static void sparc_layout_param_entities(ir_graph *const irg, calling_convention_t *const cconv, ir_type *const non_lowered) { ir_entity **const param_map = be_collect_parameter_entities(irg); ir_type *const frame_type = get_irg_frame_type(irg); size_t const n_params = cconv->n_parameters; /* calculate offsets/create missing entities */ for (size_t i = 0; i < n_params; ++i) { reg_or_stackslot_t *const param = &cconv->parameters[i]; ir_entity * entity = param_map[i]; if (entity == NULL) { if (!param->already_stored) continue; entity = new_parameter_entity(frame_type, i, param->type); } param->entity = entity; set_entity_offset(entity, param->offset); } ir_entity *const function = get_irg_entity(irg); ir_type *const function_type = get_entity_type(function); if (is_method_variadic(function_type)) { ir_type *unknown = get_unknown_type(); ident *id = new_id_from_str("$va_start"); ir_entity *va_start_addr = new_entity(frame_type, id, unknown); /* sparc_variadic_fixups() fiddled with our type, find out the * original number of parameters */ size_t const orig_n_params = get_method_n_params(non_lowered); long offset; if (orig_n_params < n_params) { assert(param_map[orig_n_params] != NULL); offset = get_entity_offset(param_map[orig_n_params]); } else { offset = cconv->param_stack_size + SPARC_MIN_STACKSIZE; } set_entity_offset(va_start_addr, offset); cconv->va_start_addr = va_start_addr; } free(param_map); }
/** * @return The lowered method type. */ static ir_type *lower_method_type(ir_type *mtp) { ir_type *res = pmap_get(ir_type, lowered_type, mtp); if (res != NULL) return res; size_t const n_param = get_method_n_params(mtp); size_t const n_res = get_method_n_ress(mtp); bool const is_variadic = is_method_variadic(mtp); res = new_type_method(n_param, n_res, is_variadic); /* set param types and result types */ for (size_t i = 0; i < n_param; ++i) { ir_type *ptp = get_method_param_type(mtp, i); ir_mode *pmode = get_type_mode(ptp); if (pmode != NULL && mode_is_float(pmode)) { ptp = lower_type(ptp); } set_method_param_type(res, i, ptp); } for (size_t i = 0; i < n_res; ++i) { ir_type *rtp = get_method_res_type(mtp, i); ir_mode *rmode = get_type_mode(rtp); if (rmode != NULL && mode_is_float(rmode)) { rtp = lower_type(rtp); } set_method_res_type(res, i, rtp); } copy_method_properties(res, mtp); set_higher_type(res, mtp); pmap_insert(lowered_type, mtp, res); return res; }
/** * Perform some fixups for variadic functions. * To make the rest of the frontend code easier to understand we add * "dummy" parameters until the number of parameters transmitted in registers. * (because otherwise the backend wouldn't store the value of the register * parameters into memory for the VLA magic) */ static bool sparc_variadic_fixups(ir_graph *const irg, calling_convention_t *const cconv) { ir_entity *entity = get_irg_entity(irg); ir_type *mtp = get_entity_type(entity); if (!is_method_variadic(mtp)) return false; if (cconv->n_param_regs >= SPARC_N_PARAM_REGS) return false; size_t const n_params = get_method_n_params(mtp); size_t const n_ress = get_method_n_ress(mtp); size_t const new_n_params = n_params + (SPARC_N_PARAM_REGS - cconv->n_param_regs); unsigned const cc_mask = get_method_calling_convention(mtp); mtp_additional_properties const props = get_method_additional_properties(mtp); ir_type *const new_mtp = new_type_method(new_n_params, n_ress, true, cc_mask, props); type_dbg_info *const dbgi = get_type_dbg_info(mtp); set_type_dbg_info(new_mtp, dbgi); for (size_t i = 0; i < n_ress; ++i) { ir_type *type = get_method_res_type(mtp, i); set_method_res_type(new_mtp, i, type); } for (size_t i = 0; i < n_params; ++i) { ir_type *type = get_method_param_type(mtp, i); set_method_param_type(new_mtp, i, type); } ir_type *const frame_type = get_irg_frame_type(irg); ir_mode *const gp_reg_mode = sparc_reg_classes[CLASS_sparc_gp].mode; ir_type *const gp_reg_type = get_type_for_mode(gp_reg_mode); for (size_t i = n_params; i < new_n_params; ++i) { set_method_param_type(new_mtp, i, gp_reg_type); new_parameter_entity(frame_type, i, gp_reg_type); } set_entity_type(entity, new_mtp); return true; }
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 (is_method_variadic(function_type)) omit_fp = false; /* The pointer to the aggregate return value belongs to the 92 magic bytes. * Thus, if the called functions increases the stack size, * it must copy the value to the appropriate location. * This is not implemented yet, so we forbid to omit the frame pointer. */ if (get_method_calling_convention(function_type) & cc_compound_ret) omit_fp = false; if (omit_fp) irg_walk_graph(irg, check_omit_fp, NULL, &omit_fp); sparc_get_irg_data(irg)->omit_fp = 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 = !omit_fp ? SPARC_MIN_STACKSIZE : 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_AGGREGATE_RETURN_OFFSET; param->already_stored = true; continue; } if (regnum < n_param_regs) { param->offset = SPARC_PARAMS_SPILL_OFFSET + regnum * SPARC_REGISTER_SIZE; param->type = param_type; arch_register_t const *reg = param_regs[regnum++]; if (irg == NULL || omit_fp) reg = map_i_to_o_reg(reg); param->reg0 = reg; param->req0 = reg->single_req; } else { param->type = param_type; param->offset = stack_offset; param->already_stored = true; /* increase offset by at least SPARC_REGISTER_SIZE bytes so * everything is aligned */ stack_offset += MAX(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) { param->offset = SPARC_PARAMS_SPILL_OFFSET + regnum * SPARC_REGISTER_SIZE; arch_register_t const *reg = param_regs[regnum++]; if (irg == NULL || omit_fp) reg = map_i_to_o_reg(reg); param->reg1 = reg; param->req1 = reg->single_req; } else { ir_mode *regmode = param_regs[0]->cls->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); 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; rbitset_clear(caller_saves, reg->global_index); ++n_reg_results; } } } calling_convention_t *cconv = XMALLOCZ(calling_convention_t); cconv->n_parameters = n_params; cconv->parameters = params; cconv->param_stack_size = stack_offset - SPARC_MIN_STACKSIZE; 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); birg->allocatable_regs = be_cconv_alloc_all_regs(&birg->obst, N_SPARC_REGISTERS); be_cconv_rem_regs(birg->allocatable_regs, ignore_regs, ARRAY_SIZE(ignore_regs)); } 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); amd64_get_irg_data(irg)->omit_fp = omit_fp; } unsigned *caller_saves = rbitset_malloc(N_AMD64_REGISTERS); unsigned *callee_saves = rbitset_malloc(N_AMD64_REGISTERS); 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("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 && mode != x86_mode_E) { 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 += round_up2(bits / 8, AMD64_REGISTER_SIZE); } } /* If the function is variadic, we add all unused parameter * passing registers to the end of the params array, first GP, * then XMM. */ if (irg && is_method_variadic(function_type)) { if (amd64_use_x64_abi) { panic("Variadic functions on Windows ABI not supported"); } int params_remaining = (n_param_regs - param_regnum) + (n_float_param_regs - float_param_regnum); params = XREALLOC(params, reg_or_stackslot_t, n_params + params_remaining); size_t i = n_params; for (; param_regnum < n_param_regs; param_regnum++, i++) { params[i].reg = param_regs[param_regnum]; } for (; float_param_regnum < n_float_param_regs; float_param_regnum++, i++) { params[i].reg = float_param_regs[float_param_regnum]; } } 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; unsigned res_x87_regnum = 0; size_t n_result_regs = ARRAY_SIZE(result_regs); size_t n_float_result_regs = ARRAY_SIZE(float_result_regs); size_t n_x87_result_regs = ARRAY_SIZE(x87_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 (result_mode == x86_mode_E) { if (res_x87_regnum >= n_x87_result_regs) panic("too manu x87 floating point results"); reg = x87_result_regs[res_x87_regnum++]; } else 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->n_parameters = n_params; cconv->param_stacksize = 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); birg->allocatable_regs = be_cconv_alloc_all_regs(&birg->obst, N_AMD64_REGISTERS); be_cconv_rem_regs(birg->allocatable_regs, ignore_regs, ARRAY_SIZE(ignore_regs)); if (!omit_fp) rbitset_clear(birg->allocatable_regs, REG_RBP); } return cconv; }