);
        const char *adr  = get_ia32_cnst(irn);
        const char *pref = pointer_size(mode, has_x87_register(irn));

        snprintf(buf, SNPRINTF_BUF_LEN, "%s %s", pref ? pref : "", adr);
        return buf;
}

/**
 * Formated print of commands and comments.
 */
static void ia32_fprintf_format(FILE *F, const ir_node *irn, char *cmd_buf, char *cmnt_buf) {
        unsigned lineno;
        const char *name = irn ? be_retrieve_dbg_info(get_irn_dbg_info((ir_node *)irn), &lineno) : NULL;

        if (name)
                fprintf(F, "\t%-35s %-60s /* %s:%u */\n", cmd_buf, cmnt_buf, name, lineno);
        else
                fprintf(F, "\t%-35s %-60s\n", cmd_buf, cmnt_buf);
}



/**
 * Add a number to a prefix. This number will not be used a second time.
 */
static char *get_unique_label(char *buf, size_t buflen, const char *prefix) {
        static unsigned long id = 0;
        snprintf(buf, buflen, "%s%lu", prefix, ++id);
        return buf;
}



/*************************************************
 *                 _ _                         _
 *                (_) |                       | |
 *   ___ _ __ ___  _| |_    ___ ___  _ __   __| |
 *  / _ \ '_ ` _ \| | __|  / __/ _ \| '_ \ / _` |
 * |  __/ | | | | | | |_  | (_| (_) | | | | (_| |
 *  \___|_| |_| |_|_|\__|  \___\___/|_| |_|\__,_|
 *
 *************************************************/

#undef IA32_DO_EMIT
#define IA32_DO_EMIT(irn) ia32_fprintf_format(F, irn, cmd_buf, cmnt_buf)

/*
 * coding of conditions
 */
struct cmp2conditon_t {
        const char *name;
        pn_Cmp      num;
};

/*
 * positive conditions for signed compares
 */
static const struct cmp2conditon_t cmp2condition_s[] = {
  { NULL,              pn_Cmp_False },  /* always false */
  { "e",               pn_Cmp_Eq },     /* == */
  { "l",               pn_Cmp_Lt },     /* < */
  { "le",              pn_Cmp_Le },     /* <= */
  { "g",               pn_Cmp_Gt },     /* > */
  { "ge",              pn_Cmp_Ge },     /* >= */
  { "ne",              pn_Cmp_Lg },     /* != */
  { "ordered",         pn_Cmp_Leg },    /* Floating point: ordered */
  { "unordered",       pn_Cmp_Uo },     /* FLoting point: unordered */
  { "e",               pn_Cmp_Ue },     /* Floating point: unordered or == */
  { "b",               pn_Cmp_Ul },     /* Floating point: unordered or < */
  { "be",              pn_Cmp_Ule },    /* Floating point: unordered or <= */
  { "a",               pn_Cmp_Ug },     /* Floating point: unordered or > */
  { "ae",              pn_Cmp_Uge },    /* Floating point: unordered or >= */
  { "ne",              pn_Cmp_Ne },     /* Floating point: unordered or != */
  { NULL,              pn_Cmp_True },   /* always true */
};

/*
 * positive conditions for unsigned compares
 */
static const struct cmp2conditon_t cmp2condition_u[] = {
        { NULL,              pn_Cmp_False },  /* always false */
        { "e",               pn_Cmp_Eq },     /* == */
        { "b",               pn_Cmp_Lt },     /* < */
        { "be",              pn_Cmp_Le },     /* <= */
        { "a",               pn_Cmp_Gt },     /* > */
        { "ae",              pn_Cmp_Ge },     /* >= */
        { "ne",              pn_Cmp_Lg },     /* != */
        { "ordered",         pn_Cmp_Leg },    /* Floating point: ordered */
        { "unordered",       pn_Cmp_Uo },     /* FLoting point: unordered */
        { "e",               pn_Cmp_Ue },     /* Floating point: unordered or == */
        { "b",               pn_Cmp_Ul },     /* Floating point: unordered or < */
        { "be",              pn_Cmp_Ule },    /* Floating point: unordered or <= */
        { "a",               pn_Cmp_Ug },     /* Floating point: unordered or > */
        { "ae",              pn_Cmp_Uge },    /* Floating point: unordered or >= */
        { "ne",              pn_Cmp_Ne },     /* Floating point: unordered or != */
        { NULL,              pn_Cmp_True },   /* always true */
};

/*
 * returns the condition code
 */
static const char *get_cmp_suffix(int cmp_code, int unsigned_cmp)
{
        assert(cmp2condition_s[cmp_code].num == cmp_code);
        assert(cmp2condition_u[cmp_code].num == cmp_code);

        return unsigned_cmp ? cmp2condition_u[cmp_code & 7].name : cmp2condition_s[cmp_code & 7].name;
}

/**
 * Returns the target block for a control flow node.
 */
static ir_node *get_cfop_target_block(const ir_node *irn) {
        return get_irn_link(irn);
}

/**
 * Returns the target label for a control flow node.
 */
static char *get_cfop_target(const ir_node *irn, char *buf) {
        ir_node *bl = get_cfop_target_block(irn);

        snprintf(buf, SNPRINTF_BUF_LEN, BLOCK_PREFIX("%ld"), get_irn_node_nr(bl));
        return buf;
}

/** Return the next block in Block schedule */
static ir_node *next_blk_sched(const ir_node *block) {
        return get_irn_link(block);
}

/**
 * Returns the Proj with projection number proj and NOT mode_M
 */
static ir_node *get_proj(const ir_node *irn, long proj) {
        const ir_edge_t *edge;
        ir_node         *src;

        assert(get_irn_mode(irn) == mode_T && "expected mode_T node");

        foreach_out_edge(irn, edge) {
                src = get_edge_src_irn(edge);

                assert(is_Proj(src) && "Proj expected");
                if (get_irn_mode(src) == mode_M)
                        continue;

                if (get_Proj_proj(src) == proj)
                        return src;
        }
        return NULL;
}

/**
 * Emits the jump sequence for a conditional jump (cmp + jmp_true + jmp_false)
 */
static void finish_CondJmp(FILE *F, const ir_node *irn, ir_mode *mode) {
        const ir_node *proj_true;
        const ir_node *proj_false;
        const ir_node *block;
        const ir_node *next_block;
        char buf[SNPRINTF_BUF_LEN];
        char cmd_buf[SNPRINTF_BUF_LEN];
        char cmnt_buf[SNPRINTF_BUF_LEN];
        int is_unsigned;
        int pnc;
        int flipped = 0;

        /* get both Proj's */
        proj_true = get_proj(irn, pn_Cond_true);
        assert(proj_true && "CondJmp without true Proj");

        proj_false = get_proj(irn, pn_Cond_false);
        assert(proj_false && "CondJmp without false Proj");

        pnc = get_ia32_pncode(irn);

        /* for now, the code works for scheduled and non-schedules blocks */
        block = get_nodes_block(irn);

        /* we have a block schedule */
        next_block = next_blk_sched(block);

        if (get_cfop_target_block(proj_true) == next_block) {
                /* exchange both proj's so the second one can be omitted */
                const ir_node *t = proj_true;
                proj_true = proj_false;
                proj_false = t;

                flipped = 1;
                pnc = get_negated_pnc(pnc, mode);
        }

        /* the first Proj must always be created */
        is_unsigned = mode_is_float(mode) || ! mode_is_signed(mode);
        snprintf(cmd_buf, SNPRINTF_BUF_LEN, "j%s %s",
                 get_cmp_suffix(pnc, is_unsigned),
                 get_cfop_target(proj_true, buf));
        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* %s(a, b) %s*/",
                 get_pnc_string(pnc), flipped ? "(was flipped)" : "");
        IA32_DO_EMIT(irn);

        /* the second Proj might be a fallthrough */
        if (get_cfop_target_block(proj_false) != next_block) {
                snprintf(cmd_buf, SNPRINTF_BUF_LEN, "jmp %s", get_cfop_target(proj_false, buf));
                snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* otherwise */");
        }
        else {
                cmd_buf[0] = '\0';
                snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* fallthrough %s */", get_cfop_target(proj_false, buf));
        }
        IA32_DO_EMIT(irn);
}

/**
 * Emits code for conditional jump.
 */
static void CondJmp_emitter(const ir_node *irn, ia32_emit_env_t *env) {
        FILE *F = env->out;
        char cmd_buf[SNPRINTF_BUF_LEN];
        char cmnt_buf[SNPRINTF_BUF_LEN];

        snprintf(cmd_buf, SNPRINTF_BUF_LEN, "cmp %s", ia32_emit_binop(irn, env));
        lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F */", irn);
        IA32_DO_EMIT(irn);
        finish_CondJmp(F, irn, get_ia32_res_mode(irn));
}

/**
 * Emits code for conditional jump with two variables.
 */
static void emit_ia32_CondJmp(const ir_node *irn, ia32_emit_env_t *env) {
        CondJmp_emitter(irn, env);
}

/**
 * Emits code for conditional test and jump.
 */
static void TestJmp_emitter(const ir_node *irn, ia32_emit_env_t *env) {

#define IA32_IS_IMMOP (is_ia32_ImmConst(irn) || is_ia32_ImmSymConst(irn))

        FILE       *F   = env->out;
        const char *op1 = arch_register_get_name(get_in_reg(irn, 0));
        const char *op2 = IA32_IS_IMMOP ? get_ia32_cnst(irn) : NULL;
        char        cmd_buf[SNPRINTF_BUF_LEN];
        char        cmnt_buf[SNPRINTF_BUF_LEN];

        if (! op2)
                op2 = arch_register_get_name(get_in_reg(irn, 1));

        snprintf(cmd_buf, SNPRINTF_BUF_LEN, "test %%%s,%s%s ", op1, IA32_IS_IMMOP ? " " : " %", op2);
        lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F */", irn);

        IA32_DO_EMIT(irn);
        finish_CondJmp(F, irn, get_ia32_res_mode(irn));

#undef IA32_IS_IMMOP
}

/**
 * Emits code for conditional test and jump with two variables.
 */
static void emit_ia32_TestJmp(const ir_node *irn, ia32_emit_env_t *env) {
        TestJmp_emitter(irn, env);
}

static void emit_ia32_CJmp(const ir_node *irn, ia32_emit_env_t *env) {
        FILE *F = env->out;
        char cmd_buf[SNPRINTF_BUF_LEN];
        char cmnt_buf[SNPRINTF_BUF_LEN];

        snprintf(cmd_buf, SNPRINTF_BUF_LEN, " ");
        lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F omitted redundant test */", irn);
        IA32_DO_EMIT(irn);
        finish_CondJmp(F, irn, get_ia32_res_mode(irn));
}

static void emit_ia32_CJmpAM(const ir_node *irn, ia32_emit_env_t *env) {
        FILE *F = env->out;
        char cmd_buf[SNPRINTF_BUF_LEN];
        char cmnt_buf[SNPRINTF_BUF_LEN];

        snprintf(cmd_buf, SNPRINTF_BUF_LEN, " ");
        lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F omitted redundant test/cmp */", irn);
        IA32_DO_EMIT(irn);
        finish_CondJmp(F, irn, get_ia32_res_mode(irn));
}

/**
 * Emits code for conditional SSE floating point jump with two variables.
 */
static void emit_ia32_xCondJmp(ir_node *irn, ia32_emit_env_t *env) {
        FILE *F = env->out;
        char cmd_buf[SNPRINTF_BUF_LEN];
        char cmnt_buf[SNPRINTF_BUF_LEN];

        lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "ucomis%M %s", irn, ia32_emit_binop(irn, env));
        lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F */", irn);
        IA32_DO_EMIT(irn);
        finish_CondJmp(F, irn, mode_F);

}

/**
 * Emits code for conditional x87 floating point jump with two variables.
 */
static void emit_ia32_x87CondJmp(ir_node *irn, ia32_emit_env_t *env) {
        FILE *F = env->out;
        char cmd_buf[SNPRINTF_BUF_LEN];
        char cmnt_buf[SNPRINTF_BUF_LEN];
        ia32_attr_t *attr = get_ia32_attr(irn);
        const char *reg = attr->x87[1]->name;
        const char *instr = "fcom";
        int reverse = 0;

        switch (get_ia32_irn_opcode(irn)) {
        case iro_ia32_fcomrJmp:
                reverse = 1;
        case iro_ia32_fcomJmp:
        default:
                instr = "fucom";
                break;
        case iro_ia32_fcomrpJmp:
                reverse = 1;
        case iro_ia32_fcompJmp:
                instr = "fucomp";
                break;
        case iro_ia32_fcomrppJmp:
                reverse = 1;
        case iro_ia32_fcomppJmp:
                instr = "fucompp";
                reg = "";
                break;
        }

        if (reverse)
                set_ia32_pncode(irn, (long)get_inversed_pnc(get_ia32_pncode(irn)));

        snprintf(cmd_buf, SNPRINTF_BUF_LEN, "%s %s%s", instr, reg[0] == '\0' ? "" : "%", reg);
        lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F */", irn);
        IA32_DO_EMIT(irn);
        lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "fnstsw %%ax", irn);
        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* Store x87 FPU Control Word */");
        IA32_DO_EMIT(irn);
        snprintf(cmd_buf, SNPRINTF_BUF_LEN, "sahf");
        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* Store ah into flags */");
        IA32_DO_EMIT(irn);

        /* the compare flags must be evaluated using carry , ie unsigned */
        finish_CondJmp(F, irn, mode_Iu);
}

static void CMov_emitter(ir_node *irn, ia32_emit_env_t *env) {
        FILE               *F       = env->out;
        const lc_arg_env_t *arg_env = ia32_get_arg_env();
        ir_mode    *mode       = get_irn_mode(get_irn_n(irn, 0));
        int        is_unsigned = mode_is_float(mode) || ! mode_is_signed(mode);
        const char *cmp_suffix = get_cmp_suffix(get_ia32_pncode(irn), is_unsigned);
        int is_PsiCondCMov     = is_ia32_PsiCondCMov(irn);
        int idx_left  = 2 - is_PsiCondCMov;
        int idx_right = 3 - is_PsiCondCMov;

        char cmd_buf[SNPRINTF_BUF_LEN];
        char cmnt_buf[SNPRINTF_BUF_LEN];
        const arch_register_t *in1, *in2, *out;

        out = arch_get_irn_register(env->arch_env, irn);
        in1 = arch_get_irn_register(env->arch_env, get_irn_n(irn, idx_left));
        in2 = arch_get_irn_register(env->arch_env, get_irn_n(irn, idx_right));

        /* we have to emit the cmp first, because the destination register */
        /* could be one of the compare registers                           */
        if (is_ia32_CmpCMov(irn)) {
                lc_esnprintf(arg_env, cmd_buf, SNPRINTF_BUF_LEN, "cmp %1S, %2S", irn, irn);
        }
        else if (is_ia32_xCmpCMov(irn)) {
                lc_esnprintf(arg_env, cmd_buf, SNPRINTF_BUF_LEN, "ucomis%M %1S, %2S", get_irn_n(irn, 0), irn, irn);
        }
        else if (is_PsiCondCMov) {
                /* omit compare because flags are already set by And/Or */
                lc_esnprintf(arg_env, cmd_buf, SNPRINTF_BUF_LEN, "test %1S, %1S", irn, irn);
        }
        else {
                assert(0 && "unsupported CMov");
        }
        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* Psi condition */" );
        IA32_DO_EMIT(irn);

        if (REGS_ARE_EQUAL(out, in2)) {
                /* best case: default in == out -> do nothing */
        }
        else if (REGS_ARE_EQUAL(out, in1)) {
                /* true in == out -> need complement compare and exchange true and default in */
                ir_node *t = get_irn_n(irn, idx_left);
                set_irn_n(irn, idx_left, get_irn_n(irn, idx_right));
                set_irn_n(irn, idx_right, t);

                cmp_suffix  = get_cmp_suffix(get_negated_pnc(get_ia32_pncode(irn), get_irn_mode(irn)), is_unsigned);

        }
        else {
                /* out is different from in: need copy default -> out */
                if (is_PsiCondCMov)
                        lc_esnprintf(arg_env, cmd_buf, SNPRINTF_BUF_LEN, "mov %1D, %3S", irn, irn);
                else
                        lc_esnprintf(arg_env, cmd_buf, SNPRINTF_BUF_LEN, "mov %1D, %4S", irn, irn);

                lc_esnprintf(arg_env, cmnt_buf, SNPRINTF_BUF_LEN, "/* copy default -> out */" );
                IA32_DO_EMIT(irn);
        }

        if (is_PsiCondCMov)
                lc_esnprintf(arg_env, cmd_buf, SNPRINTF_BUF_LEN, "cmov%s %1D, %2S", cmp_suffix, irn, irn);
        else
                lc_esnprintf(arg_env, cmd_buf, SNPRINTF_BUF_LEN, "cmov%s %1D, %3S", cmp_suffix, irn, irn);

        lc_esnprintf(arg_env, cmnt_buf, SNPRINTF_BUF_LEN, "/* condition is true case */" );
        IA32_DO_EMIT(irn);
}

static void emit_ia32_CmpCMov(ir_node *irn, ia32_emit_env_t *env) {
        CMov_emitter(irn, env);
}

static void emit_ia32_PsiCondCMov(ir_node *irn, ia32_emit_env_t *env) {
        CMov_emitter(irn, env);
}

static void emit_ia32_xCmpCMov(ir_node *irn, ia32_emit_env_t *env) {
        CMov_emitter(irn, env);
}

static void Set_emitter(ir_node *irn, ir_mode *mode, ia32_emit_env_t *env) {
        FILE               *F       = env->out;
        const lc_arg_env_t *arg_env = ia32_get_arg_env();
        int        is_unsigned = mode_is_float(mode) || ! mode_is_signed(mode);
        const char *cmp_suffix = get_cmp_suffix(get_ia32_pncode(irn), is_unsigned);
        const char *reg8bit;

        char cmd_buf[SNPRINTF_BUF_LEN];
        char cmnt_buf[SNPRINTF_BUF_LEN];
        const arch_register_t *out;

        out     = arch_get_irn_register(env->arch_env, irn);
        reg8bit = ia32_get_mapped_reg_name(env->isa->regs_8bit, out);

        if (is_ia32_CmpSet(irn)) {
                lc_esnprintf(arg_env, cmd_buf, SNPRINTF_BUF_LEN, "cmp %s", ia32_emit_binop(irn, env));
        }
        else if (is_ia32_xCmpSet(irn)) {
                lc_esnprintf(arg_env, cmd_buf, SNPRINTF_BUF_LEN, "ucomis%M %s", get_irn_n(irn, 2), ia32_emit_binop(irn, env));
        }
        else if (is_ia32_PsiCondSet(irn)) {
                /* omit compare because flags are already set by And/Or */
                snprintf(cmd_buf, SNPRINTF_BUF_LEN, " ");
        }
        else {
                assert(0 && "unsupported Set");
        }
        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* calculate Psi condition */" );
        IA32_DO_EMIT(irn);

        /* use mov to clear target because it doesn't affect the eflags */
        snprintf(cmd_buf, SNPRINTF_BUF_LEN, "mov %%%s, 0", arch_register_get_name(out));
        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* clear target as set modifies only lower 8 bit */");
        IA32_DO_EMIT(irn);

        snprintf(cmd_buf, SNPRINTF_BUF_LEN, "set%s %%%s", cmp_suffix, reg8bit);
        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* set 1 iff true, 0 otherweise */" );
        IA32_DO_EMIT(irn);
}

static void emit_ia32_CmpSet(ir_node *irn, ia32_emit_env_t *env) {
        Set_emitter(irn, get_irn_mode(get_irn_n(irn, 2)), env);
}

static void emit_ia32_PsiCondSet(ir_node *irn, ia32_emit_env_t *env) {
        Set_emitter(irn, get_irn_mode(get_irn_n(irn, 0)), env);
}

static void emit_ia32_xCmpSet(ir_node *irn, ia32_emit_env_t *env) {
        Set_emitter(irn, get_irn_mode(get_irn_n(irn, 2)), env);
}

static void emit_ia32_xCmp(ir_node *irn, ia32_emit_env_t *env) {
        FILE               *F       = env->out;
        const lc_arg_env_t *arg_env = ia32_get_arg_env();
        int                sse_pnc  = -1;
        long               pnc      = get_ia32_pncode(irn);
        long               unord    = pnc & pn_Cmp_Uo;
        char cmd_buf[SNPRINTF_BUF_LEN];
        char cmnt_buf[SNPRINTF_BUF_LEN];

        switch (pnc) {
                case pn_Cmp_Leg: /* odered */
                        sse_pnc = 7;
                        break;
                case pn_Cmp_Uo:  /* unordered */
                        sse_pnc = 3;
                        break;
                case pn_Cmp_Ue:
                case pn_Cmp_Eq:  /* == */
                        sse_pnc = 0;
                        break;
                case pn_Cmp_Ul:
                case pn_Cmp_Lt:  /* < */
                        sse_pnc = 1;
                        break;
                case pn_Cmp_Ule:
                case pn_Cmp_Le: /* <= */
                        sse_pnc = 2;
                        break;
                case pn_Cmp_Ug:
                case pn_Cmp_Gt:  /* > */
                        sse_pnc = 6;
                        break;
                case pn_Cmp_Uge:
                case pn_Cmp_Ge: /* >= */
                        sse_pnc = 5;
                        break;
                case pn_Cmp_Ne:
                case pn_Cmp_Lg:  /* != */
                        sse_pnc = 4;
                        break;
        }

        assert(sse_pnc >= 0 && "unsupported compare");

        if (unord && sse_pnc != 3) {
                /*
                        We need a separate compare against unordered.
                        Quick and Dirty solution:
                        - get some memory on stack
                        - compare
                        - store result
                        - compare
                        - and result and stored result
                    - cleanup stack
                */
                snprintf(cmd_buf, SNPRINTF_BUF_LEN, "sub %%esp, 8");
                snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* reserve some space for unordered compare result */");
                IA32_DO_EMIT(NULL);
                snprintf(cmd_buf, SNPRINTF_BUF_LEN, "cmpsd %s, 3", ia32_emit_binop(irn, env));
                snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* SSE compare: unordered */");
                IA32_DO_EMIT(NULL);
                lc_esnprintf(arg_env, cmd_buf, SNPRINTF_BUF_LEN, "movsd [%%esp], %1D", irn);
                snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* store compare result */");
                IA32_DO_EMIT(NULL);
        }

        snprintf(cmd_buf, SNPRINTF_BUF_LEN, "cmpsd %s, %d", ia32_emit_binop(irn, env), sse_pnc);
        lc_esnprintf(arg_env, cmnt_buf, SNPRINTF_BUF_LEN, "/* SSE compare (%+F) with result in %1D */", irn, irn);
        IA32_DO_EMIT(irn);

        if (unord && sse_pnc != 3) {
                lc_esnprintf(arg_env, cmd_buf, SNPRINTF_BUF_LEN, "andpd %1D, [%%esp]", irn);
                snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* build the final result */");
                IA32_DO_EMIT(NULL);
                snprintf(cmd_buf, SNPRINTF_BUF_LEN, "add %%esp, 8");
                snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* free allocated space */");
                IA32_DO_EMIT(NULL);
        }
}

/*********************************************************
 *                 _ _       _
 *                (_) |     (_)
 *   ___ _ __ ___  _| |_     _ _   _ _ __ ___  _ __  ___
 *  / _ \ '_ ` _ \| | __|   | | | | | '_ ` _ \| '_ \/ __|
 * |  __/ | | | | | | |_    | | |_| | | | | | | |_) \__ \
 *  \___|_| |_| |_|_|\__|   | |\__,_|_| |_| |_| .__/|___/
 *                         _/ |               | |
 *                        |__/                |_|
 *********************************************************/

/* jump table entry (target and corresponding number) */
typedef struct _branch_t {
        ir_node *target;
        int      value;
} branch_t;

/* jump table for switch generation */
typedef struct _jmp_tbl_t {
        ir_node  *defProj;         /**< default target */
        int       min_value;       /**< smallest switch case */
        int       max_value;       /**< largest switch case */
        int       num_branches;    /**< number of jumps */
        char     *label;           /**< label of the jump table */
        branch_t *branches;        /**< jump array */
} jmp_tbl_t;

/**
 * Compare two variables of type branch_t. Used to sort all switch cases
 */
static int ia32_cmp_branch_t(const void *a, const void *b) {
        branch_t *b1 = (branch_t *)a;
        branch_t *b2 = (branch_t *)b;

        if (b1->value <= b2->value)
                return -1;
        else
                return 1;
}

/**
 * Emits code for a SwitchJmp (creates a jump table if
 * possible otherwise a cmp-jmp cascade). Port from
 * cggg ia32 backend
 */
static void emit_ia32_SwitchJmp(const ir_node *irn, ia32_emit_env_t *emit_env) {
        unsigned long       interval;
        char                buf[SNPRINTF_BUF_LEN];
        int                 last_value, i, pn;
        jmp_tbl_t           tbl;
        ir_node            *proj;
        const ir_edge_t    *edge;
        const lc_arg_env_t *env = ia32_get_arg_env();
        FILE               *F   = emit_env->out;
        char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];

        /* fill the table structure */
        tbl.label        = xmalloc(SNPRINTF_BUF_LEN);
        tbl.label        = get_unique_label(tbl.label, SNPRINTF_BUF_LEN, ".TBL_");
        tbl.defProj      = NULL;
        tbl.num_branches = get_irn_n_edges(irn);
        tbl.branches     = xcalloc(tbl.num_branches, sizeof(tbl.branches[0]));
        tbl.min_value    = INT_MAX;
        tbl.max_value    = INT_MIN;

        i = 0;
        /* go over all proj's and collect them */
        foreach_out_edge(irn, edge) {
                proj = get_edge_src_irn(edge);
                assert(is_Proj(proj) && "Only proj allowed at SwitchJmp");

                pn = get_Proj_proj(proj);

                /* create branch entry */
                tbl.branches[i].target = proj;
                tbl.branches[i].value  = pn;

                tbl.min_value = pn < tbl.min_value ? pn : tbl.min_value;
                tbl.max_value = pn > tbl.max_value ? pn : tbl.max_value;

                /* check for default proj */
                if (pn == get_ia32_pncode(irn)) {
                        assert(tbl.defProj == NULL && "found two defProjs at SwitchJmp");
                        tbl.defProj = proj;
                }

                i++;
        }

        /* sort the branches by their number */
        qsort(tbl.branches, tbl.num_branches, sizeof(tbl.branches[0]), ia32_cmp_branch_t);

        /* two-complement's magic make this work without overflow */
        interval = tbl.max_value - tbl.min_value;

        /* emit the table */
        lc_esnprintf(env, cmd_buf, SNPRINTF_BUF_LEN, "cmp %1S, %u", irn, interval);
        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* compare for switch */");
        IA32_DO_EMIT(irn);

        snprintf(cmd_buf, SNPRINTF_BUF_LEN, "ja %s", get_cfop_target(tbl.defProj, buf));
        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* default jump if out of range  */");
        IA32_DO_EMIT(irn);

        if (tbl.num_branches > 1) {
                /* create table */

                lc_esnprintf(env, cmd_buf, SNPRINTF_BUF_LEN, "jmp %s[%1S*4]", tbl.label, irn);
                snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* get jump table entry as target */");
                IA32_DO_EMIT(irn);

                ia32_switch_section(F, SECTION_RODATA);
                fprintf(F, "\t.align 4\n");

                fprintf(F, "%s:\n", tbl.label);

                snprintf(cmd_buf, SNPRINTF_BUF_LEN, ".long %s", get_cfop_target(tbl.branches[0].target, buf));
                snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* case %d */",  tbl.branches[0].value);
                IA32_DO_EMIT(irn);

                last_value = tbl.branches[0].value;
                for (i = 1; i < tbl.num_branches; ++i) {
                        while (++last_value < tbl.branches[i].value) {
                                snprintf(cmd_buf, SNPRINTF_BUF_LEN, ".long %s", get_cfop_target(tbl.defProj, buf));
                                snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* default case */");
                                IA32_DO_EMIT(irn);
                        }
                        snprintf(cmd_buf, SNPRINTF_BUF_LEN, ".long %s", get_cfop_target(tbl.branches[i].target, buf));
                        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* case %d */", last_value);
                        IA32_DO_EMIT(irn);
                }
                ia32_switch_section(F, SECTION_TEXT);
        }
        else {
                /* one jump is enough */
                snprintf(cmd_buf, SNPRINTF_BUF_LEN, "jmp %s", get_cfop_target(tbl.branches[0].target, buf));
                snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* only one case given */");
                IA32_DO_EMIT(irn);
        }

        if (tbl.label)
                free(tbl.label);
        if (tbl.branches)
                free(tbl.branches);
}

/**
 * Emits code for a unconditional jump.
 */
static void emit_Jmp(const ir_node *irn, ia32_emit_env_t *env) {
        ir_node *block, *next_bl;
        FILE *F = env->out;
        char buf[SNPRINTF_BUF_LEN], cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];

        /* for now, the code works for scheduled and non-schedules blocks */
        block = get_nodes_block(irn);

        /* we have a block schedule */
        next_bl = next_blk_sched(block);
        if (get_cfop_target_block(irn) != next_bl) {
                snprintf(cmd_buf, SNPRINTF_BUF_LEN, "jmp %s", get_cfop_target(irn, buf));
                lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F(%+F) */", irn, get_cfop_target_block(irn));
        }
        else {
                cmd_buf[0] = '\0';
                lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* fallthrough %s */", get_cfop_target(irn, buf));
        }
        IA32_DO_EMIT(irn);
}

/****************************
 *                  _
 *                 (_)
 *  _ __  _ __ ___  _  ___
 * | '_ \| '__/ _ \| |/ __|
 * | |_) | | | (_) | |\__ \
 * | .__/|_|  \___/| ||___/
 * | |            _/ |
 * |_|           |__/
 ****************************/

/**
 * Emits code for a proj -> node
 */
static void emit_Proj(const ir_node *irn, ia32_emit_env_t *env) {
        ir_node *pred = get_Proj_pred(irn);

        if (get_irn_op(pred) == op_Start) {
                switch(get_Proj_proj(irn)) {
                        case pn_Start_X_initial_exec:
                                emit_Jmp(irn, env);
                                break;
                        default:
                                break;
                }
        }
}

/**********************************
 *   _____                  ____
 *  / ____|                |  _ \
 * | |     ___  _ __  _   _| |_) |
 * | |    / _ \| '_ \| | | |  _ <
 * | |___| (_) | |_) | |_| | |_) |
 *  \_____\___/| .__/ \__, |____/
 *             | |     __/ |
 *             |_|    |___/
 **********************************/

/**
 * Emit movsb/w instructions to make mov count divideable by 4
 */
static void emit_CopyB_prolog(FILE *F, const ir_node *irn, int rem) {
        char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];

        ir_fprintf(F, "\t/* memcopy prolog %+F */\n", irn);

        snprintf(cmd_buf, SNPRINTF_BUF_LEN, "cld");
        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* copy direction forward */");

        switch(rem) {
                case 1:
                        IA32_DO_EMIT(NULL);
                        snprintf(cmd_buf, SNPRINTF_BUF_LEN, "movsb");
                        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* memcopy remainder 1 */");
                        break;
                case 2:
                        IA32_DO_EMIT(NULL);
                        snprintf(cmd_buf, SNPRINTF_BUF_LEN, "movsw");
                        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* memcopy remainder 2 */");
                        break;
                case 3:
                        IA32_DO_EMIT(NULL);
                        snprintf(cmd_buf, SNPRINTF_BUF_LEN, "movsb");
                        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* memcopy remainder 3 */");
                        IA32_DO_EMIT(NULL);
                        snprintf(cmd_buf, SNPRINTF_BUF_LEN, "movsw");
                        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* memcopy remainder 3 */");
                        break;
        }

        IA32_DO_EMIT(NULL);
}

/**
 * Emit rep movsd instruction for memcopy.
 */
static void emit_ia32_CopyB(const ir_node *irn, ia32_emit_env_t *emit_env) {
        FILE   *F  = emit_env->out;
        tarval *tv = get_ia32_Immop_tarval(irn);
        int    rem = get_tarval_long(tv);
        char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];

        emit_CopyB_prolog(F, irn, rem);

        snprintf(cmd_buf, SNPRINTF_BUF_LEN, "rep movsd");
        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* memcopy */");
        IA32_DO_EMIT(irn);
}

/**
 * Emits unrolled memcopy.
 */
static void emit_ia32_CopyB_i(const ir_node *irn, ia32_emit_env_t *emit_env) {
        tarval *tv   = get_ia32_Immop_tarval(irn);
        int     size = get_tarval_long(tv);
        FILE   *F    = emit_env->out;
        char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];

        emit_CopyB_prolog(F, irn, size & 0x3);

        size >>= 2;
        while (size--) {
                snprintf(cmd_buf, SNPRINTF_BUF_LEN, "movsd");
                snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* memcopy unrolled */");
                IA32_DO_EMIT(irn);
        }
}



/***************************
 *   _____
 *  / ____|
 * | |     ___  _ ____   __
 * | |    / _ \| '_ \ \ / /
 * | |___| (_) | | | \ V /
 *  \_____\___/|_| |_|\_/
 *
 ***************************/

/**
 * Emit code for conversions (I, FP), (FP, I) and (FP, FP).
 */
static void emit_ia32_Conv_with_FP(const ir_node *irn, ia32_emit_env_t *emit_env) {
        FILE               *F        = emit_env->out;
        const lc_arg_env_t *env      = ia32_get_arg_env();
        ir_mode            *src_mode = get_ia32_src_mode(irn);
        ir_mode            *tgt_mode = get_ia32_tgt_mode(irn);
        char               *from, *to, buf[64];
        char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];

        from = mode_is_float(src_mode) ? (get_mode_size_bits(src_mode) == 32 ? "ss" : "sd") : "si";
        to   = mode_is_float(tgt_mode) ? (get_mode_size_bits(tgt_mode) == 32 ? "ss" : "sd") : "si";

        switch(get_ia32_op_type(irn)) {
                case ia32_Normal:
                        lc_esnprintf(env, buf, sizeof(buf), "%1D, %3S", irn, irn);
                        break;
                case ia32_AddrModeS:
                        lc_esnprintf(env, buf, sizeof(buf), "%1D, %s", irn, ia32_emit_am(irn, emit_env));
                        break;
                default:
                        assert(0 && "unsupported op type for Conv");
        }

        snprintf(cmd_buf, SNPRINTF_BUF_LEN, "cvt%s2%s %s", from, to, buf);
        lc_esnprintf(env, cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F(%+F, %+F) */", irn, src_mode, tgt_mode);
        IA32_DO_EMIT(irn);
}

static void emit_ia32_Conv_I2FP(const ir_node *irn, ia32_emit_env_t *emit_env) {
        emit_ia32_Conv_with_FP(irn, emit_env);
}

static void emit_ia32_Conv_FP2I(const ir_node *irn, ia32_emit_env_t *emit_env) {
        emit_ia32_Conv_with_FP(irn, emit_env);
}

static void emit_ia32_Conv_FP2FP(const ir_node *irn, ia32_emit_env_t *emit_env) {
        emit_ia32_Conv_with_FP(irn, emit_env);
}

/**
 * Emits code for an Int conversion.
 */
static void emit_ia32_Conv_I2I(const ir_node *irn, ia32_emit_env_t *emit_env) {
        FILE               *F        = emit_env->out;
        const lc_arg_env_t *env      = ia32_get_arg_env();
        char               *move_cmd = "movzx";
        char               *conv_cmd = NULL;
        ir_mode            *src_mode = get_ia32_src_mode(irn);
        ir_mode            *tgt_mode = get_ia32_tgt_mode(irn);
        int n, m;
        char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];
        const arch_register_t *in_reg, *out_reg;

        n = get_mode_size_bits(src_mode);
        m = get_mode_size_bits(tgt_mode);

        if (mode_is_signed(n < m ? src_mode : tgt_mode)) {
                move_cmd = "movsx";
                if (n == 8 || m == 8)
                        conv_cmd = "cbw";
                else if (n == 16 || m == 16)
                        conv_cmd = "cwde";
                else {
                        printf("%d -> %d unsupported\n", n, m);
                        assert(0 && "unsupported Conv_I2I");
                }
        }

         switch(get_ia32_op_type(irn)) {
                case ia32_Normal:
                        in_reg  = get_in_reg(irn, 2);
                        out_reg = get_out_reg(irn, 0);

                        if (REGS_ARE_EQUAL(in_reg, &ia32_gp_regs[REG_EAX]) &&
                                REGS_ARE_EQUAL(out_reg, in_reg)                &&
                                mode_is_signed(n < m ? src_mode : tgt_mode))
                        {
                                /* argument and result are both in EAX and */
                                /* signedness is ok: -> use converts       */
                                lc_esnprintf(env, cmd_buf, SNPRINTF_BUF_LEN, "%s", conv_cmd);
                        }
                        else if (REGS_ARE_EQUAL(out_reg, in_reg) &&
                                ! mode_is_signed(n < m ? src_mode : tgt_mode))
                        {
                                /* argument and result are in the same register */
                                /* and signedness is ok: -> use and with mask   */
                                int mask = (1 << (n < m ? n : m)) - 1;
                                lc_esnprintf(env, cmd_buf, SNPRINTF_BUF_LEN, "and %1D, 0x%x", irn, mask);
                        }
                        else {
                                /* use move w/o sign extension */
                                lc_esnprintf(env, cmd_buf, SNPRINTF_BUF_LEN, "%s %1D, %%%s",
                                        move_cmd, irn, ia32_get_reg_name_for_mode(emit_env, n < m ? src_mode : tgt_mode, in_reg));
                        }

                        break;
                case ia32_AddrModeS:
                        lc_esnprintf(env, cmd_buf, SNPRINTF_BUF_LEN, "%s %1D, %s",
                                move_cmd, irn, ia32_emit_am(irn, emit_env));
                        break;
                default:
                        assert(0 && "unsupported op type for Conv");
        }

        lc_esnprintf(env, cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F(%d Bit mode_%F -> %d Bit mode_%F) */",
                irn, n, src_mode, m, tgt_mode);

        IA32_DO_EMIT(irn);
}

/**
 * Emits code for an 8Bit Int conversion.
 */
void emit_ia32_Conv_I2I8Bit(const ir_node *irn, ia32_emit_env_t *emit_env) {
        emit_ia32_Conv_I2I(irn, emit_env);
}


/*******************************************
 *  _                          _
 * | |                        | |
 * | |__   ___ _ __   ___   __| | ___  ___
 * | '_ \ / _ \ '_ \ / _ \ / _` |/ _ \/ __|
 * | |_) |  __/ | | | (_) | (_| |  __/\__ \
 * |_.__/ \___|_| |_|\___/ \__,_|\___||___/
 *
 *******************************************/

/**
 * Emits a backend call
 */
static void emit_be_Call(const ir_node *irn, ia32_emit_env_t *emit_env) {
        FILE *F = emit_env->out;
        entity *ent = be_Call_get_entity(irn);
        char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];

        if (ent) {
                snprintf(cmd_buf, SNPRINTF_BUF_LEN, "call %s", get_entity_ld_name(ent));
        }
        else {
                lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "call %1D", get_irn_n(irn, be_pos_Call_ptr));
        }

        lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F (be_Call) */", irn);

        IA32_DO_EMIT(irn);
}

/**
 * Emits code to increase stack pointer.
 */
static void emit_be_IncSP(const ir_node *irn, ia32_emit_env_t *emit_env) {
        FILE          *F    = emit_env->out;
        int offs = be_get_IncSP_offset(irn);
        char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];

        if (offs) {
                if (offs > 0)
                        lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "sub %1S, %u", irn, offs);
                else
                        lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "add %1S, %u", irn, -offs);
                lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F (IncSP) */", irn);
        }
        else {
                snprintf(cmd_buf, SNPRINTF_BUF_LEN, " ");
                lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* omitted %+F (IncSP) with 0 */", irn);
        }

        IA32_DO_EMIT(irn);
}

/**
 * Emits code to set stack pointer.
 */
static void emit_be_SetSP(const ir_node *irn, ia32_emit_env_t *emit_env) {
        FILE *F = emit_env->out;
        char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];

        lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "mov %1D, %3S", irn, irn);
        lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F (restore SP) */", irn);
        IA32_DO_EMIT(irn);
}

/**
 * Emits code for Copy/CopyKeep.
 */
static void Copy_emitter(const ir_node *irn, ir_node *op, ia32_emit_env_t *emit_env) {
        FILE             *F    = emit_env->out;
        const arch_env_t *aenv = emit_env->arch_env;
        char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];

        if (REGS_ARE_EQUAL(arch_get_irn_register(aenv, irn), arch_get_irn_register(aenv, op)) ||
                arch_register_type_is(arch_get_irn_register(aenv, op), joker))
                return;

        if (mode_is_float(get_irn_mode(irn)))
                lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "movs%M %1D, %1S", irn, irn, irn);
        else
                lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "mov %1D, %1S", irn, irn);
        lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F */", irn);
        IA32_DO_EMIT(irn);
}

static void emit_be_Copy(const ir_node *irn, ia32_emit_env_t *emit_env) {
        Copy_emitter(irn, be_get_Copy_op(irn), emit_env);
}

static void emit_be_CopyKeep(const ir_node *irn, ia32_emit_env_t *emit_env) {
        Copy_emitter(irn, be_get_CopyKeep_op(irn), emit_env);
}

/**
 * Emits code for exchange.
 */
static void emit_be_Perm(const ir_node *irn, ia32_emit_env_t *emit_env) {
        FILE *F = emit_env->out;
        char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];
        const arch_register_t *in1, *in2;
        const arch_register_class_t *cls1, *cls2;

        in1 = arch_get_irn_register(emit_env->arch_env, get_irn_n(irn, 0));
        in2 = arch_get_irn_register(emit_env->arch_env, get_irn_n(irn, 1));

        cls1 = arch_register_get_class(in1);
        cls2 = arch_register_get_class(in2);

        assert(cls1 == cls2 && "Register class mismatch at Perm");

        if (cls1 == &ia32_reg_classes[CLASS_ia32_gp]) {
                if(emit_env->isa->opt_arch == arch_athlon) {
                        // xchg commands are Vector path on athlons and therefore stall the DirectPath pipeline
                        // it is nearly always beneficial to use the 3 xor trick instead of an xchg
                        cmnt_buf[0] = 0;
                        lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "xor %1S, %2S", irn, irn);
                        IA32_DO_EMIT(irn);
                        lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "xor %2S, %1S", irn, irn);
                        IA32_DO_EMIT(irn);
                        lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "xor %1S, %2S", irn, irn);
                } else {
                        lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "xchg %1S, %2S", irn, irn);
                }
        }
        else if (cls1 == &ia32_reg_classes[CLASS_ia32_xmm]) {
                lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN,
                        "pxor %1S, %2S\n\tpxor %2S, %1S\n\tpxor %1S, %2S", irn, irn, irn, irn, irn, irn);
        }
        else if (cls1 == &ia32_reg_classes[CLASS_ia32_vfp]) {
                /* is a NOP */
                cmd_buf[0] = '\0';
        }
        else if (cls1 == &ia32_reg_classes[CLASS_ia32_st]) {
                /* is a NOP */
                cmd_buf[0] = '\0';
        }

        lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F(%1A, %2A) */", irn, irn, irn);
        IA32_DO_EMIT(irn);
}

/**
 * Emits code for Constant loading.
 */
static void emit_ia32_Const(const ir_node *n, ia32_emit_env_t *env) {
        FILE *F = env->out;
        char cmd_buf[256], cmnt_buf[256];
        const lc_arg_env_t *arg_env = ia32_get_arg_env();
        ir_mode *mode = get_irn_mode(n);
        tarval *tv = get_ia32_Immop_tarval(n);

        if (get_ia32_op_type(n) == ia32_SymConst) {
                lc_esnprintf(arg_env, cmd_buf, 256, "mov %1D, OFFSET FLAT:%C ", n, n);
                lc_esnprintf(arg_env, cmnt_buf, 256, "/* Move address of SymConst into register */");
        } else {
                assert(mode == get_tarval_mode(tv));
                /* beware: in some rare cases mode is mode_b which has no tarval_null() */
                if (tv == get_tarval_b_false() || tv == get_tarval_null(mode)) {
                        const char *instr = "xor";
                        if (env->isa->opt_arch == arch_pentium_4) {
                                /* P4 prefers sub r, r, others xor r, r */
                                instr = "sub";
                        }
                        lc_esnprintf(arg_env, cmd_buf, 256, "%s %1D, %1D ", instr, n, n);
                        lc_esnprintf(arg_env, cmnt_buf, 256, "/* optimized mov 0 to register */");
                } else {
                        lc_esnprintf(arg_env, cmd_buf, 256, "mov %1D, %C ", n, n);
                        lc_esnprintf(arg_env, cmnt_buf, 256, "/* Mov Const into register */");
                }
        }
        lc_efprintf(arg_env, F, "\t%-35s %-60s /* %+F (%+G) */\n", cmd_buf, cmnt_buf, n, n);
}

/**
 * Emits code to increase stack pointer.
 */
static void emit_ia32_AddSP(const ir_node *irn, ia32_emit_env_t *emit_env) {
        FILE *F = emit_env->out;
        char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];

        if (is_ia32_ImmConst(irn)) {
                lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "sub %1D, %C", irn, irn);
        }
        else if (is_ia32_ImmSymConst(irn)) {
                if (get_ia32_op_type(irn) == ia32_Normal)
                        lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "sub %1D, OFFSET_FLAT:%C", irn, irn);
                else /* source address mode */
                        lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "sub %1D, [%s%s]", irn, get_id_str(get_ia32_am_sc(irn)), get_ia32_am_offs(irn));
        }
        else {
                lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "sub %1D, %2S", irn, irn);
        }
        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* reserve space on stack */");

        IA32_DO_EMIT(irn);
}

/**
 * Emits code to increase stack pointer.
 */
static void emit_ia32_SubSP(const ir_node *irn, ia32_emit_env_t *emit_env) {
        FILE *F = emit_env->out;
        char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];

        if (is_ia32_ImmConst(irn)) {
                lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "add %1D, %C", irn, irn);
        }
        else if (is_ia32_ImmSymConst(irn)) {
                if (get_ia32_op_type(irn) == ia32_Normal)
                        lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "add %1D, OFFSET_FLAT:%C", irn, irn);
                else /* source address mode */
                        lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "add %1D, [%s%s]", irn, get_id_str(get_ia32_am_sc(irn)), get_ia32_am_offs(irn));
        }
        else {
                lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "add %1D, %2S", irn, irn);
        }
        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* free space on stack */");

        IA32_DO_EMIT(irn);
}

/**
 * Emits code to load the TLS base
 */
static void emit_ia32_LdTls(const ir_node *irn, ia32_emit_env_t *emit_env) {
        FILE *F = emit_env->out;
        char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];

        switch (asm_flavour) {
        case ASM_LINUX_GAS:
                lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "mov %1D, DWORD PTR %%gs:0", irn);
                break;
        case ASM_MINGW_GAS:
                lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "mov %1D, DWORD PTR %%gs:0", irn);
                break;
        default:
                assert(0 && "unsupported TLS");
                break;
        }
        snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* get thread local storage base */");

        IA32_DO_EMIT(irn);
}

static void emit_be_Return(const ir_node *n, ia32_emit_env_t *env) {
        FILE *F = env->out;
        const lc_arg_env_t *arg_env = ia32_get_arg_env();

        lc_efprintf(arg_env, F, "\t%-35s %-60s /* %+F (%+G) */\n", "ret", "/* be_Return */", n, n);
}

static void emit_Nothing(const ir_node *n, ia32_emit_env_t *env) {
        FILE *F = env->out;

        ir_fprintf(F, "\t%35s /* %+F (%+G) */\n", " ", n, n);
}


/***********************************************************************************
 *                  _          __                                             _
 *                 (_)        / _|                                           | |
 *  _ __ ___   __ _ _ _ __   | |_ _ __ __ _ _ __ ___   _____      _____  _ __| | __
 * | '_ ` _ \ / _` | | '_ \  |  _| '__/ _` | '_ ` _ \ / _ \ \ /\ / / _ \| '__| |/ /
 * | | | | | | (_| | | | | | | | | | | (_| | | | | | |  __/\ V  V / (_) | |  |   <
 * |_| |_| |_|\__,_|_|_| |_| |_| |_|  \__,_|_| |_| |_|\___| \_/\_/ \___/|_|  |_|\_\
 *
 ***********************************************************************************/

/**
 * Enters the emitter functions for handled nodes into the generic
 * pointer of an opcode.
 */
static void ia32_register_emitters(void) {

#define IA32_EMIT2(a,b) op_ia32_##a->ops.generic = (op_func)emit_ia32_##b
#define IA32_EMIT(a)    IA32_EMIT2(a,a)
#define EMIT(a)         op_##a->ops.generic = (op_func)emit_##a
#define IGN(a)                  op_##a->ops.generic = (op_func)emit_Nothing
#define BE_EMIT(a)      op_be_##a->ops.generic = (op_func)emit_be_##a
#define BE_IGN(a)               op_be_##a->ops.generic = (op_func)emit_Nothing

        /* first clear the generic function pointer for all ops */
        clear_irp_opcodes_generic_func();

        /* register all emitter functions defined in spec */
        ia32_register_spec_emitters();

        /* other ia32 emitter functions */
        IA32_EMIT(CondJmp);
        IA32_EMIT(TestJmp);
        IA32_EMIT(CJmp);
        IA32_EMIT(CJmpAM);
        IA32_EMIT(CmpCMov);
        IA32_EMIT(PsiCondCMov);
        IA32_EMIT(CmpSet);
        IA32_EMIT(PsiCondSet);
        IA32_EMIT(SwitchJmp);
        IA32_EMIT(CopyB);
        IA32_EMIT(CopyB_i);
        IA32_EMIT(Conv_I2FP);
        IA32_EMIT(Conv_FP2I);
        IA32_EMIT(Conv_FP2FP);
        IA32_EMIT(Conv_I2I);
        IA32_EMIT(Conv_I2I8Bit);
        IA32_EMIT(Const);
        IA32_EMIT(AddSP);
        IA32_EMIT(SubSP);
        IA32_EMIT(LdTls);
        IA32_EMIT(xCmp);
        IA32_EMIT(xCmpSet);
        IA32_EMIT(xCmpCMov);
        IA32_EMIT(xCondJmp);
        IA32_EMIT2(fcomJmp, x87CondJmp);
        IA32_EMIT2(fcompJmp, x87CondJmp);
        IA32_EMIT2(fcomppJmp, x87CondJmp);
        IA32_EMIT2(fcomrJmp, x87CondJmp);
        IA32_EMIT2(fcomrpJmp, x87CondJmp);
        IA32_EMIT2(fcomrppJmp, x87CondJmp);

        /* benode emitter */
        BE_EMIT(Call);
        BE_EMIT(IncSP);
        BE_EMIT(SetSP);
        BE_EMIT(Copy);
        BE_EMIT(CopyKeep);
        BE_EMIT(Perm);
        BE_EMIT(Return);

        BE_IGN(RegParams);
        BE_IGN(Barrier);
        BE_IGN(Keep);

        /* firm emitter */
        EMIT(Jmp);
        EMIT(Proj);
        IGN(Phi);
        IGN(Start);

#undef BE_EMIT
#undef EMIT
#undef IGN
#undef IA32_EMIT2
#undef IA32_EMIT
}

static const char *last_name = NULL;
static unsigned last_line = -1;
static unsigned num = -1;

/**
 * Emit the debug support for node irn.
 */
static void ia32_emit_dbg(const ir_node *irn, ia32_emit_env_t *env) {
        dbg_info *db = get_irn_dbg_info(irn);
        unsigned lineno;
        const char *fname = be_retrieve_dbg_info(db, &lineno);

        if (fname) {
                if (last_name != fname) {
                        last_line = -1;
                        be_dbg_include_begin(env->cg->birg->main_env->db_handle, fname);
                        last_name = fname;
                }
                if (last_line != lineno) {
                        char name[64];
                        FILE *F = env->out;

                        snprintf(name, sizeof(name), ".LM%u", ++num);
                        last_line = lineno;
                        be_dbg_line(env->cg->birg->main_env->db_handle, lineno, name);
                        fprintf(F, "%s:\n", name);
                }
        }
}

/**
 * Emits code for a node.
 */
static void ia32_emit_node(const ir_node *irn, void *env) {
        ia32_emit_env_t   *emit_env = env;
        ir_op             *op       = get_irn_op(irn);
        DEBUG_ONLY(firm_dbg_module_t *mod = emit_env->mod;)

        DBG((mod, LEVEL_1, "emitting code for %+F\n", irn));

        if (op->ops.generic) {
                void (*emit)(const ir_node *, void *) = (void (*)(const ir_node *, void *))op->ops.generic;
                ia32_emit_dbg(irn, emit_env);
                (*emit)(irn, env);
        }
        else {
                emit_Nothing(irn, env);
                ir_fprintf(stderr, "Warning: No emit handler for node %+F (%+G)\n", irn, irn);
        }
}

/**
 * Emits gas alignment directives
 */
static void ia32_emit_alignment(FILE *F, unsigned align, unsigned skip) {
        fprintf(F, "\t.p2align %u,,%u\n", align, skip);
}

/**
 * Emits gas alignment directives for Functions depended on cpu architecture.
 */
static void ia32_emit_align_func(FILE *F, cpu_support cpu) {
        unsigned align;
        unsigned maximum_skip;

        switch (cpu) {
                case arch_i386:
                        align = 2;
                        break;
                case arch_i486:
                        align = 4;
                        break;
                case arch_k6:
                        align = 5;
                        break;
                default:
                        align = 4;
        }
        maximum_skip = (1 << align) - 1;
        ia32_emit_alignment(F, align, maximum_skip);
}

/**
 * Emits gas alignment directives for Labels depended on cpu architecture.
 */
static void ia32_emit_align_label(FILE *F, cpu_support cpu) {
        unsigned align; unsigned maximum_skip;

        switch (cpu) {
                case arch_i386:
                        align = 2;
                        break;
                case arch_i486:
                        align = 4;
                        break;
                case arch_k6:
                        align = 5;
                        break;
                default:
                        align = 4;
        }
        maximum_skip = (1 << align) - 1;
        ia32_emit_alignment(F, align, maximum_skip);
}

static int is_first_loop_block(ir_node *block, ir_node *prev_block, ia32_emit_env_t *env) {
        ir_exec_freq *execfreqs = env->cg->birg->execfreqs;
        double block_freq, prev_freq;
        static const double DELTA = .0001;
        cpu_support cpu = env->isa->opt_arch;

        if(execfreqs == NULL)
                return 0;
        if(cpu == arch_i386 || cpu == arch_i486)
                return 0;

        block_freq = get_block_execfreq(execfreqs, block);
        prev_freq = get_block_execfreq(execfreqs, prev_block);

        if(block_freq < DELTA || prev_freq < DELTA)
                return 0;

        block_freq /= prev_freq;

        switch (cpu) {
                case arch_athlon:
                case arch_athlon_64:
                case arch_k6:
                        return block_freq > 3;
                default:
                        break;
        }

        return block_freq > 2;
}

/**
 * Walks over the nodes in a block connected by scheduling edges
 * and emits code for each node.
 */
static void ia32_gen_block(ir_node *block, ir_node *last_block, void *env) {
        ia32_emit_env_t *emit_env = env;
        const ir_node *irn;
        int need_label = block != get_irg_start_block(get_irn_irg(block));
        FILE *F = emit_env->out;

        if (! is_Block(block))
                return;

        if (need_label && (emit_env->cg->opt & IA32_OPT_EXTBB)) {
                /* if the extended block scheduler is used, only leader blocks need
                   labels. */
                need_label = (block == get_extbb_leader(get_nodes_extbb(block)));
        }

        if (need_label) {
                char cmd_buf[SNPRINTF_BUF_LEN];
                int i, arity;
                int align = 1;

                // align the loop headers
                if(!is_first_loop_block(block, last_block, emit_env)) {

                        // align blocks where the previous block has no fallthrough
                        arity = get_irn_arity(block);
                        for(i = 0; i < arity; ++i) {
                                ir_node *predblock = get_Block_cfgpred_block(block, i);
                                if(predblock == last_block) {
                                        align = 0;
                                        break;
                                }
                        }
                }

                if(align)
                        ia32_emit_align_label(emit_env->out, emit_env->isa->opt_arch);

                ir_snprintf(cmd_buf, sizeof(cmd_buf), BLOCK_PREFIX("%d:"),
                            get_irn_node_nr(block));
                fprintf(F, "%-43s ", cmd_buf);

                /* emit list of pred blocks in comment */
                fprintf(F, "/* preds:");

                arity = get_irn_arity(block);
                for(i = 0; i < arity; ++i) {
                        ir_node *predblock = get_Block_cfgpred_block(block, i);
                        fprintf(F, " %ld", get_irn_node_nr(predblock));
                }
                fprintf(F, " */\n");
        }

        /* emit the contents of the block */
        ia32_emit_dbg(block, env);
        sched_foreach(block, irn) {
                ia32_emit_node(irn, env);
        }
}

/**
 * Emits code for function start.
 */
static void ia32_emit_func_prolog(FILE *F, ir_graph *irg, ia32_emit_env_t *emit_env) {
        entity     *irg_ent  = get_irg_entity(irg);
        const char *irg_name = get_entity_ld_name(irg_ent);
        cpu_support cpu      = emit_env->isa->opt_arch;
        const be_irg_t *birg = emit_env->cg->birg;

        fprintf(F, "\n");
        ia32_switch_section(F, SECTION_TEXT);
        be_dbg_method_begin(birg->main_env->db_handle, irg_ent, be_abi_get_stack_layout(birg->abi));
        ia32_emit_align_func(F, cpu);
        if (get_entity_visibility(irg_ent) == visibility_external_visible) {
                fprintf(F, ".globl %s\n", irg_name);
        }
        ia32_dump_function_object(F, irg_name);
        fprintf(F, "%s:\n", irg_name);
}

/**
 * Emits code for function end
 */
static void ia32_emit_func_epilog(FILE *F, ir_graph *irg, ia32_emit_env_t *emit_env) {
        const char *irg_name = get_entity_ld_name(get_irg_entity(irg));
        const be_irg_t *birg = emit_env->cg->birg;

        ia32_dump_function_size(F, irg_name);
        be_dbg_method_end(birg->main_env->db_handle);
        fprintf(F, "\n");
}

/**
 * Block-walker:
 * Sets labels for control flow nodes (jump target)
 * TODO: Jump optimization
 */
static void ia32_gen_labels(ir_node *block, void *env) {
        ir_node *pred;
        int n = get_Block_n_cfgpreds(block);

        for (n--; n >= 0; n--) {
                pred = get_Block_cfgpred(block, n);
                set_irn_link(pred, block);
        }
}

/**
 * Main driver. Emits the code for one routine.
 */
void ia32_gen_routine(FILE *F, ir_graph *irg, const ia32_code_gen_t *cg) {
        ia32_emit_env_t emit_env;
        ir_node *block;
        ir_node *last_block = NULL;

        emit_env.out      = F;
        emit_env.arch_env = cg->arch_env;
        emit_env.cg       = cg;
        emit_env.isa      = (ia32_isa_t *)cg->arch_env->isa;
        FIRM_DBG_REGISTER(emit_env.mod, "firm.be.ia32.emitter");

        /* set the global arch_env (needed by print hooks) */
        arch_env = cg->arch_env;

        ia32_register_emitters();

        ia32_emit_func_prolog(F, irg, &emit_env);
        irg_block_walk_graph(irg, ia32_gen_labels, NULL, &emit_env);

        if ((cg->opt & IA32_OPT_EXTBB) && cg->blk_sched) {
                int i, n = ARR_LEN(cg->blk_sched);

                for (i = 0; i < n;) {
                        ir_node *next_bl;

                        block   = cg->blk_sched[i];
                        ++i;
                        next_bl = i < n ? cg->blk_sched[i] : NULL;

                        /* set here the link. the emitter expects to find the next block here */
                        set_irn_link(block, next_bl);
                        ia32_gen_block(block, last_block, &emit_env);
                        last_block = block;
                }
        }
        else {
                /* "normal" block schedule: Note the get_next_block() returns the NUMBER of the block
                   in the block schedule. As this number should NEVER be equal the next block,
                   we does not need a clear block link here. */

                //irg_walk_blkwise_graph(irg, NULL, ia32_gen_block, &emit_env);
                // TODO
        }

        ia32_emit_func_epilog(F, irg, &emit_env);
}