diff options
author | Paul Berry <[email protected]> | 2013-04-21 08:51:33 -0700 |
---|---|---|
committer | Paul Berry <[email protected]> | 2013-09-11 11:17:54 -0700 |
commit | ebcdaa7bbc3a10fe59447ae77b508ee85eaa582f (patch) | |
tree | d607350ec2c1e39884997265805c16d26f32ac43 /src | |
parent | 564a900a4539996b139b8d7618a40b22bbad1290 (diff) |
i965/gs: implement EndPrimitive() functionality in the visitor.
According to GLSL, the shader may call EndPrimitive() at any point
during its execution, causing the line or triangle strip currently
being output to be terminated and a new strip to be begun.
This is implemented in gen7 hardware by using one control data bit per
vertex, to indicate whether EndPrimitive() was called after that
vertex was emitted.
In order to make this work without sacrificing too much efficiency, we
accumulate 32 control data bits at a time in a GRF. When we have
accumulated 32 bits (or when the shader terminates), we output them to
the appropriate DWORD in the control data header and reset the
accumulator to 0.
We have to take special care to make sure that EndPrimitive() calls
that occur prior to the first vertex have no effect.
Since geometry shaders that output a large number of vertices are
likely to be rare, an optimization kicks in if max_vertices <= 32. In
this case, we know that we can wait until the end of shader execution
before any control data bits need to be output.
I've tried to write the code in such a way that in the future, we can
easily adapt it to output stream ID bits (which are two bits/vertex
instead of one).
Fixes piglit tests "spec/glsl-1.50/glsl-1.50-geometry-end-primitive *".
Reviewed-by: Ian Romanick <[email protected]>
Reviewed-by: Kenneth Graunke <[email protected]>
Diffstat (limited to 'src')
-rw-r--r-- | src/mesa/drivers/dri/i965/brw_vec4_gs_visitor.cpp | 240 | ||||
-rw-r--r-- | src/mesa/drivers/dri/i965/brw_vec4_gs_visitor.h | 2 |
2 files changed, 241 insertions, 1 deletions
diff --git a/src/mesa/drivers/dri/i965/brw_vec4_gs_visitor.cpp b/src/mesa/drivers/dri/i965/brw_vec4_gs_visitor.cpp index 37cde6437cd..960f9703252 100644 --- a/src/mesa/drivers/dri/i965/brw_vec4_gs_visitor.cpp +++ b/src/mesa/drivers/dri/i965/brw_vec4_gs_visitor.cpp @@ -135,6 +135,23 @@ vec4_gs_visitor::emit_prolog() vec4_instruction *inst = emit(MOV(dst_reg(this->vertex_count), 0u)); inst->force_writemask_all = true; + if (c->control_data_header_size_bits > 0) { + /* Create a virtual register to hold the current set of control data + * bits. + */ + this->control_data_bits = src_reg(this, glsl_type::uint_type); + + /* If we're outputting more than 32 control data bits, then EmitVertex() + * will set control_data_bits to 0 after emitting the first vertex. + * Otherwise, we need to initialize it to 0 here. + */ + if (c->control_data_header_size_bits <= 32) { + this->current_annotation = "initialize control data bits"; + inst = emit(MOV(dst_reg(this->control_data_bits), 0u)); + inst->force_writemask_all = true; + } + } + this->current_annotation = NULL; } @@ -150,6 +167,16 @@ vec4_gs_visitor::emit_program_code() void vec4_gs_visitor::emit_thread_end() { + if (c->control_data_header_size_bits > 0) { + /* During shader execution, we only ever call emit_control_data_bits() + * just prior to outputting a vertex. Therefore, the control data bits + * corresponding to the most recently output vertex still need to be + * emitted. + */ + current_annotation = "thread end: emit control data bits"; + emit_control_data_bits(); + } + /* MRF 0 is reserved for the debugger, so start with message header * in MRF 1. */ @@ -224,6 +251,124 @@ vec4_gs_visitor::compute_array_stride(ir_dereference_array *ir) } +/** + * Write out a batch of 32 control data bits from the control_data_bits + * register to the URB. + * + * The current value of the vertex_count register determines which DWORD in + * the URB receives the control data bits. The control_data_bits register is + * assumed to contain the correct data for the vertex that was most recently + * output, and all previous vertices that share the same DWORD. + * + * This function takes care of ensuring that if no vertices have been output + * yet, no control bits are emitted. + */ +void +vec4_gs_visitor::emit_control_data_bits() +{ + assert(c->control_data_bits_per_vertex != 0); + + /* Since the URB_WRITE_OWORD message operates with 128-bit (vec4 sized) + * granularity, we need to use two tricks to ensure that the batch of 32 + * control data bits is written to the appropriate DWORD in the URB. To + * select which vec4 we are writing to, we use the "slot {0,1} offset" + * fields of the message header. To select which DWORD in the vec4 we are + * writing to, we use the channel mask fields of the message header. To + * avoid penalizing geometry shaders that emit a small number of vertices + * with extra bookkeeping, we only do each of these tricks when + * c->prog_data.control_data_header_size_bits is large enough to make it + * necessary. + * + * Note: this means that if we're outputting just a single DWORD of control + * data bits, we'll actually replicate it four times since we won't do any + * channel masking. But that's not a problem since in this case the + * hardware only pays attention to the first DWORD. + */ + enum brw_urb_write_flags urb_write_flags = BRW_URB_WRITE_OWORD; + if (c->control_data_header_size_bits > 32) + urb_write_flags = urb_write_flags | BRW_URB_WRITE_USE_CHANNEL_MASKS; + if (c->control_data_header_size_bits > 128) + urb_write_flags = urb_write_flags | BRW_URB_WRITE_PER_SLOT_OFFSET; + + /* If vertex_count is 0, then no control data bits have been accumulated + * yet, so we should do nothing. + */ + emit(CMP(dst_null_d(), this->vertex_count, 0u, BRW_CONDITIONAL_NEQ)); + emit(IF(BRW_PREDICATE_NORMAL)); + { + /* If we are using either channel masks or a per-slot offset, then we + * need to figure out which DWORD we are trying to write to, using the + * formula: + * + * dword_index = (vertex_count - 1) * bits_per_vertex / 32 + * + * Since bits_per_vertex is a power of two, and is known at compile + * time, this can be optimized to: + * + * dword_index = (vertex_count - 1) >> (6 - log2(bits_per_vertex)) + */ + src_reg dword_index(this, glsl_type::uint_type); + if (urb_write_flags) { + src_reg prev_count(this, glsl_type::uint_type); + emit(ADD(dst_reg(prev_count), this->vertex_count, 0xffffffffu)); + unsigned log2_bits_per_vertex = + _mesa_fls(c->control_data_bits_per_vertex); + emit(SHR(dst_reg(dword_index), prev_count, + (uint32_t) (6 - log2_bits_per_vertex))); + } + + /* Start building the URB write message. The first MRF gets a copy of + * R0. + */ + int base_mrf = 1; + dst_reg mrf_reg(MRF, base_mrf); + src_reg r0(retype(brw_vec8_grf(0, 0), BRW_REGISTER_TYPE_UD)); + vec4_instruction *inst = emit(MOV(mrf_reg, r0)); + inst->force_writemask_all = true; + + if (urb_write_flags & BRW_URB_WRITE_PER_SLOT_OFFSET) { + /* Set the per-slot offset to dword_index / 4, to that we'll write to + * the appropriate OWORD within the control data header. + */ + src_reg per_slot_offset(this, glsl_type::uint_type); + emit(SHR(dst_reg(per_slot_offset), dword_index, 2u)); + emit(GS_OPCODE_SET_WRITE_OFFSET, mrf_reg, per_slot_offset, 1u); + } + + if (urb_write_flags & BRW_URB_WRITE_USE_CHANNEL_MASKS) { + /* Set the channel masks to 1 << (dword_index % 4), so that we'll + * write to the appropriate DWORD within the OWORD. We need to do + * this computation with force_writemask_all, otherwise garbage data + * from invocation 0 might clobber the mask for invocation 1 when + * GS_OPCODE_PREPARE_CHANNEL_MASKS tries to OR the two masks + * together. + */ + src_reg channel(this, glsl_type::uint_type); + inst = emit(AND(dst_reg(channel), dword_index, 3u)); + inst->force_writemask_all = true; + src_reg one(this, glsl_type::uint_type); + inst = emit(MOV(dst_reg(one), 1u)); + inst->force_writemask_all = true; + src_reg channel_mask(this, glsl_type::uint_type); + inst = emit(SHL(dst_reg(channel_mask), one, channel)); + inst->force_writemask_all = true; + emit(GS_OPCODE_PREPARE_CHANNEL_MASKS, dst_reg(channel_mask)); + emit(GS_OPCODE_SET_CHANNEL_MASKS, mrf_reg, channel_mask); + } + + /* Store the control data bits in the message payload and send it. */ + dst_reg mrf_reg2(MRF, base_mrf + 1); + inst = emit(MOV(mrf_reg2, this->control_data_bits)); + inst->force_writemask_all = true; + inst = emit(GS_OPCODE_URB_WRITE); + inst->urb_write_flags = urb_write_flags; + inst->base_mrf = base_mrf; + inst->mlen = 2; + } + emit(BRW_OPCODE_ENDIF); +} + + void vec4_gs_visitor::visit(ir_emit_vertex *) { @@ -238,6 +383,54 @@ vec4_gs_visitor::visit(ir_emit_vertex *) src_reg(num_output_vertices), BRW_CONDITIONAL_L)); emit(IF(BRW_PREDICATE_NORMAL)); { + /* If we're outputting 32 control data bits or less, then we can wait + * until the shader is over to output them all. Otherwise we need to + * output them as we go. Now is the time to do it, since we're about to + * output the vertex_count'th vertex, so it's guaranteed that the + * control data bits associated with the (vertex_count - 1)th vertex are + * correct. + */ + if (c->control_data_header_size_bits > 32) { + this->current_annotation = "emit vertex: emit control data bits"; + /* Only emit control data bits if we've finished accumulating a batch + * of 32 bits. This is the case when: + * + * (vertex_count * bits_per_vertex) % 32 == 0 + * + * (in other words, when the last 5 bits of vertex_count * + * bits_per_vertex are 0). Assuming bits_per_vertex == 2^n for some + * integer n (which is always the case, since bits_per_vertex is + * always 1 or 2), this is equivalent to requiring that the last 5-n + * bits of vertex_count are 0: + * + * vertex_count & (2^(5-n) - 1) == 0 + * + * 2^(5-n) == 2^5 / 2^n == 32 / bits_per_vertex, so this is + * equivalent to: + * + * vertex_count & (32 / bits_per_vertex - 1) == 0 + */ + vec4_instruction *inst = + emit(AND(dst_null_d(), this->vertex_count, + (uint32_t) (32 / c->control_data_bits_per_vertex - 1))); + inst->conditional_mod = BRW_CONDITIONAL_Z; + emit(IF(BRW_PREDICATE_NORMAL)); + { + emit_control_data_bits(); + + /* Reset control_data_bits to 0 so we can start accumulating a new + * batch. + * + * Note: in the case where vertex_count == 0, this neutralizes the + * effect of any call to EndPrimitive() that the shader may have + * made before outputting its first vertex. + */ + inst = emit(MOV(dst_reg(this->control_data_bits), 0u)); + inst->force_writemask_all = true; + } + emit(BRW_OPCODE_ENDIF); + } + this->current_annotation = "emit vertex: vertex data"; emit_vertex(); @@ -253,7 +446,52 @@ vec4_gs_visitor::visit(ir_emit_vertex *) void vec4_gs_visitor::visit(ir_end_primitive *) { - assert(!"Not implemented yet"); + /* We can only do EndPrimitive() functionality when the control data + * consists of cut bits. Fortunately, the only time it isn't is when the + * output type is points, in which case EndPrimitive() is a no-op. + */ + if (c->prog_data.control_data_format != + GEN7_GS_CONTROL_DATA_FORMAT_GSCTL_CUT) { + return; + } + + /* Cut bits use one bit per vertex. */ + assert(c->control_data_bits_per_vertex == 1); + + /* Cut bit n should be set to 1 if EndPrimitive() was called after emitting + * vertex n, 0 otherwise. So all we need to do here is mark bit + * (vertex_count - 1) % 32 in the cut_bits register to indicate that + * EndPrimitive() was called after emitting vertex (vertex_count - 1); + * vec4_gs_visitor::emit_control_data_bits() will take care of the rest. + * + * Note that if EndPrimitve() is called before emitting any vertices, this + * will cause us to set bit 31 of the control_data_bits register to 1. + * That's fine because: + * + * - If max_vertices < 32, then vertex number 31 (zero-based) will never be + * output, so the hardware will ignore cut bit 31. + * + * - If max_vertices == 32, then vertex number 31 is guaranteed to be the + * last vertex, so setting cut bit 31 has no effect (since the primitive + * is automatically ended when the GS terminates). + * + * - If max_vertices > 32, then the ir_emit_vertex visitor will reset the + * control_data_bits register to 0 when the first vertex is emitted. + */ + + /* control_data_bits |= 1 << ((vertex_count - 1) % 32) */ + src_reg one(this, glsl_type::uint_type); + emit(MOV(dst_reg(one), 1u)); + src_reg prev_count(this, glsl_type::uint_type); + emit(ADD(dst_reg(prev_count), this->vertex_count, 0xffffffffu)); + src_reg mask(this, glsl_type::uint_type); + /* Note: we're relying on the fact that the GEN SHL instruction only pays + * attention to the lower 5 bits of its second source argument, so on this + * architecture, 1 << (vertex_count - 1) is equivalent to 1 << + * ((vertex_count - 1) % 32). + */ + emit(SHL(dst_reg(mask), one, prev_count)); + emit(OR(dst_reg(this->control_data_bits), this->control_data_bits, mask)); } diff --git a/src/mesa/drivers/dri/i965/brw_vec4_gs_visitor.h b/src/mesa/drivers/dri/i965/brw_vec4_gs_visitor.h index 1193e28715c..90dd1de7c7a 100644 --- a/src/mesa/drivers/dri/i965/brw_vec4_gs_visitor.h +++ b/src/mesa/drivers/dri/i965/brw_vec4_gs_visitor.h @@ -96,8 +96,10 @@ protected: private: int setup_varying_inputs(int payload_reg, int *attribute_map); + void emit_control_data_bits(); src_reg vertex_count; + src_reg control_data_bits; const struct brw_gs_compile * const c; }; |