diff options
Diffstat (limited to 'src/compiler/glsl')
| -rw-r--r-- | src/compiler/glsl/builtin_functions.cpp | 8 | ||||
| -rw-r--r-- | src/compiler/glsl/builtin_functions.h | 6 | ||||
| -rw-r--r-- | src/compiler/glsl/builtin_int64.h | 672 | ||||
| -rw-r--r-- | src/compiler/glsl/glcpp/glcpp-parse.y | 2 | ||||
| -rw-r--r-- | src/compiler/glsl/int64.glsl | 77 |
5 files changed, 763 insertions, 2 deletions
diff --git a/src/compiler/glsl/builtin_functions.cpp b/src/compiler/glsl/builtin_functions.cpp index f64ab6a5f33..6d9ff4b504c 100644 --- a/src/compiler/glsl/builtin_functions.cpp +++ b/src/compiler/glsl/builtin_functions.cpp @@ -3099,10 +3099,18 @@ builtin_builder::create_builtins() add_function("allInvocationsARB", _vote(ir_unop_vote_all), NULL); add_function("allInvocationsEqualARB", _vote(ir_unop_vote_eq), NULL); + add_function("__builtin_idiv64", + generate_ir::idiv64(mem_ctx, integer_functions_supported), + NULL); + add_function("__builtin_sign64", generate_ir::sign64(mem_ctx, integer_functions_supported), NULL); + add_function("__builtin_udiv64", + generate_ir::udiv64(mem_ctx, integer_functions_supported), + NULL); + add_function("__builtin_umul64", generate_ir::umul64(mem_ctx, integer_functions_supported), NULL); diff --git a/src/compiler/glsl/builtin_functions.h b/src/compiler/glsl/builtin_functions.h index c66f523f692..ac1a8ccd1eb 100644 --- a/src/compiler/glsl/builtin_functions.h +++ b/src/compiler/glsl/builtin_functions.h @@ -46,6 +46,12 @@ _mesa_glsl_release_builtin_functions(void); namespace generate_ir { ir_function_signature * +udiv64(void *mem_ctx, builtin_available_predicate avail); + +ir_function_signature * +idiv64(void *mem_ctx, builtin_available_predicate avail); + +ir_function_signature * umul64(void *mem_ctx, builtin_available_predicate avail); ir_function_signature * diff --git a/src/compiler/glsl/builtin_int64.h b/src/compiler/glsl/builtin_int64.h index c12565d14c7..5eaa4a8eac9 100644 --- a/src/compiler/glsl/builtin_int64.h +++ b/src/compiler/glsl/builtin_int64.h @@ -54,3 +54,675 @@ sign64(void *mem_ctx, builtin_available_predicate avail) sig->replace_parameters(&sig_parameters); return sig; } +ir_function_signature * +udivmod64(void *mem_ctx, builtin_available_predicate avail) +{ + ir_function_signature *const sig = + new(mem_ctx) ir_function_signature(glsl_type::uvec4_type, avail); + ir_factory body(&sig->body, mem_ctx); + sig->is_defined = true; + + exec_list sig_parameters; + + ir_variable *const r000C = new(mem_ctx) ir_variable(glsl_type::uvec2_type, "n", ir_var_function_in); + sig_parameters.push_tail(r000C); + ir_variable *const r000D = new(mem_ctx) ir_variable(glsl_type::uvec2_type, "d", ir_var_function_in); + sig_parameters.push_tail(r000D); + ir_variable *const r000E = new(mem_ctx) ir_variable(glsl_type::int_type, "i", ir_var_auto); + body.emit(r000E); + ir_variable *const r000F = new(mem_ctx) ir_variable(glsl_type::uint64_t_type, "n64", ir_var_auto); + body.emit(r000F); + ir_variable *const r0010 = new(mem_ctx) ir_variable(glsl_type::int_type, "log2_denom", ir_var_auto); + body.emit(r0010); + ir_variable *const r0011 = new(mem_ctx) ir_variable(glsl_type::uvec2_type, "quot", ir_var_auto); + body.emit(r0011); + body.emit(assign(r0011, ir_constant::zero(mem_ctx, glsl_type::uvec2_type), 0x03)); + + ir_expression *const r0012 = expr(ir_unop_find_msb, swizzle_y(r000D)); + body.emit(assign(r0010, add(r0012, body.constant(int(32))), 0x01)); + + /* IF CONDITION */ + ir_expression *const r0014 = equal(swizzle_y(r000D), body.constant(0u)); + ir_expression *const r0015 = gequal(swizzle_y(r000C), swizzle_x(r000D)); + ir_expression *const r0016 = logic_and(r0014, r0015); + ir_if *f0013 = new(mem_ctx) ir_if(operand(r0016).val); + exec_list *const f0013_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f0013->then_instructions; + + ir_variable *const r0017 = new(mem_ctx) ir_variable(glsl_type::int_type, "i", ir_var_auto); + body.emit(r0017); + ir_variable *const r0018 = body.make_temp(glsl_type::int_type, "findMSB_retval"); + body.emit(assign(r0018, expr(ir_unop_find_msb, swizzle_x(r000D)), 0x01)); + + body.emit(assign(r0010, r0018, 0x01)); + + body.emit(assign(r0017, body.constant(int(31)), 0x01)); + + /* LOOP BEGIN */ + ir_loop *f0019 = new(mem_ctx) ir_loop(); + exec_list *const f0019_parent_instructions = body.instructions; + + body.instructions = &f0019->body_instructions; + + /* IF CONDITION */ + ir_expression *const r001B = less(r0017, body.constant(int(1))); + ir_if *f001A = new(mem_ctx) ir_if(operand(r001B).val); + exec_list *const f001A_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f001A->then_instructions; + + body.emit(new(mem_ctx) ir_loop_jump(ir_loop_jump::jump_break)); + + + body.instructions = f001A_parent_instructions; + body.emit(f001A); + + /* END IF */ + + /* IF CONDITION */ + ir_expression *const r001D = sub(body.constant(int(31)), r0017); + ir_expression *const r001E = lequal(r0018, r001D); + ir_expression *const r001F = lshift(swizzle_x(r000D), r0017); + ir_expression *const r0020 = lequal(r001F, swizzle_y(r000C)); + ir_expression *const r0021 = logic_and(r001E, r0020); + ir_if *f001C = new(mem_ctx) ir_if(operand(r0021).val); + exec_list *const f001C_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f001C->then_instructions; + + ir_expression *const r0022 = lshift(swizzle_x(r000D), r0017); + body.emit(assign(r000C, sub(swizzle_y(r000C), r0022), 0x02)); + + ir_expression *const r0023 = lshift(body.constant(1u), r0017); + body.emit(assign(r0011, bit_or(swizzle_y(r0011), r0023), 0x02)); + + + body.instructions = f001C_parent_instructions; + body.emit(f001C); + + /* END IF */ + + body.emit(assign(r0017, add(r0017, body.constant(int(-1))), 0x01)); + + /* LOOP END */ + + body.instructions = f0019_parent_instructions; + body.emit(f0019); + + /* IF CONDITION */ + ir_expression *const r0025 = lequal(swizzle_x(r000D), swizzle_y(r000C)); + ir_if *f0024 = new(mem_ctx) ir_if(operand(r0025).val); + exec_list *const f0024_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f0024->then_instructions; + + body.emit(assign(r000C, sub(swizzle_y(r000C), swizzle_x(r000D)), 0x02)); + + body.emit(assign(r0011, bit_or(swizzle_y(r0011), body.constant(1u)), 0x02)); + + + body.instructions = f0024_parent_instructions; + body.emit(f0024); + + /* END IF */ + + + body.instructions = f0013_parent_instructions; + body.emit(f0013); + + /* END IF */ + + ir_variable *const r0026 = body.make_temp(glsl_type::uint64_t_type, "packUint2x32_retval"); + body.emit(assign(r0026, expr(ir_unop_pack_uint_2x32, r000D), 0x01)); + + body.emit(assign(r000F, expr(ir_unop_pack_uint_2x32, r000C), 0x01)); + + body.emit(assign(r000E, body.constant(int(31)), 0x01)); + + /* LOOP BEGIN */ + ir_loop *f0027 = new(mem_ctx) ir_loop(); + exec_list *const f0027_parent_instructions = body.instructions; + + body.instructions = &f0027->body_instructions; + + /* IF CONDITION */ + ir_expression *const r0029 = less(r000E, body.constant(int(1))); + ir_if *f0028 = new(mem_ctx) ir_if(operand(r0029).val); + exec_list *const f0028_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f0028->then_instructions; + + body.emit(new(mem_ctx) ir_loop_jump(ir_loop_jump::jump_break)); + + + body.instructions = f0028_parent_instructions; + body.emit(f0028); + + /* END IF */ + + /* IF CONDITION */ + ir_expression *const r002B = sub(body.constant(int(63)), r000E); + ir_expression *const r002C = lequal(r0010, r002B); + ir_expression *const r002D = lshift(r0026, r000E); + ir_expression *const r002E = lequal(r002D, r000F); + ir_expression *const r002F = logic_and(r002C, r002E); + ir_if *f002A = new(mem_ctx) ir_if(operand(r002F).val); + exec_list *const f002A_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f002A->then_instructions; + + ir_expression *const r0030 = lshift(r0026, r000E); + body.emit(assign(r000F, sub(r000F, r0030), 0x01)); + + ir_expression *const r0031 = lshift(body.constant(1u), r000E); + body.emit(assign(r0011, bit_or(swizzle_x(r0011), r0031), 0x01)); + + + body.instructions = f002A_parent_instructions; + body.emit(f002A); + + /* END IF */ + + body.emit(assign(r000E, add(r000E, body.constant(int(-1))), 0x01)); + + /* LOOP END */ + + body.instructions = f0027_parent_instructions; + body.emit(f0027); + + /* IF CONDITION */ + ir_expression *const r0033 = lequal(r0026, r000F); + ir_if *f0032 = new(mem_ctx) ir_if(operand(r0033).val); + exec_list *const f0032_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f0032->then_instructions; + + body.emit(assign(r000F, sub(r000F, r0026), 0x01)); + + body.emit(assign(r0011, bit_or(swizzle_x(r0011), body.constant(1u)), 0x01)); + + + body.instructions = f0032_parent_instructions; + body.emit(f0032); + + /* END IF */ + + ir_variable *const r0034 = body.make_temp(glsl_type::uvec4_type, "vec_ctor"); + body.emit(assign(r0034, r0011, 0x03)); + + body.emit(assign(r0034, expr(ir_unop_unpack_uint_2x32, r000F), 0x0c)); + + body.emit(ret(r0034)); + + sig->replace_parameters(&sig_parameters); + return sig; +} +ir_function_signature * +udiv64(void *mem_ctx, builtin_available_predicate avail) +{ + ir_function_signature *const sig = + new(mem_ctx) ir_function_signature(glsl_type::uvec2_type, avail); + ir_factory body(&sig->body, mem_ctx); + sig->is_defined = true; + + exec_list sig_parameters; + + ir_variable *const r0035 = new(mem_ctx) ir_variable(glsl_type::uvec2_type, "n", ir_var_function_in); + sig_parameters.push_tail(r0035); + ir_variable *const r0036 = new(mem_ctx) ir_variable(glsl_type::uvec2_type, "d", ir_var_function_in); + sig_parameters.push_tail(r0036); + ir_variable *const r0037 = new(mem_ctx) ir_variable(glsl_type::uvec2_type, "n", ir_var_auto); + body.emit(r0037); + body.emit(assign(r0037, r0035, 0x03)); + + ir_variable *const r0038 = new(mem_ctx) ir_variable(glsl_type::int_type, "i", ir_var_auto); + body.emit(r0038); + ir_variable *const r0039 = new(mem_ctx) ir_variable(glsl_type::uint64_t_type, "n64", ir_var_auto); + body.emit(r0039); + ir_variable *const r003A = new(mem_ctx) ir_variable(glsl_type::int_type, "log2_denom", ir_var_auto); + body.emit(r003A); + ir_variable *const r003B = new(mem_ctx) ir_variable(glsl_type::uvec2_type, "quot", ir_var_auto); + body.emit(r003B); + body.emit(assign(r003B, ir_constant::zero(mem_ctx, glsl_type::uvec2_type), 0x03)); + + ir_expression *const r003C = expr(ir_unop_find_msb, swizzle_y(r0036)); + body.emit(assign(r003A, add(r003C, body.constant(int(32))), 0x01)); + + /* IF CONDITION */ + ir_expression *const r003E = equal(swizzle_y(r0036), body.constant(0u)); + ir_expression *const r003F = gequal(swizzle_y(r0035), swizzle_x(r0036)); + ir_expression *const r0040 = logic_and(r003E, r003F); + ir_if *f003D = new(mem_ctx) ir_if(operand(r0040).val); + exec_list *const f003D_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f003D->then_instructions; + + ir_variable *const r0041 = new(mem_ctx) ir_variable(glsl_type::int_type, "i", ir_var_auto); + body.emit(r0041); + ir_variable *const r0042 = body.make_temp(glsl_type::int_type, "findMSB_retval"); + body.emit(assign(r0042, expr(ir_unop_find_msb, swizzle_x(r0036)), 0x01)); + + body.emit(assign(r003A, r0042, 0x01)); + + body.emit(assign(r0041, body.constant(int(31)), 0x01)); + + /* LOOP BEGIN */ + ir_loop *f0043 = new(mem_ctx) ir_loop(); + exec_list *const f0043_parent_instructions = body.instructions; + + body.instructions = &f0043->body_instructions; + + /* IF CONDITION */ + ir_expression *const r0045 = less(r0041, body.constant(int(1))); + ir_if *f0044 = new(mem_ctx) ir_if(operand(r0045).val); + exec_list *const f0044_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f0044->then_instructions; + + body.emit(new(mem_ctx) ir_loop_jump(ir_loop_jump::jump_break)); + + + body.instructions = f0044_parent_instructions; + body.emit(f0044); + + /* END IF */ + + /* IF CONDITION */ + ir_expression *const r0047 = sub(body.constant(int(31)), r0041); + ir_expression *const r0048 = lequal(r0042, r0047); + ir_expression *const r0049 = lshift(swizzle_x(r0036), r0041); + ir_expression *const r004A = lequal(r0049, swizzle_y(r0037)); + ir_expression *const r004B = logic_and(r0048, r004A); + ir_if *f0046 = new(mem_ctx) ir_if(operand(r004B).val); + exec_list *const f0046_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f0046->then_instructions; + + ir_expression *const r004C = lshift(swizzle_x(r0036), r0041); + body.emit(assign(r0037, sub(swizzle_y(r0037), r004C), 0x02)); + + ir_expression *const r004D = lshift(body.constant(1u), r0041); + body.emit(assign(r003B, bit_or(swizzle_y(r003B), r004D), 0x02)); + + + body.instructions = f0046_parent_instructions; + body.emit(f0046); + + /* END IF */ + + body.emit(assign(r0041, add(r0041, body.constant(int(-1))), 0x01)); + + /* LOOP END */ + + body.instructions = f0043_parent_instructions; + body.emit(f0043); + + /* IF CONDITION */ + ir_expression *const r004F = lequal(swizzle_x(r0036), swizzle_y(r0037)); + ir_if *f004E = new(mem_ctx) ir_if(operand(r004F).val); + exec_list *const f004E_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f004E->then_instructions; + + body.emit(assign(r0037, sub(swizzle_y(r0037), swizzle_x(r0036)), 0x02)); + + body.emit(assign(r003B, bit_or(swizzle_y(r003B), body.constant(1u)), 0x02)); + + + body.instructions = f004E_parent_instructions; + body.emit(f004E); + + /* END IF */ + + + body.instructions = f003D_parent_instructions; + body.emit(f003D); + + /* END IF */ + + ir_variable *const r0050 = body.make_temp(glsl_type::uint64_t_type, "packUint2x32_retval"); + body.emit(assign(r0050, expr(ir_unop_pack_uint_2x32, r0036), 0x01)); + + body.emit(assign(r0039, expr(ir_unop_pack_uint_2x32, r0037), 0x01)); + + body.emit(assign(r0038, body.constant(int(31)), 0x01)); + + /* LOOP BEGIN */ + ir_loop *f0051 = new(mem_ctx) ir_loop(); + exec_list *const f0051_parent_instructions = body.instructions; + + body.instructions = &f0051->body_instructions; + + /* IF CONDITION */ + ir_expression *const r0053 = less(r0038, body.constant(int(1))); + ir_if *f0052 = new(mem_ctx) ir_if(operand(r0053).val); + exec_list *const f0052_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f0052->then_instructions; + + body.emit(new(mem_ctx) ir_loop_jump(ir_loop_jump::jump_break)); + + + body.instructions = f0052_parent_instructions; + body.emit(f0052); + + /* END IF */ + + /* IF CONDITION */ + ir_expression *const r0055 = sub(body.constant(int(63)), r0038); + ir_expression *const r0056 = lequal(r003A, r0055); + ir_expression *const r0057 = lshift(r0050, r0038); + ir_expression *const r0058 = lequal(r0057, r0039); + ir_expression *const r0059 = logic_and(r0056, r0058); + ir_if *f0054 = new(mem_ctx) ir_if(operand(r0059).val); + exec_list *const f0054_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f0054->then_instructions; + + ir_expression *const r005A = lshift(r0050, r0038); + body.emit(assign(r0039, sub(r0039, r005A), 0x01)); + + ir_expression *const r005B = lshift(body.constant(1u), r0038); + body.emit(assign(r003B, bit_or(swizzle_x(r003B), r005B), 0x01)); + + + body.instructions = f0054_parent_instructions; + body.emit(f0054); + + /* END IF */ + + body.emit(assign(r0038, add(r0038, body.constant(int(-1))), 0x01)); + + /* LOOP END */ + + body.instructions = f0051_parent_instructions; + body.emit(f0051); + + /* IF CONDITION */ + ir_expression *const r005D = lequal(r0050, r0039); + ir_if *f005C = new(mem_ctx) ir_if(operand(r005D).val); + exec_list *const f005C_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f005C->then_instructions; + + body.emit(assign(r0039, sub(r0039, r0050), 0x01)); + + body.emit(assign(r003B, bit_or(swizzle_x(r003B), body.constant(1u)), 0x01)); + + + body.instructions = f005C_parent_instructions; + body.emit(f005C); + + /* END IF */ + + body.emit(ret(r003B)); + + sig->replace_parameters(&sig_parameters); + return sig; +} +ir_function_signature * +idiv64(void *mem_ctx, builtin_available_predicate avail) +{ + ir_function_signature *const sig = + new(mem_ctx) ir_function_signature(glsl_type::ivec2_type, avail); + ir_factory body(&sig->body, mem_ctx); + sig->is_defined = true; + + exec_list sig_parameters; + + ir_variable *const r005E = new(mem_ctx) ir_variable(glsl_type::ivec2_type, "_n", ir_var_function_in); + sig_parameters.push_tail(r005E); + ir_variable *const r005F = new(mem_ctx) ir_variable(glsl_type::ivec2_type, "_d", ir_var_function_in); + sig_parameters.push_tail(r005F); + ir_variable *const r0060 = new(mem_ctx) ir_variable(glsl_type::bool_type, "negate", ir_var_auto); + body.emit(r0060); + ir_expression *const r0061 = less(swizzle_y(r005E), body.constant(int(0))); + ir_expression *const r0062 = less(swizzle_y(r005F), body.constant(int(0))); + body.emit(assign(r0060, nequal(r0061, r0062), 0x01)); + + ir_variable *const r0063 = new(mem_ctx) ir_variable(glsl_type::uvec2_type, "n", ir_var_auto); + body.emit(r0063); + ir_expression *const r0064 = expr(ir_unop_pack_int_2x32, r005E); + ir_expression *const r0065 = expr(ir_unop_abs, r0064); + ir_expression *const r0066 = expr(ir_unop_i642u64, r0065); + body.emit(assign(r0063, expr(ir_unop_unpack_uint_2x32, r0066), 0x03)); + + ir_variable *const r0067 = new(mem_ctx) ir_variable(glsl_type::uvec2_type, "d", ir_var_auto); + body.emit(r0067); + ir_expression *const r0068 = expr(ir_unop_pack_int_2x32, r005F); + ir_expression *const r0069 = expr(ir_unop_abs, r0068); + ir_expression *const r006A = expr(ir_unop_i642u64, r0069); + body.emit(assign(r0067, expr(ir_unop_unpack_uint_2x32, r006A), 0x03)); + + ir_variable *const r006B = new(mem_ctx) ir_variable(glsl_type::int_type, "i", ir_var_auto); + body.emit(r006B); + ir_variable *const r006C = new(mem_ctx) ir_variable(glsl_type::uint64_t_type, "n64", ir_var_auto); + body.emit(r006C); + ir_variable *const r006D = new(mem_ctx) ir_variable(glsl_type::int_type, "log2_denom", ir_var_auto); + body.emit(r006D); + ir_variable *const r006E = new(mem_ctx) ir_variable(glsl_type::uvec2_type, "quot", ir_var_auto); + body.emit(r006E); + body.emit(assign(r006E, ir_constant::zero(mem_ctx, glsl_type::uvec2_type), 0x03)); + + ir_expression *const r006F = expr(ir_unop_find_msb, swizzle_y(r0067)); + body.emit(assign(r006D, add(r006F, body.constant(int(32))), 0x01)); + + /* IF CONDITION */ + ir_expression *const r0071 = equal(swizzle_y(r0067), body.constant(0u)); + ir_expression *const r0072 = gequal(swizzle_y(r0063), swizzle_x(r0067)); + ir_expression *const r0073 = logic_and(r0071, r0072); + ir_if *f0070 = new(mem_ctx) ir_if(operand(r0073).val); + exec_list *const f0070_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f0070->then_instructions; + + ir_variable *const r0074 = new(mem_ctx) ir_variable(glsl_type::int_type, "i", ir_var_auto); + body.emit(r0074); + ir_variable *const r0075 = body.make_temp(glsl_type::int_type, "findMSB_retval"); + body.emit(assign(r0075, expr(ir_unop_find_msb, swizzle_x(r0067)), 0x01)); + + body.emit(assign(r006D, r0075, 0x01)); + + body.emit(assign(r0074, body.constant(int(31)), 0x01)); + + /* LOOP BEGIN */ + ir_loop *f0076 = new(mem_ctx) ir_loop(); + exec_list *const f0076_parent_instructions = body.instructions; + + body.instructions = &f0076->body_instructions; + + /* IF CONDITION */ + ir_expression *const r0078 = less(r0074, body.constant(int(1))); + ir_if *f0077 = new(mem_ctx) ir_if(operand(r0078).val); + exec_list *const f0077_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f0077->then_instructions; + + body.emit(new(mem_ctx) ir_loop_jump(ir_loop_jump::jump_break)); + + + body.instructions = f0077_parent_instructions; + body.emit(f0077); + + /* END IF */ + + /* IF CONDITION */ + ir_expression *const r007A = sub(body.constant(int(31)), r0074); + ir_expression *const r007B = lequal(r0075, r007A); + ir_expression *const r007C = lshift(swizzle_x(r0067), r0074); + ir_expression *const r007D = lequal(r007C, swizzle_y(r0063)); + ir_expression *const r007E = logic_and(r007B, r007D); + ir_if *f0079 = new(mem_ctx) ir_if(operand(r007E).val); + exec_list *const f0079_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f0079->then_instructions; + + ir_expression *const r007F = lshift(swizzle_x(r0067), r0074); + body.emit(assign(r0063, sub(swizzle_y(r0063), r007F), 0x02)); + + ir_expression *const r0080 = lshift(body.constant(1u), r0074); + body.emit(assign(r006E, bit_or(swizzle_y(r006E), r0080), 0x02)); + + + body.instructions = f0079_parent_instructions; + body.emit(f0079); + + /* END IF */ + + body.emit(assign(r0074, add(r0074, body.constant(int(-1))), 0x01)); + + /* LOOP END */ + + body.instructions = f0076_parent_instructions; + body.emit(f0076); + + /* IF CONDITION */ + ir_expression *const r0082 = lequal(swizzle_x(r0067), swizzle_y(r0063)); + ir_if *f0081 = new(mem_ctx) ir_if(operand(r0082).val); + exec_list *const f0081_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f0081->then_instructions; + + body.emit(assign(r0063, sub(swizzle_y(r0063), swizzle_x(r0067)), 0x02)); + + body.emit(assign(r006E, bit_or(swizzle_y(r006E), body.constant(1u)), 0x02)); + + + body.instructions = f0081_parent_instructions; + body.emit(f0081); + + /* END IF */ + + + body.instructions = f0070_parent_instructions; + body.emit(f0070); + + /* END IF */ + + ir_variable *const r0083 = body.make_temp(glsl_type::uint64_t_type, "packUint2x32_retval"); + body.emit(assign(r0083, expr(ir_unop_pack_uint_2x32, r0067), 0x01)); + + body.emit(assign(r006C, expr(ir_unop_pack_uint_2x32, r0063), 0x01)); + + body.emit(assign(r006B, body.constant(int(31)), 0x01)); + + /* LOOP BEGIN */ + ir_loop *f0084 = new(mem_ctx) ir_loop(); + exec_list *const f0084_parent_instructions = body.instructions; + + body.instructions = &f0084->body_instructions; + + /* IF CONDITION */ + ir_expression *const r0086 = less(r006B, body.constant(int(1))); + ir_if *f0085 = new(mem_ctx) ir_if(operand(r0086).val); + exec_list *const f0085_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f0085->then_instructions; + + body.emit(new(mem_ctx) ir_loop_jump(ir_loop_jump::jump_break)); + + + body.instructions = f0085_parent_instructions; + body.emit(f0085); + + /* END IF */ + + /* IF CONDITION */ + ir_expression *const r0088 = sub(body.constant(int(63)), r006B); + ir_expression *const r0089 = lequal(r006D, r0088); + ir_expression *const r008A = lshift(r0083, r006B); + ir_expression *const r008B = lequal(r008A, r006C); + ir_expression *const r008C = logic_and(r0089, r008B); + ir_if *f0087 = new(mem_ctx) ir_if(operand(r008C).val); + exec_list *const f0087_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f0087->then_instructions; + + ir_expression *const r008D = lshift(r0083, r006B); + body.emit(assign(r006C, sub(r006C, r008D), 0x01)); + + ir_expression *const r008E = lshift(body.constant(1u), r006B); + body.emit(assign(r006E, bit_or(swizzle_x(r006E), r008E), 0x01)); + + + body.instructions = f0087_parent_instructions; + body.emit(f0087); + + /* END IF */ + + body.emit(assign(r006B, add(r006B, body.constant(int(-1))), 0x01)); + + /* LOOP END */ + + body.instructions = f0084_parent_instructions; + body.emit(f0084); + + /* IF CONDITION */ + ir_expression *const r0090 = lequal(r0083, r006C); + ir_if *f008F = new(mem_ctx) ir_if(operand(r0090).val); + exec_list *const f008F_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f008F->then_instructions; + + body.emit(assign(r006C, sub(r006C, r0083), 0x01)); + + body.emit(assign(r006E, bit_or(swizzle_x(r006E), body.constant(1u)), 0x01)); + + + body.instructions = f008F_parent_instructions; + body.emit(f008F); + + /* END IF */ + + ir_variable *const r0091 = body.make_temp(glsl_type::ivec2_type, "conditional_tmp"); + /* IF CONDITION */ + ir_if *f0092 = new(mem_ctx) ir_if(operand(r0060).val); + exec_list *const f0092_parent_instructions = body.instructions; + + /* THEN INSTRUCTIONS */ + body.instructions = &f0092->then_instructions; + + ir_expression *const r0093 = expr(ir_unop_pack_uint_2x32, r006E); + ir_expression *const r0094 = expr(ir_unop_u642i64, r0093); + ir_expression *const r0095 = neg(r0094); + body.emit(assign(r0091, expr(ir_unop_unpack_int_2x32, r0095), 0x03)); + + + /* ELSE INSTRUCTIONS */ + body.instructions = &f0092->else_instructions; + + body.emit(assign(r0091, expr(ir_unop_u2i, r006E), 0x03)); + + + body.instructions = f0092_parent_instructions; + body.emit(f0092); + + /* END IF */ + + body.emit(ret(r0091)); + + sig->replace_parameters(&sig_parameters); + return sig; +} diff --git a/src/compiler/glsl/glcpp/glcpp-parse.y b/src/compiler/glsl/glcpp/glcpp-parse.y index 39a7a89258f..d801cf8a9d7 100644 --- a/src/compiler/glsl/glcpp/glcpp-parse.y +++ b/src/compiler/glsl/glcpp/glcpp-parse.y @@ -2345,6 +2345,8 @@ _glcpp_parser_handle_version_declaration(glcpp_parser_t *parser, intmax_t versio if (parser->extension_list->MESA_shader_integer_functions) { add_builtin_define(parser, "__have_builtin_builtin_sign64", 1); add_builtin_define(parser, "__have_builtin_builtin_umul64", 1); + add_builtin_define(parser, "__have_builtin_builtin_udiv64", 1); + add_builtin_define(parser, "__have_builtin_builtin_idiv64", 1); } } diff --git a/src/compiler/glsl/int64.glsl b/src/compiler/glsl/int64.glsl index a2bec011e3e..84e80ee349b 100644 --- a/src/compiler/glsl/int64.glsl +++ b/src/compiler/glsl/int64.glsl @@ -4,8 +4,9 @@ * * Using version 1.40+ prevents built-in variables from being included. */ -#version 140 -#extension GL_MESA_shader_integer_functions: require +#version 400 +#extension GL_ARB_gpu_shader_int64: require +#extension GL_ARB_shading_language_420pack: require uvec2 umul64(uvec2 a, uvec2 b) @@ -28,3 +29,75 @@ sign64(ivec2 a) return result; } + +uvec4 +udivmod64(uvec2 n, uvec2 d) +{ + uvec2 quot = uvec2(0U, 0U); + int log2_denom = findMSB(d.y) + 32; + + /* If the upper 32 bits of denom are non-zero, it is impossible for shifts + * greater than 32 bits to occur. If the upper 32 bits of the numerator + * are zero, it is impossible for (denom << [63, 32]) <= numer unless + * denom == 0. + */ + if (d.y == 0 && n.y >= d.x) { + log2_denom = findMSB(d.x); + + /* Since the upper 32 bits of denom are zero, log2_denom <= 31 and we + * don't have to compare log2_denom inside the loop as is done in the + * general case (below). + */ + for (int i = 31; i >= 1; i--) { + if (log2_denom <= 31 - i && (d.x << i) <= n.y) { + n.y -= d.x << i; + quot.y |= 1U << i; + } + } + + /* log2_denom is always <= 31, so manually peel the last loop + * iteration. + */ + if (d.x <= n.y) { + n.y -= d.x; + quot.y |= 1U; + } + } + + uint64_t d64 = packUint2x32(d); + uint64_t n64 = packUint2x32(n); + for (int i = 31; i >= 1; i--) { + if (log2_denom <= 63 - i && (d64 << i) <= n64) { + n64 -= d64 << i; + quot.x |= 1U << i; + } + } + + /* log2_denom is always <= 63, so manually peel the last loop + * iteration. + */ + if (d64 <= n64) { + n64 -= d64; + quot.x |= 1U; + } + + return uvec4(quot, unpackUint2x32(n64)); +} + +uvec2 +udiv64(uvec2 n, uvec2 d) +{ + return udivmod64(n, d).xy; +} + +ivec2 +idiv64(ivec2 _n, ivec2 _d) +{ + const bool negate = (_n.y < 0) != (_d.y < 0); + uvec2 n = unpackUint2x32(uint64_t(abs(packInt2x32(_n)))); + uvec2 d = unpackUint2x32(uint64_t(abs(packInt2x32(_d)))); + + uvec2 quot = udivmod64(n, d).xy; + + return negate ? unpackInt2x32(-int64_t(packUint2x32(quot))) : ivec2(quot); +} |