const arch_register_req_t *be_create_reg_req(struct obstack *obst,
const arch_register_t *reg,
bool ignore)
{
arch_register_class_t const *cls = reg->cls;
unsigned *limited
= rbitset_obstack_alloc(obst, cls->n_regs);
rbitset_set(limited, reg->index);
arch_register_req_t *req = OALLOCZ(obst, arch_register_req_t);
req->cls = cls;
req->limited = limited;
req->width = 1;
req->ignore = ignore;
return req;
}
arch_register_req_t const *be_create_reg_req(ir_graph *const irg, arch_register_t const *const reg, bool const ignore)
{
if (!ignore)
return reg->single_req;
struct obstack *const obst = be_get_be_obst(irg);
arch_register_class_t const *const cls = reg->cls;
unsigned *const limited = rbitset_obstack_alloc(obst, cls->n_regs);
rbitset_set(limited, reg->index);
arch_register_req_t *const req = OALLOCZ(obst, arch_register_req_t);
req->cls = cls;
req->limited = limited;
req->width = 1;
req->ignore = ignore;
return req;
}
x86_cconv_t *ia32_decide_calling_convention(ir_type *function_type,
ir_graph *irg)
{
bool omit_fp = false;
if (irg != NULL) {
omit_fp = be_options.omit_fp;
if (omit_fp)
irg_walk_graph(irg, check_omit_fp, NULL, &omit_fp);
}
mtp_additional_properties mtp
= get_method_additional_properties(function_type);
(void)mtp;
/* TODO: do something with cc_reg_param/cc_this_call */
unsigned *caller_saves = rbitset_malloc(N_IA32_REGISTERS);
unsigned *callee_saves = rbitset_malloc(N_IA32_REGISTERS);
rbitset_copy(caller_saves, default_caller_saves, N_IA32_REGISTERS);
rbitset_copy(callee_saves, default_callee_saves, N_IA32_REGISTERS);
/* determine how parameters are passed */
unsigned n_params = get_method_n_params(function_type);
unsigned param_regnum = 0;
unsigned float_param_regnum = 0;
reg_or_stackslot_t *params = XMALLOCNZ(reg_or_stackslot_t,
n_params);
unsigned n_param_regs = ARRAY_SIZE(default_param_regs);
unsigned n_float_param_regs = ARRAY_SIZE(float_param_regs);
unsigned stack_offset = 0;
for (unsigned i = 0; i < n_params; ++i) {
ir_type *param_type = get_method_param_type(function_type, i);
reg_or_stackslot_t *param = ¶ms[i];
if (is_aggregate_type(param_type)) {
param->type = param_type;
param->offset = stack_offset;
stack_offset += get_type_size_bytes(param_type);
goto align_stack;
}
ir_mode *mode = get_type_mode(param_type);
if (mode_is_float(mode) && float_param_regnum < n_float_param_regs) {
param->reg = float_param_regs[float_param_regnum++];
} else if (!mode_is_float(mode) && param_regnum < n_param_regs) {
param->reg = default_param_regs[param_regnum++];
} else {
param->type = param_type;
param->offset = stack_offset;
stack_offset += get_type_size_bytes(param_type);
align_stack:;
/* increase offset by at least IA32_REGISTER_SIZE bytes so
* everything is aligned */
unsigned misalign = stack_offset % IA32_REGISTER_SIZE;
if (misalign > 0)
stack_offset += IA32_REGISTER_SIZE - misalign;
}
}
unsigned n_param_regs_used = param_regnum + float_param_regnum;
/* determine how results are passed */
unsigned n_results = get_method_n_ress(function_type);
unsigned n_reg_results = 0;
reg_or_stackslot_t *results = XMALLOCNZ(reg_or_stackslot_t, n_results);
unsigned res_regnum = 0;
unsigned res_float_regnum = 0;
unsigned n_result_regs = ARRAY_SIZE(result_regs);
unsigned n_float_result_regs = ARRAY_SIZE(float_result_regs);
for (size_t i = 0; i < n_results; ++i) {
ir_type *result_type = get_method_res_type(function_type, i);
ir_mode *result_mode = get_type_mode(result_type);
reg_or_stackslot_t *result = &results[i];
const arch_register_t *reg;
if (mode_is_float(result_mode)) {
if (res_float_regnum >= n_float_result_regs) {
panic("too many floating points results");
}
reg = float_result_regs[res_float_regnum++];
} else {
if (res_regnum >= n_result_regs) {
panic("too many results");
}
reg = result_regs[res_regnum++];
}
result->reg = reg;
rbitset_clear(caller_saves, reg->global_index);
++n_reg_results;
}
calling_convention cc = get_method_calling_convention(function_type);
x86_cconv_t *cconv = XMALLOCZ(x86_cconv_t);
cconv->sp_delta = (cc & cc_compound_ret) && !(cc & cc_reg_param)
? IA32_REGISTER_SIZE : 0;
cconv->parameters = params;
cconv->n_parameters = n_params;
cconv->callframe_size = stack_offset;
cconv->n_param_regs = n_param_regs_used;
cconv->n_xmm_regs = float_param_regnum;
cconv->results = results;
cconv->omit_fp = omit_fp;
cconv->caller_saves = caller_saves;
cconv->callee_saves = callee_saves;
cconv->n_reg_results = n_reg_results;
if (irg != NULL) {
be_irg_t *birg = be_birg_from_irg(irg);
size_t n_ignores = ARRAY_SIZE(ignore_regs);
struct obstack *obst = &birg->obst;
birg->allocatable_regs = rbitset_obstack_alloc(obst, N_IA32_REGISTERS);
rbitset_set_all(birg->allocatable_regs, N_IA32_REGISTERS);
for (size_t r = 0; r < n_ignores; ++r) {
rbitset_clear(birg->allocatable_regs, ignore_regs[r]);
}
if (!omit_fp)
rbitset_clear(birg->allocatable_regs, REG_EBP);
}
return cconv;
}
calling_convention_t *sparc_decide_calling_convention(ir_type *function_type,
ir_graph *irg)
{
bool omit_fp = false;
if (irg != NULL) {
omit_fp = be_options.omit_fp;
/* our current vaarg handling needs the standard space to store the
* args 0-5 in it */
if (get_method_variadicity(function_type) == variadicity_variadic)
omit_fp = false;
if (omit_fp == true) {
irg_walk_graph(irg, check_omit_fp, NULL, &omit_fp);
}
}
mtp_additional_properties mtp
= get_method_additional_properties(function_type);
unsigned *caller_saves = rbitset_malloc(N_SPARC_REGISTERS);
if (mtp & mtp_property_returns_twice) {
rbitset_copy(caller_saves, default_returns_twice_saves,
N_SPARC_REGISTERS);
} else {
rbitset_copy(caller_saves, default_caller_saves, N_SPARC_REGISTERS);
}
/* determine how parameters are passed */
int n_params = get_method_n_params(function_type);
int regnum = 0;
reg_or_stackslot_t *params = XMALLOCNZ(reg_or_stackslot_t, n_params);
int n_param_regs = ARRAY_SIZE(param_regs);
unsigned stack_offset = 0;
for (int i = 0; i < n_params; ++i) {
ir_type *param_type = get_method_param_type(function_type,i);
ir_mode *mode;
int bits;
reg_or_stackslot_t *param;
if (is_compound_type(param_type))
panic("compound arguments not supported yet");
mode = get_type_mode(param_type);
bits = get_mode_size_bits(mode);
param = ¶ms[i];
if (i == 0 &&
(get_method_calling_convention(function_type) & cc_compound_ret)) {
assert(mode_is_reference(mode) && bits == 32);
/* special case, we have reserved space for this on the between
* type */
param->type = param_type;
param->offset = -SPARC_MIN_STACKSIZE+SPARC_AGGREGATE_RETURN_OFFSET;
continue;
}
if (regnum < n_param_regs) {
const arch_register_t *reg = param_regs[regnum];
if (irg == NULL || omit_fp)
reg = map_i_to_o_reg(reg);
param->reg0 = reg;
param->req0 = reg->single_req;
param->reg_offset = regnum;
++regnum;
} else {
param->type = param_type;
param->offset = stack_offset;
/* increase offset by at least SPARC_REGISTER_SIZE bytes so everything is aligned */
stack_offset += bits > 8 * SPARC_REGISTER_SIZE ? bits / 8 : SPARC_REGISTER_SIZE;
continue;
}
/* we might need a 2nd 32bit component (for 64bit or double values) */
if (bits > 32) {
if (bits > 64)
panic("only 32 and 64bit modes supported");
if (regnum < n_param_regs) {
const arch_register_t *reg = param_regs[regnum];
if (irg == NULL || omit_fp)
reg = map_i_to_o_reg(reg);
param->reg1 = reg;
param->req1 = reg->single_req;
++regnum;
} else {
ir_mode *regmode = param_regs[0]->reg_class->mode;
ir_type *type = get_type_for_mode(regmode);
param->type = type;
param->offset = stack_offset;
assert(get_mode_size_bits(regmode) == 32);
stack_offset += SPARC_REGISTER_SIZE;
}
}
}
unsigned n_param_regs_used = regnum;
/* determine how results are passed */
int n_results = get_method_n_ress(function_type);
unsigned float_regnum = 0;
unsigned n_reg_results = 0;
unsigned n_float_result_regs = ARRAY_SIZE(float_result_regs);
reg_or_stackslot_t *results = XMALLOCNZ(reg_or_stackslot_t, n_results);
regnum = 0;
for (int i = 0; i < n_results; ++i) {
ir_type *result_type = get_method_res_type(function_type, i);
ir_mode *result_mode = get_type_mode(result_type);
reg_or_stackslot_t *result = &results[i];
if (mode_is_float(result_mode)) {
unsigned n_regs = determine_n_float_regs(result_mode);
unsigned next_reg = round_up2(float_regnum, n_regs);
if (next_reg >= n_float_result_regs) {
panic("Too many float results");
} else {
const arch_register_t *reg = float_result_regs[next_reg];
rbitset_clear(caller_saves, reg->global_index);
result->reg_offset = i;
if (n_regs == 1) {
result->req0 = reg->single_req;
} else if (n_regs == 2) {
result->req0 = &float_result_reqs_double[next_reg];
rbitset_clear(caller_saves, reg->global_index+1);
} else if (n_regs == 4) {
result->req0 = &float_result_reqs_quad[next_reg];
rbitset_clear(caller_saves, reg->global_index+1);
rbitset_clear(caller_saves, reg->global_index+2);
rbitset_clear(caller_saves, reg->global_index+3);
} else {
panic("invalid number of registers in result");
}
float_regnum = next_reg + n_regs;
++n_reg_results;
}
} else {
if (get_mode_size_bits(result_mode) > 32) {
panic("Results with more than 32bits not supported yet");
}
if (regnum >= n_param_regs) {
panic("Too many results");
} else {
const arch_register_t *reg = param_regs[regnum++];
if (irg == NULL || omit_fp)
reg = map_i_to_o_reg(reg);
result->req0 = reg->single_req;
result->reg_offset = i;
rbitset_clear(caller_saves, reg->global_index);
++n_reg_results;
}
}
}
calling_convention_t *cconv = XMALLOCZ(calling_convention_t);
cconv->parameters = params;
cconv->param_stack_size = stack_offset;
cconv->n_param_regs = n_param_regs_used;
cconv->results = results;
cconv->omit_fp = omit_fp;
cconv->caller_saves = caller_saves;
cconv->n_reg_results = n_reg_results;
/* setup ignore register array */
if (irg != NULL) {
be_irg_t *birg = be_birg_from_irg(irg);
size_t n_ignores = ARRAY_SIZE(ignore_regs);
struct obstack *obst = &birg->obst;
size_t r;
birg->allocatable_regs = rbitset_obstack_alloc(obst, N_SPARC_REGISTERS);
rbitset_set_all(birg->allocatable_regs, N_SPARC_REGISTERS);
for (r = 0; r < n_ignores; ++r) {
rbitset_clear(birg->allocatable_regs, ignore_regs[r]);
}
}
return cconv;
}
x86_cconv_t *amd64_decide_calling_convention(ir_type *function_type,
ir_graph *irg)
{
bool omit_fp = false;
if (irg != NULL) {
omit_fp = be_options.omit_fp;
if (omit_fp)
irg_walk_graph(irg, check_omit_fp, NULL, &omit_fp);
}
mtp_additional_properties mtp
= get_method_additional_properties(function_type);
unsigned *caller_saves = rbitset_malloc(N_AMD64_REGISTERS);
unsigned *callee_saves = rbitset_malloc(N_AMD64_REGISTERS);
if (mtp & mtp_property_returns_twice)
panic("amd64: returns_twice calling convention NIY");
rbitset_copy(caller_saves, default_caller_saves, N_AMD64_REGISTERS);
rbitset_copy(callee_saves, default_callee_saves, N_AMD64_REGISTERS);
/* determine how parameters are passed */
size_t n_params = get_method_n_params(function_type);
size_t param_regnum = 0;
size_t float_param_regnum = 0;
reg_or_stackslot_t *params = XMALLOCNZ(reg_or_stackslot_t,
n_params);
/* x64 always reserves space to spill the first 4 arguments to have it
* easy in case of variadic functions. */
unsigned stack_offset = amd64_use_x64_abi ? 32 : 0;
for (size_t i = 0; i < n_params; ++i) {
ir_type *param_type = get_method_param_type(function_type,i);
if (is_compound_type(param_type))
panic("amd64: compound arguments NIY");
ir_mode *mode = get_type_mode(param_type);
int bits = get_mode_size_bits(mode);
reg_or_stackslot_t *param = ¶ms[i];
if (mode_is_float(mode) && float_param_regnum < n_float_param_regs) {
param->reg = float_param_regs[float_param_regnum++];
if (amd64_use_x64_abi)
++param_regnum;
} else if (!mode_is_float(mode) && param_regnum < n_param_regs) {
param->reg = param_regs[param_regnum++];
if (amd64_use_x64_abi)
++float_param_regnum;
} else {
param->type = param_type;
param->offset = stack_offset;
/* increase offset by at least AMD64_REGISTER_SIZE bytes so
* everything is aligned */
stack_offset += MAX(bits / 8, AMD64_REGISTER_SIZE);
continue;
}
}
unsigned n_param_regs_used
= amd64_use_x64_abi ? param_regnum : param_regnum + float_param_regnum;
/* determine how results are passed */
size_t n_results = get_method_n_ress(function_type);
unsigned n_reg_results = 0;
reg_or_stackslot_t *results = XMALLOCNZ(reg_or_stackslot_t, n_results);
unsigned res_regnum = 0;
unsigned res_float_regnum = 0;
size_t n_result_regs = ARRAY_SIZE(result_regs);
size_t n_float_result_regs = ARRAY_SIZE(float_result_regs);
for (size_t i = 0; i < n_results; ++i) {
ir_type *result_type = get_method_res_type(function_type, i);
ir_mode *result_mode = get_type_mode(result_type);
reg_or_stackslot_t *result = &results[i];
const arch_register_t *reg;
if (mode_is_float(result_mode)) {
if (res_float_regnum >= n_float_result_regs) {
panic("too many floating points results");
}
reg = float_result_regs[res_float_regnum++];
} else {
if (res_regnum >= n_result_regs) {
panic("too many results");
}
reg = result_regs[res_regnum++];
}
result->reg = reg;
rbitset_clear(caller_saves, reg->global_index);
++n_reg_results;
}
x86_cconv_t *cconv = XMALLOCZ(x86_cconv_t);
cconv->parameters = params;
cconv->callframe_size = stack_offset;
cconv->n_param_regs = n_param_regs_used;
cconv->n_xmm_regs = float_param_regnum;
cconv->results = results;
cconv->omit_fp = omit_fp;
cconv->caller_saves = caller_saves;
cconv->callee_saves = callee_saves;
cconv->n_reg_results = n_reg_results;
if (irg != NULL) {
be_irg_t *birg = be_birg_from_irg(irg);
size_t n_ignores = ARRAY_SIZE(ignore_regs);
struct obstack *obst = &birg->obst;
birg->allocatable_regs = rbitset_obstack_alloc(obst, N_AMD64_REGISTERS);
rbitset_set_all(birg->allocatable_regs, N_AMD64_REGISTERS);
for (size_t r = 0; r < n_ignores; ++r) {
rbitset_clear(birg->allocatable_regs, ignore_regs[r]);
}
if (!omit_fp)
rbitset_clear(birg->allocatable_regs, REG_RBP);
}
return cconv;
}
