/* * Copyright (c) 2017 Lima Project * Copyright (c) 2013 Connor Abbott * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. * */ #ifndef LIMA_IR_PP_PPIR_H #define LIMA_IR_PP_PPIR_H #include "util/u_math.h" #include "util/list.h" #include "util/set.h" #include "ir/lima_ir.h" typedef enum { ppir_op_mov, ppir_op_abs, ppir_op_neg, ppir_op_sat, ppir_op_add, ppir_op_ddx, ppir_op_ddy, ppir_op_mul, ppir_op_rcp, ppir_op_sin_lut, ppir_op_cos_lut, ppir_op_sum3, ppir_op_sum4, ppir_op_normalize2, ppir_op_normalize3, ppir_op_normalize4, ppir_op_select, ppir_op_sin, ppir_op_cos, ppir_op_tan, ppir_op_asin, ppir_op_acos, ppir_op_atan, ppir_op_atan2, ppir_op_atan_pt1, ppir_op_atan2_pt1, ppir_op_atan_pt2, ppir_op_exp, ppir_op_log, ppir_op_exp2, ppir_op_log2, ppir_op_sqrt, ppir_op_rsqrt, ppir_op_sign, ppir_op_floor, ppir_op_ceil, ppir_op_fract, ppir_op_mod, ppir_op_min, ppir_op_max, ppir_op_trunc, ppir_op_and, ppir_op_or, ppir_op_xor, ppir_op_lt, ppir_op_gt, ppir_op_le, ppir_op_ge, ppir_op_eq, ppir_op_ne, ppir_op_not, ppir_op_load_uniform, ppir_op_load_varying, ppir_op_load_coords, ppir_op_load_coords_reg, ppir_op_load_fragcoord, ppir_op_load_pointcoord, ppir_op_load_frontface, ppir_op_load_texture, ppir_op_load_temp, ppir_op_store_temp, ppir_op_const, ppir_op_discard, ppir_op_branch, ppir_op_undef, ppir_op_dummy, ppir_op_num, } ppir_op; typedef enum { ppir_node_type_alu, ppir_node_type_const, ppir_node_type_load, ppir_node_type_store, ppir_node_type_load_texture, ppir_node_type_discard, ppir_node_type_branch, } ppir_node_type; typedef struct { char *name; ppir_node_type type; int *slots; } ppir_op_info; extern const ppir_op_info ppir_op_infos[]; typedef enum { ppir_dep_src, ppir_dep_write_after_read, ppir_dep_sequence, } ppir_dep_type; typedef struct { void *pred, *succ; ppir_dep_type type; struct list_head pred_link; struct list_head succ_link; } ppir_dep; typedef struct ppir_node { struct list_head list; struct list_head sched_list; ppir_op op; ppir_node_type type; int index; char name[16]; bool printed; struct ppir_instr *instr; int instr_pos; struct ppir_block *block; bool is_end; bool succ_different_block; /* for scheduler */ struct list_head succ_list; struct list_head pred_list; } ppir_node; typedef enum { ppir_pipeline_reg_const0, ppir_pipeline_reg_const1, ppir_pipeline_reg_sampler, ppir_pipeline_reg_uniform, ppir_pipeline_reg_vmul, ppir_pipeline_reg_fmul, ppir_pipeline_reg_discard, /* varying load */ } ppir_pipeline; typedef struct ppir_reg { struct list_head list; int index; int regalloc_index; int num_components; /* whether this reg has to start from the x component * of a full physical reg, this is true for reg used * in load/store instr which has no swizzle field */ bool is_head; bool spilled; bool undef; } ppir_reg; typedef enum { ppir_target_ssa, ppir_target_pipeline, ppir_target_register, } ppir_target; typedef struct ppir_src { ppir_target type; ppir_node *node; union { ppir_reg *ssa; ppir_reg *reg; ppir_pipeline pipeline; }; uint8_t swizzle[4]; bool absolute, negate; } ppir_src; typedef enum { ppir_outmod_none, ppir_outmod_clamp_fraction, ppir_outmod_clamp_positive, ppir_outmod_round, } ppir_outmod; typedef struct ppir_dest { ppir_target type; union { ppir_reg ssa; ppir_reg *reg; ppir_pipeline pipeline; }; ppir_outmod modifier; unsigned write_mask : 4; } ppir_dest; typedef struct { ppir_node node; ppir_dest dest; ppir_src src[3]; int num_src; int shift : 3; /* Only used for ppir_op_mul */ } ppir_alu_node; typedef struct ppir_const { union fi value[4]; int num; } ppir_const; typedef struct { ppir_node node; ppir_const constant; ppir_dest dest; } ppir_const_node; typedef struct { ppir_node node; int index; int num_components; ppir_dest dest; ppir_src src; int num_src; } ppir_load_node; typedef struct { ppir_node node; int index; int num_components; ppir_src src; } ppir_store_node; typedef struct { ppir_node node; ppir_dest dest; ppir_src src[2]; int num_src; int sampler; int sampler_dim; bool lod_bias_en; bool explicit_lod; } ppir_load_texture_node; typedef struct { ppir_node node; } ppir_discard_node; enum ppir_instr_slot { PPIR_INSTR_SLOT_VARYING, PPIR_INSTR_SLOT_TEXLD, PPIR_INSTR_SLOT_UNIFORM, PPIR_INSTR_SLOT_ALU_VEC_MUL, PPIR_INSTR_SLOT_ALU_SCL_MUL, PPIR_INSTR_SLOT_ALU_VEC_ADD, PPIR_INSTR_SLOT_ALU_SCL_ADD, PPIR_INSTR_SLOT_ALU_COMBINE, PPIR_INSTR_SLOT_STORE_TEMP, PPIR_INSTR_SLOT_BRANCH, PPIR_INSTR_SLOT_NUM, PPIR_INSTR_SLOT_END, PPIR_INSTR_SLOT_ALU_START = PPIR_INSTR_SLOT_ALU_VEC_MUL, PPIR_INSTR_SLOT_ALU_END = PPIR_INSTR_SLOT_ALU_COMBINE, }; typedef struct ppir_instr { struct list_head list; int index; bool printed; int seq; /* command sequence after schedule */ ppir_node *slots[PPIR_INSTR_SLOT_NUM]; ppir_const constant[2]; bool is_end; /* for scheduler */ struct list_head succ_list; struct list_head pred_list; float reg_pressure; int est; /* earliest start time */ int parent_index; bool scheduled; int offset; int encode_size; /* for liveness analysis */ BITSET_WORD *live_set; uint8_t *live_mask; /* mask for non-ssa registers */ /* live_internal is to mark registers only live within an * instruction, without propagation */ BITSET_WORD *live_internal; } ppir_instr; typedef struct ppir_block { struct list_head list; struct list_head node_list; struct list_head instr_list; struct ppir_block *successors[2]; struct ppir_compiler *comp; /* for scheduler */ int sched_instr_index; int sched_instr_base; int index; } ppir_block; typedef struct { ppir_node node; ppir_src src[2]; int num_src; bool cond_gt; bool cond_eq; bool cond_lt; bool negate; ppir_block *target; } ppir_branch_node; struct ra_regs; struct lima_fs_compiled_shader; typedef struct ppir_compiler { struct list_head block_list; struct hash_table_u64 *blocks; int cur_index; int cur_instr_index; struct list_head reg_list; int reg_num; /* array for searching ssa/reg node */ ppir_node **var_nodes; unsigned reg_base; struct ra_regs *ra; struct lima_fs_compiled_shader *prog; bool uses_discard; /* for scheduler */ int sched_instr_base; /* for regalloc spilling debug */ int force_spilling; /* shaderdb */ int num_loops; int num_spills; int num_fills; ppir_block *discard_block; ppir_block *current_block; ppir_block *loop_break_block; ppir_block *loop_cont_block; } ppir_compiler; void *ppir_node_create(ppir_block *block, ppir_op op, int index, unsigned mask); void ppir_node_add_dep(ppir_node *succ, ppir_node *pred, ppir_dep_type type); void ppir_node_remove_dep(ppir_dep *dep); void ppir_node_delete(ppir_node *node); void ppir_node_print_prog(ppir_compiler *comp); void ppir_node_replace_child(ppir_node *parent, ppir_node *old_child, ppir_node *new_child); void ppir_node_replace_all_succ(ppir_node *dst, ppir_node *src); void ppir_node_replace_pred(ppir_dep *dep, ppir_node *new_pred); ppir_dep *ppir_dep_for_pred(ppir_node *node, ppir_node *pred); /* Assumes that node successors are in the same block */ ppir_node *ppir_node_insert_mov(ppir_node *node); static inline bool ppir_node_is_root(ppir_node *node) { return list_is_empty(&node->succ_list); } static inline bool ppir_node_is_leaf(ppir_node *node) { return list_is_empty(&node->pred_list); } static inline bool ppir_node_has_single_succ(ppir_node *node) { return list_is_singular(&node->succ_list) && !node->succ_different_block; } bool ppir_node_has_single_src_succ(ppir_node *node); static inline ppir_node *ppir_node_first_succ(ppir_node *node) { return list_first_entry(&node->succ_list, ppir_dep, succ_link)->succ; } static inline bool ppir_node_has_single_pred(ppir_node *node) { return list_is_singular(&node->pred_list); } static inline ppir_node *ppir_node_first_pred(ppir_node *node) { return list_first_entry(&node->pred_list, ppir_dep, pred_link)->pred; } #define ppir_node_foreach_succ(node, dep) \ list_for_each_entry(ppir_dep, dep, &node->succ_list, succ_link) #define ppir_node_foreach_succ_safe(node, dep) \ list_for_each_entry_safe(ppir_dep, dep, &node->succ_list, succ_link) #define ppir_node_foreach_pred(node, dep) \ list_for_each_entry(ppir_dep, dep, &node->pred_list, pred_link) #define ppir_node_foreach_pred_safe(node, dep) \ list_for_each_entry_safe(ppir_dep, dep, &node->pred_list, pred_link) #define ppir_node_to_alu(node) ((ppir_alu_node *)(node)) #define ppir_node_to_const(node) ((ppir_const_node *)(node)) #define ppir_node_to_load(node) ((ppir_load_node *)(node)) #define ppir_node_to_store(node) ((ppir_store_node *)(node)) #define ppir_node_to_load_texture(node) ((ppir_load_texture_node *)(node)) #define ppir_node_to_discard(node) ((ppir_discard_node *)(node)) #define ppir_node_to_branch(node) ((ppir_branch_node *)(node)) static inline ppir_dest *ppir_node_get_dest(ppir_node *node) { switch (node->type) { case ppir_node_type_alu: return &ppir_node_to_alu(node)->dest; case ppir_node_type_load: return &ppir_node_to_load(node)->dest; case ppir_node_type_const: return &ppir_node_to_const(node)->dest; case ppir_node_type_load_texture: return &ppir_node_to_load_texture(node)->dest; default: return NULL; } } static inline int ppir_node_get_src_num(ppir_node *node) { switch (node->type) { case ppir_node_type_alu: return ppir_node_to_alu(node)->num_src; case ppir_node_type_branch: return ppir_node_to_branch(node)->num_src; case ppir_node_type_load: return ppir_node_to_load(node)->num_src; case ppir_node_type_load_texture: return ppir_node_to_load_texture(node)->num_src; case ppir_node_type_store: return 1; default: return 0; } return 0; } static inline ppir_src *ppir_node_get_src(ppir_node *node, int idx) { if (idx < 0 || idx >= ppir_node_get_src_num(node)) return NULL; switch (node->type) { case ppir_node_type_alu: return &ppir_node_to_alu(node)->src[idx]; case ppir_node_type_branch: return &ppir_node_to_branch(node)->src[idx]; case ppir_node_type_load_texture: return &ppir_node_to_load_texture(node)->src[idx]; case ppir_node_type_load: return &ppir_node_to_load(node)->src; case ppir_node_type_store: return &ppir_node_to_store(node)->src; default: break; } return NULL; } static inline ppir_reg *ppir_src_get_reg(ppir_src *src) { switch (src->type) { case ppir_target_ssa: return src->ssa; case ppir_target_register: return src->reg; default: return NULL; } } static inline ppir_reg *ppir_dest_get_reg(ppir_dest *dest) { switch (dest->type) { case ppir_target_ssa: return &dest->ssa; case ppir_target_register: return dest->reg; default: return NULL; } } static inline void ppir_node_target_assign(ppir_src *src, ppir_node *node) { ppir_dest *dest = ppir_node_get_dest(node); src->type = dest->type; switch (src->type) { case ppir_target_ssa: src->ssa = &dest->ssa; src->node = node; break; case ppir_target_register: src->reg = dest->reg; /* Registers can be assigned from multiple nodes, so don't keep * pointer to the node here */ src->node = NULL; break; case ppir_target_pipeline: src->pipeline = dest->pipeline; src->node = node; break; } } static inline bool ppir_node_target_equal(ppir_src *src, ppir_dest *dest) { if (src->type != dest->type || (src->type == ppir_target_ssa && src->ssa != &dest->ssa) || (src->type == ppir_target_register && src->reg != dest->reg) || (src->type == ppir_target_pipeline && src->pipeline != dest->pipeline)) return false; return true; } static inline int ppir_target_get_src_reg_index(ppir_src *src) { switch (src->type) { case ppir_target_ssa: if (src->ssa) return src->ssa->index; break; case ppir_target_register: if (src->reg) return src->reg->index; break; case ppir_target_pipeline: if (src->pipeline == ppir_pipeline_reg_discard) return 15 * 4; return (src->pipeline + 12) * 4; } return -1; } static inline int ppir_target_get_dest_reg_index(ppir_dest *dest) { switch (dest->type) { case ppir_target_ssa: return dest->ssa.index; case ppir_target_register: return dest->reg->index; case ppir_target_pipeline: if (dest->pipeline == ppir_pipeline_reg_discard) return 15 * 4; return (dest->pipeline + 12) * 4; } return -1; } static inline int ppir_src_get_mask(ppir_src *src) { ppir_reg *reg = ppir_src_get_reg(src); int mask = 0; for (int i = 0; i < reg->num_components; i++) mask |= (1 << src->swizzle[i]); return mask; } static inline bool ppir_target_is_scalar(ppir_dest *dest) { switch (dest->type) { case ppir_target_ssa: return dest->ssa.num_components == 1; case ppir_target_register: /* only one bit in mask is set */ if ((dest->write_mask & 0x3) == 0x3 || (dest->write_mask & 0x5) == 0x5 || (dest->write_mask & 0x9) == 0x9 || (dest->write_mask & 0x6) == 0x6 || (dest->write_mask & 0xa) == 0xa || (dest->write_mask & 0xc) == 0xc) return false; else return true; case ppir_target_pipeline: if (dest->pipeline == ppir_pipeline_reg_fmul) return true; else return false; default: return false; } } static inline bool ppir_node_schedulable_slot(ppir_node *node, enum ppir_instr_slot slot) { int *slots = ppir_op_infos[node->op].slots; for (int i = 0; slots[i] != PPIR_INSTR_SLOT_END; i++) if (slots[i] == slot) return true; return false; } ppir_instr *ppir_instr_create(ppir_block *block); bool ppir_instr_insert_node(ppir_instr *instr, ppir_node *node); void ppir_instr_add_dep(ppir_instr *succ, ppir_instr *pred); void ppir_instr_print_list(ppir_compiler *comp); void ppir_instr_print_dep(ppir_compiler *comp); void ppir_instr_insert_mul_node(ppir_node *add, ppir_node *mul); #define ppir_instr_foreach_succ(instr, dep) \ list_for_each_entry(ppir_dep, dep, &instr->succ_list, succ_link) #define ppir_instr_foreach_succ_safe(instr, dep) \ list_for_each_entry_safe(ppir_dep, dep, &instr->succ_list, succ_link) #define ppir_instr_foreach_pred(instr, dep) \ list_for_each_entry(ppir_dep, dep, &instr->pred_list, pred_link) #define ppir_instr_foreach_pred_safe(instr, dep) \ list_for_each_entry_safe(ppir_dep, dep, &instr->pred_list, pred_link) static inline bool ppir_instr_is_root(ppir_instr *instr) { return list_is_empty(&instr->succ_list); } static inline bool ppir_instr_is_leaf(ppir_instr *instr) { return list_is_empty(&instr->pred_list); } bool ppir_lower_prog(ppir_compiler *comp); bool ppir_node_to_instr(ppir_compiler *comp); bool ppir_schedule_prog(ppir_compiler *comp); bool ppir_regalloc_prog(ppir_compiler *comp); bool ppir_codegen_prog(ppir_compiler *comp); void ppir_liveness_analysis(ppir_compiler *comp); static inline unsigned int reg_mask_size(unsigned int num_reg) { return (num_reg + 1) / 2; } static inline uint8_t get_reg_mask(uint8_t *set, unsigned index) { unsigned int i = index / 2; unsigned int shift = index % 2 ? 4 : 0; uint8_t mask = 0x0f << shift; return (set[i] & mask) >> shift; } static inline void set_reg_mask(uint8_t *set, unsigned int index, uint8_t bits) { unsigned int i = index / 2; unsigned int shift = index % 2 ? 4 : 0; uint8_t mask = 0x0f << shift; set[i] &= ~mask; set[i] |= (bits << shift); } #endif