/* * Copyright © 2017 Gert Wollny * * 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 (including the next * paragraph) 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. */ #include "st_glsl_to_tgsi_temprename.h" #include "tgsi/tgsi_info.h" #include "tgsi/tgsi_strings.h" #include "program/prog_instruction.h" #include "util/bitscan.h" #include #include /* std::sort is significantly faster than qsort */ #define USE_STL_SORT #ifdef USE_STL_SORT #include #endif #ifndef NDEBUG #include #include #include "program/prog_print.h" #include "util/debug.h" using std::cerr; using std::setw; using std::ostream; #endif /* If is included this is defined and clashes with * std::numeric_limits<>::max() */ #ifdef max #undef max #endif using std::numeric_limits; /* Without c++11 define the nullptr for forward-compatibility * and better readibility */ #if __cplusplus < 201103L #define nullptr 0 #endif #ifndef NDEBUG /* Prepare to make it possible to specify log file */ static std::ostream& debug_log = cerr; /* Helper function to check whether we want to seen debugging output */ static inline bool is_debug_enabled () { static int debug_enabled = -1; if (debug_enabled < 0) debug_enabled = env_var_as_boolean("GLSL_TO_TGSI_RENAME_DEBUG", false); return debug_enabled > 0; } #define RENAME_DEBUG(X) if (is_debug_enabled()) do { X; } while (false); #else #define RENAME_DEBUG(X) #endif namespace { enum prog_scope_type { outer_scope, /* Outer program scope */ loop_body, /* Inside a loop */ if_branch, /* Inside if branch */ else_branch, /* Inside else branch */ switch_body, /* Inside switch statmenet */ switch_case_branch, /* Inside switch case statmenet */ switch_default_branch, /* Inside switch default statmenet */ undefined_scope }; class prog_scope { public: prog_scope(prog_scope *parent, prog_scope_type type, int id, int depth, int begin); prog_scope_type type() const; prog_scope *parent() const; int nesting_depth() const; int id() const; int end() const; int begin() const; int loop_break_line() const; const prog_scope *in_else_scope() const; const prog_scope *in_ifelse_scope() const; const prog_scope *in_parent_ifelse_scope() const; const prog_scope *innermost_loop() const; const prog_scope *outermost_loop() const; const prog_scope *enclosing_conditional() const; bool is_loop() const; bool is_in_loop() const; bool is_switchcase_scope_in_loop() const; bool is_conditional() const; bool is_child_of(const prog_scope *scope) const; bool is_child_of_ifelse_id_sibling(const prog_scope *scope) const; bool break_is_for_switchcase() const; bool contains_range_of(const prog_scope& other) const; void set_end(int end); void set_loop_break_line(int line); private: prog_scope_type scope_type; int scope_id; int scope_nesting_depth; int scope_begin; int scope_end; int break_loop_line; prog_scope *parent_scope; }; /* Some storage class to encapsulate the prog_scope (de-)allocations */ class prog_scope_storage { public: prog_scope_storage(void *mem_ctx, int n); ~prog_scope_storage(); prog_scope * create(prog_scope *p, prog_scope_type type, int id, int lvl, int s_begin); private: void *mem_ctx; int current_slot; prog_scope *storage; }; /* Class to track the access to a component of a temporary register. */ class temp_comp_access { public: temp_comp_access(); void record_read(int line, prog_scope *scope); void record_write(int line, prog_scope *scope); lifetime get_required_lifetime(); private: void propagate_lifetime_to_dominant_write_scope(); bool conditional_ifelse_write_in_loop() const; void record_ifelse_write(const prog_scope& scope); void record_if_write(const prog_scope& scope); void record_else_write(const prog_scope& scope); prog_scope *last_read_scope; prog_scope *first_read_scope; prog_scope *first_write_scope; int first_write; int last_read; int last_write; int first_read; /* This member variable tracks the current resolution of conditional writing * to this temporary in IF/ELSE clauses. * * The initial value "conditionality_untouched" indicates that this * temporary has not yet been written to within an if clause. * * A positive (other than "conditionality_untouched") number refers to the * last loop id for which the write was resolved as unconditional. With each * new loop this value will be overwitten by "conditionality_unresolved" * on entering the first IF clause writing this temporary. * * The value "conditionality_unresolved" indicates that no resolution has * been achieved so far. If the variable is set to this value at the end of * the processing of the whole shader it also indicates a conditional write. * * The value "write_is_conditional" marks that the variable is written * conditionally (i.e. not in all relevant IF/ELSE code path pairs) in at * least one loop. */ int conditionality_in_loop_id; /* Helper constants to make the tracking code more readable. */ static const int write_is_conditional = -1; static const int conditionality_unresolved = 0; static const int conditionality_untouched; static const int write_is_unconditional; /* A bit field tracking the nexting levels of if-else clauses where the * temporary has (so far) been written to in the if branch, but not in the * else branch. */ unsigned int if_scope_write_flags; int next_ifelse_nesting_depth; static const int supported_ifelse_nesting_depth = 32; /* Tracks the last if scope in which the temporary was written to * without a write in the correspondig else branch. Is also used * to track read-before-write in the according scope. */ const prog_scope *current_unpaired_if_write_scope; /* Flag to resolve read-before-write in the else scope. */ bool was_written_in_current_else_scope; }; const int temp_comp_access::conditionality_untouched = numeric_limits::max(); const int temp_comp_access::write_is_unconditional = numeric_limits::max() - 1; /* Class to track the access to all components of a temporary register. */ class temp_access { public: temp_access(); void record_read(int line, prog_scope *scope, int swizzle); void record_write(int line, prog_scope *scope, int writemask); lifetime get_required_lifetime(); private: void update_access_mask(int mask); temp_comp_access comp[4]; int access_mask; bool needs_component_tracking; }; prog_scope_storage::prog_scope_storage(void *mc, int n): mem_ctx(mc), current_slot(0) { storage = ralloc_array(mem_ctx, prog_scope, n); } prog_scope_storage::~prog_scope_storage() { ralloc_free(storage); } prog_scope* prog_scope_storage::create(prog_scope *p, prog_scope_type type, int id, int lvl, int s_begin) { storage[current_slot] = prog_scope(p, type, id, lvl, s_begin); return &storage[current_slot++]; } prog_scope::prog_scope(prog_scope *parent, prog_scope_type type, int id, int depth, int scope_begin): scope_type(type), scope_id(id), scope_nesting_depth(depth), scope_begin(scope_begin), scope_end(-1), break_loop_line(numeric_limits::max()), parent_scope(parent) { } prog_scope_type prog_scope::type() const { return scope_type; } prog_scope *prog_scope::parent() const { return parent_scope; } int prog_scope::nesting_depth() const { return scope_nesting_depth; } bool prog_scope::is_loop() const { return (scope_type == loop_body); } bool prog_scope::is_in_loop() const { if (scope_type == loop_body) return true; if (parent_scope) return parent_scope->is_in_loop(); return false; } const prog_scope *prog_scope::innermost_loop() const { if (scope_type == loop_body) return this; if (parent_scope) return parent_scope->innermost_loop(); return nullptr; } const prog_scope *prog_scope::outermost_loop() const { const prog_scope *loop = nullptr; const prog_scope *p = this; do { if (p->type() == loop_body) loop = p; p = p->parent(); } while (p); return loop; } bool prog_scope::is_child_of_ifelse_id_sibling(const prog_scope *scope) const { const prog_scope *my_parent = in_parent_ifelse_scope(); while (my_parent) { /* is a direct child? */ if (my_parent == scope) return false; /* is a child of the conditions sibling? */ if (my_parent->id() == scope->id()) return true; my_parent = my_parent->in_parent_ifelse_scope(); } return false; } bool prog_scope::is_child_of(const prog_scope *scope) const { const prog_scope *my_parent = parent(); while (my_parent) { if (my_parent == scope) return true; my_parent = my_parent->parent(); } return false; } const prog_scope *prog_scope::enclosing_conditional() const { if (is_conditional()) return this; if (parent_scope) return parent_scope->enclosing_conditional(); return nullptr; } bool prog_scope::contains_range_of(const prog_scope& other) const { return (begin() <= other.begin()) && (end() >= other.end()); } bool prog_scope::is_conditional() const { return scope_type == if_branch || scope_type == else_branch || scope_type == switch_case_branch || scope_type == switch_default_branch; } const prog_scope *prog_scope::in_else_scope() const { if (scope_type == else_branch) return this; if (parent_scope) return parent_scope->in_else_scope(); return nullptr; } const prog_scope *prog_scope::in_parent_ifelse_scope() const { if (parent_scope) return parent_scope->in_ifelse_scope(); else return nullptr; } const prog_scope *prog_scope::in_ifelse_scope() const { if (scope_type == if_branch || scope_type == else_branch) return this; if (parent_scope) return parent_scope->in_ifelse_scope(); return nullptr; } bool prog_scope::is_switchcase_scope_in_loop() const { return (scope_type == switch_case_branch || scope_type == switch_default_branch) && is_in_loop(); } bool prog_scope::break_is_for_switchcase() const { if (scope_type == loop_body) return false; if (scope_type == switch_case_branch || scope_type == switch_default_branch || scope_type == switch_body) return true; if (parent_scope) return parent_scope->break_is_for_switchcase(); return false; } int prog_scope::id() const { return scope_id; } int prog_scope::begin() const { return scope_begin; } int prog_scope::end() const { return scope_end; } void prog_scope::set_end(int end) { if (scope_end == -1) scope_end = end; } void prog_scope::set_loop_break_line(int line) { if (scope_type == loop_body) { break_loop_line = MIN2(break_loop_line, line); } else { if (parent_scope) parent()->set_loop_break_line(line); } } int prog_scope::loop_break_line() const { return break_loop_line; } temp_access::temp_access(): access_mask(0), needs_component_tracking(false) { } void temp_access::update_access_mask(int mask) { if (access_mask && access_mask != mask) needs_component_tracking = true; access_mask |= mask; } void temp_access::record_write(int line, prog_scope *scope, int writemask) { update_access_mask(writemask); if (writemask & WRITEMASK_X) comp[0].record_write(line, scope); if (writemask & WRITEMASK_Y) comp[1].record_write(line, scope); if (writemask & WRITEMASK_Z) comp[2].record_write(line, scope); if (writemask & WRITEMASK_W) comp[3].record_write(line, scope); } void temp_access::record_read(int line, prog_scope *scope, int swizzle) { int readmask = 0; for (int idx = 0; idx < 4; ++idx) { int swz = GET_SWZ(swizzle, idx); readmask |= (1 << swz) & 0xF; } update_access_mask(readmask); if (readmask & WRITEMASK_X) comp[0].record_read(line, scope); if (readmask & WRITEMASK_Y) comp[1].record_read(line, scope); if (readmask & WRITEMASK_Z) comp[2].record_read(line, scope); if (readmask & WRITEMASK_W) comp[3].record_read(line, scope); } inline static lifetime make_lifetime(int b, int e) { lifetime lt; lt.begin = b; lt.end = e; return lt; } lifetime temp_access::get_required_lifetime() { lifetime result = make_lifetime(-1, -1); unsigned mask = access_mask; while (mask) { unsigned chan = u_bit_scan(&mask); lifetime lt = comp[chan].get_required_lifetime(); if (lt.begin >= 0) { if ((result.begin < 0) || (result.begin > lt.begin)) result.begin = lt.begin; } if (lt.end > result.end) result.end = lt.end; if (!needs_component_tracking) break; } return result; } temp_comp_access::temp_comp_access(): last_read_scope(nullptr), first_read_scope(nullptr), first_write_scope(nullptr), first_write(-1), last_read(-1), last_write(-1), first_read(numeric_limits::max()), conditionality_in_loop_id(conditionality_untouched), if_scope_write_flags(0), next_ifelse_nesting_depth(0), current_unpaired_if_write_scope(nullptr), was_written_in_current_else_scope(false) { } void temp_comp_access::record_read(int line, prog_scope *scope) { last_read_scope = scope; last_read = line; if (first_read > line) { first_read = line; first_read_scope = scope; } /* If the conditionality of the first write is already resolved then * no further checks are required. */ if (conditionality_in_loop_id == write_is_unconditional || conditionality_in_loop_id == write_is_conditional) return; /* Check whether we are in a condition within a loop */ const prog_scope *ifelse_scope = scope->in_ifelse_scope(); const prog_scope *enclosing_loop; if (ifelse_scope && (enclosing_loop = ifelse_scope->innermost_loop())) { /* If we have either not yet written to this register nor writes are * resolved as unconditional in the enclosing loop then check whether * we read before write in an IF/ELSE branch. */ if ((conditionality_in_loop_id != write_is_conditional) && (conditionality_in_loop_id != enclosing_loop->id())) { if (current_unpaired_if_write_scope) { /* Has been written in this or a parent scope? - this makes the temporary * unconditionally set at this point. */ if (scope->is_child_of(current_unpaired_if_write_scope)) return; /* Has been written in the same scope before it was read? */ if (ifelse_scope->type() == if_branch) { if (current_unpaired_if_write_scope->id() == scope->id()) return; } else { if (was_written_in_current_else_scope) return; } } /* The temporary was read (conditionally) before it is written, hence * it should survive a loop. This can be signaled like if it were * conditionally written. */ conditionality_in_loop_id = write_is_conditional; } } } void temp_comp_access::record_write(int line, prog_scope *scope) { last_write = line; if (first_write < 0) { first_write = line; first_write_scope = scope; /* If the first write we encounter is not in a conditional branch, or * the conditional write is not within a loop, then this is to be * considered an unconditional dominant write. */ const prog_scope *conditional = scope->enclosing_conditional(); if (!conditional || !conditional->innermost_loop()) { conditionality_in_loop_id = write_is_unconditional; } } /* The conditionality of the first write is already resolved. */ if (conditionality_in_loop_id == write_is_unconditional || conditionality_in_loop_id == write_is_conditional) return; /* If the nesting depth is larger than the supported level, * then we assume conditional writes. */ if (next_ifelse_nesting_depth >= supported_ifelse_nesting_depth) { conditionality_in_loop_id = write_is_conditional; return; } /* If we are in an IF/ELSE scope within a loop and the loop has not * been resolved already, then record this write. */ const prog_scope *ifelse_scope = scope->in_ifelse_scope(); if (ifelse_scope && ifelse_scope->innermost_loop() && ifelse_scope->innermost_loop()->id() != conditionality_in_loop_id) record_ifelse_write(*ifelse_scope); } void temp_comp_access::record_ifelse_write(const prog_scope& scope) { if (scope.type() == if_branch) { /* The first write in an IF branch within a loop implies unresolved * conditionality (if it was untouched or unconditional before). */ conditionality_in_loop_id = conditionality_unresolved; was_written_in_current_else_scope = false; record_if_write(scope); } else { was_written_in_current_else_scope = true; record_else_write(scope); } } void temp_comp_access::record_if_write(const prog_scope& scope) { /* Don't record write if this IF scope if it ... * - is not the first write in this IF scope, * - has already been written in a parent IF scope. * In both cases this write is a secondary write that doesn't contribute * to resolve conditionality. * * Record the write if it * - is the first one (obviously), * - happens in an IF branch that is a child of the ELSE branch of the * last active IF/ELSE pair. In this case recording this write is used to * established whether the write is (un-)conditional in the scope enclosing * this outer IF/ELSE pair. */ if (!current_unpaired_if_write_scope || (current_unpaired_if_write_scope->id() != scope.id() && scope.is_child_of_ifelse_id_sibling(current_unpaired_if_write_scope))) { if_scope_write_flags |= 1 << next_ifelse_nesting_depth; current_unpaired_if_write_scope = &scope; next_ifelse_nesting_depth++; } } void temp_comp_access::record_else_write(const prog_scope& scope) { int mask = 1 << (next_ifelse_nesting_depth - 1); /* If the temporary was written in an IF branch on the same scope level * and this branch is the sibling of this ELSE branch, then we have a * pair of writes that makes write access to this temporary unconditional * in the enclosing scope. */ if ((if_scope_write_flags & mask) && (scope.id() == current_unpaired_if_write_scope->id())) { --next_ifelse_nesting_depth; if_scope_write_flags &= ~mask; /* The following code deals with propagating unconditionality from * inner levels of nested IF/ELSE to the outer levels like in * * 1: var t; * 2: if (a) { <- start scope A * 3: if (b) * 4: t = ... * 5: else * 6: t = ... * 7: } else { <- start scope B * 8: if (c) * 9: t = ... * A: else <- start scope C * B: t = ... * C: } * */ const prog_scope *parent_ifelse = scope.parent()->in_ifelse_scope(); if (1 << (next_ifelse_nesting_depth - 1) & if_scope_write_flags) { /* We are at the end of scope C and already recorded a write * within an IF scope (A), the sibling of the parent ELSE scope B, * and it is not yet resolved. Mark that as the last relevant * IF scope. Below the write will be resolved for the A/B * scope pair. */ current_unpaired_if_write_scope = parent_ifelse; } else { current_unpaired_if_write_scope = nullptr; } /* If some parent is IF/ELSE and in a loop then propagate the * write to that scope. Otherwise the write is unconditional * because it happens in both corresponding IF/ELSE branches * in this loop, and hence, record the loop id to signal the * resolution. */ if (parent_ifelse && parent_ifelse->is_in_loop()) { record_ifelse_write(*parent_ifelse); } else { conditionality_in_loop_id = scope.innermost_loop()->id(); } } else { /* The temporary was not written in the IF branch corresponding * to this ELSE branch, hence the write is conditional. */ conditionality_in_loop_id = write_is_conditional; } } bool temp_comp_access::conditional_ifelse_write_in_loop() const { return conditionality_in_loop_id <= conditionality_unresolved; } void temp_comp_access::propagate_lifetime_to_dominant_write_scope() { first_write = first_write_scope->begin(); int lr = first_write_scope->end(); if (last_read < lr) last_read = lr; } lifetime temp_comp_access::get_required_lifetime() { bool keep_for_full_loop = false; /* This register component is not used at all, or only read, * mark it as unused and ignore it when renaming. * glsl_to_tgsi_visitor::renumber_registers will take care of * eliminating registers that are not written to. */ if (last_write < 0) return make_lifetime(-1, -1); assert(first_write_scope); /* Only written to, just make sure the register component is not * reused in the range it is used to write to */ if (!last_read_scope) return make_lifetime(first_write, last_write + 1); const prog_scope *enclosing_scope_first_read = first_read_scope; const prog_scope *enclosing_scope_first_write = first_write_scope; /* We read before writing in a loop * hence the value must survive the loops */ if ((first_read <= first_write) && first_read_scope->is_in_loop()) { keep_for_full_loop = true; enclosing_scope_first_read = first_read_scope->outermost_loop(); } /* A conditional write within a (nested) loop must survive the outermost * loop if the last read was not within the same scope. */ const prog_scope *conditional = enclosing_scope_first_write->enclosing_conditional(); if (conditional && !conditional->contains_range_of(*last_read_scope) && (conditional->is_switchcase_scope_in_loop() || conditional_ifelse_write_in_loop())) { keep_for_full_loop = true; enclosing_scope_first_write = conditional->outermost_loop(); } /* Evaluate the scope that is shared by all: required first write scope, * required first read before write scope, and last read scope. */ const prog_scope *enclosing_scope = enclosing_scope_first_read; if (enclosing_scope_first_write->contains_range_of(*enclosing_scope)) enclosing_scope = enclosing_scope_first_write; if (last_read_scope->contains_range_of(*enclosing_scope)) enclosing_scope = last_read_scope; while (!enclosing_scope->contains_range_of(*enclosing_scope_first_write) || !enclosing_scope->contains_range_of(*last_read_scope)) { enclosing_scope = enclosing_scope->parent(); assert(enclosing_scope); } /* Propagate the last read scope to the target scope */ while (enclosing_scope->nesting_depth() < last_read_scope->nesting_depth()) { /* If the read is in a loop and we have to move up the scope we need to * extend the life time to the end of this current loop because at this * point we don't know whether the component was written before * un-conditionally in the same loop. */ if (last_read_scope->is_loop()) last_read = last_read_scope->end(); last_read_scope = last_read_scope->parent(); } /* If the variable has to be kept for the whole loop, and we * are currently in a loop, then propagate the life time. */ if (keep_for_full_loop && first_write_scope->is_loop()) propagate_lifetime_to_dominant_write_scope(); /* Propagate the first_dominant_write scope to the target scope */ while (enclosing_scope->nesting_depth() < first_write_scope->nesting_depth()) { /* Propagate lifetime if there was a break in a loop and the write was * after the break inside that loop. Note, that this is only needed if * we move up in the scopes. */ if (first_write_scope->loop_break_line() < first_write) { keep_for_full_loop = true; propagate_lifetime_to_dominant_write_scope(); } first_write_scope = first_write_scope->parent(); /* Propagte lifetime if we are now in a loop */ if (keep_for_full_loop && first_write_scope->is_loop()) propagate_lifetime_to_dominant_write_scope(); } /* The last write past the last read is dead code, but we have to * ensure that the component is not reused too early, hence extend the * lifetime past the last write. */ if (last_write >= last_read) last_read = last_write + 1; /* Here we are at the same scope, all is resolved */ return make_lifetime(first_write, last_read); } /* Helper class for sorting and searching the registers based * on life times. */ class access_record { public: int begin; int end; int reg; bool erase; bool operator < (const access_record& rhs) const { return begin < rhs.begin; } }; class access_recorder { public: access_recorder(int _ntemps); ~access_recorder(); void record_read(const st_src_reg& src, int line, prog_scope *scope); void record_write(const st_dst_reg& src, int line, prog_scope *scope); void get_required_lifetimes(struct lifetime *lifetimes); private: int ntemps; temp_access *acc; }; access_recorder::access_recorder(int _ntemps): ntemps(_ntemps) { acc = new temp_access[ntemps]; } access_recorder::~access_recorder() { delete[] acc; } void access_recorder::record_read(const st_src_reg& src, int line, prog_scope *scope) { if (src.file == PROGRAM_TEMPORARY) acc[src.index].record_read(line, scope, src.swizzle); if (src.reladdr) record_read(*src.reladdr, line, scope); if (src.reladdr2) record_read(*src.reladdr2, line, scope); } void access_recorder::record_write(const st_dst_reg& dst, int line, prog_scope *scope) { if (dst.file == PROGRAM_TEMPORARY) acc[dst.index].record_write(line, scope, dst.writemask); if (dst.reladdr) record_read(*dst.reladdr, line, scope); if (dst.reladdr2) record_read(*dst.reladdr2, line, scope); } void access_recorder::get_required_lifetimes(struct lifetime *lifetimes) { RENAME_DEBUG(debug_log << "========= lifetimes ==============\n"); for(int i = 0; i < ntemps; ++i) { RENAME_DEBUG(debug_log<< setw(4) << i); lifetimes[i] = acc[i].get_required_lifetime(); RENAME_DEBUG(debug_log << ": [" << lifetimes[i].begin << ", " << lifetimes[i].end << "]\n"); } RENAME_DEBUG(debug_log << "==================================\n\n"); } } #ifndef NDEBUG /* Function used for debugging. */ static void dump_instruction(ostream& os, int line, prog_scope *scope, const glsl_to_tgsi_instruction& inst); #endif /* Scan the program and estimate the required register life times. * The array lifetimes must be pre-allocated */ bool get_temp_registers_required_lifetimes(void *mem_ctx, exec_list *instructions, int ntemps, struct lifetime *lifetimes) { int line = 0; int loop_id = 1; int if_id = 1; int switch_id = 0; bool is_at_end = false; int n_scopes = 1; /* Count scopes to allocate the needed space without the need for * re-allocation */ foreach_in_list(glsl_to_tgsi_instruction, inst, instructions) { if (inst->op == TGSI_OPCODE_BGNLOOP || inst->op == TGSI_OPCODE_SWITCH || inst->op == TGSI_OPCODE_CASE || inst->op == TGSI_OPCODE_IF || inst->op == TGSI_OPCODE_UIF || inst->op == TGSI_OPCODE_ELSE || inst->op == TGSI_OPCODE_DEFAULT) ++n_scopes; } prog_scope_storage scopes(mem_ctx, n_scopes); access_recorder access(ntemps); prog_scope *cur_scope = scopes.create(nullptr, outer_scope, 0, 0, line); RENAME_DEBUG(debug_log << "========= Begin shader ============\n"); foreach_in_list(glsl_to_tgsi_instruction, inst, instructions) { if (is_at_end) { assert(!"GLSL_TO_TGSI: shader has instructions past end marker"); break; } RENAME_DEBUG(dump_instruction(debug_log, line, cur_scope, *inst)); switch (inst->op) { case TGSI_OPCODE_BGNLOOP: { cur_scope = scopes.create(cur_scope, loop_body, loop_id++, cur_scope->nesting_depth() + 1, line); break; } case TGSI_OPCODE_ENDLOOP: { cur_scope->set_end(line); cur_scope = cur_scope->parent(); assert(cur_scope); break; } case TGSI_OPCODE_IF: case TGSI_OPCODE_UIF: { assert(num_inst_src_regs(inst) == 1); access.record_read(inst->src[0], line, cur_scope); cur_scope = scopes.create(cur_scope, if_branch, if_id++, cur_scope->nesting_depth() + 1, line + 1); break; } case TGSI_OPCODE_ELSE: { assert(cur_scope->type() == if_branch); cur_scope->set_end(line - 1); cur_scope = scopes.create(cur_scope->parent(), else_branch, cur_scope->id(), cur_scope->nesting_depth(), line + 1); break; } case TGSI_OPCODE_END: { cur_scope->set_end(line); is_at_end = true; break; } case TGSI_OPCODE_ENDIF: { cur_scope->set_end(line - 1); cur_scope = cur_scope->parent(); assert(cur_scope); break; } case TGSI_OPCODE_SWITCH: { assert(num_inst_src_regs(inst) == 1); prog_scope *scope = scopes.create(cur_scope, switch_body, switch_id++, cur_scope->nesting_depth() + 1, line); /* We record the read only for the SWITCH statement itself, like it * is used by the only consumer of TGSI_OPCODE_SWITCH in tgsi_exec.c. */ access.record_read(inst->src[0], line, cur_scope); cur_scope = scope; break; } case TGSI_OPCODE_ENDSWITCH: { cur_scope->set_end(line - 1); /* Remove the case level, it might not have been * closed with a break. */ if (cur_scope->type() != switch_body) cur_scope = cur_scope->parent(); cur_scope = cur_scope->parent(); assert(cur_scope); break; } case TGSI_OPCODE_CASE: { /* Take care of tracking the registers. */ prog_scope *switch_scope = cur_scope->type() == switch_body ? cur_scope : cur_scope->parent(); assert(num_inst_src_regs(inst) == 1); access.record_read(inst->src[0], line, switch_scope); /* Fall through to allocate the scope. */ } case TGSI_OPCODE_DEFAULT: { prog_scope_type t = inst->op == TGSI_OPCODE_CASE ? switch_case_branch : switch_default_branch; prog_scope *switch_scope = (cur_scope->type() == switch_body) ? cur_scope : cur_scope->parent(); assert(switch_scope->type() == switch_body); prog_scope *scope = scopes.create(switch_scope, t, switch_scope->id(), switch_scope->nesting_depth() + 1, line); /* Previous case falls through, so scope was not yet closed. */ if ((cur_scope != switch_scope) && (cur_scope->end() == -1)) cur_scope->set_end(line - 1); cur_scope = scope; break; } case TGSI_OPCODE_BRK: { if (cur_scope->break_is_for_switchcase()) { cur_scope->set_end(line - 1); } else { cur_scope->set_loop_break_line(line); } break; } case TGSI_OPCODE_CAL: case TGSI_OPCODE_RET: /* These opcodes are not supported and if a subroutine would * be called in a shader, then the lifetime tracking would have * to follow that call to see which registers are used there. * Since this is not done, we have to bail out here and signal * that no register merge will take place. */ return false; default: { for (unsigned j = 0; j < num_inst_src_regs(inst); j++) { access.record_read(inst->src[j], line, cur_scope); } for (unsigned j = 0; j < inst->tex_offset_num_offset; j++) { access.record_read(inst->tex_offsets[j], line, cur_scope); } for (unsigned j = 0; j < num_inst_dst_regs(inst); j++) { access.record_write(inst->dst[j], line, cur_scope); } } } ++line; } RENAME_DEBUG(debug_log << "==================================\n\n"); /* Make sure last scope is closed, even though no * TGSI_OPCODE_END was given. */ if (cur_scope->end() < 0) cur_scope->set_end(line - 1); access.get_required_lifetimes(lifetimes); return true; } /* Find the next register between [start, end) that has a life time starting * at or after bound by using a binary search. * start points at the beginning of the search range, * end points at the element past the end of the search range, and * the array comprising [start, end) must be sorted in ascending order. */ static access_record* find_next_rename(access_record* start, access_record* end, int bound) { int delta = (end - start); while (delta > 0) { int half = delta >> 1; access_record* middle = start + half; if (bound <= middle->begin) { delta = half; } else { start = middle; ++start; delta -= half + 1; } } return start; } #ifndef USE_STL_SORT static int access_record_compare (const void *a, const void *b) { const access_record *aa = static_cast(a); const access_record *bb = static_cast(b); return aa->begin < bb->begin ? -1 : (aa->begin > bb->begin ? 1 : 0); } #endif /* This functions evaluates the register merges by using a binary * search to find suitable merge candidates. */ void get_temp_registers_remapping(void *mem_ctx, int ntemps, const struct lifetime* lifetimes, struct rename_reg_pair *result) { access_record *reg_access = ralloc_array(mem_ctx, access_record, ntemps); int used_temps = 0; for (int i = 0; i < ntemps; ++i) { if (lifetimes[i].begin >= 0) { reg_access[used_temps].begin = lifetimes[i].begin; reg_access[used_temps].end = lifetimes[i].end; reg_access[used_temps].reg = i; reg_access[used_temps].erase = false; ++used_temps; } } #ifdef USE_STL_SORT std::sort(reg_access, reg_access + used_temps); #else std::qsort(reg_access, used_temps, sizeof(access_record), access_record_compare); #endif access_record *trgt = reg_access; access_record *reg_access_end = reg_access + used_temps; access_record *first_erase = reg_access_end; access_record *search_start = trgt + 1; while (trgt != reg_access_end) { access_record *src = find_next_rename(search_start, reg_access_end, trgt->end); if (src != reg_access_end) { result[src->reg].new_reg = trgt->reg; result[src->reg].valid = true; trgt->end = src->end; /* Since we only search forward, don't remove the renamed * register just now, only mark it. */ src->erase = true; if (first_erase == reg_access_end) first_erase = src; search_start = src + 1; } else { /* Moving to the next target register it is time to remove * the already merged registers from the search range */ if (first_erase != reg_access_end) { access_record *outp = first_erase; access_record *inp = first_erase + 1; while (inp != reg_access_end) { if (!inp->erase) *outp++ = *inp; ++inp; } reg_access_end = outp; first_erase = reg_access_end; } ++trgt; search_start = trgt + 1; } } ralloc_free(reg_access); } /* Code below used for debugging */ #ifndef NDEBUG static void dump_instruction(ostream& os, int line, prog_scope *scope, const glsl_to_tgsi_instruction& inst) { const struct tgsi_opcode_info *info = inst.info; int indent = scope->nesting_depth(); if ((scope->type() == switch_case_branch || scope->type() == switch_default_branch) && (info->opcode == TGSI_OPCODE_CASE || info->opcode == TGSI_OPCODE_DEFAULT)) --indent; if (info->opcode == TGSI_OPCODE_ENDIF || info->opcode == TGSI_OPCODE_ELSE || info->opcode == TGSI_OPCODE_ENDLOOP || info->opcode == TGSI_OPCODE_ENDSWITCH) --indent; os << setw(4) << line << ": "; os << setw(indent * 4) << " "; os << inst << "\n"; } #endif