/**
* @file
* @brief emit assembler for a backend graph
- * @version $Id$
+ * @author Hannes Rapp, Matthias Braun
*/
#include "config.h"
#include <limits.h>
+#include "bitfiddle.h"
#include "xmalloc.h"
#include "tv.h"
#include "iredges.h"
#include "raw_bitset.h"
#include "dbginfo.h"
#include "heights.h"
-
-#include "../besched.h"
-#include "../beblocksched.h"
-#include "../beirg.h"
-#include "../begnuas.h"
-#include "../be_dbgout.h"
-#include "../benode.h"
-#include "../bestack.h"
+#include "pmap.h"
+#include "execfreq_t.h"
+
+#include "besched.h"
+#include "beblocksched.h"
+#include "beirg.h"
+#include "begnuas.h"
+#include "bedwarf.h"
+#include "benode.h"
+#include "bestack.h"
+#include "bepeephole.h"
#include "sparc_emitter.h"
#include "gen_sparc_emitter.h"
DEBUG_ONLY(static firm_dbg_module_t *dbg = NULL;)
-static ir_heights_t *heights;
-static const ir_node *delay_slot_filler; /**< this node has been choosen to fill
- the next delay slot */
+static ir_heights_t *heights;
+static unsigned *delay_slot_fillers;
+static pmap *delay_slots;
static void sparc_emit_node(const ir_node *node);
+static bool emitting_delay_slot;
/**
- * Returns the register at in position pos.
- */
-static const arch_register_t *get_in_reg(const ir_node *node, int pos)
-{
- ir_node *op;
- const arch_register_t *reg = NULL;
-
- assert(get_irn_arity(node) > pos && "Invalid IN position");
-
- /* The out register of the operator at position pos is the
- in register we need. */
- op = get_irn_n(node, pos);
-
- reg = arch_get_irn_register(op);
-
- assert(reg && "no in register found");
- return reg;
-}
-
-/**
- * Returns the register at out position pos.
+ * indent before instruction. (Adds additional indentation when emitting
+ * delay slots)
*/
-static const arch_register_t *get_out_reg(const ir_node *node, 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(node) != mode_T) {
- reg = arch_get_irn_register(node);
- } else if (is_sparc_irn(node)) {
- reg = arch_irn_get_register(node, pos);
- } else {
- const ir_edge_t *edge;
-
- foreach_out_edge(node, 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(proj);
- break;
- }
- }
- }
-
- assert(reg && "no out register found");
- return reg;
-}
-
-static bool is_valid_immediate(int32_t value)
+static void sparc_emit_indent(void)
{
- return -4096 <= value && value < 4096;
+ be_emit_char('\t');
+ if (emitting_delay_slot)
+ be_emit_char(' ');
}
-void sparc_emit_immediate(const ir_node *node)
+static void sparc_emit_immediate(ir_node const *const node)
{
const sparc_attr_t *attr = get_sparc_attr_const(node);
ir_entity *entity = attr->immediate_value_entity;
if (entity == NULL) {
int32_t value = attr->immediate_value;
- assert(is_valid_immediate(value));
+ assert(sparc_is_value_imm_encodeable(value));
be_emit_irprintf("%d", value);
} else {
- be_emit_cstring("%lo(");
+ if (get_entity_owner(entity) == get_tls_type()) {
+ be_emit_cstring("%tle_lox10(");
+ } else {
+ be_emit_cstring("%lo(");
+ }
be_gas_emit_entity(entity);
if (attr->immediate_value != 0) {
be_emit_irprintf("%+d", attr->immediate_value);
}
}
-void sparc_emit_high_immediate(const ir_node *node)
+static void sparc_emit_high_immediate(ir_node const *node)
{
const sparc_attr_t *attr = get_sparc_attr_const(node);
ir_entity *entity = attr->immediate_value_entity;
- be_emit_cstring("%hi(");
if (entity == NULL) {
uint32_t value = (uint32_t) attr->immediate_value;
- be_emit_irprintf("0x%X", value);
+ be_emit_irprintf("%%hi(0x%X)", value);
} else {
+ if (get_entity_owner(entity) == get_tls_type()) {
+ be_emit_cstring("%tle_hix22(");
+ } else {
+ be_emit_cstring("%hi(");
+ }
be_gas_emit_entity(entity);
if (attr->immediate_value != 0) {
be_emit_irprintf("%+d", attr->immediate_value);
}
+ be_emit_char(')');
}
- be_emit_char(')');
}
-void sparc_emit_source_register(const ir_node *node, int pos)
+static void sparc_emit_source_register(ir_node const *node, int const pos)
{
- const arch_register_t *reg = get_in_reg(node, pos);
+ const arch_register_t *reg = arch_get_irn_register_in(node, pos);
be_emit_char('%');
- be_emit_string(arch_register_get_name(reg));
+ be_emit_string(reg->name);
}
-void sparc_emit_dest_register(const ir_node *node, int pos)
+static void sparc_emit_dest_register(ir_node const *const node, int const pos)
{
- const arch_register_t *reg = get_out_reg(node, pos);
+ const arch_register_t *reg = arch_get_irn_register_out(node, pos);
be_emit_char('%');
- be_emit_string(arch_register_get_name(reg));
-}
-
-/**
- * Emits either a imm or register depending on arity of node
- * @param node
- * @param register no (-1 if no register)
- */
-void sparc_emit_reg_or_imm(const ir_node *node, int pos)
-{
- if (get_irn_arity(node) > pos) {
- // we have reg input
- sparc_emit_source_register(node, pos);
- } else {
- // we have a imm input
- sparc_emit_immediate(node);
- }
-}
-
-static bool is_stack_pointer_relative(const ir_node *node)
-{
- const arch_register_t *sp = &sparc_registers[REG_SP];
- return (is_sparc_St(node) && get_in_reg(node, n_sparc_St_ptr) == sp)
- || (is_sparc_Ld(node) && get_in_reg(node, n_sparc_Ld_ptr) == sp);
+ be_emit_string(reg->name);
}
/**
* emit SP offset
*/
-void sparc_emit_offset(const ir_node *node, int offset_node_pos)
+static void sparc_emit_offset(const ir_node *node, int offset_node_pos)
{
const sparc_load_store_attr_t *attr = get_sparc_load_store_attr_const(node);
sparc_emit_source_register(node, offset_node_pos);
} else if (attr->is_frame_entity) {
int32_t offset = attr->base.immediate_value;
- /* bad hack: the real stack stuff is behind the always-there spill
- * space for the register window and stack */
- if (is_stack_pointer_relative(node))
- offset += SPARC_MIN_STACKSIZE;
if (offset != 0) {
- assert(is_valid_immediate(offset));
+ assert(sparc_is_value_imm_encodeable(offset));
be_emit_irprintf("%+ld", offset);
}
} else if (attr->base.immediate_value != 0
}
}
-void sparc_emit_float_load_store_mode(const ir_node *node)
-{
- const sparc_load_store_attr_t *attr = get_sparc_load_store_attr_const(node);
- ir_mode *mode = attr->load_store_mode;
- int bits = get_mode_size_bits(mode);
-
- assert(mode_is_float(mode));
-
- switch (bits) {
- case 32: return;
- case 64: be_emit_char('d'); return;
- case 128: be_emit_char('q'); return;
- }
- panic("invalid flaot load/store mode %+F", mode);
-}
-
/**
- * Emit load mode char
+ * Emit load mode
*/
-void sparc_emit_load_mode(const ir_node *node)
+static void sparc_emit_load_mode(ir_node const *const node)
{
const sparc_load_store_attr_t *attr = get_sparc_load_store_attr_const(node);
ir_mode *mode = attr->load_store_mode;
int bits = get_mode_size_bits(mode);
bool is_signed = mode_is_signed(mode);
- if (bits == 16) {
- be_emit_string(is_signed ? "sh" : "uh");
- } else if (bits == 8) {
- be_emit_string(is_signed ? "sb" : "ub");
- } else if (bits == 64) {
- be_emit_char('d');
- } else {
- assert(bits == 32);
+ switch (bits) {
+ case 8: be_emit_string(is_signed ? "sb" : "ub"); break;
+ case 16: be_emit_string(is_signed ? "sh" : "uh"); break;
+ case 32: break;
+ case 64: be_emit_char('d'); break;
+ case 128: be_emit_char('q'); break;
+ default: panic("invalid load/store mode %+F", mode);
}
}
/**
* Emit store mode char
*/
-void sparc_emit_store_mode(const ir_node *node)
+static void sparc_emit_store_mode(ir_node const *const node)
{
const sparc_load_store_attr_t *attr = get_sparc_load_store_attr_const(node);
ir_mode *mode = attr->load_store_mode;
int bits = get_mode_size_bits(mode);
- if (bits == 16) {
- be_emit_string("h");
- } else if (bits == 8) {
- be_emit_string("b");
- } else if (bits == 64) {
- be_emit_char('d');
- } else {
- assert(bits == 32);
+ switch (bits) {
+ case 8: be_emit_char('b'); break;
+ case 16: be_emit_char('h'); break;
+ case 32: break;
+ case 64: be_emit_char('d'); break;
+ case 128: be_emit_char('q'); break;
+ default: panic("invalid load/store mode %+F", mode);
}
}
-/**
- * emit integer signed/unsigned prefix char
- */
-void sparc_emit_mode_sign_prefix(const ir_node *node)
-{
- ir_mode *mode = get_irn_mode(node);
- bool is_signed = mode_is_signed(mode);
- be_emit_string(is_signed ? "s" : "u");
-}
-
static void emit_fp_suffix(const ir_mode *mode)
{
- unsigned bits = get_mode_size_bits(mode);
assert(mode_is_float(mode));
-
- if (bits == 32) {
- be_emit_char('s');
- } else if (bits == 64) {
- be_emit_char('d');
- } else if (bits == 128) {
- be_emit_char('q');
- } else {
- panic("invalid FP mode");
+ switch (get_mode_size_bits(mode)) {
+ case 32: be_emit_char('s'); break;
+ case 64: be_emit_char('d'); break;
+ case 128: be_emit_char('q'); break;
+ default: panic("invalid FP mode");
}
}
-void sparc_emit_fp_conv_source(const ir_node *node)
-{
- const sparc_fp_conv_attr_t *attr = get_sparc_fp_conv_attr_const(node);
- emit_fp_suffix(attr->src_mode);
-}
-
-void sparc_emit_fp_conv_destination(const ir_node *node)
-{
- const sparc_fp_conv_attr_t *attr = get_sparc_fp_conv_attr_const(node);
- emit_fp_suffix(attr->dest_mode);
-}
-
-/**
- * emits the FP mode suffix char
- */
-void sparc_emit_fp_mode_suffix(const ir_node *node)
+static void set_jump_target(ir_node *jump, ir_node *target)
{
- const sparc_fp_attr_t *attr = get_sparc_fp_attr_const(node);
- emit_fp_suffix(attr->fp_mode);
+ set_irn_link(jump, target);
}
static ir_node *get_jump_target(const ir_node *jump)
be_gas_emit_block_name(block);
}
+/**
+ * returns true if a sparc_call calls a register and not an immediate
+ */
+static bool is_sparc_reg_call(const ir_node *node)
+{
+ const sparc_attr_t *attr = get_sparc_attr_const(node);
+ return attr->immediate_value_entity == NULL;
+}
+
static int get_sparc_Call_dest_addr_pos(const ir_node *node)
{
+ assert(is_sparc_reg_call(node));
return get_irn_arity(node)-1;
}
{
ir_node *block = get_nodes_block(node);
ir_node *next_block = (ir_node*)get_irn_link(block);
- return get_irn_link(node) == next_block;
+ return get_jump_target(node) == next_block;
}
static bool is_no_instruction(const ir_node *node)
{
/* copies are nops if src_reg == dest_reg */
if (be_is_Copy(node) || be_is_CopyKeep(node)) {
- const arch_register_t *src_reg = get_in_reg(node, 0);
- const arch_register_t *dest_reg = get_out_reg(node, 0);
+ const arch_register_t *src_reg = arch_get_irn_register_in(node, 0);
+ const arch_register_t *dest_reg = arch_get_irn_register_out(node, 0);
if (src_reg == dest_reg)
return true;
static bool has_delay_slot(const ir_node *node)
{
- if (is_sparc_Ba(node) && ba_is_fallthrough(node))
- return false;
+ if (is_sparc_Ba(node)) {
+ return !ba_is_fallthrough(node);
+ }
- return is_sparc_Bicc(node) || is_sparc_fbfcc(node) || is_sparc_Ba(node)
- || is_sparc_SwitchJmp(node) || is_sparc_Call(node)
- || is_sparc_SDiv(node) || is_sparc_UDiv(node)
- || be_is_Return(node);
+ return arch_get_irn_flags(node) & sparc_arch_irn_flag_has_delay_slot;
}
/** returns true if the emitter for this sparc node can produce more than one
if (has_delay_slot(node))
return true;
- return is_sparc_Mulh(node) || is_sparc_SDiv(node) || is_sparc_UDiv(node)
- || be_is_MemPerm(node) || be_is_Perm(node);
+ if (is_sparc_Call(node))
+ return arch_get_irn_flags(node) & sparc_arch_irn_flag_aggregate_return;
+
+ return is_sparc_SMulh(node) || is_sparc_UMulh(node)
+ || is_sparc_SDiv(node) || is_sparc_UDiv(node)
+ || be_is_MemPerm(node) || be_is_Perm(node)
+ || is_sparc_SubSP(node);
}
-/**
- * search for an instruction that can fill the delay slot of @p node
- */
-static const ir_node *pick_delay_slot_for(const ir_node *node)
+static bool uses_reg(const ir_node *node, unsigned reg_index, unsigned width)
{
- const ir_node *check = node;
- const ir_node *schedpoint = node;
- unsigned tries = 0;
- /* currently we don't track which registers are still alive, so we can't
- * pick any other instructions other than the one directly preceding */
- static const unsigned PICK_DELAY_SLOT_MAX_DISTANCE = 1;
+ int arity = get_irn_arity(node);
+ for (int i = 0; i < arity; ++i) {
+ const arch_register_t *in_reg = arch_get_irn_register_in(node, i);
+ const arch_register_req_t *in_req = arch_get_irn_register_req_in(node, i);
+ if (in_reg == NULL)
+ continue;
+ if (reg_index < (unsigned)in_reg->global_index + in_req->width
+ && reg_index + width > in_reg->global_index)
+ return true;
+ }
+ return false;
+}
- assert(has_delay_slot(node));
+static bool writes_reg(const ir_node *node, unsigned reg_index, unsigned width)
+{
+ unsigned n_outs = arch_get_irn_n_outs(node);
+ for (unsigned o = 0; o < n_outs; ++o) {
+ const arch_register_t *out_reg = arch_get_irn_register_out(node, o);
+ if (out_reg == NULL)
+ continue;
+ const arch_register_req_t *out_req = arch_get_irn_register_req_out(node, o);
+ if (reg_index < (unsigned)out_reg->global_index + out_req->width
+ && reg_index + width > out_reg->global_index)
+ return true;
+ }
+ return false;
+}
- if (is_sparc_Call(node)) {
- const sparc_attr_t *attr = get_sparc_attr_const(node);
- ir_entity *entity = attr->immediate_value_entity;
- if (entity != NULL) {
- check = NULL; /* pick any instruction, dependencies on Call
- don't matter */
- } else {
- /* we only need to check the value for the call destination */
- check = get_irn_n(node, get_sparc_Call_dest_addr_pos(node));
+static bool is_legal_delay_slot_filler(const ir_node *node)
+{
+ if (is_no_instruction(node))
+ return false;
+ if (emits_multiple_instructions(node))
+ return false;
+ if (rbitset_is_set(delay_slot_fillers, get_irn_idx(node)))
+ return false;
+ return true;
+}
+
+static bool can_move_down_into_delayslot(const ir_node *node, const ir_node *to)
+{
+ if (!is_legal_delay_slot_filler(node))
+ return false;
+
+ if (!be_can_move_down(heights, node, to))
+ return false;
+
+ if (is_sparc_Call(to)) {
+ ir_node *check;
+ /** all inputs are used after the delay slot so, we're fine */
+ if (!is_sparc_reg_call(to))
+ return true;
+
+ check = get_irn_n(to, get_sparc_Call_dest_addr_pos(to));
+ if (skip_Proj(check) == node)
+ return false;
+
+ /* the Call also destroys the value of %o7, but since this is
+ * currently marked as ignore register in the backend, it
+ * should never be used by the instruction in the delay slot. */
+ if (uses_reg(node, REG_O7, 1))
+ return false;
+ return true;
+ } else if (is_sparc_Return(to)) {
+ /* return uses the value of %o7, all other values are not
+ * immediately used */
+ if (writes_reg(node, REG_O7, 1))
+ return false;
+ return true;
+ } else {
+ /* the node must not use our computed values */
+ int arity = get_irn_arity(to);
+ for (int i = 0; i < arity; ++i) {
+ ir_node *in = get_irn_n(to, i);
+ if (skip_Proj(in) == node)
+ return false;
}
+ return true;
+ }
+}
- /* the Call also destroys the value of %o7, but since this is currently
- * marked as ignore register in the backend, it should never be used by
- * the instruction in the delay slot. */
- } else if (be_is_Return(node)) {
- /* we only have to check the jump destination value */
- int arity = get_irn_arity(node);
- int i;
-
- check = NULL;
- for (i = 0; i < arity; ++i) {
- ir_node *in = get_irn_n(node, i);
- const arch_register_t *reg = arch_get_irn_register(in);
- if (reg == &sparc_registers[REG_O7]) {
- check = skip_Proj(in);
- break;
- }
+static bool can_move_up_into_delayslot(const ir_node *node, const ir_node *to)
+{
+ if (!be_can_move_up(heights, node, to))
+ return false;
+
+ /* node must not use any results of 'to' */
+ int arity = get_irn_arity(node);
+ for (int i = 0; i < arity; ++i) {
+ ir_node *in = get_irn_n(node, i);
+ ir_node *skipped = skip_Proj(in);
+ if (skipped == to)
+ return false;
+ }
+
+ /* register window cycling effects at Restore aren't correctly represented
+ * in the graph yet so we need this exception here */
+ if (is_sparc_Restore(node) || is_sparc_RestoreZero(node)) {
+ return false;
+ } else if (is_sparc_Call(to)) {
+ /* node must not overwrite any of the inputs of the call,
+ * (except for the dest_addr) */
+ int dest_addr_pos = is_sparc_reg_call(to)
+ ? get_sparc_Call_dest_addr_pos(to) : -1;
+
+ int call_arity = get_irn_arity(to);
+ for (int i = 0; i < call_arity; ++i) {
+ if (i == dest_addr_pos)
+ continue;
+ const arch_register_t *reg = arch_get_irn_register_in(to, i);
+ if (reg == NULL)
+ continue;
+ const arch_register_req_t *req = arch_get_irn_register_req_in(to, i);
+ if (writes_reg(node, reg->global_index, req->width))
+ return false;
}
- } else {
- check = node;
+
+ /* node must not write to one of the call outputs */
+ unsigned n_call_outs = arch_get_irn_n_outs(to);
+ for (unsigned o = 0; o < n_call_outs; ++o) {
+ const arch_register_t *reg = arch_get_irn_register_out(to, o);
+ if (reg == NULL)
+ continue;
+ const arch_register_req_t *req = arch_get_irn_register_req_out(to, o);
+ if (writes_reg(node, reg->global_index, req->width))
+ return false;
+ }
+ } else if (is_sparc_SDiv(to) || is_sparc_UDiv(to)) {
+ /* node will be inserted between wr and div so it must not overwrite
+ * anything except the wr input */
+ int arity = get_irn_arity(to);
+ for (int i = 0; i < arity; ++i) {
+ assert((long)n_sparc_SDiv_dividend_high == (long)n_sparc_UDiv_dividend_high);
+ if (i == n_sparc_SDiv_dividend_high)
+ continue;
+ const arch_register_t *reg = arch_get_irn_register_in(to, i);
+ if (reg == NULL)
+ continue;
+ const arch_register_req_t *req = arch_get_irn_register_req_in(to, i);
+ if (writes_reg(node, reg->global_index, req->width))
+ return false;
+ }
+}
+ return true;
+}
+
+static void optimize_fallthrough(ir_node *node)
+{
+ ir_node *proj_true = NULL;
+ ir_node *proj_false = NULL;
+
+ assert((long)pn_sparc_Bicc_false == (long)pn_sparc_fbfcc_false);
+ assert((long)pn_sparc_Bicc_true == (long)pn_sparc_fbfcc_true);
+ foreach_out_edge(node, edge) {
+ ir_node *proj = get_edge_src_irn(edge);
+ long nr = get_Proj_proj(proj);
+ if (nr == pn_sparc_Bicc_true) {
+ proj_true = proj;
+ } else {
+ assert(nr == pn_sparc_Bicc_false);
+ proj_false = proj;
+ }
+ }
+ assert(proj_true != NULL && proj_false != NULL);
+
+ /* for now, the code works for scheduled and non-schedules blocks */
+ const ir_node *block = get_nodes_block(node);
+
+ /* we have a block schedule */
+ const ir_node *next_block = (ir_node*)get_irn_link(block);
+
+ if (get_jump_target(proj_true) == next_block) {
+ /* exchange both proj destinations so the second one can be omitted */
+ set_Proj_proj(proj_true, pn_sparc_Bicc_false);
+ set_Proj_proj(proj_false, pn_sparc_Bicc_true);
+
+ sparc_jmp_cond_attr_t *attr = get_sparc_jmp_cond_attr(node);
+ attr->relation = get_negated_relation(attr->relation);
}
+}
+
+/**
+ * search for an instruction that can fill the delay slot of @p node
+ */
+static ir_node *pick_delay_slot_for(ir_node *node)
+{
+ static const unsigned PICK_DELAY_SLOT_MAX_DISTANCE = 10;
+ assert(has_delay_slot(node));
- while (sched_has_prev(schedpoint)) {
- schedpoint = sched_prev(schedpoint);
+ if (is_sparc_Bicc(node) || is_sparc_fbfcc(node)) {
+ optimize_fallthrough(node);
+ }
+ unsigned tries = 0;
+ sched_foreach_reverse_from(sched_prev(node), schedpoint) {
if (has_delay_slot(schedpoint))
break;
+ if (tries++ >= PICK_DELAY_SLOT_MAX_DISTANCE)
+ break;
- /* skip things which don't really result in instructions */
- if (is_no_instruction(schedpoint))
+ if (!can_move_down_into_delayslot(schedpoint, node))
continue;
+ /* found something */
+ return schedpoint;
+ }
+
+ /* search after the current position */
+ tries = 0;
+ sched_foreach_from(sched_next(node), schedpoint) {
+ if (has_delay_slot(schedpoint))
+ break;
if (tries++ >= PICK_DELAY_SLOT_MAX_DISTANCE)
break;
-
- if (emits_multiple_instructions(schedpoint))
+ if (!is_legal_delay_slot_filler(schedpoint))
continue;
-
- /* allowed for delayslot: any instruction which is not necessary to
- * compute an input to the branch. */
- if (check != NULL
- && heights_reachable_in_block(heights, check, schedpoint))
+ if (!can_move_up_into_delayslot(schedpoint, node))
continue;
/* found something */
return schedpoint;
}
+ /* look in successor blocks */
+ ir_node *block = get_nodes_block(node);
+ /* TODO: sort succs by execution frequency */
+ foreach_block_succ(block, edge) {
+ ir_node *succ = get_edge_src_irn(edge);
+ /* we can't easily move up stuff from blocks with multiple predecessors
+ * since the instruction is lacking for the other preds then.
+ * (We also don't have to do any phi translation) */
+ if (get_Block_n_cfgpreds(succ) > 1)
+ continue;
+
+ tries = 0;
+ sched_foreach(succ, schedpoint) {
+ if (has_delay_slot(schedpoint))
+ break;
+ /* can't move pinned nodes accross blocks */
+ if (get_irn_pinned(schedpoint) == op_pin_state_pinned)
+ continue;
+ /* restore doesn't model register window switching correctly,
+ * so it appears like we could move it, which is not true */
+ if (is_sparc_Restore(schedpoint)
+ || is_sparc_RestoreZero(schedpoint))
+ continue;
+ if (tries++ >= PICK_DELAY_SLOT_MAX_DISTANCE)
+ break;
+ if (!is_legal_delay_slot_filler(schedpoint))
+ continue;
+ if (can_move_up_into_delayslot(schedpoint, node)) {
+ /* it's fine to move the insn accross blocks */
+ return schedpoint;
+ } else if (is_sparc_Bicc(node) || is_sparc_fbfcc(node)) {
+ ir_node *proj = get_Block_cfgpred(succ, 0);
+ long nr = get_Proj_proj(proj);
+ if ((nr == pn_sparc_Bicc_true || nr == pn_sparc_fbfcc_true)
+ && be_can_move_up(heights, schedpoint, succ)) {
+ /* we can use it with the annul flag */
+ sparc_jmp_cond_attr_t *attr = get_sparc_jmp_cond_attr(node);
+ attr->annul_delay_slot = true;
+ return schedpoint;
+ }
+ }
+ }
+ }
+
return NULL;
}
+void sparc_emitf(ir_node const *const node, char const *fmt, ...)
+{
+ va_list ap;
+ va_start(ap, fmt);
+ sparc_emit_indent();
+ for (;;) {
+ char const *start = fmt;
+
+ while (*fmt != '%' && *fmt != '\0')
+ ++fmt;
+ be_emit_string_len(start, fmt - start);
+ if (*fmt == '\0')
+ break;
+ ++fmt;
+
+ bool plus = false;
+ if (*fmt == '+') {
+ plus = true;
+ ++fmt;
+ }
+
+ switch (*fmt++) {
+ case '%':
+ be_emit_char('%');
+ break;
+
+ case 'A': {
+ const sparc_jmp_cond_attr_t *attr
+ = get_sparc_jmp_cond_attr_const(node);
+ if (attr->annul_delay_slot) {
+ be_emit_cstring(",a");
+ }
+ break;
+ }
+
+ case 'D':
+ if (*fmt < '0' || '9' <= *fmt)
+ goto unknown;
+ sparc_emit_dest_register(node, *fmt++ - '0');
+ break;
+
+ case 'E': {
+ sparc_attr_t const *const attr = get_sparc_attr_const(node);
+ be_gas_emit_entity(attr->immediate_value_entity);
+ if (attr->immediate_value != 0) {
+ be_emit_irprintf(plus ? "%+d" : "%d", attr->immediate_value);
+ }
+ break;
+ }
+
+ case 'F': {
+ ir_mode *mode;
+ switch (*fmt++) {
+ case 'D': mode = get_sparc_fp_conv_attr_const(node)->dest_mode; break;
+ case 'M': mode = get_sparc_fp_attr_const(node)->fp_mode; break;
+ case 'S': mode = get_sparc_fp_conv_attr_const(node)->src_mode; break;
+ default: goto unknown;
+ }
+ emit_fp_suffix(mode);
+ break;
+ }
+
+ case 'H':
+ sparc_emit_high_immediate(node);
+ break;
+
+ case 'L': {
+ ir_node *n = va_arg(ap, ir_node*);
+ sparc_emit_cfop_target(n);
+ break;
+ }
+
+ case 'M':
+ switch (*fmt++) {
+ case 'L': sparc_emit_load_mode(node); break;
+ case 'S': sparc_emit_store_mode(node); break;
+ default: goto unknown;
+ }
+ break;
+
+ case 'O':
+ if (*fmt < '0' || '9' <= *fmt)
+ goto unknown;
+ sparc_emit_offset(node, *fmt++ - '0');
+ break;
+
+ case 'R': {
+ arch_register_t const *const reg = va_arg(ap, const arch_register_t*);
+ be_emit_char('%');
+ be_emit_string(reg->name);
+ break;
+ }
+
+ case 'S': {
+ bool imm = false;
+ if (*fmt == 'I') {
+ imm = true;
+ ++fmt;
+ }
+ if (*fmt < '0' || '9' <= *fmt)
+ goto unknown;
+ unsigned const pos = *fmt++ - '0';
+ if (imm && arch_get_irn_flags(node) & (arch_irn_flags_t)sparc_arch_irn_flag_immediate_form) {
+ sparc_emit_immediate(node);
+ } else {
+ sparc_emit_source_register(node, pos);
+ }
+ break;
+ }
+
+ case 'd': {
+ int const num = va_arg(ap, int);
+ be_emit_irprintf(plus ? "%+d" : "%d", num);
+ break;
+ }
+
+ case 's': {
+ char const *const str = va_arg(ap, char const*);
+ be_emit_string(str);
+ break;
+ }
+
+ case 'u': {
+ unsigned const num = va_arg(ap, unsigned);
+ be_emit_irprintf(plus ? "%+u" : "%u", num);
+ break;
+ }
+
+ default:
+unknown:
+ panic("unknown format conversion in sparc_emitf()");
+ }
+ }
+ be_emit_finish_line_gas(node);
+ va_end(ap);
+}
+
/**
* Emits code for stack space management
*/
static void emit_be_IncSP(const ir_node *irn)
{
- int offs = -be_get_IncSP_offset(irn);
+ int offset = be_get_IncSP_offset(irn);
- if (offs == 0)
+ if (offset == 0)
return;
/* SPARC stack grows downwards */
- if (offs < 0) {
- be_emit_cstring("\tsub ");
- offs = -offs;
- } else {
- be_emit_cstring("\tadd ");
- }
-
- sparc_emit_source_register(irn, 0);
- be_emit_irprintf(", %d", offs);
- be_emit_cstring(", ");
- sparc_emit_dest_register(irn, 0);
- be_emit_finish_line_gas(irn);
+ char const *const insn = offset > 0 ? offset = -offset, "add" : "sub";
+ sparc_emitf(irn, "%s %S0, %d, %D0", insn, offset);
}
/**
- * emits code for mulh
+ * Emits code for stack space management.
*/
-static void emit_sparc_Mulh(const ir_node *irn)
+static void emit_sparc_SubSP(const ir_node *irn)
{
- be_emit_cstring("\t");
- sparc_emit_mode_sign_prefix(irn);
- be_emit_cstring("mul ");
-
- sparc_emit_source_register(irn, 0);
- be_emit_cstring(", ");
- sparc_emit_reg_or_imm(irn, 1);
- be_emit_cstring(", ");
- sparc_emit_dest_register(irn, 0);
- be_emit_finish_line_gas(irn);
-
- // our result is in the y register now
- // we just copy it to the assigned target reg
- be_emit_cstring("\tmov %y, ");
- sparc_emit_dest_register(irn, 0);
- be_emit_finish_line_gas(irn);
+ sparc_emitf(irn, "sub %S0, %SI1, %D0");
+ sparc_emitf(irn, "add %S0, %u, %D1", SPARC_MIN_STACKSIZE);
}
-static void fill_delay_slot(void)
+static void fill_delay_slot(const ir_node *node)
{
- if (delay_slot_filler != NULL) {
- sparc_emit_node(delay_slot_filler);
- delay_slot_filler = NULL;
+ emitting_delay_slot = true;
+ const ir_node *filler = pmap_get(ir_node, delay_slots, node);
+ if (filler != NULL) {
+ assert(!is_no_instruction(filler));
+ assert(!emits_multiple_instructions(filler));
+ sparc_emit_node(filler);
} else {
- be_emit_cstring("\tnop\n");
- be_emit_write_line();
+ sparc_emitf(NULL, "nop");
}
+ emitting_delay_slot = false;
}
-static void emit_sparc_Div(const ir_node *node, bool is_signed)
+static void emit_sparc_Div(const ir_node *node, char const *const insn)
{
- /* can we get the delay count of the wr instruction somewhere? */
- unsigned wry_delay_count = 3;
- unsigned i;
-
- be_emit_cstring("\twr ");
- sparc_emit_source_register(node, 0);
- be_emit_cstring(", 0, %y");
- be_emit_finish_line_gas(node);
+ sparc_emitf(node, "wr %S0, 0, %%y");
- for (i = 0; i < wry_delay_count; ++i) {
- fill_delay_slot();
+ /* TODO: we should specify number of delayslots in an architecture
+ * specification */
+ unsigned wry_delay_count = 3;
+ for (unsigned i = 0; i < wry_delay_count; ++i) {
+ if (i == 0) {
+ fill_delay_slot(node);
+ } else {
+ emitting_delay_slot = true;
+ sparc_emitf(NULL, "nop");
+ emitting_delay_slot = false;
+ }
}
- be_emit_irprintf("\t%s ", is_signed ? "sdiv" : "udiv");
- sparc_emit_source_register(node, 1);
- be_emit_cstring(", ");
- sparc_emit_reg_or_imm(node, 2);
- be_emit_cstring(", ");
- sparc_emit_dest_register(node, 0);
- be_emit_finish_line_gas(node);
+ sparc_emitf(node, "%s %S1, %SI2, %D0", insn);
}
static void emit_sparc_SDiv(const ir_node *node)
{
- emit_sparc_Div(node, true);
+ emit_sparc_Div(node, "sdiv");
}
static void emit_sparc_UDiv(const ir_node *node)
{
- emit_sparc_Div(node, false);
+ emit_sparc_Div(node, "udiv");
}
-/**
- * Emits code for Call node
- */
static void emit_sparc_Call(const ir_node *node)
{
- const sparc_attr_t *attr = get_sparc_attr_const(node);
- ir_entity *entity = attr->immediate_value_entity;
+ if (is_sparc_reg_call(node)) {
+ int dest_addr = get_sparc_Call_dest_addr_pos(node);
+ sparc_emitf(node, "call %R", arch_get_irn_register_in(node, dest_addr));
+ } else {
+ sparc_emitf(node, "call %E, 0");
+ }
- be_emit_cstring("\tcall ");
- if (entity != NULL) {
- be_gas_emit_entity(entity);
- if (attr->immediate_value != 0) {
- be_emit_irprintf("%+d", attr->immediate_value);
+ fill_delay_slot(node);
+
+ if (arch_get_irn_flags(node) & sparc_arch_irn_flag_aggregate_return) {
+ sparc_emitf(NULL, "unimp 8");
+ }
+}
+
+static void emit_be_Perm(const ir_node *irn)
+{
+ ir_mode *mode = get_irn_mode(get_irn_n(irn, 0));
+ if (mode_is_float(mode)) {
+ const arch_register_t *reg0 = arch_get_irn_register_in(irn, 0);
+ const arch_register_t *reg1 = arch_get_irn_register_in(irn, 1);
+ unsigned reg_idx0 = reg0->global_index;
+ unsigned reg_idx1 = reg1->global_index;
+ unsigned width = arch_get_irn_register_req_in(irn, 0)->width;
+ for (unsigned i = 0; i < width; ++i) {
+ const arch_register_t *r0 = &sparc_registers[reg_idx0+i];
+ const arch_register_t *r1 = &sparc_registers[reg_idx1+i];
+ sparc_emitf(irn, "fmovs %R, %%f31", r0);
+ sparc_emitf(irn, "fmovs %R, %R", r1, r0);
+ sparc_emitf(irn, "fmovs %%f31, %R", r1);
}
- be_emit_cstring(", 0");
} else {
- int dest_addr = get_sparc_Call_dest_addr_pos(node);
- sparc_emit_source_register(node, dest_addr);
+ sparc_emitf(irn, "xor %S1, %S0, %S0");
+ sparc_emitf(irn, "xor %S1, %S0, %S1");
+ sparc_emitf(irn, "xor %S1, %S0, %S0");
}
- be_emit_finish_line_gas(node);
+}
- fill_delay_slot();
+/* The stack pointer must always be SPARC_STACK_ALIGNMENT bytes aligned, so get
+ * the next bigger integer that's evenly divisible by it. */
+static unsigned get_aligned_sp_change(const unsigned num_regs)
+{
+ const unsigned bytes = num_regs * SPARC_REGISTER_SIZE;
+ return round_up2(bytes, SPARC_STACK_ALIGNMENT);
}
-/**
- * Emit code for Perm node
- */
-static void emit_be_Perm(const ir_node *irn)
+/* Spill register l0 or both l0 and l1, depending on n_spilled and n_to_spill.*/
+static void memperm_emit_spill_registers(const ir_node *node, int n_spilled,
+ int n_to_spill)
{
- be_emit_cstring("\txor ");
- sparc_emit_source_register(irn, 1);
- be_emit_cstring(", ");
- sparc_emit_source_register(irn, 0);
- be_emit_cstring(", ");
- sparc_emit_source_register(irn, 0);
- be_emit_finish_line_gas(NULL);
-
- be_emit_cstring("\txor ");
- sparc_emit_source_register(irn, 1);
- be_emit_cstring(", ");
- sparc_emit_source_register(irn, 0);
- be_emit_cstring(", ");
- sparc_emit_source_register(irn, 1);
- be_emit_finish_line_gas(NULL);
-
- be_emit_cstring("\txor ");
- sparc_emit_source_register(irn, 1);
- be_emit_cstring(", ");
- sparc_emit_source_register(irn, 0);
- be_emit_cstring(", ");
- sparc_emit_source_register(irn, 0);
- be_emit_finish_line_gas(irn);
+ assert(n_spilled < n_to_spill);
+
+ if (n_spilled == 0) {
+ /* We always reserve stack space for two registers because during copy
+ * processing we don't know yet if we also need to handle a cycle which
+ * needs two registers. More complicated code in emit_MemPerm would
+ * prevent wasting SPARC_REGISTER_SIZE bytes of stack space but
+ * it is not worth the worse readability of emit_MemPerm. */
+
+ /* Keep stack pointer aligned. */
+ unsigned sp_change = get_aligned_sp_change(2);
+ sparc_emitf(node, "sub %%sp, %u, %%sp", sp_change);
+
+ /* Spill register l0. */
+ sparc_emitf(node, "st %%l0, [%%sp%+d]", SPARC_MIN_STACKSIZE);
+ }
+
+ if (n_to_spill == 2) {
+ /* Spill register l1. */
+ sparc_emitf(node, "st %%l1, [%%sp%+d]", SPARC_MIN_STACKSIZE + SPARC_REGISTER_SIZE);
+ }
+}
+
+/* Restore register l0 or both l0 and l1, depending on n_spilled. */
+static void memperm_emit_restore_registers(const ir_node *node, int n_spilled)
+{
+ if (n_spilled == 2) {
+ /* Restore register l1. */
+ sparc_emitf(node, "ld [%%sp%+d], %%l1", SPARC_MIN_STACKSIZE + SPARC_REGISTER_SIZE);
+ }
+
+ /* Restore register l0. */
+ sparc_emitf(node, "ld [%%sp%+d], %%l0", SPARC_MIN_STACKSIZE);
+
+ /* Restore stack pointer. */
+ unsigned sp_change = get_aligned_sp_change(2);
+ sparc_emitf(node, "add %%sp, %u, %%sp", sp_change);
+}
+
+/* Emit code to copy in_ent to out_ent. Only uses l0. */
+static void memperm_emit_copy(const ir_node *node, ir_entity *in_ent,
+ ir_entity *out_ent)
+{
+ ir_graph *irg = get_irn_irg(node);
+ be_stack_layout_t *layout = be_get_irg_stack_layout(irg);
+ int off_in = be_get_stack_entity_offset(layout, in_ent, 0);
+ int off_out = be_get_stack_entity_offset(layout, out_ent, 0);
+
+ /* Load from input entity. */
+ sparc_emitf(node, "ld [%%fp%+d], %%l0", off_in);
+ /* Store to output entity. */
+ sparc_emitf(node, "st %%l0, [%%fp%+d]", off_out);
}
+/* Emit code to swap ent1 and ent2. Uses l0 and l1. */
+static void memperm_emit_swap(const ir_node *node, ir_entity *ent1,
+ ir_entity *ent2)
+{
+ ir_graph *irg = get_irn_irg(node);
+ be_stack_layout_t *layout = be_get_irg_stack_layout(irg);
+ int off1 = be_get_stack_entity_offset(layout, ent1, 0);
+ int off2 = be_get_stack_entity_offset(layout, ent2, 0);
+
+ /* Load from first input entity. */
+ sparc_emitf(node, "ld [%%fp%+d], %%l0", off1);
+ /* Load from second input entity. */
+ sparc_emitf(node, "ld [%%fp%+d], %%l1", off2);
+ /* Store first value to second output entity. */
+ sparc_emitf(node, "st %%l0, [%%fp%+d]", off2);
+ /* Store second value to first output entity. */
+ sparc_emitf(node, "st %%l1, [%%fp%+d]", off1);
+}
+
+/* Find the index of ent in ents or return -1 if not found. */
+static int get_index(ir_entity **ents, int n, ir_entity *ent)
+{
+ for (int i = 0; i < n; ++i) {
+ if (ents[i] == ent)
+ return i;
+ }
+
+ return -1;
+}
+
+/*
+ * Emit code for a MemPerm node.
+ *
+ * Analyze MemPerm for copy chains and cyclic swaps and resolve them using
+ * loads and stores.
+ * This function is conceptually very similar to permute_values in
+ * beprefalloc.c.
+ */
static void emit_be_MemPerm(const ir_node *node)
{
- int i;
- int memperm_arity;
- int sp_change = 0;
+ int memperm_arity = be_get_MemPerm_entity_arity(node);
+ /* Upper limit for the number of participating entities is twice the
+ * arity, e.g., for a simple copying MemPerm node with one input/output. */
+ int max_size = 2 * memperm_arity;
+ ir_entity **entities = ALLOCANZ(ir_entity *, max_size);
+ /* sourceof contains the input entity for each entity. If an entity is
+ * never used as an output, its entry in sourceof is a fix point. */
+ int *sourceof = ALLOCANZ(int, max_size);
+ /* n_users counts how many output entities use this entity as their input.*/
+ int *n_users = ALLOCANZ(int, max_size);
+ /* n_spilled records the number of spilled registers, either 1 or 2. */
+ int n_spilled = 0;
+
+ /* This implementation currently only works with frame pointers. */
ir_graph *irg = get_irn_irg(node);
be_stack_layout_t *layout = be_get_irg_stack_layout(irg);
+ assert(!layout->sp_relative && "MemPerms currently do not work without frame pointers");
- /* this implementation only works with frame pointers currently */
- assert(layout->sp_relative == false);
+ for (int i = 0; i < max_size; ++i) {
+ sourceof[i] = i;
+ }
- /* TODO: this implementation is slower than necessary.
- The longterm goal is however to avoid the memperm node completely */
+ int n = 0;
+ for (int i = 0; i < memperm_arity; ++i) {
+ ir_entity *out = be_get_MemPerm_out_entity(node, i);
+ ir_entity *in = be_get_MemPerm_in_entity(node, i);
- memperm_arity = be_get_MemPerm_entity_arity(node);
- // we use our local registers - so this is limited to 8 inputs !
- if (memperm_arity > 8)
- panic("memperm with more than 8 inputs not supported yet");
+ /* Insert into entities to be able to operate on unique indices. */
+ if (get_index(entities, n, out) == -1)
+ entities[n++] = out;
+ if (get_index(entities, n, in) == -1)
+ entities[n++] = in;
- be_emit_irprintf("\tsub %%sp, %d, %%sp", memperm_arity*4);
- be_emit_finish_line_gas(node);
+ int oidx = get_index(entities, n, out);
+ int iidx = get_index(entities, n, in);
+
+ sourceof[oidx] = iidx; /* Remember the source. */
+ ++n_users[iidx]; /* Increment number of users of this entity. */
+ }
+
+ /* First do all the copies. */
+ for (int oidx = 0; oidx < n; /* empty */) {
+ int iidx = sourceof[oidx];
+
+ /* Nothing to do for fix points.
+ * Also, if entities[oidx] is used as an input by another copy, we
+ * can't overwrite entities[oidx] yet.*/
+ if (iidx == oidx || n_users[oidx] > 0) {
+ ++oidx;
+ continue;
+ }
+
+ /* We found the end of a 'chain', so do the copy. */
+ if (n_spilled == 0) {
+ memperm_emit_spill_registers(node, n_spilled, /*n_to_spill=*/1);
+ n_spilled = 1;
+ }
+ memperm_emit_copy(node, entities[iidx], entities[oidx]);
- for (i = 0; i < memperm_arity; ++i) {
- ir_entity *entity = be_get_MemPerm_in_entity(node, i);
- int offset = be_get_stack_entity_offset(layout, entity, 0);
+ /* Mark as done. */
+ sourceof[oidx] = oidx;
- /* spill register */
- be_emit_irprintf("\tst %%l%d, [%%sp%+d]", i, sp_change + SPARC_MIN_STACKSIZE);
- be_emit_finish_line_gas(node);
+ assert(n_users[iidx] > 0);
+ /* Decrementing the number of users might enable us to do another
+ * copy. */
+ --n_users[iidx];
- /* load from entity */
- be_emit_irprintf("\tld [%%fp%+d], %%l%d", offset, i);
- be_emit_finish_line_gas(node);
- sp_change += 4;
+ if (iidx < oidx && n_users[iidx] == 0) {
+ oidx = iidx;
+ } else {
+ ++oidx;
+ }
}
- for (i = memperm_arity-1; i >= 0; --i) {
- ir_entity *entity = be_get_MemPerm_out_entity(node, i);
- int offset = be_get_stack_entity_offset(layout, entity, 0);
+ /* The rest are cycles. */
+ for (int oidx = 0; oidx < n; /* empty */) {
+ int iidx = sourceof[oidx];
- sp_change -= 4;
+ /* Nothing to do for fix points. */
+ if (iidx == oidx) {
+ ++oidx;
+ continue;
+ }
+
+ assert(n_users[iidx] == 1);
+
+ /* Swap the two values to resolve the cycle. */
+ if (n_spilled < 2) {
+ memperm_emit_spill_registers(node, n_spilled, /*n_to_spill=*/2);
+ n_spilled = 2;
+ }
+ memperm_emit_swap(node, entities[iidx], entities[oidx]);
+
+ int tidx = sourceof[iidx];
+ /* Mark as done. */
+ sourceof[iidx] = iidx;
- /* store to new entity */
- be_emit_irprintf("\tst %%l%d, [%%fp%+d]", i, offset);
- be_emit_finish_line_gas(node);
- /* restore register */
- be_emit_irprintf("\tld [%%sp%+d], %%l%d", sp_change + SPARC_MIN_STACKSIZE, i);
- be_emit_finish_line_gas(node);
+ /* The source of oidx is now the old source of iidx, because we swapped
+ * the two entities. */
+ sourceof[oidx] = tidx;
}
- be_emit_irprintf("\tadd %%sp, %d, %%sp", memperm_arity*4);
- be_emit_finish_line_gas(node);
+#ifdef DEBUG_libfirm
+ /* Only fix points should remain. */
+ for (int i = 0; i < max_size; ++i) {
+ assert(sourceof[i] == i);
+ }
+#endif
+
+ assert(n_spilled > 0 && "Useless MemPerm node");
- assert(sp_change == 0);
+ memperm_emit_restore_registers(node, n_spilled);
}
-static void emit_be_Return(const ir_node *node)
+static void emit_sparc_Return(const ir_node *node)
{
+ ir_graph *irg = get_irn_irg(node);
+ ir_entity *entity = get_irg_entity(irg);
+ ir_type *type = get_entity_type(entity);
+
const char *destreg = "%o7";
/* hack: we don't explicitely model register changes because of the
* restore node. So we have to do it manually here */
- if (delay_slot_filler != NULL &&
- (is_sparc_Restore(delay_slot_filler)
- || is_sparc_RestoreZero(delay_slot_filler))) {
+ const ir_node *delay_slot = pmap_get(ir_node, delay_slots, node);
+ if (delay_slot != NULL &&
+ (is_sparc_Restore(delay_slot) || is_sparc_RestoreZero(delay_slot))) {
destreg = "%i7";
}
- be_emit_cstring("\tjmp ");
- be_emit_string(destreg);
- be_emit_cstring("+8");
- be_emit_finish_line_gas(node);
- fill_delay_slot();
+ char const *const offset = get_method_calling_convention(type) & cc_compound_ret ? "12" : "8";
+ sparc_emitf(node, "jmp %s+%s", destreg, offset);
+ fill_delay_slot(node);
}
-static void emit_sparc_FrameAddr(const ir_node *node)
+static const arch_register_t *map_i_to_o_reg(const arch_register_t *reg)
{
- const sparc_attr_t *attr = get_sparc_attr_const(node);
+ unsigned idx = reg->global_index;
+ if (idx < REG_I0 || idx > REG_I7)
+ return reg;
+ idx += REG_O0 - REG_I0;
+ assert(REG_O0 <= idx && idx <= REG_O7);
+ return &sparc_registers[idx];
+}
- // no need to fix offset as we are adressing via the framepointer
- if (attr->immediate_value >= 0) {
- be_emit_cstring("\tadd ");
- sparc_emit_source_register(node, 0);
- be_emit_cstring(", ");
- be_emit_irprintf("%ld", attr->immediate_value);
- } else {
- be_emit_cstring("\tsub ");
- sparc_emit_source_register(node, 0);
- be_emit_cstring(", ");
- be_emit_irprintf("%ld", -attr->immediate_value);
- }
+static void emit_sparc_Restore(const ir_node *node)
+{
+ const arch_register_t *destreg
+ = arch_get_irn_register_out(node, pn_sparc_Restore_res);
+ sparc_emitf(node, "restore %S2, %SI3, %R", map_i_to_o_reg(destreg));
+}
- be_emit_cstring(", ");
- sparc_emit_dest_register(node, 0);
- be_emit_finish_line_gas(node);
+static void emit_sparc_FrameAddr(const ir_node *node)
+{
+ const sparc_attr_t *attr = get_sparc_attr_const(node);
+ int32_t offset = attr->immediate_value;
+
+ char const *const insn = offset > 0 ? offset = -offset, "sub" : "add";
+ assert(sparc_is_value_imm_encodeable(offset));
+ sparc_emitf(node, "%s %S0, %d, %D0", insn, offset);
}
static const char *get_icc_unsigned(ir_relation relation)
static void emit_sparc_branch(const ir_node *node, get_cc_func get_cc)
{
const sparc_jmp_cond_attr_t *attr = get_sparc_jmp_cond_attr_const(node);
- ir_relation relation = attr->relation;
- const ir_node *proj_true = NULL;
- const ir_node *proj_false = NULL;
- const ir_edge_t *edge;
- const ir_node *block;
- const ir_node *next_block;
+ ir_relation relation = attr->relation;
+ const ir_node *proj_true = NULL;
+ const ir_node *proj_false = NULL;
+ assert((long)pn_sparc_Bicc_false == (long)pn_sparc_fbfcc_false);
+ assert((long)pn_sparc_Bicc_true == (long)pn_sparc_fbfcc_true);
foreach_out_edge(node, edge) {
ir_node *proj = get_edge_src_irn(edge);
long nr = get_Proj_proj(proj);
- if (nr == pn_Cond_true) {
+ if (nr == pn_sparc_Bicc_true) {
proj_true = proj;
} else {
+ assert(nr == pn_sparc_Bicc_false);
proj_false = proj;
}
}
- /* for now, the code works for scheduled and non-schedules blocks */
- block = get_nodes_block(node);
-
- /* we have a block schedule */
- next_block = (ir_node*)get_irn_link(block);
-
- if (get_irn_link(proj_true) == next_block) {
- /* exchange both proj's so the second one can be omitted */
- const ir_node *t = proj_true;
+ /* emit the true proj */
+ sparc_emitf(node, "%s%A %L", get_cc(relation), proj_true);
+ fill_delay_slot(node);
- proj_true = proj_false;
- proj_false = t;
- relation = get_negated_relation(relation);
- }
+ const ir_node *block = get_nodes_block(node);
+ const ir_node *next_block = (ir_node*)get_irn_link(block);
- /* emit the true proj */
- be_emit_cstring("\t");
- be_emit_string(get_cc(relation));
- be_emit_char(' ');
- sparc_emit_cfop_target(proj_true);
- be_emit_finish_line_gas(proj_true);
-
- fill_delay_slot();
-
- if (get_irn_link(proj_false) == next_block) {
- be_emit_cstring("\t/* fallthrough to ");
- sparc_emit_cfop_target(proj_false);
- be_emit_cstring(" */");
- be_emit_finish_line_gas(proj_false);
+ if (get_jump_target(proj_false) == next_block) {
+ if (be_options.verbose_asm) {
+ sparc_emitf(node, "/* fallthrough to %L */", proj_false);
+ }
} else {
- be_emit_cstring("\tba ");
- sparc_emit_cfop_target(proj_false);
- be_emit_finish_line_gas(proj_false);
- fill_delay_slot();
+ sparc_emitf(node, "ba %L", proj_false);
+ /* TODO: fill this slot as well */
+ emitting_delay_slot = true;
+ sparc_emitf(NULL, "nop");
+ emitting_delay_slot = false;
}
}
static void emit_sparc_fbfcc(const ir_node *node)
{
+ /* if the flags producing node was immediately in front of us, emit
+ * a nop */
+ ir_node *flags = get_irn_n(node, n_sparc_fbfcc_flags);
+ ir_node *prev = sched_prev(node);
+ if (is_Block(prev)) {
+ /* TODO: when the flags come from another block, then we have to do
+ * more complicated tests to see wether the flag producing node is
+ * potentially in front of us (could happen for fallthroughs) */
+ panic("TODO: fbfcc flags come from other block");
+ }
+ if (skip_Proj(flags) == prev) {
+ sparc_emitf(NULL, "nop");
+ }
emit_sparc_branch(node, get_fcc);
}
static void emit_sparc_Ba(const ir_node *node)
{
if (ba_is_fallthrough(node)) {
- be_emit_cstring("\t/* fallthrough to ");
- sparc_emit_cfop_target(node);
- be_emit_cstring(" */");
+ if (be_options.verbose_asm) {
+ sparc_emitf(node, "/* fallthrough to %L */", node);
+ }
} else {
- be_emit_cstring("\tba ");
- sparc_emit_cfop_target(node);
- be_emit_finish_line_gas(node);
- fill_delay_slot();
+ sparc_emitf(node, "ba %L", node);
+ fill_delay_slot(node);
}
- be_emit_finish_line_gas(node);
}
-static void emit_jump_table(const ir_node *node)
+static void emit_sparc_SwitchJmp(const ir_node *node)
{
const sparc_switch_jmp_attr_t *attr = get_sparc_switch_jmp_attr_const(node);
- long switch_max = LONG_MIN;
- long default_pn = attr->default_proj_num;
- ir_entity *entity = attr->jump_table;
- ir_node *default_block = NULL;
- unsigned long length;
- const ir_edge_t *edge;
- unsigned i;
- ir_node **table;
-
- /* go over all proj's and collect them */
- foreach_out_edge(node, edge) {
- ir_node *proj = get_edge_src_irn(edge);
- long pn = get_Proj_proj(proj);
-
- /* check for default proj */
- if (pn == default_pn) {
- assert(default_block == NULL); /* more than 1 default_pn? */
- default_block = get_jump_target(proj);
- } else {
- switch_max = pn > switch_max ? pn : switch_max;
- }
- }
- assert(switch_max > LONG_MIN);
-
- length = (unsigned long) switch_max + 1;
- /* the 16000 isn't a real limit of the architecture. But should protect us
- * from seamingly endless compiler runs */
- if (length > 16000) {
- /* switch lowerer should have broken this monster to pieces... */
- panic("too large switch encountered");
- }
-
- table = XMALLOCNZ(ir_node*, length);
- foreach_out_edge(node, edge) {
- ir_node *proj = get_edge_src_irn(edge);
- long pn = get_Proj_proj(proj);
- if (pn == default_pn)
- continue;
- table[pn] = get_jump_target(proj);
- }
-
- /* emit table */
- be_gas_emit_switch_section(GAS_SECTION_RODATA);
- be_emit_cstring("\t.align 4\n");
- be_gas_emit_entity(entity);
- be_emit_cstring(":\n");
- for (i = 0; i < length; ++i) {
- ir_node *block = table[i];
- if (block == NULL)
- block = default_block;
- be_emit_cstring("\t.long ");
- be_gas_emit_block_name(block);
- be_emit_char('\n');
- be_emit_write_line();
- }
- be_gas_emit_switch_section(GAS_SECTION_TEXT);
-
- xfree(table);
-}
-
-static void emit_sparc_SwitchJmp(const ir_node *node)
-{
- be_emit_cstring("\tjmp ");
- sparc_emit_source_register(node, 0);
- be_emit_finish_line_gas(node);
- fill_delay_slot();
+ sparc_emitf(node, "jmp %S0");
+ fill_delay_slot(node);
- emit_jump_table(node);
+ be_emit_jump_table(node, attr->table, attr->table_entity, get_jump_target);
}
static void emit_fmov(const ir_node *node, const arch_register_t *src_reg,
const arch_register_t *dst_reg)
{
- be_emit_cstring("\tfmovs %");
- be_emit_string(arch_register_get_name(src_reg));
- be_emit_cstring(", %");
- be_emit_string(arch_register_get_name(dst_reg));
- be_emit_finish_line_gas(node);
+ sparc_emitf(node, "fmovs %R, %R", src_reg, dst_reg);
}
static const arch_register_t *get_next_fp_reg(const arch_register_t *reg)
{
- unsigned index = reg->global_index;
- assert(reg == &sparc_registers[index]);
- index++;
- assert(index - REG_F0 < N_sparc_fp_REGS);
- return &sparc_registers[index];
+ unsigned idx = reg->global_index;
+ assert(reg == &sparc_registers[idx]);
+ idx++;
+ assert(idx - REG_F0 < N_sparc_fp_REGS);
+ return &sparc_registers[idx];
}
static void emit_be_Copy(const ir_node *node)
{
ir_mode *mode = get_irn_mode(node);
- const arch_register_t *src_reg = get_in_reg(node, 0);
- const arch_register_t *dst_reg = get_out_reg(node, 0);
+ const arch_register_t *src_reg = arch_get_irn_register_in(node, 0);
+ const arch_register_t *dst_reg = arch_get_irn_register_out(node, 0);
if (src_reg == dst_reg)
return;
if (mode_is_float(mode)) {
unsigned bits = get_mode_size_bits(mode);
int n = bits > 32 ? bits > 64 ? 3 : 1 : 0;
- int i;
emit_fmov(node, src_reg, dst_reg);
- for (i = 0; i < n; ++i) {
+ for (int i = 0; i < n; ++i) {
src_reg = get_next_fp_reg(src_reg);
dst_reg = get_next_fp_reg(dst_reg);
emit_fmov(node, src_reg, dst_reg);
}
} else if (mode_is_data(mode)) {
- be_emit_cstring("\tmov ");
- sparc_emit_source_register(node, 0);
- be_emit_cstring(", ");
- sparc_emit_dest_register(node, 0);
- be_emit_finish_line_gas(node);
+ sparc_emitf(node, "mov %S0, %D0");
} else {
- panic("emit_be_Copy: invalid mode");
+ panic("invalid mode");
}
}
static void sparc_register_emitters(void)
{
/* first clear the generic function pointer for all ops */
- clear_irp_opcodes_generic_func();
+ ir_clear_opcodes_generic_func();
/* register all emitter functions defined in spec */
sparc_register_spec_emitters();
set_emitter(op_be_IncSP, emit_be_IncSP);
set_emitter(op_be_MemPerm, emit_be_MemPerm);
set_emitter(op_be_Perm, emit_be_Perm);
- set_emitter(op_be_Return, emit_be_Return);
set_emitter(op_sparc_Ba, emit_sparc_Ba);
set_emitter(op_sparc_Bicc, emit_sparc_Bicc);
set_emitter(op_sparc_Call, emit_sparc_Call);
set_emitter(op_sparc_fbfcc, emit_sparc_fbfcc);
set_emitter(op_sparc_FrameAddr, emit_sparc_FrameAddr);
- set_emitter(op_sparc_Mulh, emit_sparc_Mulh);
+ set_emitter(op_sparc_SubSP, emit_sparc_SubSP);
+ set_emitter(op_sparc_Restore, emit_sparc_Restore);
+ set_emitter(op_sparc_Return, emit_sparc_Return);
set_emitter(op_sparc_SDiv, emit_sparc_SDiv);
set_emitter(op_sparc_SwitchJmp, emit_sparc_SwitchJmp);
set_emitter(op_sparc_UDiv, emit_sparc_UDiv);
/* no need to emit anything for the following nodes */
- set_emitter(op_be_Keep, emit_nothing);
- set_emitter(op_be_Start, emit_nothing);
- set_emitter(op_Phi, emit_nothing);
+ set_emitter(op_be_Keep, emit_nothing);
+ set_emitter(op_sparc_Start, emit_nothing);
+ set_emitter(op_Phi, emit_nothing);
}
/**
if (op->ops.generic) {
emit_func func = (emit_func) op->ops.generic;
- be_dbg_set_dbg_info(get_irn_dbg_info(node));
+ be_dwarf_location(get_irn_dbg_info(node));
(*func) (node);
} else {
panic("No emit handler for node %+F (graph %+F)\n", node,
- current_ir_graph);
+ get_irn_irg(node));
}
}
-static ir_node *find_next_delay_slot(ir_node *from)
+static bool block_needs_label(const ir_node *block, const ir_node *sched_prev)
{
- ir_node *schedpoint = from;
- while (!has_delay_slot(schedpoint)) {
- if (!sched_has_next(schedpoint))
- return NULL;
- schedpoint = sched_next(schedpoint);
+ if (get_Block_entity(block) != NULL)
+ return true;
+
+ int n_cfgpreds = get_Block_n_cfgpreds(block);
+ if (n_cfgpreds == 0) {
+ return false;
+ } else if (n_cfgpreds > 1) {
+ return true;
+ } else {
+ ir_node *cfgpred = get_Block_cfgpred(block, 0);
+ ir_node *cfgpred_block = get_nodes_block(cfgpred);
+ if (is_Proj(cfgpred) && is_sparc_SwitchJmp(get_Proj_pred(cfgpred)))
+ return true;
+ return sched_prev != cfgpred_block || get_jump_target(cfgpred) != block;
}
- return schedpoint;
}
/**
* Walks over the nodes in a block connected by scheduling edges
* and emits code for each node.
*/
-static void sparc_emit_block(ir_node *block)
+static void sparc_emit_block(ir_node *block, ir_node *prev)
{
- ir_node *node;
- ir_node *next_delay_slot;
-
- assert(is_Block(block));
-
- be_gas_emit_block_name(block);
- be_emit_cstring(":\n");
- be_emit_write_line();
-
- next_delay_slot = find_next_delay_slot(sched_first(block));
- if (next_delay_slot != NULL)
- delay_slot_filler = pick_delay_slot_for(next_delay_slot);
+ bool needs_label = block_needs_label(block, prev);
+ be_gas_begin_block(block, needs_label);
sched_foreach(block, node) {
- if (node == delay_slot_filler) {
+ if (rbitset_is_set(delay_slot_fillers, get_irn_idx(node)))
continue;
- }
-
sparc_emit_node(node);
-
- if (node == next_delay_slot) {
- assert(delay_slot_filler == NULL);
- next_delay_slot = find_next_delay_slot(sched_next(node));
- if (next_delay_slot != NULL)
- delay_slot_filler = pick_delay_slot_for(next_delay_slot);
- }
}
}
*/
static void sparc_emit_func_prolog(ir_graph *irg)
{
- ir_entity *ent = get_irg_entity(irg);
- be_gas_emit_function_prolog(ent, 4);
- be_emit_write_line();
+ ir_entity *entity = get_irg_entity(irg);
+ be_gas_emit_function_prolog(entity, 4, NULL);
}
/**
*/
static void sparc_emit_func_epilog(ir_graph *irg)
{
- ir_entity *ent = get_irg_entity(irg);
- const char *irg_name = get_entity_ld_name(ent);
- be_emit_write_line();
- be_emit_irprintf("\t.size %s, .-%s\n", irg_name, irg_name);
- be_emit_cstring("# -- End ");
- be_emit_string(irg_name);
- be_emit_cstring("\n");
- be_emit_write_line();
+ ir_entity *entity = get_irg_entity(irg);
+ be_gas_emit_function_epilog(entity);
}
-static void sparc_gen_labels(ir_node *block, void *env)
+static void init_jump_links(ir_node *block, void *env)
{
- ir_node *pred;
- int n = get_Block_n_cfgpreds(block);
(void) env;
+ int n = get_Block_n_cfgpreds(block);
for (n--; n >= 0; n--) {
- pred = get_Block_cfgpred(block, n);
- set_irn_link(pred, block); // link the pred of a block (which is a jmp)
+ ir_node *pred = get_Block_cfgpred(block, n);
+ set_jump_target(pred, block);
}
}
-void sparc_emit_routine(ir_graph *irg)
+static int cmp_block_execfreqs(const void *d1, const void *d2)
{
- ir_entity *entity = get_irg_entity(irg);
- ir_node **block_schedule;
- size_t i;
- size_t n;
+ ir_node **p1 = (ir_node**)d1;
+ ir_node **p2 = (ir_node**)d2;
+ double freq1 = get_block_execfreq(*p1);
+ double freq2 = get_block_execfreq(*p2);
+ if (freq1 < freq2)
+ return -1;
+ if (freq1 > freq2)
+ return 1;
+ return get_irn_node_nr(*p2)-get_irn_node_nr(*p1);
+}
- be_gas_elf_type_char = '#';
- be_gas_object_file_format = OBJECT_FILE_FORMAT_ELF_SPARC;
+static void pick_delay_slots(size_t n_blocks, ir_node **blocks)
+{
+ /* create blocklist sorted by execution frequency */
+ ir_node **sorted_blocks = XMALLOCN(ir_node*, n_blocks);
+ memcpy(sorted_blocks, blocks, n_blocks*sizeof(sorted_blocks[0]));
+ qsort(sorted_blocks, n_blocks, sizeof(sorted_blocks[0]),
+ cmp_block_execfreqs);
+
+ for (size_t i = 0; i < n_blocks; ++i) {
+ const ir_node *block = sorted_blocks[i];
+ sched_foreach(block, node) {
+ if (!has_delay_slot(node))
+ continue;
+ ir_node *filler = pick_delay_slot_for(node);
+ if (filler == NULL)
+ continue;
+ rbitset_set(delay_slot_fillers, get_irn_idx(filler));
+ pmap_insert(delay_slots, node, filler);
+ }
+ }
+}
- heights = heights_new(irg);
+void sparc_emit_routine(ir_graph *irg)
+{
+ heights = heights_new(irg);
+ delay_slot_fillers = rbitset_malloc(get_irg_last_idx(irg));
+ delay_slots = pmap_create();
/* register all emitter functions */
sparc_register_emitters();
- be_dbg_method_begin(entity);
/* create the block schedule. For now, we don't need it earlier. */
- block_schedule = be_create_block_schedule(irg);
+ ir_node **block_schedule = be_create_block_schedule(irg);
sparc_emit_func_prolog(irg);
- irg_block_walk_graph(irg, sparc_gen_labels, NULL, NULL);
+ irg_block_walk_graph(irg, init_jump_links, NULL, NULL);
/* inject block scheduling links & emit code of each block */
- n = ARR_LEN(block_schedule);
- for (i = 0; i < n; ++i) {
+ size_t n_blocks = ARR_LEN(block_schedule);
+ for (size_t i = 0; i < n_blocks; ++i) {
ir_node *block = block_schedule[i];
- ir_node *next_block = i+1 < n ? block_schedule[i+1] : NULL;
+ ir_node *next_block = i+1 < n_blocks ? block_schedule[i+1] : NULL;
set_irn_link(block, next_block);
}
- for (i = 0; i < n; ++i) {
+ pick_delay_slots(n_blocks, block_schedule);
+
+ for (size_t i = 0; i < n_blocks; ++i) {
ir_node *block = block_schedule[i];
+ ir_node *prev = i>=1 ? block_schedule[i-1] : NULL;
if (block == get_irg_end_block(irg))
continue;
- sparc_emit_block(block);
+ sparc_emit_block(block, prev);
}
/* emit function epilog */
sparc_emit_func_epilog(irg);
+ pmap_destroy(delay_slots);
+ xfree(delay_slot_fillers);
heights_free(heights);
}