-/**
- * This file implements the x87 support and virtual to stack
- * register translation for the ia32 backend.
+/*
+ * Copyright (C) 1995-2010 University of Karlsruhe. All right reserved.
+ *
+ * This file is part of libFirm.
*
- * @author: Michael Beck
+ * 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.
*
- * $Id$
+ * 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 This file implements the x87 support and virtual to stack
+ * register translation for the ia32 backend.
+ * @author Michael Beck
*/
-#ifdef HAVE_CONFIG_H
#include "config.h"
-#endif
#include <assert.h>
#include "irgwalk.h"
#include "obst.h"
#include "pmap.h"
+#include "array_t.h"
#include "pdeq.h"
#include "irprintf.h"
#include "debug.h"
#include "error.h"
-#include "../belive_t.h"
-#include "../besched_t.h"
-#include "../benode_t.h"
+#include "belive_t.h"
+#include "besched.h"
+#include "benode.h"
+#include "bearch_ia32_t.h"
#include "ia32_new_nodes.h"
#include "gen_ia32_new_nodes.h"
#include "gen_ia32_regalloc_if.h"
#include "ia32_x87.h"
-
-#define N_x87_REGS 8
-
-/* first and second binop index */
-#define BINOP_IDX_1 2
-#define BINOP_IDX_2 3
-
-/* the unop index */
-#define UNOP_IDX 0
-
-/* the store val index */
-#define STORE_VAL_IDX 2
-
-#define MASK_TOS(x) ((x) & (N_x87_REGS - 1))
+#include "ia32_architecture.h"
/** the debug handle */
DEBUG_ONLY(static firm_dbg_module_t *dbg = NULL;)
/* Forward declaration. */
-typedef struct _x87_simulator x87_simulator;
+typedef struct x87_simulator x87_simulator;
/**
* An exchange template.
* their opcodes!
* Further, x87 supports inverse instructions, so we can handle them.
*/
-typedef struct _exchange_tmpl {
+typedef struct exchange_tmpl {
ir_op *normal_op; /**< the normal one */
ir_op *reverse_op; /**< the reverse one if exists */
ir_op *normal_pop_op; /**< the normal one with tos pop */
/**
* An entry on the simulated x87 stack.
*/
-typedef struct _st_entry {
- int reg_idx; /**< the virtual register index of this stack value */
- ir_node *node; /**< the node that produced this value */
+typedef struct st_entry {
+ int reg_idx; /**< the virtual register index of this stack value */
+ ir_node *node; /**< the node that produced this value */
} st_entry;
/**
* The x87 state.
*/
-typedef struct _x87_state {
- st_entry st[N_x87_REGS]; /**< the register stack */
- int depth; /**< the current stack depth */
- int tos; /**< position of the tos */
- x87_simulator *sim; /**< The simulator. */
+typedef struct x87_state {
+ st_entry st[N_ia32_st_REGS]; /**< the register stack */
+ int depth; /**< the current stack depth */
+ x87_simulator *sim; /**< The simulator. */
} x87_state;
/** An empty state, used for blocks without fp instructions. */
-static x87_state _empty = { { {0, NULL}, }, 0, 0 };
-static x87_state *empty = (x87_state *)&_empty;
+static x87_state empty = { { {0, NULL}, }, 0, NULL };
-/** The type of an instruction simulator function. */
+/**
+ * Return values of the instruction simulator functions.
+ */
+enum {
+ NO_NODE_ADDED = 0, /**< No node that needs simulation was added. */
+ NODE_ADDED = 1 /**< A node that must be simulated was added by the simulator
+ in the schedule AFTER the current node. */
+};
+
+/**
+ * The type of an instruction simulator function.
+ *
+ * @param state the x87 state
+ * @param n the node to be simulated
+ *
+ * @return NODE_ADDED if a node was added AFTER n in schedule that MUST be
+ * simulated further
+ * NO_NODE_ADDED otherwise
+ */
typedef int (*sim_func)(x87_state *state, ir_node *n);
/**
* A block state: Every block has a x87 state at the beginning and at the end.
*/
-typedef struct _blk_state {
+typedef struct blk_state {
x87_state *begin; /**< state at the begin or NULL if not assigned */
x87_state *end; /**< state at the end or NULL if not assigned */
} blk_state;
-#define PTR_TO_BLKSTATE(p) ((blk_state *)(p))
-
/** liveness bitset for vfp registers. */
typedef unsigned char vfp_liveness;
/**
* The x87 simulator.
*/
-struct _x87_simulator {
- struct obstack obst; /**< An obstack for fast allocating. */
- pmap *blk_states; /**< Map blocks to states. */
- const arch_env_t *arch_env; /**< The architecture environment. */
- be_lv_t *lv; /**< intrablock liveness. */
- vfp_liveness *live; /**< Liveness information. */
- unsigned n_idx; /**< The cached get_irg_last_idx() result. */
- waitq *worklist; /**< list of blocks to process. */
+struct x87_simulator {
+ struct obstack obst; /**< An obstack for fast allocating. */
+ pmap *blk_states; /**< Map blocks to states. */
+ be_lv_t *lv; /**< intrablock liveness. */
+ vfp_liveness *live; /**< Liveness information. */
+ unsigned n_idx; /**< The cached get_irg_last_idx() result. */
+ waitq *worklist; /**< Worklist of blocks that must be processed. */
};
/**
*
* @return the x87 stack depth
*/
-static int x87_get_depth(const x87_state *state) {
+static int x87_get_depth(const x87_state *state)
+{
return state->depth;
}
-#if 0
-/**
- * Check if the state is empty.
- *
- * @param state the x87 state
- *
- * returns non-zero if the x87 stack is empty
- */
-static int x87_state_is_empty(const x87_state *state) {
- return state->depth == 0;
+static st_entry *x87_get_entry(x87_state *const state, int const pos)
+{
+ assert(0 <= pos && pos < state->depth);
+ return &state->st[N_ia32_st_REGS - state->depth + pos];
}
-#endif
/**
* Return the virtual register index at st(pos).
*
* @return the vfp register index that produced the value at st(pos)
*/
-static int x87_get_st_reg(const x87_state *state, int pos) {
- assert(pos < state->depth);
- return state->st[MASK_TOS(state->tos + pos)].reg_idx;
+static int x87_get_st_reg(const x87_state *state, int pos)
+{
+ return x87_get_entry((x87_state*)state, pos)->reg_idx;
}
-/**
- * Return the node at st(pos).
- *
- * @param state the x87 state
- * @param pos a stack position
- *
- * @return the IR node that produced the value at st(pos)
- */
-static ir_node *x87_get_st_node(const x87_state *state, int pos) {
- assert(pos < state->depth);
- return state->st[MASK_TOS(state->tos + pos)].node;
-} /* x87_get_st_node */
-
#ifdef DEBUG_libfirm
/**
* Dump the stack for debugging.
*
* @param state the x87 state
*/
-static void x87_dump_stack(const x87_state *state) {
- int i;
-
- for (i = state->depth - 1; i >= 0; --i) {
- DB((dbg, LEVEL_2, "vf%d(%+F) ", x87_get_st_reg(state, i),
- x87_get_st_node(state, i)));
+static void x87_dump_stack(const x87_state *state)
+{
+ for (int i = state->depth; i-- != 0;) {
+ st_entry const *const entry = x87_get_entry((x87_state*)state, i);
+ DB((dbg, LEVEL_2, "vf%d(%+F) ", entry->reg_idx, entry->node));
}
DB((dbg, LEVEL_2, "<-- TOS\n"));
-} /* x87_dump_stack */
+}
#endif /* DEBUG_libfirm */
/**
* @param node the IR node that produces the value of the vfp register
* @param pos the stack position where the new value should be entered
*/
-static void x87_set_st(x87_state *state, int reg_idx, ir_node *node, int pos) {
- assert(0 < state->depth);
- state->st[MASK_TOS(state->tos + pos)].reg_idx = reg_idx;
- state->st[MASK_TOS(state->tos + pos)].node = node;
+static void x87_set_st(x87_state *state, int reg_idx, ir_node *node, int pos)
+{
+ st_entry *const entry = x87_get_entry(state, pos);
+ entry->reg_idx = reg_idx;
+ entry->node = node;
DB((dbg, LEVEL_2, "After SET_REG: "));
- DEBUG_ONLY(x87_dump_stack(state));
-} /* x87_set_st */
+ DEBUG_ONLY(x87_dump_stack(state);)
+}
/**
* Set the tos virtual register.
* @param reg_idx the vfp register index that should be set
* @param node the IR node that produces the value of the vfp register
*/
-static void x87_set_tos(x87_state *state, int reg_idx, ir_node *node) {
+static void x87_set_tos(x87_state *state, int reg_idx, ir_node *node)
+{
x87_set_st(state, reg_idx, node, 0);
-} /* x87_set_tos */
-
-#if 0
-/**
- * Flush the x87 stack.
- *
- * @param state the x87 state
- */
-static void x87_flush(x87_state *state) {
- state->depth = 0;
- state->tos = 0;
-} /* x87_flush */
-#endif
+}
/**
* Swap st(0) with st(pos).
* @param state the x87 state
* @param pos the stack position to change the tos with
*/
-static void x87_fxch(x87_state *state, int pos) {
- st_entry entry;
- assert(pos < state->depth);
-
- entry = state->st[MASK_TOS(state->tos + pos)];
- state->st[MASK_TOS(state->tos + pos)] = state->st[MASK_TOS(state->tos)];
- state->st[MASK_TOS(state->tos)] = entry;
-
- DB((dbg, LEVEL_2, "After FXCH: ")); DEBUG_ONLY(x87_dump_stack(state));
-} /* x87_fxch */
+static void x87_fxch(x87_state *state, int pos)
+{
+ st_entry *const a = x87_get_entry(state, pos);
+ st_entry *const b = x87_get_entry(state, 0);
+ st_entry const t = *a;
+ *a = *b;
+ *b = t;
+
+ DB((dbg, LEVEL_2, "After FXCH: "));
+ DEBUG_ONLY(x87_dump_stack(state);)
+}
/**
* Convert a virtual register to the stack index.
* @return the stack position where the register is stacked
* or -1 if the virtual register was not found
*/
-static int x87_on_stack(const x87_state *state, int reg_idx) {
- int i, tos = state->tos;
-
- for (i = 0; i < state->depth; ++i)
- if (state->st[MASK_TOS(tos + i)].reg_idx == reg_idx)
+static int x87_on_stack(const x87_state *state, int reg_idx)
+{
+ for (int i = 0; i < state->depth; ++i) {
+ if (x87_get_st_reg(state, i) == reg_idx)
return i;
+ }
return -1;
-} /* x87_on_stack */
+}
/**
* Push a virtual Register onto the stack, double pushed allowed.
* @param reg_idx the register vfp index
* @param node the node that produces the value of the vfp register
*/
-static void x87_push_dbl(x87_state *state, int reg_idx, ir_node *node) {
- assert(state->depth < N_x87_REGS && "stack overrun");
+static void x87_push_dbl(x87_state *state, int reg_idx, ir_node *node)
+{
+ assert(state->depth < N_ia32_st_REGS && "stack overrun");
++state->depth;
- state->tos = MASK_TOS(state->tos - 1);
- state->st[state->tos].reg_idx = reg_idx;
- state->st[state->tos].node = node;
+ st_entry *const entry = x87_get_entry(state, 0);
+ entry->reg_idx = reg_idx;
+ entry->node = node;
- DB((dbg, LEVEL_2, "After PUSH: ")); DEBUG_ONLY(x87_dump_stack(state));
-} /* x87_push_dbl */
+ DB((dbg, LEVEL_2, "After PUSH: ")); DEBUG_ONLY(x87_dump_stack(state);)
+}
/**
- * Push a virtual Register onto the stack, double pushes are NOT allowed..
+ * Push a virtual Register onto the stack, double pushes are NOT allowed.
*
* @param state the x87 state
* @param reg_idx the register vfp index
* @param node the node that produces the value of the vfp register
- * @param dbl_push if != 0 double pushes are allowed
*/
-static void x87_push(x87_state *state, int reg_idx, ir_node *node) {
+static void x87_push(x87_state *state, int reg_idx, ir_node *node)
+{
assert(x87_on_stack(state, reg_idx) == -1 && "double push");
x87_push_dbl(state, reg_idx, node);
-} /* x87_push */
+}
/**
* Pop a virtual Register from the stack.
+ *
+ * @param state the x87 state
*/
-static void x87_pop(x87_state *state) {
+static void x87_pop(x87_state *state)
+{
assert(state->depth > 0 && "stack underrun");
--state->depth;
- state->tos = MASK_TOS(state->tos + 1);
- DB((dbg, LEVEL_2, "After POP: ")); DEBUG_ONLY(x87_dump_stack(state));
-} /* x87_pop */
+ DB((dbg, LEVEL_2, "After POP: ")); DEBUG_ONLY(x87_dump_stack(state);)
+}
/**
- * Returns the block state of a block.
- *
- * @param sim the x87 simulator handle
- * @param block the current block
+ * Empty the fpu stack
*
- * @return the block state
+ * @param state the x87 state
*/
-static blk_state *x87_get_bl_state(x87_simulator *sim, ir_node *block) {
- pmap_entry *entry = pmap_find(sim->blk_states, block);
-
- if (! entry) {
- blk_state *bl_state = obstack_alloc(&sim->obst, sizeof(*bl_state));
- bl_state->begin = NULL;
- bl_state->end = NULL;
-
- pmap_insert(sim->blk_states, block, bl_state);
- return bl_state;
- }
-
- return PTR_TO_BLKSTATE(entry->value);
-} /* x87_get_bl_state */
+static void x87_emms(x87_state *state)
+{
+ state->depth = 0;
+}
/**
- * Creates a new x87 state.
+ * Returns the block state of a block.
*
* @param sim the x87 simulator handle
+ * @param block the current block
*
- * @return a new x87 state
+ * @return the block state
*/
-static x87_state *x87_alloc_state(x87_simulator *sim) {
- x87_state *res = obstack_alloc(&sim->obst, sizeof(*res));
+static blk_state *x87_get_bl_state(x87_simulator *sim, ir_node *block)
+{
+ blk_state *res = pmap_get(blk_state, sim->blk_states, block);
- res->sim = sim;
- return res;
-} /* x87_alloc_state */
+ if (res == NULL) {
+ res = OALLOC(&sim->obst, blk_state);
+ res->begin = NULL;
+ res->end = NULL;
-#if 0
-/**
- * Create a new empty x87 state.
- *
- * @param sim the x87 simulator handle
- *
- * @return a new empty x87 state
- */
-static x87_state *x87_alloc_empty_state(x87_simulator *sim) {
- x87_state *res = x87_alloc_state(sim);
+ pmap_insert(sim->blk_states, block, res);
+ }
- x87_flush(res);
return res;
-} /* x87_alloc_empty_state */
-#endif
+}
/**
* Clone a x87 state.
*
* @return a cloned copy of the src state
*/
-static x87_state *x87_clone_state(x87_simulator *sim, const x87_state *src) {
- x87_state *res = x87_alloc_state(sim);
-
- memcpy(res, src, sizeof(*res));
+static x87_state *x87_clone_state(x87_simulator *sim, const x87_state *src)
+{
+ x87_state *const res = OALLOC(&sim->obst, x87_state);
+ *res = *src;
return res;
-} /* x87_clone_state */
+}
/**
* Patch a virtual instruction into a x87 one and return
- * the value node.
+ * the node representing the result value.
*
* @param n the IR node to patch
* @param op the x87 opcode to patch in
*/
-static ir_node *x87_patch_insn(ir_node *n, ir_op *op) {
+static ir_node *x87_patch_insn(ir_node *n, ir_op *op)
+{
ir_mode *mode = get_irn_mode(n);
ir_node *res = n;
if (mode == mode_T) {
/* patch all Proj's */
- const ir_edge_t *edge;
-
foreach_out_edge(n, edge) {
ir_node *proj = get_edge_src_irn(edge);
if (is_Proj(proj)) {
mode = get_irn_mode(proj);
if (mode_is_float(mode)) {
res = proj;
- set_irn_mode(proj, mode_E);
+ set_irn_mode(proj, ia32_reg_classes[CLASS_ia32_st].mode);
}
}
}
- }
- else if (mode_is_float(mode))
- set_irn_mode(n, mode_E);
+ } else if (mode_is_float(mode))
+ set_irn_mode(n, ia32_reg_classes[CLASS_ia32_st].mode);
return res;
-} /* x87_patch_insn */
+}
/**
* Returns the first Proj of a mode_T node having a given mode.
* @param m the desired mode of the Proj
* @return The first Proj of mode @p m found or NULL.
*/
-static ir_node *get_irn_Proj_for_mode(ir_node *n, ir_mode *m) {
- const ir_edge_t *edge;
-
+static ir_node *get_irn_Proj_for_mode(ir_node *n, ir_mode *m)
+{
assert(get_irn_mode(n) == mode_T && "Need mode_T node");
foreach_out_edge(n, edge) {
}
return NULL;
-} /* get_irn_Proj_for_mode */
+}
/**
* Wrap the arch_* function here so we can check for errors.
*/
-static INLINE const arch_register_t *x87_get_irn_register(x87_simulator *sim, const ir_node *irn) {
- const arch_register_t *res;
+static inline const arch_register_t *x87_get_irn_register(const ir_node *irn)
+{
+ const arch_register_t *res = arch_get_irn_register(irn);
- res = arch_get_irn_register(sim->arch_env, irn);
- assert(res->reg_class->regs == ia32_vfp_regs);
+ assert(res->reg_class == &ia32_reg_classes[CLASS_ia32_vfp]);
return res;
}
-/* -------------- x87 perm --------------- */
+static inline const arch_register_t *x87_irn_get_register(const ir_node *irn,
+ int pos)
+{
+ const arch_register_t *res = arch_get_irn_register_out(irn, pos);
+
+ assert(res->reg_class == &ia32_reg_classes[CLASS_ia32_vfp]);
+ return res;
+}
+
+static inline const arch_register_t *get_st_reg(int index)
+{
+ return &ia32_registers[REG_ST0 + index];
+}
/**
- * Creates a fxch for shuffle.
- *
- * @param state the x87 state
- * @param pos parameter for fxch
- * @param block the block were fxch is inserted
+ * Create a fxch node before another node.
*
- * Creates a new fxch node and reroute the user of the old node
- * to the fxch.
+ * @param state the x87 state
+ * @param n the node after the fxch
+ * @param pos exchange st(pos) with st(0)
*
- * @return the fxch node
+ * @return the fxch
*/
-static ir_node *x87_fxch_shuffle(x87_state *state, int pos, ir_node *block)
+static ir_node *x87_create_fxch(x87_state *state, ir_node *n, int pos)
{
- ir_node *fxch;
- ia32_attr_t *attr;
+ x87_fxch(state, pos);
- fxch = new_rd_ia32_fxch(NULL, get_irn_irg(block), block, mode_E);
- attr = get_ia32_attr(fxch);
- attr->x87[0] = &ia32_st_regs[pos];
- attr->x87[2] = &ia32_st_regs[0];
+ ir_node *const block = get_nodes_block(n);
+ ir_node *const fxch = new_bd_ia32_fxch(NULL, block);
+ ia32_x87_attr_t *const attr = get_ia32_x87_attr(fxch);
+ attr->x87[0] = get_st_reg(pos);
+ attr->x87[2] = get_st_reg(0);
keep_alive(fxch);
- x87_fxch(state, pos);
+ sched_add_before(n, fxch);
+ DB((dbg, LEVEL_1, "<<< %s %s, %s\n", get_irn_opname(fxch), attr->x87[0]->name, attr->x87[2]->name));
return fxch;
-} /* x87_fxch_shuffle */
+}
+
+/* -------------- x87 perm --------------- */
/**
* Calculate the necessary permutations to reach dst_state.
* Note that critical edges are removed here, so we need only
* a shuffle if the current block has only one successor.
*
- * @param sim the simulator handle
* @param block the current block
* @param state the current x87 stack state, might be modified
- * @param dst_block the destination block
* @param dst_state destination state
*
* @return state
*/
-static x87_state *x87_shuffle(x87_simulator *sim, ir_node *block, x87_state *state, ir_node *dst_block, const x87_state *dst_state) {
+static x87_state *x87_shuffle(ir_node *block, x87_state *state, const x87_state *dst_state)
+{
int i, n_cycles, k, ri;
unsigned cycles[4], all_mask;
char cycle_idx[4][8];
- ir_node *fxch, *before, *after;
assert(state->depth == dst_state->depth);
/* Some mathematics here:
- If we have a cycle of length n that includes the tos,
- we need n-1 exchange operations.
- We can always add the tos and restore it, so we need
- n+1 exchange operations for a cycle not containing the tos.
- So, the maximum of needed operations is for a cycle of 7
- not including the tos == 8.
- This is the same number of ops we would need for using stores,
- so exchange is cheaper (we save the loads).
- On the other hand, we might need an additional exchange
- in the next block to bring one operand on top, so the
- number of ops in the first case is identical.
- Further, no more than 4 cycles can exists (4 x 2).
- */
+ * If we have a cycle of length n that includes the tos,
+ * we need n-1 exchange operations.
+ * We can always add the tos and restore it, so we need
+ * n+1 exchange operations for a cycle not containing the tos.
+ * So, the maximum of needed operations is for a cycle of 7
+ * not including the tos == 8.
+ * This is the same number of ops we would need for using stores,
+ * so exchange is cheaper (we save the loads).
+ * On the other hand, we might need an additional exchange
+ * in the next block to bring one operand on top, so the
+ * number of ops in the first case is identical.
+ * Further, no more than 4 cycles can exists (4 x 2). */
all_mask = (1 << (state->depth)) - 1;
for (n_cycles = 0; all_mask; ++n_cycles) {
/* Hmm: permutation needed */
DB((dbg, LEVEL_2, "\n%+F needs permutation: from\n", block));
- DEBUG_ONLY(x87_dump_stack(state));
+ DEBUG_ONLY(x87_dump_stack(state);)
DB((dbg, LEVEL_2, " to\n"));
- DEBUG_ONLY(x87_dump_stack(dst_state));
+ DEBUG_ONLY(x87_dump_stack(dst_state);)
#ifdef DEBUG_libfirm
}
#endif
- after = NULL;
-
/*
* Find the place node must be insert.
* We have only one successor block, so the last instruction should
* be a jump.
*/
- before = sched_last(block);
+ ir_node *const before = sched_last(block);
assert(is_cfop(before));
/* now do the permutations */
for (ri = 0; ri < n_cycles; ++ri) {
if ((cycles[ri] & 1) == 0) {
/* this cycle does not include the tos */
- fxch = x87_fxch_shuffle(state, cycle_idx[ri][0], block);
- if (after)
- sched_add_after(after, fxch);
- else
- sched_add_before(before, fxch);
- after = fxch;
+ x87_create_fxch(state, before, cycle_idx[ri][0]);
}
for (k = 1; cycle_idx[ri][k] != -1; ++k) {
- fxch = x87_fxch_shuffle(state, cycle_idx[ri][k], block);
- if (after)
- sched_add_after(after, fxch);
- else
- sched_add_before(before, fxch);
- after = fxch;
+ x87_create_fxch(state, before, cycle_idx[ri][k]);
}
if ((cycles[ri] & 1) == 0) {
/* this cycle does not include the tos */
- fxch = x87_fxch_shuffle(state, cycle_idx[ri][0], block);
- sched_add_after(after, fxch);
+ x87_create_fxch(state, before, cycle_idx[ri][0]);
}
}
return state;
-} /* x87_shuffle */
-
-/**
- * Create a fxch node before another node.
- *
- * @param state the x87 state
- * @param n the node after the fxch
- * @param pos exchange st(pos) with st(0)
- * @param op_idx if >= 0, replace input op_idx of n with the fxch result
- *
- * @return the fxch
- */
-static ir_node *x87_create_fxch(x87_state *state, ir_node *n, int pos, int op_idx) {
- ir_node *fxch;
- ia32_attr_t *attr;
- ir_graph *irg = get_irn_irg(n);
- ir_node *block = get_nodes_block(n);
-
- x87_fxch(state, pos);
-
- fxch = new_rd_ia32_fxch(NULL, irg, block, mode_E);
- attr = get_ia32_attr(fxch);
- attr->x87[0] = &ia32_st_regs[pos];
- attr->x87[2] = &ia32_st_regs[0];
-
- keep_alive(fxch);
-
- sched_add_before(n, fxch);
- DB((dbg, LEVEL_1, "<<< %s %s, %s\n", get_irn_opname(fxch), attr->x87[0]->name, attr->x87[2]->name));
- return fxch;
-} /* x87_create_fxch */
+}
/**
* Create a fpush before node n.
* @param state the x87 state
* @param n the node after the fpush
* @param pos push st(pos) on stack
- * @param op_idx replace input op_idx of n with the fpush result
+ * @param val the value to push
*/
-static void x87_create_fpush(x87_state *state, ir_node *n, int pos, int op_idx) {
- ir_node *fpush, *pred = get_irn_n(n, op_idx);
- ia32_attr_t *attr;
- const arch_register_t *out = x87_get_irn_register(state->sim, pred);
-
- x87_push_dbl(state, arch_register_get_index(out), pred);
+static void x87_create_fpush(x87_state *state, ir_node *n, int pos, ir_node *const val)
+{
+ arch_register_t const *const out = x87_get_irn_register(val);
+ x87_push_dbl(state, arch_register_get_index(out), val);
- fpush = new_rd_ia32_fpush(NULL, get_irn_irg(n), get_nodes_block(n), mode_E);
- attr = get_ia32_attr(fpush);
- attr->x87[0] = &ia32_st_regs[pos];
- attr->x87[2] = &ia32_st_regs[0];
+ ir_node *const fpush = new_bd_ia32_fpush(NULL, get_nodes_block(n));
+ ia32_x87_attr_t *const attr = get_ia32_x87_attr(fpush);
+ attr->x87[0] = get_st_reg(pos);
+ attr->x87[2] = get_st_reg(0);
keep_alive(fpush);
sched_add_before(n, fpush);
DB((dbg, LEVEL_1, "<<< %s %s, %s\n", get_irn_opname(fpush), attr->x87[0]->name, attr->x87[2]->name));
-} /* x87_create_fpush */
+}
/**
* Create a fpop before node n.
* @param state the x87 state
* @param n the node after the fpop
* @param num pop 1 or 2 values
- * @param pred node to use as predecessor of the fpop
*
* @return the fpop node
*/
-static ir_node *x87_create_fpop(x87_state *state, ir_node *n, int num, ir_node *pred) {
- ir_node *fpop = pred;
- ia32_attr_t *attr;
-
- while (num > 0) {
- keep_alive(pred);
+static ir_node *x87_create_fpop(x87_state *state, ir_node *n, int num)
+{
+ ir_node *fpop = NULL;
+ ia32_x87_attr_t *attr;
+ assert(num > 0);
+ do {
x87_pop(state);
- fpop = new_rd_ia32_fpop(NULL, get_irn_irg(n), get_nodes_block(n), mode_E);
- attr = get_ia32_attr(fpop);
- attr->x87[0] = &ia32_st_regs[0];
- attr->x87[1] = &ia32_st_regs[0];
- attr->x87[2] = &ia32_st_regs[0];
+ if (ia32_cg_config.use_ffreep)
+ fpop = new_bd_ia32_ffreep(NULL, get_nodes_block(n));
+ else
+ fpop = new_bd_ia32_fpop(NULL, get_nodes_block(n));
+ attr = get_ia32_x87_attr(fpop);
+ attr->x87[0] = get_st_reg(0);
+ attr->x87[1] = get_st_reg(0);
+ attr->x87[2] = get_st_reg(0);
keep_alive(fpop);
sched_add_before(n, fpop);
DB((dbg, LEVEL_1, "<<< %s %s\n", get_irn_opname(fpop), attr->x87[0]->name));
-
- pred = fpop;
- --num;
- }
+ } while (--num > 0);
return fpop;
-} /* x87_create_fpop */
-
-/**
- * Creates an fldz before node n
- *
- * @param state the x87 state
- * @param n the node after the fldz
- *
- * @return the fldz node
- */
-static ir_node *x87_create_fldz(x87_state *state, ir_node *n, int regidx) {
- ir_graph *irg = get_irn_irg(n);
- ir_node *block = get_nodes_block(n);
- ir_node *fldz;
-
- fldz = new_rd_ia32_fldz(NULL, irg, block, mode_E);
-
- sched_add_before(n, fldz);
- DB((dbg, LEVEL_1, "<<< %s\n", get_irn_opname(fldz)));
- keep_alive(fldz);
-
- x87_push(state, regidx, fldz);
-
- return fldz;
}
/* --------------------------------- liveness ------------------------------------------ */
* Updates a live set over a single step from a given node to its predecessor.
* Everything defined at the node is removed from the set, the uses of the node get inserted.
*
- * @param sim The simulator handle.
* @param irn The node at which liveness should be computed.
* @param live The bitset of registers live before @p irn. This set gets modified by updating it to
* the registers live after irn.
*
* @return The live bitset.
*/
-static vfp_liveness vfp_liveness_transfer(x87_simulator *sim, ir_node *irn, vfp_liveness live)
+static vfp_liveness vfp_liveness_transfer(ir_node *irn, vfp_liveness live)
{
int i, n;
const arch_register_class_t *cls = &ia32_reg_classes[CLASS_ia32_vfp];
- const arch_env_t *arch_env = sim->arch_env;
- if (arch_irn_consider_in_reg_alloc(arch_env, cls, irn)) {
- const arch_register_t *reg = x87_get_irn_register(sim, irn);
- live &= ~(1 << arch_register_get_index(reg));
+ if (get_irn_mode(irn) == mode_T) {
+ foreach_out_edge(irn, edge) {
+ ir_node *proj = get_edge_src_irn(edge);
+
+ if (arch_irn_consider_in_reg_alloc(cls, proj)) {
+ const arch_register_t *reg = x87_get_irn_register(proj);
+ live &= ~(1 << arch_register_get_index(reg));
+ }
+ }
+ } else if (arch_irn_consider_in_reg_alloc(cls, irn)) {
+ const arch_register_t *reg = x87_get_irn_register(irn);
+ live &= ~(1 << arch_register_get_index(reg));
}
for (i = 0, n = get_irn_arity(irn); i < n; ++i) {
ir_node *op = get_irn_n(irn, i);
- if (mode_is_float(get_irn_mode(op)) && arch_irn_consider_in_reg_alloc(arch_env, cls, op)) {
- const arch_register_t *reg = x87_get_irn_register(sim, op);
+ if (mode_is_float(get_irn_mode(op)) &&
+ arch_irn_consider_in_reg_alloc(cls, op)) {
+ const arch_register_t *reg = x87_get_irn_register(op);
live |= 1 << arch_register_get_index(reg);
}
}
return live;
-} /* vfp_liveness_transfer */
+}
/**
* Put all live virtual registers at the end of a block into a bitset.
*
* @param sim the simulator handle
- * @param lv the liveness information
* @param bl the block
*
* @return The live bitset at the end of this block
*/
static vfp_liveness vfp_liveness_end_of_block(x87_simulator *sim, const ir_node *block)
{
- int i;
vfp_liveness live = 0;
const arch_register_class_t *cls = &ia32_reg_classes[CLASS_ia32_vfp];
- const arch_env_t *arch_env = sim->arch_env;
const be_lv_t *lv = sim->lv;
- be_lv_foreach(lv, block, be_lv_state_end, i) {
+ be_lv_foreach(lv, block, be_lv_state_end, node) {
const arch_register_t *reg;
- const ir_node *node = be_lv_get_irn(lv, block, i);
- if (!arch_irn_consider_in_reg_alloc(arch_env, cls, node))
+ if (!arch_irn_consider_in_reg_alloc(cls, node))
continue;
- reg = x87_get_irn_register(sim, node);
+ reg = x87_get_irn_register(node);
live |= 1 << arch_register_get_index(reg);
}
return live;
-} /* vfp_liveness_end_of_block */
+}
/** get the register mask from an arch_register */
-#define REGMASK(reg) (1 << (arch_register_get_index(reg)))
+#define REGMASK(reg) (1 << (arch_register_get_index(reg)))
/**
* Return a bitset of argument registers which are live at the end of a node.
assert(idx < sim->n_idx);
return sim->live[idx] & ~kill;
-} /* vfp_live_args_after */
+}
/**
* Calculate the liveness for a whole block and cache it.
*
* @param sim the simulator handle
- * @param lv the liveness handle
* @param block the block
*/
-static void update_liveness(x87_simulator *sim, ir_node *block) {
+static void update_liveness(x87_simulator *sim, ir_node *block)
+{
vfp_liveness live = vfp_liveness_end_of_block(sim, block);
unsigned idx;
- ir_node *irn;
/* now iterate through the block backward and cache the results */
sched_foreach_reverse(block, irn) {
idx = get_irn_idx(irn);
sim->live[idx] = live;
- live = vfp_liveness_transfer(sim, irn, live);
+ live = vfp_liveness_transfer(irn, live);
}
idx = get_irn_idx(block);
sim->live[idx] = live;
-} /* update_liveness */
+}
/**
* Returns true if a register is live in a set.
*
* @param live the live bitset
*/
-static void vfp_dump_live(vfp_liveness live) {
+static void vfp_dump_live(vfp_liveness live)
+{
int i;
DB((dbg, LEVEL_2, "Live after: "));
}
}
DB((dbg, LEVEL_2, "\n"));
-} /* vfp_dump_live */
+}
#endif /* DEBUG_libfirm */
/* --------------------------------- simulators ---------------------------------------- */
-#define XCHG(a, b) do { int t = (a); (a) = (b); (b) = t; } while (0)
-
/**
* Simulate a virtual binop.
*
* @param state the x87 state
* @param n the node that should be simulated (and patched)
* @param tmpl the template containing the 4 possible x87 opcodes
+ *
+ * @return NO_NODE_ADDED
*/
-static int sim_binop(x87_state *state, ir_node *n, const exchange_tmpl *tmpl) {
+static int sim_binop(x87_state *state, ir_node *n, const exchange_tmpl *tmpl)
+{
int op2_idx = 0, op1_idx;
int out_idx, do_pop = 0;
- ia32_attr_t *attr;
+ ia32_x87_attr_t *attr;
+ int permuted;
ir_node *patched_insn;
ir_op *dst;
- x87_simulator *sim = state->sim;
- const arch_register_t *op1 = x87_get_irn_register(sim, get_irn_n(n, BINOP_IDX_1));
- const arch_register_t *op2 = x87_get_irn_register(sim, get_irn_n(n, BINOP_IDX_2));
- const arch_register_t *out = x87_get_irn_register(sim, n);
- int reg_index_1 = arch_register_get_index(op1);
- int reg_index_2 = arch_register_get_index(op2);
- vfp_liveness live = vfp_live_args_after(sim, n, REGMASK(out));
+ x87_simulator *sim = state->sim;
+ ir_node *op1 = get_irn_n(n, n_ia32_binary_left);
+ ir_node *op2 = get_irn_n(n, n_ia32_binary_right);
+ const arch_register_t *op1_reg = x87_get_irn_register(op1);
+ const arch_register_t *op2_reg = x87_get_irn_register(op2);
+ const arch_register_t *out = x87_irn_get_register(n, pn_ia32_res);
+ int reg_index_1 = arch_register_get_index(op1_reg);
+ int reg_index_2 = arch_register_get_index(op2_reg);
+ vfp_liveness live = vfp_live_args_after(sim, n, REGMASK(out));
+ int op1_live_after;
+ int op2_live_after;
DB((dbg, LEVEL_1, ">>> %+F %s, %s -> %s\n", n,
- arch_register_get_name(op1), arch_register_get_name(op2),
+ arch_register_get_name(op1_reg), arch_register_get_name(op2_reg),
arch_register_get_name(out)));
- DEBUG_ONLY(vfp_dump_live(live));
+ DEBUG_ONLY(vfp_dump_live(live);)
DB((dbg, LEVEL_1, "Stack before: "));
- DEBUG_ONLY(x87_dump_stack(state));
+ DEBUG_ONLY(x87_dump_stack(state);)
op1_idx = x87_on_stack(state, reg_index_1);
assert(op1_idx >= 0);
+ op1_live_after = is_vfp_live(reg_index_1, live);
+
+ attr = get_ia32_x87_attr(n);
+ permuted = attr->attr.data.ins_permuted;
+
+ if (reg_index_2 != REG_VFP_VFP_NOREG) {
+ assert(!permuted);
- if (reg_index_2 != REG_VFP_NOREG) {
/* second operand is a vfp register */
op2_idx = x87_on_stack(state, reg_index_2);
assert(op2_idx >= 0);
+ op2_live_after = is_vfp_live(reg_index_2, live);
- if (is_vfp_live(arch_register_get_index(op2), live)) {
+ if (op2_live_after) {
/* Second operand is live. */
- if (is_vfp_live(arch_register_get_index(op1), live)) {
+ if (op1_live_after) {
/* Both operands are live: push the first one.
This works even for op1 == op2. */
- x87_create_fpush(state, n, op1_idx, BINOP_IDX_2);
+ x87_create_fpush(state, n, op1_idx, op2);
/* now do fxxx (tos=tos X op) */
op1_idx = 0;
op2_idx += 1;
} else {
/* Second live, first operand is dead here, bring it to tos. */
if (op1_idx != 0) {
- x87_create_fxch(state, n, op1_idx, BINOP_IDX_1);
+ x87_create_fxch(state, n, op1_idx);
if (op2_idx == 0)
op2_idx = op1_idx;
op1_idx = 0;
}
} else {
/* Second operand is dead. */
- if (is_vfp_live(arch_register_get_index(op1), live)) {
+ if (op1_live_after) {
/* First operand is live: bring second to tos. */
if (op2_idx != 0) {
- x87_create_fxch(state, n, op2_idx, BINOP_IDX_2);
+ x87_create_fxch(state, n, op2_idx);
if (op1_idx == 0)
op1_idx = op2_idx;
op2_idx = 0;
out_idx = op2_idx;
} else {
/* Bring the second on top. */
- x87_create_fxch(state, n, op2_idx, BINOP_IDX_2);
+ x87_create_fxch(state, n, op2_idx);
if (op1_idx == op2_idx) {
/* Both are identically and on tos now, no pop needed. */
op1_idx = 0;
}
} else {
/* second operand is an address mode */
- if (is_vfp_live(arch_register_get_index(op1), live)) {
+ if (op1_live_after) {
/* first operand is live: push it here */
- x87_create_fpush(state, n, op1_idx, BINOP_IDX_1);
+ x87_create_fpush(state, n, op1_idx, op1);
op1_idx = 0;
- /* use fxxx (tos = tos X mem) */
- dst = tmpl->normal_op;
- out_idx = 0;
} else {
/* first operand is dead: bring it to tos */
if (op1_idx != 0) {
- x87_create_fxch(state, n, op1_idx, BINOP_IDX_1);
+ x87_create_fxch(state, n, op1_idx);
op1_idx = 0;
}
-
- /* use fxxxp (tos = tos X mem) */
- dst = tmpl->normal_op;
- out_idx = 0;
}
+
+ /* use fxxx (tos = tos X mem) */
+ dst = permuted ? tmpl->reverse_op : tmpl->normal_op;
+ out_idx = 0;
}
patched_insn = x87_patch_insn(n, dst);
}
/* patch the operation */
- attr = get_ia32_attr(n);
- attr->x87[0] = op1 = &ia32_st_regs[op1_idx];
- if (reg_index_2 != REG_VFP_NOREG) {
- attr->x87[1] = op2 = &ia32_st_regs[op2_idx];
+ attr->x87[0] = op1_reg = get_st_reg(op1_idx);
+ if (reg_index_2 != REG_VFP_VFP_NOREG) {
+ attr->x87[1] = op2_reg = get_st_reg(op2_idx);
}
- attr->x87[2] = out = &ia32_st_regs[out_idx];
+ attr->x87[2] = out = get_st_reg(out_idx);
- if (reg_index_2 != REG_VFP_NOREG) {
+ if (reg_index_2 != REG_VFP_VFP_NOREG) {
DB((dbg, LEVEL_1, "<<< %s %s, %s -> %s\n", get_irn_opname(n),
- arch_register_get_name(op1), arch_register_get_name(op2),
+ arch_register_get_name(op1_reg), arch_register_get_name(op2_reg),
arch_register_get_name(out)));
} else {
DB((dbg, LEVEL_1, "<<< %s %s, [AM] -> %s\n", get_irn_opname(n),
- arch_register_get_name(op1),
+ arch_register_get_name(op1_reg),
arch_register_get_name(out)));
}
- return 0;
-} /* sim_binop */
+ return NO_NODE_ADDED;
+}
/**
* Simulate a virtual Unop.
* @param state the x87 state
* @param n the node that should be simulated (and patched)
* @param op the x87 opcode that will replace n's opcode
+ *
+ * @return NO_NODE_ADDED
*/
-static int sim_unop(x87_state *state, ir_node *n, ir_op *op) {
- int op1_idx, out_idx;
- x87_simulator *sim = state->sim;
- const arch_register_t *op1 = x87_get_irn_register(sim, get_irn_n(n, UNOP_IDX));
- const arch_register_t *out = x87_get_irn_register(sim, n);
- ia32_attr_t *attr;
- unsigned live = vfp_live_args_after(sim, n, REGMASK(out));
-
+static int sim_unop(x87_state *state, ir_node *n, ir_op *op)
+{
+ arch_register_t const *const out = x87_get_irn_register(n);
+ unsigned const live = vfp_live_args_after(state->sim, n, REGMASK(out));
DB((dbg, LEVEL_1, ">>> %+F -> %s\n", n, out->name));
- DEBUG_ONLY(vfp_dump_live(live));
-
- op1_idx = x87_on_stack(state, arch_register_get_index(op1));
+ DEBUG_ONLY(vfp_dump_live(live);)
- if (is_vfp_live(arch_register_get_index(op1), live)) {
+ ir_node *const op1 = get_irn_n(n, 0);
+ arch_register_t const *const op1_reg = x87_get_irn_register(op1);
+ int const op1_reg_idx = arch_register_get_index(op1_reg);
+ int const op1_idx = x87_on_stack(state, op1_reg_idx);
+ if (is_vfp_live(op1_reg_idx, live)) {
/* push the operand here */
- x87_create_fpush(state, n, op1_idx, UNOP_IDX);
- op1_idx = 0;
- }
- else {
+ x87_create_fpush(state, n, op1_idx, op1);
+ } else {
/* operand is dead, bring it to tos */
if (op1_idx != 0) {
- x87_create_fxch(state, n, op1_idx, UNOP_IDX);
- op1_idx = 0;
+ x87_create_fxch(state, n, op1_idx);
}
}
x87_set_tos(state, arch_register_get_index(out), x87_patch_insn(n, op));
- out_idx = 0;
- attr = get_ia32_attr(n);
- attr->x87[0] = op1 = &ia32_st_regs[0];
- attr->x87[2] = out = &ia32_st_regs[0];
- DB((dbg, LEVEL_1, "<<< %s -> %s\n", get_irn_opname(n), out->name));
+ ia32_x87_attr_t *const attr = get_ia32_x87_attr(n);
+ attr->x87[2] = attr->x87[0] = get_st_reg(0);
+ DB((dbg, LEVEL_1, "<<< %s -> %s\n", get_irn_opname(n), attr->x87[2]->name));
- return 0;
-} /* sim_unop */
+ return NO_NODE_ADDED;
+}
/**
* Simulate a virtual Load instruction.
* @param state the x87 state
* @param n the node that should be simulated (and patched)
* @param op the x87 opcode that will replace n's opcode
+ *
+ * @return NO_NODE_ADDED
*/
-static int sim_load(x87_state *state, ir_node *n, ir_op *op) {
- const arch_register_t *out = x87_get_irn_register(state->sim, n);
- ia32_attr_t *attr;
+static int sim_load(x87_state *state, ir_node *n, ir_op *op, int res_pos)
+{
+ const arch_register_t *out = x87_irn_get_register(n, res_pos);
+ ia32_x87_attr_t *attr;
DB((dbg, LEVEL_1, ">>> %+F -> %s\n", n, arch_register_get_name(out)));
x87_push(state, arch_register_get_index(out), x87_patch_insn(n, op));
- assert(out == x87_get_irn_register(state->sim, n));
- attr = get_ia32_attr(n);
- attr->x87[2] = out = &ia32_st_regs[0];
+ assert(out == x87_irn_get_register(n, res_pos));
+ attr = get_ia32_x87_attr(n);
+ attr->x87[2] = out = get_st_reg(0);
DB((dbg, LEVEL_1, "<<< %s -> %s\n", get_irn_opname(n), arch_register_get_name(out)));
- return 0;
-} /* sim_load */
+ return NO_NODE_ADDED;
+}
/**
* Rewire all users of @p old_val to @new_val iff they are scheduled after @p store.
* @param old_val The former value
* @param new_val The new value
*/
-static void collect_and_rewire_users(ir_node *store, ir_node *old_val, ir_node *new_val) {
- const ir_edge_t *edge, *ne;
-
- foreach_out_edge_safe(old_val, edge, ne) {
+static void collect_and_rewire_users(ir_node *store, ir_node *old_val, ir_node *new_val)
+{
+ foreach_out_edge_safe(old_val, edge) {
ir_node *user = get_edge_src_irn(edge);
if (! user || user == store)
}
}
}
-} /* collect_and_rewire_users */
+}
/**
* Simulate a virtual Store.
* @param op the x87 store opcode
* @param op_p the x87 store and pop opcode
*/
-static int sim_store(x87_state *state, ir_node *n, ir_op *op, ir_op *op_p) {
- x87_simulator *sim = state->sim;
- ir_node *val = get_irn_n(n, STORE_VAL_IDX);
- const arch_register_t *op2 = x87_get_irn_register(sim, val);
- unsigned live = vfp_live_args_after(sim, n, 0);
- int insn = 0;
- ia32_attr_t *attr;
- int op2_reg_idx, op2_idx, depth;
- int live_after_node;
- ir_mode *mode;
-
- op2_reg_idx = arch_register_get_index(op2);
- if (op2_reg_idx == REG_VFP_UKNWN) {
- // just take any value from stack
- if(state->depth > 0) {
- op2_idx = 0;
- DEBUG_ONLY(op2 = NULL);
- live_after_node = 1;
- } else {
- // produce a new value which we will consume imediately
- x87_create_fldz(state, n, op2_reg_idx);
- live_after_node = 0;
- op2_idx = x87_on_stack(state, op2_reg_idx);
- assert(op2_idx >= 0);
- }
- } else {
- op2_idx = x87_on_stack(state, op2_reg_idx);
- live_after_node = is_vfp_live(arch_register_get_index(op2), live);
- assert(op2_idx >= 0);
- DB((dbg, LEVEL_1, ">>> %+F %s ->\n", n, arch_register_get_name(op2)));
- }
-
- mode = get_ia32_ls_mode(n);
- depth = x87_get_depth(state);
-
+static int sim_store(x87_state *state, ir_node *n, ir_op *op, ir_op *op_p)
+{
+ ir_node *const val = get_irn_n(n, n_ia32_vfst_val);
+ arch_register_t const *const op2 = x87_get_irn_register(val);
+ DB((dbg, LEVEL_1, ">>> %+F %s ->\n", n, arch_register_get_name(op2)));
+
+ int insn = NO_NODE_ADDED;
+ int const op2_reg_idx = arch_register_get_index(op2);
+ int const op2_idx = x87_on_stack(state, op2_reg_idx);
+ unsigned const live = vfp_live_args_after(state->sim, n, 0);
+ int const live_after_node = is_vfp_live(op2_reg_idx, live);
+ assert(op2_idx >= 0);
if (live_after_node) {
- /*
- Problem: fst doesn't support mode_E (spills), only fstp does
- Solution:
- - stack not full: push value and fstp
- - stack full: fstp value and load again
- */
- if (mode == mode_E) {
- if (depth < N_x87_REGS) {
+ /* Problem: fst doesn't support 80bit modes (spills), only fstp does
+ * fist doesn't support 64bit mode, only fistp
+ * Solution:
+ * - stack not full: push value and fstp
+ * - stack full: fstp value and load again
+ * Note that we cannot test on mode_E, because floats might be 80bit ... */
+ ir_mode *const mode = get_ia32_ls_mode(n);
+ if (get_mode_size_bits(mode) > (mode_is_int(mode) ? 32 : 64)) {
+ if (x87_get_depth(state) < N_ia32_st_REGS) {
/* ok, we have a free register: push + fstp */
- x87_create_fpush(state, n, op2_idx, STORE_VAL_IDX);
+ x87_create_fpush(state, n, op2_idx, val);
x87_pop(state);
x87_patch_insn(n, op_p);
- }
- else {
- ir_node *vfld, *mem, *block, *rproj, *mproj;
- ir_graph *irg;
-
+ } else {
/* stack full here: need fstp + load */
x87_pop(state);
x87_patch_insn(n, op_p);
- block = get_nodes_block(n);
- irg = get_irn_irg(n);
- vfld = new_rd_ia32_vfld(NULL, irg, block, get_irn_n(n, 0), get_irn_n(n, 1), new_rd_NoMem(irg));
+ ir_node *const block = get_nodes_block(n);
+ ir_graph *const irg = get_irn_irg(n);
+ ir_node *const nomem = get_irg_no_mem(irg);
+ ir_node *const vfld = new_bd_ia32_vfld(NULL, block, get_irn_n(n, 0), get_irn_n(n, 1), nomem, mode);
/* copy all attributes */
set_ia32_frame_ent(vfld, get_ia32_frame_ent(n));
if (is_ia32_use_frame(n))
set_ia32_use_frame(vfld);
- set_ia32_am_flavour(vfld, get_ia32_am_flavour(n));
- set_ia32_op_type(vfld, ia32_am_Source);
+ set_ia32_op_type(vfld, ia32_AddrModeS);
add_ia32_am_offs_int(vfld, get_ia32_am_offs_int(n));
set_ia32_am_sc(vfld, get_ia32_am_sc(n));
- set_ia32_ls_mode(vfld, get_ia32_ls_mode(n));
+ set_ia32_ls_mode(vfld, mode);
- rproj = new_r_Proj(irg, block, vfld, get_ia32_ls_mode(vfld), pn_ia32_vfld_res);
- mproj = new_r_Proj(irg, block, vfld, mode_M, pn_ia32_vfld_M);
- mem = get_irn_Proj_for_mode(n, mode_M);
+ ir_node *const rproj = new_r_Proj(vfld, mode, pn_ia32_vfld_res);
+ ir_node *const mproj = new_r_Proj(vfld, mode_M, pn_ia32_vfld_M);
+ ir_node *const mem = get_irn_Proj_for_mode(n, mode_M);
assert(mem && "Store memory not found");
- arch_set_irn_register(sim->arch_env, rproj, op2);
+ arch_set_irn_register(rproj, op2);
/* reroute all former users of the store memory to the load memory */
- edges_reroute(mem, mproj, irg);
+ edges_reroute(mem, mproj);
/* set the memory input of the load to the store memory */
- set_irn_n(vfld, 2, mem);
+ set_irn_n(vfld, n_ia32_vfld_mem, mem);
sched_add_after(n, vfld);
sched_add_after(vfld, rproj);
/* rewire all users, scheduled after the store, to the loaded value */
collect_and_rewire_users(n, val, rproj);
- insn = 1;
+ insn = NODE_ADDED;
}
- }
- else {
+ } else {
/* we can only store the tos to memory */
- if(op2_idx != 0)
- x87_create_fxch(state, n, op2_idx, STORE_VAL_IDX);
+ if (op2_idx != 0)
+ x87_create_fxch(state, n, op2_idx);
- /* mode != mode_E -> use normal fst */
+ /* mode size 64 or smaller -> use normal fst */
x87_patch_insn(n, op);
}
- }
- else {
+ } else {
/* we can only store the tos to memory */
- if(op2_idx != 0)
- x87_create_fxch(state, n, op2_idx, STORE_VAL_IDX);
+ if (op2_idx != 0)
+ x87_create_fxch(state, n, op2_idx);
x87_pop(state);
x87_patch_insn(n, op_p);
}
- attr = get_ia32_attr(n);
- attr->x87[1] = op2 = &ia32_st_regs[0];
- DB((dbg, LEVEL_1, "<<< %s %s ->\n", get_irn_opname(n), arch_register_get_name(op2)));
+ ia32_x87_attr_t *const attr = get_ia32_x87_attr(n);
+ attr->x87[1] = get_st_reg(0);
+ DB((dbg, LEVEL_1, "<<< %s %s ->\n", get_irn_opname(n), arch_register_get_name(attr->x87[1])));
return insn;
-} /* sim_store */
-
-/**
- * Simulate a virtual Phi.
- * Just for cosmetic reasons change the mode of Phi nodes to mode_E.
- *
- * @param state the x87 state
- * @param n the node that should be simulated (and patched)
- * @param arch_env the architecture environment
- */
-static int sim_Phi(x87_state *state, ir_node *n, const arch_env_t *arch_env) {
- ir_mode *mode = get_irn_mode(n);
-
- if (mode_is_float(mode))
- set_irn_mode(n, mode_E);
-
- return 0;
-} /* sim_Phi */
+}
#define _GEN_BINOP(op, rev) \
static int sim_##op(x87_state *state, ir_node *n) { \
}
#define GEN_BINOP(op) _GEN_BINOP(op, op)
-#define GEN_BINOPR(op) _GEN_BINOP(op, op##r)
+#define GEN_BINOPR(op) _GEN_BINOP(op, op##r)
-#define GEN_LOAD2(op, nop) \
-static int sim_##op(x87_state *state, ir_node *n) { \
- return sim_load(state, n, op_ia32_##nop); \
+#define GEN_LOAD(op) \
+static int sim_##op(x87_state *state, ir_node *n) { \
+ return sim_load(state, n, op_ia32_##op, pn_ia32_v##op##_res); \
}
-#define GEN_LOAD(op) GEN_LOAD2(op, op)
-
#define GEN_UNOP(op) \
static int sim_##op(x87_state *state, ir_node *n) { \
return sim_unop(state, n, op_ia32_##op); \
GEN_UNOP(fabs)
GEN_UNOP(fchs)
-GEN_UNOP(fsin)
-GEN_UNOP(fcos)
-GEN_UNOP(fsqrt)
GEN_LOAD(fld)
GEN_LOAD(fild)
GEN_STORE(fist)
/**
- * Simulate a fCondJmp.
+ * Simulate a virtual fisttp.
*
* @param state the x87 state
* @param n the node that should be simulated (and patched)
+ *
+ * @return NO_NODE_ADDED
*/
-static int sim_fCondJmp(x87_state *state, ir_node *n) {
+static int sim_fisttp(x87_state *state, ir_node *n)
+{
+ ir_node *val = get_irn_n(n, n_ia32_vfst_val);
+ const arch_register_t *op2 = x87_get_irn_register(val);
+ ia32_x87_attr_t *attr;
+ int op2_reg_idx, op2_idx;
+
+ op2_reg_idx = arch_register_get_index(op2);
+ op2_idx = x87_on_stack(state, op2_reg_idx);
+ DB((dbg, LEVEL_1, ">>> %+F %s ->\n", n, arch_register_get_name(op2)));
+ assert(op2_idx >= 0);
+
+ /* Note: although the value is still live here, it is destroyed because
+ of the pop. The register allocator is aware of that and introduced a copy
+ if the value must be alive. */
+
+ /* we can only store the tos to memory */
+ if (op2_idx != 0)
+ x87_create_fxch(state, n, op2_idx);
+
+ x87_pop(state);
+ x87_patch_insn(n, op_ia32_fisttp);
+
+ attr = get_ia32_x87_attr(n);
+ attr->x87[1] = op2 = get_st_reg(0);
+ DB((dbg, LEVEL_1, "<<< %s %s ->\n", get_irn_opname(n), arch_register_get_name(op2)));
+
+ return NO_NODE_ADDED;
+}
+
+/**
+ * Simulate a virtual FtstFnstsw.
+ *
+ * @param state the x87 state
+ * @param n the node that should be simulated (and patched)
+ *
+ * @return NO_NODE_ADDED
+ */
+static int sim_FtstFnstsw(x87_state *state, ir_node *n)
+{
+ x87_simulator *sim = state->sim;
+ ia32_x87_attr_t *attr = get_ia32_x87_attr(n);
+ ir_node *op1_node = get_irn_n(n, n_ia32_vFtstFnstsw_left);
+ const arch_register_t *reg1 = x87_get_irn_register(op1_node);
+ int reg_index_1 = arch_register_get_index(reg1);
+ int op1_idx = x87_on_stack(state, reg_index_1);
+ unsigned live = vfp_live_args_after(sim, n, 0);
+
+ DB((dbg, LEVEL_1, ">>> %+F %s\n", n, arch_register_get_name(reg1)));
+ DEBUG_ONLY(vfp_dump_live(live);)
+ DB((dbg, LEVEL_1, "Stack before: "));
+ DEBUG_ONLY(x87_dump_stack(state);)
+ assert(op1_idx >= 0);
+
+ if (op1_idx != 0) {
+ /* bring the value to tos */
+ x87_create_fxch(state, n, op1_idx);
+ op1_idx = 0;
+ }
+
+ /* patch the operation */
+ x87_patch_insn(n, op_ia32_FtstFnstsw);
+ reg1 = get_st_reg(op1_idx);
+ attr->x87[0] = reg1;
+ attr->x87[1] = NULL;
+ attr->x87[2] = NULL;
+
+ if (!is_vfp_live(reg_index_1, live))
+ x87_create_fpop(state, sched_next(n), 1);
+
+ return NO_NODE_ADDED;
+}
+
+/**
+ * Simulate a Fucom
+ *
+ * @param state the x87 state
+ * @param n the node that should be simulated (and patched)
+ *
+ * @return NO_NODE_ADDED
+ */
+static int sim_Fucom(x87_state *state, ir_node *n)
+{
int op1_idx;
int op2_idx = -1;
- int pop_cnt = 0;
- ia32_attr_t *attr;
+ ia32_x87_attr_t *attr = get_ia32_x87_attr(n);
ir_op *dst;
- x87_simulator *sim = state->sim;
- const arch_register_t *op1 = x87_get_irn_register(sim, get_irn_n(n, BINOP_IDX_1));
- const arch_register_t *op2 = x87_get_irn_register(sim, get_irn_n(n, BINOP_IDX_2));
+ x87_simulator *sim = state->sim;
+ ir_node *op1_node = get_irn_n(n, n_ia32_vFucomFnstsw_left);
+ ir_node *op2_node = get_irn_n(n, n_ia32_vFucomFnstsw_right);
+ const arch_register_t *op1 = x87_get_irn_register(op1_node);
+ const arch_register_t *op2 = x87_get_irn_register(op2_node);
int reg_index_1 = arch_register_get_index(op1);
- int reg_index_2 = arch_register_get_index(op2);
- unsigned live = vfp_live_args_after(sim, n, 0);
+ int reg_index_2 = arch_register_get_index(op2);
+ unsigned live = vfp_live_args_after(sim, n, 0);
+ bool permuted = attr->attr.data.ins_permuted;
+ bool xchg = false;
+ int pops = 0;
DB((dbg, LEVEL_1, ">>> %+F %s, %s\n", n,
arch_register_get_name(op1), arch_register_get_name(op2)));
- DEBUG_ONLY(vfp_dump_live(live));
+ DEBUG_ONLY(vfp_dump_live(live);)
DB((dbg, LEVEL_1, "Stack before: "));
- DEBUG_ONLY(x87_dump_stack(state));
+ DEBUG_ONLY(x87_dump_stack(state);)
op1_idx = x87_on_stack(state, reg_index_1);
assert(op1_idx >= 0);
/* BEWARE: check for comp a,a cases, they might happen */
- if (reg_index_2 != REG_VFP_NOREG) {
+ if (reg_index_2 != REG_VFP_VFP_NOREG) {
/* second operand is a vfp register */
op2_idx = x87_on_stack(state, reg_index_2);
assert(op2_idx >= 0);
- if (is_vfp_live(arch_register_get_index(op2), live)) {
+ if (is_vfp_live(reg_index_2, live)) {
/* second operand is live */
- if (is_vfp_live(arch_register_get_index(op1), live)) {
+ if (is_vfp_live(reg_index_1, live)) {
/* both operands are live */
if (op1_idx == 0) {
/* res = tos X op */
- dst = op_ia32_fcomJmp;
} else if (op2_idx == 0) {
/* res = op X tos */
- dst = op_ia32_fcomrJmp;
+ permuted = !permuted;
+ xchg = true;
} else {
/* bring the first one to tos */
- x87_create_fxch(state, n, op1_idx, BINOP_IDX_1);
- if (op2_idx == 0)
+ x87_create_fxch(state, n, op1_idx);
+ if (op1_idx == op2_idx) {
+ op2_idx = 0;
+ } else if (op2_idx == 0) {
op2_idx = op1_idx;
+ }
op1_idx = 0;
/* res = tos X op */
- dst = op_ia32_fcomJmp;
}
} else {
/* second live, first operand is dead here, bring it to tos.
This means further, op1_idx != op2_idx. */
assert(op1_idx != op2_idx);
if (op1_idx != 0) {
- x87_create_fxch(state, n, op1_idx, BINOP_IDX_1);
+ x87_create_fxch(state, n, op1_idx);
if (op2_idx == 0)
op2_idx = op1_idx;
op1_idx = 0;
}
/* res = tos X op, pop */
- dst = op_ia32_fcompJmp;
- pop_cnt = 1;
+ pops = 1;
}
} else {
/* second operand is dead */
- if (is_vfp_live(arch_register_get_index(op1), live)) {
+ if (is_vfp_live(reg_index_1, live)) {
/* first operand is live: bring second to tos.
This means further, op1_idx != op2_idx. */
assert(op1_idx != op2_idx);
if (op2_idx != 0) {
- x87_create_fxch(state, n, op2_idx, BINOP_IDX_2);
+ x87_create_fxch(state, n, op2_idx);
if (op1_idx == 0)
op1_idx = op2_idx;
op2_idx = 0;
}
/* res = op X tos, pop */
- dst = op_ia32_fcomrpJmp;
- pop_cnt = 1;
+ pops = 1;
+ permuted = !permuted;
+ xchg = true;
} else {
/* both operands are dead here, check first for identity. */
if (op1_idx == op2_idx) {
/* identically, one pop needed */
if (op1_idx != 0) {
- x87_create_fxch(state, n, op1_idx, BINOP_IDX_1);
+ x87_create_fxch(state, n, op1_idx);
op1_idx = 0;
op2_idx = 0;
}
/* res = tos X op, pop */
- dst = op_ia32_fcompJmp;
- pop_cnt = 1;
+ pops = 1;
}
/* different, move them to st and st(1) and pop both.
The tricky part is to get one into st(1).*/
/* good, second operand is already in the right place, move the first */
if (op1_idx != 0) {
/* bring the first on top */
- x87_create_fxch(state, n, op1_idx, BINOP_IDX_1);
+ x87_create_fxch(state, n, op1_idx);
assert(op2_idx != 0);
op1_idx = 0;
}
/* res = tos X op, pop, pop */
- dst = op_ia32_fcomppJmp;
- pop_cnt = 2;
+ pops = 2;
} else if (op1_idx == 1) {
/* good, first operand is already in the right place, move the second */
if (op2_idx != 0) {
/* bring the first on top */
- x87_create_fxch(state, n, op2_idx, BINOP_IDX_2);
+ x87_create_fxch(state, n, op2_idx);
assert(op1_idx != 0);
op2_idx = 0;
}
- dst = op_ia32_fcomrppJmp;
- pop_cnt = 2;
+ /* res = op X tos, pop, pop */
+ permuted = !permuted;
+ xchg = true;
+ pops = 2;
} else {
/* if one is already the TOS, we need two fxch */
if (op1_idx == 0) {
/* first one is TOS, move to st(1) */
- x87_create_fxch(state, n, 1, BINOP_IDX_1);
+ x87_create_fxch(state, n, 1);
assert(op2_idx != 1);
op1_idx = 1;
- x87_create_fxch(state, n, op2_idx, BINOP_IDX_2);
+ x87_create_fxch(state, n, op2_idx);
op2_idx = 0;
/* res = op X tos, pop, pop */
- dst = op_ia32_fcomrppJmp;
- pop_cnt = 2;
+ pops = 2;
+ permuted = !permuted;
+ xchg = true;
} else if (op2_idx == 0) {
/* second one is TOS, move to st(1) */
- x87_create_fxch(state, n, 1, BINOP_IDX_2);
+ x87_create_fxch(state, n, 1);
assert(op1_idx != 1);
op2_idx = 1;
- x87_create_fxch(state, n, op1_idx, BINOP_IDX_1);
+ x87_create_fxch(state, n, op1_idx);
op1_idx = 0;
/* res = tos X op, pop, pop */
- dst = op_ia32_fcomppJmp;
- pop_cnt = 2;
+ pops = 2;
} else {
/* none of them is either TOS or st(1), 3 fxch needed */
- x87_create_fxch(state, n, op2_idx, BINOP_IDX_2);
+ x87_create_fxch(state, n, op2_idx);
assert(op1_idx != 0);
- x87_create_fxch(state, n, 1, BINOP_IDX_2);
+ x87_create_fxch(state, n, 1);
op2_idx = 1;
- x87_create_fxch(state, n, op1_idx, BINOP_IDX_1);
+ x87_create_fxch(state, n, op1_idx);
op1_idx = 0;
/* res = tos X op, pop, pop */
- dst = op_ia32_fcomppJmp;
- pop_cnt = 2;
+ pops = 2;
}
}
}
}
} else {
/* second operand is an address mode */
- if (is_vfp_live(arch_register_get_index(op1), live)) {
+ if (is_vfp_live(reg_index_1, live)) {
/* first operand is live: bring it to TOS */
if (op1_idx != 0) {
- x87_create_fxch(state, n, op1_idx, BINOP_IDX_1);
+ x87_create_fxch(state, n, op1_idx);
op1_idx = 0;
}
- dst = op_ia32_fcomJmp;
} else {
/* first operand is dead: bring it to tos */
if (op1_idx != 0) {
- x87_create_fxch(state, n, op1_idx, BINOP_IDX_1);
+ x87_create_fxch(state, n, op1_idx);
op1_idx = 0;
}
- dst = op_ia32_fcompJmp;
- pop_cnt = 1;
+ pops = 1;
}
}
+ /* patch the operation */
+ if (is_ia32_vFucomFnstsw(n)) {
+ int i;
+
+ switch (pops) {
+ case 0: dst = op_ia32_FucomFnstsw; break;
+ case 1: dst = op_ia32_FucompFnstsw; break;
+ case 2: dst = op_ia32_FucomppFnstsw; break;
+ default: panic("invalid popcount");
+ }
+
+ for (i = 0; i < pops; ++i) {
+ x87_pop(state);
+ }
+ } else if (is_ia32_vFucomi(n)) {
+ switch (pops) {
+ case 0: dst = op_ia32_Fucomi; break;
+ case 1: dst = op_ia32_Fucompi; x87_pop(state); break;
+ case 2:
+ dst = op_ia32_Fucompi;
+ x87_pop(state);
+ x87_create_fpop(state, sched_next(n), 1);
+ break;
+ default: panic("invalid popcount");
+ }
+ } else {
+ panic("invalid operation %+F", n);
+ }
+
x87_patch_insn(n, dst);
- assert(pop_cnt < 3);
- if (pop_cnt >= 2)
- x87_pop(state);
- if (pop_cnt >= 1)
- x87_pop(state);
+ if (xchg) {
+ int tmp = op1_idx;
+ op1_idx = op2_idx;
+ op2_idx = tmp;
+ }
- /* patch the operation */
- attr = get_ia32_attr(n);
- op1 = &ia32_st_regs[op1_idx];
+ op1 = get_st_reg(op1_idx);
attr->x87[0] = op1;
if (op2_idx >= 0) {
- op2 = &ia32_st_regs[op2_idx];
+ op2 = get_st_reg(op2_idx);
attr->x87[1] = op2;
}
attr->x87[2] = NULL;
+ attr->attr.data.ins_permuted = permuted;
- if (op2_idx >= 0)
+ if (op2_idx >= 0) {
DB((dbg, LEVEL_1, "<<< %s %s, %s\n", get_irn_opname(n),
arch_register_get_name(op1), arch_register_get_name(op2)));
- else
+ } else {
DB((dbg, LEVEL_1, "<<< %s %s, [AM]\n", get_irn_opname(n),
arch_register_get_name(op1)));
+ }
+
+ return NO_NODE_ADDED;
+}
+
+/**
+ * Simulate a Keep.
+ *
+ * @param state the x87 state
+ * @param n the node that should be simulated (and patched)
+ *
+ * @return NO_NODE_ADDED
+ */
+static int sim_Keep(x87_state *state, ir_node *node)
+{
+ const ir_node *op;
+ const arch_register_t *op_reg;
+ int reg_id;
+ int op_stack_idx;
+ unsigned live;
+ int i, arity;
+
+ DB((dbg, LEVEL_1, ">>> %+F\n", node));
+
+ arity = get_irn_arity(node);
+ for (i = 0; i < arity; ++i) {
+ op = get_irn_n(node, i);
+ op_reg = arch_get_irn_register(op);
+ if (arch_register_get_class(op_reg) != &ia32_reg_classes[CLASS_ia32_vfp])
+ continue;
+
+ reg_id = arch_register_get_index(op_reg);
+ live = vfp_live_args_after(state->sim, node, 0);
- return 0;
-} /* sim_fCondJmp */
+ op_stack_idx = x87_on_stack(state, reg_id);
+ if (op_stack_idx >= 0 && !is_vfp_live(reg_id, live))
+ x87_create_fpop(state, sched_next(node), 1);
+ }
+
+ DB((dbg, LEVEL_1, "Stack after: "));
+ DEBUG_ONLY(x87_dump_stack(state);)
+
+ return NO_NODE_ADDED;
+}
+
+/**
+ * Keep the given node alive by adding a be_Keep.
+ *
+ * @param node the node to kept alive
+ */
+static void keep_float_node_alive(ir_node *node)
+{
+ ir_node *block = get_nodes_block(node);
+ ir_node *keep = be_new_Keep(block, 1, &node);
+
+ assert(sched_is_scheduled(node));
+ sched_add_after(node, keep);
+}
-static ir_node *create_Copy(x87_state *state, ir_node *n) {
- x87_simulator *sim = state->sim;
- ir_graph *irg = get_irn_irg(n);
+/**
+ * Create a copy of a node. Recreate the node if it's a constant.
+ *
+ * @param state the x87 state
+ * @param n the node to be copied
+ *
+ * @return the copy of n
+ */
+static ir_node *create_Copy(x87_state *state, ir_node *n)
+{
dbg_info *n_dbg = get_irn_dbg_info(n);
ir_mode *mode = get_irn_mode(n);
ir_node *block = get_nodes_block(n);
ir_node *pred = get_irn_n(n, 0);
- ir_node *(*cnstr)(dbg_info *, ir_graph *, ir_node *, ir_mode *) = NULL;
+ ir_node *(*cnstr)(dbg_info *, ir_node *, ir_mode *) = NULL;
ir_node *res;
const arch_register_t *out;
const arch_register_t *op1;
- ia32_attr_t *attr;
+ ia32_x87_attr_t *attr;
/* Do not copy constants, recreate them. */
switch (get_ia32_irn_opcode(pred)) {
- case iro_ia32_Unknown_VFP:
case iro_ia32_fldz:
- cnstr = new_rd_ia32_fldz;
+ cnstr = new_bd_ia32_fldz;
break;
case iro_ia32_fld1:
- cnstr = new_rd_ia32_fld1;
+ cnstr = new_bd_ia32_fld1;
break;
case iro_ia32_fldpi:
- cnstr = new_rd_ia32_fldpi;
+ cnstr = new_bd_ia32_fldpi;
break;
case iro_ia32_fldl2e:
- cnstr = new_rd_ia32_fldl2e;
+ cnstr = new_bd_ia32_fldl2e;
break;
case iro_ia32_fldl2t:
- cnstr = new_rd_ia32_fldl2t;
+ cnstr = new_bd_ia32_fldl2t;
break;
case iro_ia32_fldlg2:
- cnstr = new_rd_ia32_fldlg2;
+ cnstr = new_bd_ia32_fldlg2;
break;
case iro_ia32_fldln2:
- cnstr = new_rd_ia32_fldln2;
+ cnstr = new_bd_ia32_fldln2;
+ break;
+ default:
break;
}
- out = x87_get_irn_register(sim, n);
- op1 = x87_get_irn_register(sim, pred);
+ out = x87_get_irn_register(n);
+ op1 = x87_get_irn_register(pred);
- if(cnstr != NULL) {
+ if (cnstr != NULL) {
/* copy a constant */
- res = (*cnstr)(n_dbg, irg, block, mode);
+ res = (*cnstr)(n_dbg, block, mode);
x87_push(state, arch_register_get_index(out), res);
- attr = get_ia32_attr(res);
- attr->x87[2] = out = &ia32_st_regs[0];
+ attr = get_ia32_x87_attr(res);
+ attr->x87[2] = get_st_reg(0);
} else {
int op1_idx = x87_on_stack(state, arch_register_get_index(op1));
- res = new_rd_ia32_fpushCopy(n_dbg, irg, block, pred, mode);
+ res = new_bd_ia32_fpushCopy(n_dbg, block, pred, mode);
x87_push(state, arch_register_get_index(out), res);
- attr = get_ia32_attr(res);
- attr->x87[0] = op1 = &ia32_st_regs[op1_idx];
- attr->x87[2] = out = &ia32_st_regs[0];
+ attr = get_ia32_x87_attr(res);
+ attr->x87[0] = get_st_reg(op1_idx);
+ attr->x87[2] = get_st_reg(0);
}
- arch_set_irn_register(sim->arch_env, res, out);
+ arch_set_irn_register(res, out);
return res;
}
*
* @param state the x87 state
* @param n the node that should be simulated (and patched)
+ *
+ * @return NO_NODE_ADDED
*/
-static int sim_Copy(x87_state *state, ir_node *n) {
- x87_simulator *sim;
- ir_node *pred;
- const arch_register_t *out;
- const arch_register_t *op1;
- ir_node *node, *next;
- ia32_attr_t *attr;
- int op1_idx, out_idx;
- unsigned live;
-
- ir_mode *mode = get_irn_mode(n);
-
- if (!mode_is_float(mode))
- return 0;
+static int sim_Copy(x87_state *state, ir_node *n)
+{
+ arch_register_class_t const *const cls = arch_get_irn_reg_class(n);
+ if (cls != &ia32_reg_classes[CLASS_ia32_vfp])
+ return NO_NODE_ADDED;
- sim = state->sim;
- pred = get_irn_n(n, 0);
- out = x87_get_irn_register(sim, n);
- op1 = x87_get_irn_register(sim, pred);
- live = vfp_live_args_after(sim, n, REGMASK(out));
+ ir_node *const pred = be_get_Copy_op(n);
+ arch_register_t const *const op1 = x87_get_irn_register(pred);
+ arch_register_t const *const out = x87_get_irn_register(n);
+ unsigned const live = vfp_live_args_after(state->sim, n, REGMASK(out));
DB((dbg, LEVEL_1, ">>> %+F %s -> %s\n", n,
arch_register_get_name(op1), arch_register_get_name(out)));
- DEBUG_ONLY(vfp_dump_live(live));
+ DEBUG_ONLY(vfp_dump_live(live);)
- /* handle the infamous unknown value */
- if (arch_register_get_index(op1) == REG_VFP_UKNWN) {
+ if (is_vfp_live(arch_register_get_index(op1), live)) {
/* Operand is still live, a real copy. We need here an fpush that can
hold a a register, so use the fpushCopy or recreate constants */
- node = create_Copy(state, n);
-
- assert(is_ia32_fldz(node));
- next = sched_next(n);
+ ir_node *const node = create_Copy(state, n);
+
+ /* We have to make sure the old value doesn't go dead (which can happen
+ * when we recreate constants). As the simulator expected that value in
+ * the pred blocks. This is unfortunate as removing it would save us 1
+ * instruction, but we would have to rerun all the simulation to get
+ * this correct...
+ */
+ ir_node *const next = sched_next(n);
sched_remove(n);
exchange(n, node);
sched_add_before(next, node);
- DB((dbg, LEVEL_1, "<<< %+F %s -> %s\n", node, op1->name,
- arch_get_irn_register(sim->arch_env, node)->name));
- return 0;
- }
-
- op1_idx = x87_on_stack(state, arch_register_get_index(op1));
-
- if (is_vfp_live(arch_register_get_index(op1), live)) {
- /* Operand is still live, a real copy. We need here an fpush that can
- hold a a register, so use the fpushCopy or recreate constants */
- node = create_Copy(state, n);
+ if (get_irn_n_edges(pred) == 0) {
+ keep_float_node_alive(pred);
+ }
- next = sched_next(n);
- sched_remove(n);
- exchange(n, node);
- sched_add_before(next, node);
- DB((dbg, LEVEL_1, "<<< %+F %s -> %s\n", node, op1->name,
- arch_get_irn_register(sim->arch_env, node)->name));
+ DB((dbg, LEVEL_1, "<<< %+F %s -> ?\n", node, op1->name));
} else {
- out_idx = x87_on_stack(state, arch_register_get_index(out));
-
+ int const op1_idx = x87_on_stack(state, arch_register_get_index(op1));
+ int const out_idx = x87_on_stack(state, arch_register_get_index(out));
if (out_idx >= 0 && out_idx != op1_idx) {
/* Matze: out already on stack? how can this happen? */
- assert(0);
+ panic("invalid stack state");
+#if 0
/* op1 must be killed and placed where out is */
if (out_idx == 0) {
+ ia32_x87_attr_t *attr;
/* best case, simple remove and rename */
x87_patch_insn(n, op_ia32_Pop);
- attr = get_ia32_attr(n);
- attr->x87[0] = op1 = &ia32_st_regs[0];
+ attr = get_ia32_x87_attr(n);
+ attr->x87[0] = op1 = get_st_reg(0);
x87_pop(state);
x87_set_st(state, arch_register_get_index(out), n, op1_idx - 1);
} else {
+ ia32_x87_attr_t *attr;
/* move op1 to tos, store and pop it */
if (op1_idx != 0) {
- x87_create_fxch(state, n, op1_idx, 0);
+ x87_create_fxch(state, n, op1_idx);
op1_idx = 0;
}
x87_patch_insn(n, op_ia32_Pop);
- attr = get_ia32_attr(n);
- attr->x87[0] = op1 = &ia32_st_regs[out_idx];
+ attr = get_ia32_x87_attr(n);
+ attr->x87[0] = op1 = get_st_reg(out_idx);
x87_pop(state);
x87_set_st(state, arch_register_get_index(out), n, out_idx - 1);
}
DB((dbg, LEVEL_1, "<<< %+F %s\n", n, op1->name));
+#endif
} else {
/* just a virtual copy */
- x87_set_st(state, arch_register_get_index(out), get_unop_op(n), op1_idx);
+ x87_set_st(state, arch_register_get_index(out), pred, op1_idx);
+ /* don't remove the node to keep the verifier quiet :),
+ the emitter won't emit any code for the node */
+#if 0
sched_remove(n);
DB((dbg, LEVEL_1, "<<< KILLED %s\n", get_irn_opname(n)));
- exchange(n, get_unop_op(n));
+ exchange(n, pred);
+#endif
}
}
-
- return 0;
-} /* sim_Copy */
+ return NO_NODE_ADDED;
+}
/**
- * Returns the result proj of the call, or NULL if the result is not used
+ * Returns the vf0 result Proj of a Call.
+ *
+ * @para call the Call node
*/
static ir_node *get_call_result_proj(ir_node *call)
{
- const ir_edge_t *edge;
- ir_node *resproj = NULL;
-
/* search the result proj */
foreach_out_edge(call, edge) {
ir_node *proj = get_edge_src_irn(edge);
long pn = get_Proj_proj(proj);
- if(pn == pn_be_Call_first_res) {
- resproj = proj;
- break;
- }
+ if (pn == pn_ia32_Call_vf0)
+ return proj;
}
- if(resproj == NULL) {
- return NULL;
+
+ panic("result Proj missing");
+}
+
+static int sim_Asm(x87_state *const state, ir_node *const n)
+{
+ (void)state;
+
+ for (size_t i = get_irn_arity(n); i-- != 0;) {
+ arch_register_req_t const *const req = arch_get_irn_register_req_in(n, i);
+ if (req->cls == &ia32_reg_classes[CLASS_ia32_vfp])
+ panic("cannot handle %+F with x87 constraints", n);
}
- /* the result proj is connected to a Keep and maybe other nodes */
- foreach_out_edge(resproj, edge) {
- ir_node *pred = get_edge_src_irn(edge);
- if(!be_is_Keep(pred)) {
- return resproj;
- }
+ for (size_t i = arch_get_irn_n_outs(n); i-- != 0;) {
+ arch_register_req_t const *const req = arch_get_irn_register_req_out(n, i);
+ if (req->cls == &ia32_reg_classes[CLASS_ia32_vfp])
+ panic("cannot handle %+F with x87 constraints", n);
}
- /* only be_Keep found, so result is not used */
- return NULL;
+ return NO_NODE_ADDED;
}
/**
- * Simulate a be_Call.
+ * Simulate a ia32_Call.
*
* @param state the x87 state
- * @param n the node that should be simulated
- * @param arch_env the architecture environment
+ * @param n the node that should be simulated (and patched)
+ *
+ * @return NO_NODE_ADDED
*/
-static int sim_Call(x87_state *state, ir_node *n, const arch_env_t *arch_env) {
- ir_type *call_tp = be_Call_get_type(n);
- ir_type *res_type;
- ir_mode *mode;
- ir_node *resproj;
- const arch_register_t *reg;
+static int sim_Call(x87_state *state, ir_node *n)
+{
+ DB((dbg, LEVEL_1, ">>> %+F\n", n));
/* at the begin of a call the x87 state should be empty */
assert(state->depth == 0 && "stack not empty before call");
- if (get_method_n_ress(call_tp) <= 0)
- return 0;
-
- /*
- * If the called function returns a float, it is returned in st(0).
- * This even happens if the return value is NOT used.
- * Moreover, only one return result is supported.
- */
- res_type = get_method_res_type(call_tp, 0);
- mode = get_type_mode(res_type);
-
- if (mode == NULL || !mode_is_float(mode))
- return 0;
-
- resproj = get_call_result_proj(n);
- if (resproj == NULL)
- return 0;
-
- reg = x87_get_irn_register(state->sim, resproj);
- x87_push(state, arch_register_get_index(reg), resproj);
-
- return 0;
-} /* sim_Call */
-
-/**
- * Simulate a be_Spill.
- *
- * @param state the x87 state
- * @param n the node that should be simulated (and patched)
- *
- * Should not happen, spills are lowered before x87 simulator see them.
- */
-static int sim_Spill(x87_state *state, ir_node *n) {
- assert(0 && "Spill not lowered");
- return sim_fst(state, n);
-} /* sim_Spill */
+ ir_type *const call_tp = get_ia32_call_attr_const(n)->call_tp;
+ if (get_method_n_ress(call_tp) != 0) {
+ /* If the called function returns a float, it is returned in st(0).
+ * This even happens if the return value is NOT used.
+ * Moreover, only one return result is supported. */
+ ir_type *const res_type = get_method_res_type(call_tp, 0);
+ ir_mode *const mode = get_type_mode(res_type);
+ if (mode && mode_is_float(mode)) {
+ ir_node *const resproj = get_call_result_proj(n);
+ arch_register_t const *const reg = x87_get_irn_register(resproj);
+ x87_push(state, arch_register_get_index(reg), resproj);
+ }
+ }
+ DB((dbg, LEVEL_1, "Stack after: "));
+ DEBUG_ONLY(x87_dump_stack(state);)
-/**
- * Simulate a be_Reload.
- *
- * @param state the x87 state
- * @param n the node that should be simulated (and patched)
- *
- * Should not happen, reloads are lowered before x87 simulator see them.
- */
-static int sim_Reload(x87_state *state, ir_node *n) {
- assert(0 && "Reload not lowered");
- return sim_fld(state, n);
-} /* sim_Reload */
+ return NO_NODE_ADDED;
+}
/**
* Simulate a be_Return.
*
* @param state the x87 state
* @param n the node that should be simulated (and patched)
+ *
+ * @return NO_NODE_ADDED
*/
-static int sim_Return(x87_state *state, ir_node *n) {
- int n_res = be_Return_get_n_rets(n);
- int i, n_float_res = 0;
-
- /* only floating point return values must resist on stack */
- for (i = 0; i < n_res; ++i) {
- ir_node *res = get_irn_n(n, be_pos_Return_val + i);
-
+static int sim_Return(x87_state *state, ir_node *n)
+{
+#ifdef DEBUG_libfirm
+ /* only floating point return values must reside on stack */
+ int n_float_res = 0;
+ int const n_res = be_Return_get_n_rets(n);
+ for (int i = 0; i < n_res; ++i) {
+ ir_node *const res = get_irn_n(n, n_be_Return_val + i);
if (mode_is_float(get_irn_mode(res)))
++n_float_res;
}
assert(x87_get_depth(state) == n_float_res);
+#endif
/* pop them virtually */
- for (i = n_float_res - 1; i >= 0; --i)
- x87_pop(state);
-
- return 0;
-} /* sim_Return */
-
-typedef struct _perm_data_t {
- const arch_register_t *in;
- const arch_register_t *out;
-} perm_data_t;
+ x87_emms(state);
+ return NO_NODE_ADDED;
+}
/**
* Simulate a be_Perm.
*
* @param state the x87 state
* @param irn the node that should be simulated (and patched)
+ *
+ * @return NO_NODE_ADDED
*/
-static int sim_Perm(x87_state *state, ir_node *irn) {
- int i, n;
- x87_simulator *sim = state->sim;
- ir_node *pred = get_irn_n(irn, 0);
- int *stack_pos;
- const ir_edge_t *edge;
+static int sim_Perm(x87_state *state, ir_node *irn)
+{
+ int i, n;
+ ir_node *pred = get_irn_n(irn, 0);
+ int *stack_pos;
/* handle only floating point Perms */
if (! mode_is_float(get_irn_mode(pred)))
- return 0;
+ return NO_NODE_ADDED;
DB((dbg, LEVEL_1, ">>> %+F\n", irn));
/* collect old stack positions */
for (i = 0; i < n; ++i) {
- const arch_register_t *inreg = x87_get_irn_register(sim, get_irn_n(irn, i));
+ const arch_register_t *inreg = x87_get_irn_register(get_irn_n(irn, i));
int idx = x87_on_stack(state, arch_register_get_index(inreg));
assert(idx >= 0 && "Perm argument not on x87 stack");
/* now do the permutation */
foreach_out_edge(irn, edge) {
ir_node *proj = get_edge_src_irn(edge);
- const arch_register_t *out = x87_get_irn_register(sim, proj);
+ const arch_register_t *out = x87_get_irn_register(proj);
long num = get_Proj_proj(proj);
assert(0 <= num && num < n && "More Proj's than Perm inputs");
}
DB((dbg, LEVEL_1, "<<< %+F\n", irn));
- return 0;
-} /* be_Perm */
+ return NO_NODE_ADDED;
+}
/**
* Kill any dead registers at block start by popping them from the stack.
*
- * @param sim the simulator handle
- * @param block the current block
- * @param start_state the x87 state at the begin of the block
+ * @param sim the simulator handle
+ * @param block the current block
+ * @param state the x87 state at the begin of the block
*/
-static x87_state *x87_kill_deads(x87_simulator *sim, ir_node *block, x87_state *start_state) {
- x87_state *state = start_state;
+static void x87_kill_deads(x87_simulator *const sim, ir_node *const block, x87_state *const state)
+{
ir_node *first_insn = sched_first(block);
ir_node *keep = NULL;
unsigned live = vfp_live_args_after(sim, block, 0);
}
if (kill_mask) {
- /* create a new state, will be changed */
- state = x87_clone_state(sim, state);
-
DB((dbg, LEVEL_1, "Killing deads:\n"));
- DEBUG_ONLY(vfp_dump_live(live));
- DEBUG_ONLY(x87_dump_stack(state));
-
+ DEBUG_ONLY(vfp_dump_live(live);)
+ DEBUG_ONLY(x87_dump_stack(state);)
+
+ if (kill_mask != 0 && live == 0) {
+ /* special case: kill all registers */
+ if (ia32_cg_config.use_femms || ia32_cg_config.use_emms) {
+ if (ia32_cg_config.use_femms) {
+ /* use FEMMS on AMD processors to clear all */
+ keep = new_bd_ia32_femms(NULL, block);
+ } else {
+ /* use EMMS to clear all */
+ keep = new_bd_ia32_emms(NULL, block);
+ }
+ sched_add_before(first_insn, keep);
+ keep_alive(keep);
+ x87_emms(state);
+ return;
+ }
+ }
/* now kill registers */
while (kill_mask) {
/* we can only kill from TOS, so bring them up */
if (keep)
x87_set_st(state, -1, keep, i);
- keep = x87_create_fxch(state, first_insn, i, -1);
+ x87_create_fxch(state, first_insn, i);
}
- else if (! keep)
- keep = x87_get_st_node(state, 0);
if ((kill_mask & 3) == 3) {
/* we can do a double-pop */
depth -= num_pop;
kill_mask >>= num_pop;
- keep = x87_create_fpop(state, first_insn, num_pop, keep);
+ keep = x87_create_fpop(state, first_insn, num_pop);
}
keep_alive(keep);
}
- return state;
-} /* x87_kill_deads */
+}
/**
* Run a simulation and fix all virtual instructions for a block.
*
* @param sim the simulator handle
* @param block the current block
- *
- * @return non-zero if simulation is complete,
- * zero if the simulation must be rerun
*/
-static void x87_simulate_block(x87_simulator *sim, ir_node *block) {
+static void x87_simulate_block(x87_simulator *sim, ir_node *block)
+{
ir_node *n, *next;
blk_state *bl_state = x87_get_bl_state(sim, block);
x87_state *state = bl_state->begin;
- const ir_edge_t *edge;
ir_node *start_block;
assert(state != NULL);
- // already processed?
- if(bl_state->end != NULL)
+ /* already processed? */
+ if (bl_state->end != NULL)
return;
- //update_liveness(sim, block);
-
DB((dbg, LEVEL_1, "Simulate %+F\n", block));
DB((dbg, LEVEL_2, "State at Block begin:\n "));
- DEBUG_ONLY(x87_dump_stack(state));
+ DEBUG_ONLY(x87_dump_stack(state);)
+ /* create a new state, will be changed */
+ state = x87_clone_state(sim, state);
/* at block begin, kill all dead registers */
- state = x87_kill_deads(sim, block, state);
+ x87_kill_deads(sim, block, state);
/* beware, n might change */
for (n = sched_first(block); !sched_is_end(n); n = next) {
sim_func func;
ir_op *op = get_irn_op(n);
+ /*
+ * get the next node to be simulated here.
+ * n might be completely removed from the schedule-
+ */
next = sched_next(n);
- if (op->ops.generic == NULL)
- continue;
-
- func = (sim_func)op->ops.generic;
-
- /* have work to do */
- if (state == bl_state->begin) {
- /* create a new state, will be changed */
- state = x87_clone_state(sim, state);
+ if (op->ops.generic != NULL) {
+ func = (sim_func)op->ops.generic;
+
+ /* simulate it */
+ node_inserted = (*func)(state, n);
+
+ /*
+ * sim_func might have added an additional node after n,
+ * so update next node
+ * beware: n must not be changed by sim_func
+ * (i.e. removed from schedule) in this case
+ */
+ if (node_inserted != NO_NODE_ADDED)
+ next = sched_next(n);
}
-
- /* simulate it */
- node_inserted = (*func)(state, n);
-
- /*
- sim_func might have added additional nodes after n,
- so update next node
- beware: n must not be changed by sim_func
- (i.e. removed from schedule) in this case
- */
- if (node_inserted)
- next = sched_next(n);
}
start_block = get_irg_start_block(get_irn_irg(block));
+ DB((dbg, LEVEL_2, "State at Block end:\n ")); DEBUG_ONLY(x87_dump_stack(state);)
+
/* check if the state must be shuffled */
foreach_block_succ(block, edge) {
ir_node *succ = get_edge_src_irn(edge);
blk_state *succ_state;
- if(succ == start_block)
+ if (succ == start_block)
continue;
succ_state = x87_get_bl_state(sim, succ);
if (succ_state->begin == NULL) {
+ DB((dbg, LEVEL_2, "Set begin state for succ %+F:\n", succ));
+ DEBUG_ONLY(x87_dump_stack(state);)
succ_state->begin = state;
+
waitq_put(sim->worklist, succ);
} else {
+ DB((dbg, LEVEL_2, "succ %+F already has a state, shuffling\n", succ));
/* There is already a begin state for the successor, bad.
Do the necessary permutations.
- Note that critical edges are removed, so this is always possible. */
- x87_shuffle(sim, block, state, succ, succ_state->begin);
+ Note that critical edges are removed, so this is always possible:
+ If the successor has more than one possible input, then it must
+ be the only one.
+ */
+ x87_shuffle(block, state, succ_state->begin);
}
}
bl_state->end = state;
+}
- DB((dbg, LEVEL_2, "State at Block end:\n ")); DEBUG_ONLY(x87_dump_stack(state));
-} /* x87_simulate_block */
+/**
+ * Register a simulator function.
+ *
+ * @param op the opcode to simulate
+ * @param func the simulator function for the opcode
+ */
+static void register_sim(ir_op *op, sim_func func)
+{
+ assert(op->ops.generic == NULL);
+ op->ops.generic = (op_func) func;
+}
/**
* Create a new x87 simulator.
*
* @param sim a simulator handle, will be initialized
* @param irg the current graph
- * @param arch_env the architecture environment
*/
-static void x87_init_simulator(x87_simulator *sim, ir_graph *irg,
- const arch_env_t *arch_env)
+static void x87_init_simulator(x87_simulator *sim, ir_graph *irg)
{
obstack_init(&sim->obst);
sim->blk_states = pmap_create();
- sim->arch_env = arch_env;
sim->n_idx = get_irg_last_idx(irg);
- sim->live = obstack_alloc(&sim->obst, sizeof(*sim->live) * sim->n_idx);
+ sim->live = OALLOCN(&sim->obst, vfp_liveness, sim->n_idx);
DB((dbg, LEVEL_1, "--------------------------------\n"
"x87 Simulator started for %+F\n", irg));
/* set the generic function pointer of instruction we must simulate */
- clear_irp_opcodes_generic_func();
-
-#define ASSOC(op) (op_ ## op)->ops.generic = (op_func)(sim_##op)
-#define ASSOC_IA32(op) (op_ia32_v ## op)->ops.generic = (op_func)(sim_##op)
-#define ASSOC_BE(op) (op_be_ ## op)->ops.generic = (op_func)(sim_##op)
- ASSOC_IA32(fld);
- ASSOC_IA32(fild);
- ASSOC_IA32(fld1);
- ASSOC_IA32(fldz);
- ASSOC_IA32(fadd);
- ASSOC_IA32(fsub);
- ASSOC_IA32(fmul);
- ASSOC_IA32(fdiv);
- ASSOC_IA32(fprem);
- ASSOC_IA32(fabs);
- ASSOC_IA32(fchs);
- ASSOC_IA32(fsin);
- ASSOC_IA32(fcos);
- ASSOC_IA32(fsqrt);
- ASSOC_IA32(fist);
- ASSOC_IA32(fst);
- ASSOC_IA32(fCondJmp);
- ASSOC_BE(Copy);
- ASSOC_BE(Call);
- ASSOC_BE(Spill);
- ASSOC_BE(Reload);
- ASSOC_BE(Return);
- ASSOC_BE(Perm);
- ASSOC(Phi);
-#undef ASSOC_BE
-#undef ASSOC_IA32
-#undef ASSOC
-} /* x87_init_simulator */
+ ir_clear_opcodes_generic_func();
+
+ register_sim(op_ia32_Asm, sim_Asm);
+ register_sim(op_ia32_Call, sim_Call);
+ register_sim(op_ia32_vfld, sim_fld);
+ register_sim(op_ia32_vfild, sim_fild);
+ register_sim(op_ia32_vfld1, sim_fld1);
+ register_sim(op_ia32_vfldz, sim_fldz);
+ register_sim(op_ia32_vfadd, sim_fadd);
+ register_sim(op_ia32_vfsub, sim_fsub);
+ register_sim(op_ia32_vfmul, sim_fmul);
+ register_sim(op_ia32_vfdiv, sim_fdiv);
+ register_sim(op_ia32_vfprem, sim_fprem);
+ register_sim(op_ia32_vfabs, sim_fabs);
+ register_sim(op_ia32_vfchs, sim_fchs);
+ register_sim(op_ia32_vfist, sim_fist);
+ register_sim(op_ia32_vfisttp, sim_fisttp);
+ register_sim(op_ia32_vfst, sim_fst);
+ register_sim(op_ia32_vFtstFnstsw, sim_FtstFnstsw);
+ register_sim(op_ia32_vFucomFnstsw, sim_Fucom);
+ register_sim(op_ia32_vFucomi, sim_Fucom);
+ register_sim(op_be_Copy, sim_Copy);
+ register_sim(op_be_Return, sim_Return);
+ register_sim(op_be_Perm, sim_Perm);
+ register_sim(op_be_Keep, sim_Keep);
+}
/**
* Destroy a x87 simulator.
*
* @param sim the simulator handle
*/
-static void x87_destroy_simulator(x87_simulator *sim) {
+static void x87_destroy_simulator(x87_simulator *sim)
+{
pmap_destroy(sim->blk_states);
obstack_free(&sim->obst, NULL);
DB((dbg, LEVEL_1, "x87 Simulator stopped\n\n"));
-} /* x87_destroy_simulator */
+}
+/**
+ * Pre-block walker: calculate the liveness information for the block
+ * and store it into the sim->live cache.
+ */
static void update_liveness_walker(ir_node *block, void *data)
{
- x87_simulator *sim = data;
+ x87_simulator *sim = (x87_simulator*)data;
update_liveness(sim, block);
}
-/**
+/*
* Run a simulation and fix all virtual instructions for a graph.
- *
- * @param env the architecture environment
- * @param irg the current graph
- *
- * Needs a block-schedule.
+ * Replaces all virtual floating point instructions and registers
+ * by real ones.
*/
-void x87_simulate_graph(const arch_env_t *arch_env, be_irg_t *birg) {
+void ia32_x87_simulate_graph(ir_graph *irg)
+{
+ /* TODO improve code quality (less executed fxch) by using execfreqs */
+
ir_node *block, *start_block;
blk_state *bl_state;
x87_simulator sim;
- ir_graph *irg = birg->irg;
/* create the simulator */
- x87_init_simulator(&sim, irg, arch_env);
+ x87_init_simulator(&sim, irg);
start_block = get_irg_start_block(irg);
- bl_state = x87_get_bl_state(&sim, start_block);
+ bl_state = x87_get_bl_state(&sim, start_block);
/* start with the empty state */
- bl_state->begin = empty;
- empty->sim = ∼
+ empty.sim = ∼
+ bl_state->begin = ∅
sim.worklist = new_waitq();
waitq_put(sim.worklist, start_block);
- be_invalidate_liveness(birg);
- be_assure_liveness(birg);
- sim.lv = birg->lv;
+ be_assure_live_sets(irg);
+ sim.lv = be_get_irg_liveness(irg);
/* Calculate the liveness for all nodes. We must precalculate this info,
* because the simulator adds new nodes (possible before Phi nodes) which
/* iterate */
do {
- block = waitq_get(sim.worklist);
+ block = (ir_node*)waitq_get(sim.worklist);
x87_simulate_block(&sim, block);
- } while (! pdeq_empty(sim.worklist));
+ } while (! waitq_empty(sim.worklist));
/* kill it */
del_waitq(sim.worklist);
x87_destroy_simulator(&sim);
-} /* x87_simulate_graph */
+}
+/* Initializes the x87 simulator. */
void ia32_init_x87(void)
{
FIRM_DBG_REGISTER(dbg, "firm.be.ia32.x87");