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-rw-r--r--src/intel/compiler/brw_compile_ff_gs.c660
1 files changed, 0 insertions, 660 deletions
diff --git a/src/intel/compiler/brw_compile_ff_gs.c b/src/intel/compiler/brw_compile_ff_gs.c
deleted file mode 100644
index a5cc45a4876..00000000000
--- a/src/intel/compiler/brw_compile_ff_gs.c
+++ /dev/null
@@ -1,660 +0,0 @@
-/*
- Copyright (C) Intel Corp. 2006. All Rights Reserved.
- Intel funded Tungsten Graphics to
- develop this 3D driver.
-
- 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 COPYRIGHT OWNER(S) AND/OR ITS SUPPLIERS 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.
-
- **********************************************************************/
- /*
- * Authors:
- * Keith Whitwell <keithw@vmware.com>
- */
-
-#include "brw_compiler.h"
-#include "brw_eu.h"
-
-#include "dev/intel_debug.h"
-
-#define MAX_GS_VERTS (4)
-
-struct brw_ff_gs_compile {
- struct brw_codegen func;
- struct brw_ff_gs_prog_key key;
- struct brw_ff_gs_prog_data *prog_data;
-
- struct {
- struct brw_reg R0;
-
- /**
- * Register holding streamed vertex buffer pointers -- see the Sandy
- * Bridge PRM, volume 2 part 1, section 4.4.2 (GS Thread Payload
- * [DevSNB]). These pointers are delivered in GRF 1.
- */
- struct brw_reg SVBI;
-
- struct brw_reg vertex[MAX_GS_VERTS];
- struct brw_reg header;
- struct brw_reg temp;
-
- /**
- * Register holding destination indices for streamed buffer writes.
- * Only used for SOL programs.
- */
- struct brw_reg destination_indices;
- } reg;
-
- /* Number of registers used to store vertex data */
- GLuint nr_regs;
-
- struct brw_vue_map vue_map;
-};
-
-/**
- * Allocate registers for GS.
- *
- * If sol_program is true, then:
- *
- * - The thread will be spawned with the "SVBI Payload Enable" bit set, so GRF
- * 1 needs to be set aside to hold the streamed vertex buffer indices.
- *
- * - The thread will need to use the destination_indices register.
- */
-static void brw_ff_gs_alloc_regs(struct brw_ff_gs_compile *c,
- GLuint nr_verts,
- bool sol_program)
-{
- GLuint i = 0,j;
-
- /* Register usage is static, precompute here:
- */
- c->reg.R0 = retype(brw_vec8_grf(i, 0), BRW_REGISTER_TYPE_UD); i++;
-
- /* Streamed vertex buffer indices */
- if (sol_program)
- c->reg.SVBI = retype(brw_vec8_grf(i++, 0), BRW_REGISTER_TYPE_UD);
-
- /* Payload vertices plus space for more generated vertices:
- */
- for (j = 0; j < nr_verts; j++) {
- c->reg.vertex[j] = brw_vec4_grf(i, 0);
- i += c->nr_regs;
- }
-
- c->reg.header = retype(brw_vec8_grf(i++, 0), BRW_REGISTER_TYPE_UD);
- c->reg.temp = retype(brw_vec8_grf(i++, 0), BRW_REGISTER_TYPE_UD);
-
- if (sol_program) {
- c->reg.destination_indices =
- retype(brw_vec4_grf(i++, 0), BRW_REGISTER_TYPE_UD);
- }
-
- c->prog_data->urb_read_length = c->nr_regs;
- c->prog_data->total_grf = i;
-}
-
-
-/**
- * Set up the initial value of c->reg.header register based on c->reg.R0.
- *
- * The following information is passed to the GS thread in R0, and needs to be
- * included in the first URB_WRITE or FF_SYNC message sent by the GS:
- *
- * - DWORD 0 [31:0] handle info (Gen4 only)
- * - DWORD 5 [7:0] FFTID
- * - DWORD 6 [31:0] Debug info
- * - DWORD 7 [31:0] Debug info
- *
- * This function sets up the above data by copying by copying the contents of
- * R0 to the header register.
- */
-static void brw_ff_gs_initialize_header(struct brw_ff_gs_compile *c)
-{
- struct brw_codegen *p = &c->func;
- brw_MOV(p, c->reg.header, c->reg.R0);
-}
-
-/**
- * Overwrite DWORD 2 of c->reg.header with the given immediate unsigned value.
- *
- * In URB_WRITE messages, DWORD 2 contains the fields PrimType, PrimStart,
- * PrimEnd, Increment CL_INVOCATIONS, and SONumPrimsWritten, many of which we
- * need to be able to update on a per-vertex basis.
- */
-static void brw_ff_gs_overwrite_header_dw2(struct brw_ff_gs_compile *c,
- unsigned dw2)
-{
- struct brw_codegen *p = &c->func;
- brw_MOV(p, get_element_ud(c->reg.header, 2), brw_imm_ud(dw2));
-}
-
-/**
- * Overwrite DWORD 2 of c->reg.header with the primitive type from c->reg.R0.
- *
- * When the thread is spawned, GRF 0 contains the primitive type in bits 4:0
- * of DWORD 2. URB_WRITE messages need the primitive type in bits 6:2 of
- * DWORD 2. So this function extracts the primitive type field, bitshifts it
- * appropriately, and stores it in c->reg.header.
- */
-static void brw_ff_gs_overwrite_header_dw2_from_r0(struct brw_ff_gs_compile *c)
-{
- struct brw_codegen *p = &c->func;
- brw_AND(p, get_element_ud(c->reg.header, 2), get_element_ud(c->reg.R0, 2),
- brw_imm_ud(0x1f));
- brw_SHL(p, get_element_ud(c->reg.header, 2),
- get_element_ud(c->reg.header, 2), brw_imm_ud(2));
-}
-
-/**
- * Apply an additive offset to DWORD 2 of c->reg.header.
- *
- * This is used to set/unset the "PrimStart" and "PrimEnd" flags appropriately
- * for each vertex.
- */
-static void brw_ff_gs_offset_header_dw2(struct brw_ff_gs_compile *c,
- int offset)
-{
- struct brw_codegen *p = &c->func;
- brw_ADD(p, get_element_d(c->reg.header, 2), get_element_d(c->reg.header, 2),
- brw_imm_d(offset));
-}
-
-
-/**
- * Emit a vertex using the URB_WRITE message. Use the contents of
- * c->reg.header for the message header, and the registers starting at \c vert
- * for the vertex data.
- *
- * If \c last is true, then this is the last vertex, so no further URB space
- * should be allocated, and this message should end the thread.
- *
- * If \c last is false, then a new URB entry will be allocated, and its handle
- * will be stored in DWORD 0 of c->reg.header for use in the next URB_WRITE
- * message.
- */
-static void brw_ff_gs_emit_vue(struct brw_ff_gs_compile *c,
- struct brw_reg vert,
- bool last)
-{
- struct brw_codegen *p = &c->func;
- int write_offset = 0;
- bool complete = false;
-
- do {
- /* We can't write more than 14 registers at a time to the URB */
- int write_len = MIN2(c->nr_regs - write_offset, 14);
- if (write_len == c->nr_regs - write_offset)
- complete = true;
-
- /* Copy the vertex from vertn into m1..mN+1:
- */
- brw_copy8(p, brw_message_reg(1), offset(vert, write_offset), write_len);
-
- /* Send the vertex data to the URB. If this is the last write for this
- * vertex, then we mark it as complete, and either end the thread or
- * allocate another vertex URB entry (depending whether this is the last
- * vertex).
- */
- enum brw_urb_write_flags flags;
- if (!complete)
- flags = BRW_URB_WRITE_NO_FLAGS;
- else if (last)
- flags = BRW_URB_WRITE_EOT_COMPLETE;
- else
- flags = BRW_URB_WRITE_ALLOCATE_COMPLETE;
- brw_urb_WRITE(p,
- (flags & BRW_URB_WRITE_ALLOCATE) ? c->reg.temp
- : retype(brw_null_reg(), BRW_REGISTER_TYPE_UD),
- 0,
- c->reg.header,
- flags,
- write_len + 1, /* msg length */
- (flags & BRW_URB_WRITE_ALLOCATE) ? 1
- : 0, /* response length */
- write_offset, /* urb offset */
- BRW_URB_SWIZZLE_NONE);
- write_offset += write_len;
- } while (!complete);
-
- if (!last) {
- brw_MOV(p, get_element_ud(c->reg.header, 0),
- get_element_ud(c->reg.temp, 0));
- }
-}
-
-/**
- * Send an FF_SYNC message to ensure that all previously spawned GS threads
- * have finished sending primitives down the pipeline, and to allocate a URB
- * entry for the first output vertex. Only needed on Ironlake+.
- *
- * This function modifies c->reg.header: in DWORD 1, it stores num_prim (which
- * is needed by the FF_SYNC message), and in DWORD 0, it stores the handle to
- * the allocated URB entry (which will be needed by the URB_WRITE meesage that
- * follows).
- */
-static void brw_ff_gs_ff_sync(struct brw_ff_gs_compile *c, int num_prim)
-{
- struct brw_codegen *p = &c->func;
-
- brw_MOV(p, get_element_ud(c->reg.header, 1), brw_imm_ud(num_prim));
- brw_ff_sync(p,
- c->reg.temp,
- 0,
- c->reg.header,
- 1, /* allocate */
- 1, /* response length */
- 0 /* eot */);
- brw_MOV(p, get_element_ud(c->reg.header, 0),
- get_element_ud(c->reg.temp, 0));
-}
-
-
-static void
-brw_ff_gs_quads(struct brw_ff_gs_compile *c,
- const struct brw_ff_gs_prog_key *key)
-{
- brw_ff_gs_alloc_regs(c, 4, false);
- brw_ff_gs_initialize_header(c);
- /* Use polygons for correct edgeflag behaviour. Note that vertex 3
- * is the PV for quads, but vertex 0 for polygons:
- */
- if (c->func.devinfo->ver == 5)
- brw_ff_gs_ff_sync(c, 1);
- brw_ff_gs_overwrite_header_dw2(
- c, ((_3DPRIM_POLYGON << URB_WRITE_PRIM_TYPE_SHIFT)
- | URB_WRITE_PRIM_START));
- if (key->pv_first) {
- brw_ff_gs_emit_vue(c, c->reg.vertex[0], 0);
- brw_ff_gs_overwrite_header_dw2(
- c, _3DPRIM_POLYGON << URB_WRITE_PRIM_TYPE_SHIFT);
- brw_ff_gs_emit_vue(c, c->reg.vertex[1], 0);
- brw_ff_gs_emit_vue(c, c->reg.vertex[2], 0);
- brw_ff_gs_overwrite_header_dw2(
- c, ((_3DPRIM_POLYGON << URB_WRITE_PRIM_TYPE_SHIFT)
- | URB_WRITE_PRIM_END));
- brw_ff_gs_emit_vue(c, c->reg.vertex[3], 1);
- }
- else {
- brw_ff_gs_emit_vue(c, c->reg.vertex[3], 0);
- brw_ff_gs_overwrite_header_dw2(
- c, _3DPRIM_POLYGON << URB_WRITE_PRIM_TYPE_SHIFT);
- brw_ff_gs_emit_vue(c, c->reg.vertex[0], 0);
- brw_ff_gs_emit_vue(c, c->reg.vertex[1], 0);
- brw_ff_gs_overwrite_header_dw2(
- c, ((_3DPRIM_POLYGON << URB_WRITE_PRIM_TYPE_SHIFT)
- | URB_WRITE_PRIM_END));
- brw_ff_gs_emit_vue(c, c->reg.vertex[2], 1);
- }
-}
-
-static void
-brw_ff_gs_quad_strip(struct brw_ff_gs_compile *c,
- const struct brw_ff_gs_prog_key *key)
-{
- brw_ff_gs_alloc_regs(c, 4, false);
- brw_ff_gs_initialize_header(c);
-
- if (c->func.devinfo->ver == 5)
- brw_ff_gs_ff_sync(c, 1);
- brw_ff_gs_overwrite_header_dw2(
- c, ((_3DPRIM_POLYGON << URB_WRITE_PRIM_TYPE_SHIFT)
- | URB_WRITE_PRIM_START));
- if (key->pv_first) {
- brw_ff_gs_emit_vue(c, c->reg.vertex[0], 0);
- brw_ff_gs_overwrite_header_dw2(
- c, _3DPRIM_POLYGON << URB_WRITE_PRIM_TYPE_SHIFT);
- brw_ff_gs_emit_vue(c, c->reg.vertex[1], 0);
- brw_ff_gs_emit_vue(c, c->reg.vertex[2], 0);
- brw_ff_gs_overwrite_header_dw2(
- c, ((_3DPRIM_POLYGON << URB_WRITE_PRIM_TYPE_SHIFT)
- | URB_WRITE_PRIM_END));
- brw_ff_gs_emit_vue(c, c->reg.vertex[3], 1);
- }
- else {
- brw_ff_gs_emit_vue(c, c->reg.vertex[2], 0);
- brw_ff_gs_overwrite_header_dw2(
- c, _3DPRIM_POLYGON << URB_WRITE_PRIM_TYPE_SHIFT);
- brw_ff_gs_emit_vue(c, c->reg.vertex[3], 0);
- brw_ff_gs_emit_vue(c, c->reg.vertex[0], 0);
- brw_ff_gs_overwrite_header_dw2(
- c, ((_3DPRIM_POLYGON << URB_WRITE_PRIM_TYPE_SHIFT)
- | URB_WRITE_PRIM_END));
- brw_ff_gs_emit_vue(c, c->reg.vertex[1], 1);
- }
-}
-
-static void brw_ff_gs_lines(struct brw_ff_gs_compile *c)
-{
- brw_ff_gs_alloc_regs(c, 2, false);
- brw_ff_gs_initialize_header(c);
-
- if (c->func.devinfo->ver == 5)
- brw_ff_gs_ff_sync(c, 1);
- brw_ff_gs_overwrite_header_dw2(
- c, ((_3DPRIM_LINESTRIP << URB_WRITE_PRIM_TYPE_SHIFT)
- | URB_WRITE_PRIM_START));
- brw_ff_gs_emit_vue(c, c->reg.vertex[0], 0);
- brw_ff_gs_overwrite_header_dw2(
- c, ((_3DPRIM_LINESTRIP << URB_WRITE_PRIM_TYPE_SHIFT)
- | URB_WRITE_PRIM_END));
- brw_ff_gs_emit_vue(c, c->reg.vertex[1], 1);
-}
-
-/**
- * Generate the geometry shader program used on Gen6 to perform stream output
- * (transform feedback).
- */
-static void
-gfx6_sol_program(struct brw_ff_gs_compile *c, const struct brw_ff_gs_prog_key *key,
- unsigned num_verts, bool check_edge_flags)
-{
- struct brw_codegen *p = &c->func;
- brw_inst *inst;
- c->prog_data->svbi_postincrement_value = num_verts;
-
- brw_ff_gs_alloc_regs(c, num_verts, true);
- brw_ff_gs_initialize_header(c);
-
- if (key->num_transform_feedback_bindings > 0) {
- unsigned vertex, binding;
- struct brw_reg destination_indices_uw =
- vec8(retype(c->reg.destination_indices, BRW_REGISTER_TYPE_UW));
-
- /* Note: since we use the binding table to keep track of buffer offsets
- * and stride, the GS doesn't need to keep track of a separate pointer
- * into each buffer; it uses a single pointer which increments by 1 for
- * each vertex. So we use SVBI0 for this pointer, regardless of whether
- * transform feedback is in interleaved or separate attribs mode.
- *
- * Make sure that the buffers have enough room for all the vertices.
- */
- brw_ADD(p, get_element_ud(c->reg.temp, 0),
- get_element_ud(c->reg.SVBI, 0), brw_imm_ud(num_verts));
- brw_CMP(p, vec1(brw_null_reg()), BRW_CONDITIONAL_LE,
- get_element_ud(c->reg.temp, 0),
- get_element_ud(c->reg.SVBI, 4));
- brw_IF(p, BRW_EXECUTE_1);
-
- /* Compute the destination indices to write to. Usually we use SVBI[0]
- * + (0, 1, 2). However, for odd-numbered triangles in tristrips, the
- * vertices come down the pipeline in reversed winding order, so we need
- * to flip the order when writing to the transform feedback buffer. To
- * ensure that flatshading accuracy is preserved, we need to write them
- * in order SVBI[0] + (0, 2, 1) if we're using the first provoking
- * vertex convention, and in order SVBI[0] + (1, 0, 2) if we're using
- * the last provoking vertex convention.
- *
- * Note: since brw_imm_v can only be used in instructions in
- * packed-word execution mode, and SVBI is a double-word, we need to
- * first move the appropriate immediate constant ((0, 1, 2), (0, 2, 1),
- * or (1, 0, 2)) to the destination_indices register, and then add SVBI
- * using a separate instruction. Also, since the immediate constant is
- * expressed as packed words, and we need to load double-words into
- * destination_indices, we need to intersperse zeros to fill the upper
- * halves of each double-word.
- */
- brw_MOV(p, destination_indices_uw,
- brw_imm_v(0x00020100)); /* (0, 1, 2) */
- if (num_verts == 3) {
- /* Get primitive type into temp register. */
- brw_AND(p, get_element_ud(c->reg.temp, 0),
- get_element_ud(c->reg.R0, 2), brw_imm_ud(0x1f));
-
- /* Test if primitive type is TRISTRIP_REVERSE. We need to do this as
- * an 8-wide comparison so that the conditional MOV that follows
- * moves all 8 words correctly.
- */
- brw_CMP(p, vec8(brw_null_reg()), BRW_CONDITIONAL_EQ,
- get_element_ud(c->reg.temp, 0),
- brw_imm_ud(_3DPRIM_TRISTRIP_REVERSE));
-
- /* If so, then overwrite destination_indices_uw with the appropriate
- * reordering.
- */
- inst = brw_MOV(p, destination_indices_uw,
- brw_imm_v(key->pv_first ? 0x00010200 /* (0, 2, 1) */
- : 0x00020001)); /* (1, 0, 2) */
- brw_inst_set_pred_control(p->devinfo, inst, BRW_PREDICATE_NORMAL);
- }
-
- assert(c->reg.destination_indices.width == BRW_EXECUTE_4);
- brw_push_insn_state(p);
- brw_set_default_exec_size(p, BRW_EXECUTE_4);
- brw_ADD(p, c->reg.destination_indices,
- c->reg.destination_indices, get_element_ud(c->reg.SVBI, 0));
- brw_pop_insn_state(p);
- /* For each vertex, generate code to output each varying using the
- * appropriate binding table entry.
- */
- for (vertex = 0; vertex < num_verts; ++vertex) {
- /* Set up the correct destination index for this vertex */
- brw_MOV(p, get_element_ud(c->reg.header, 5),
- get_element_ud(c->reg.destination_indices, vertex));
-
- for (binding = 0; binding < key->num_transform_feedback_bindings;
- ++binding) {
- unsigned char varying =
- key->transform_feedback_bindings[binding];
- unsigned char slot = c->vue_map.varying_to_slot[varying];
- /* From the Sandybridge PRM, Volume 2, Part 1, Section 4.5.1:
- *
- * "Prior to End of Thread with a URB_WRITE, the kernel must
- * ensure that all writes are complete by sending the final
- * write as a committed write."
- */
- bool final_write =
- binding == key->num_transform_feedback_bindings - 1 &&
- vertex == num_verts - 1;
- struct brw_reg vertex_slot = c->reg.vertex[vertex];
- vertex_slot.nr += slot / 2;
- vertex_slot.subnr = (slot % 2) * 16;
- /* gl_PointSize is stored in VARYING_SLOT_PSIZ.w. */
- vertex_slot.swizzle = varying == VARYING_SLOT_PSIZ
- ? BRW_SWIZZLE_WWWW : key->transform_feedback_swizzles[binding];
- brw_set_default_access_mode(p, BRW_ALIGN_16);
- brw_push_insn_state(p);
- brw_set_default_exec_size(p, BRW_EXECUTE_4);
-
- brw_MOV(p, stride(c->reg.header, 4, 4, 1),
- retype(vertex_slot, BRW_REGISTER_TYPE_UD));
- brw_pop_insn_state(p);
-
- brw_set_default_access_mode(p, BRW_ALIGN_1);
- brw_svb_write(p,
- final_write ? c->reg.temp : brw_null_reg(), /* dest */
- 1, /* msg_reg_nr */
- c->reg.header, /* src0 */
- BRW_GFX6_SOL_BINDING_START + binding, /* binding_table_index */
- final_write); /* send_commit_msg */
- }
- }
- brw_ENDIF(p);
-
- /* Now, reinitialize the header register from R0 to restore the parts of
- * the register that we overwrote while streaming out transform feedback
- * data.
- */
- brw_ff_gs_initialize_header(c);
-
- /* Finally, wait for the write commit to occur so that we can proceed to
- * other things safely.
- *
- * From the Sandybridge PRM, Volume 4, Part 1, Section 3.3:
- *
- * The write commit does not modify the destination register, but
- * merely clears the dependency associated with the destination
- * register. Thus, a simple “mov” instruction using the register as a
- * source is sufficient to wait for the write commit to occur.
- */
- brw_MOV(p, c->reg.temp, c->reg.temp);
- }
-
- brw_ff_gs_ff_sync(c, 1);
-
- brw_ff_gs_overwrite_header_dw2_from_r0(c);
- switch (num_verts) {
- case 1:
- brw_ff_gs_offset_header_dw2(c,
- URB_WRITE_PRIM_START | URB_WRITE_PRIM_END);
- brw_ff_gs_emit_vue(c, c->reg.vertex[0], true);
- break;
- case 2:
- brw_ff_gs_offset_header_dw2(c, URB_WRITE_PRIM_START);
- brw_ff_gs_emit_vue(c, c->reg.vertex[0], false);
- brw_ff_gs_offset_header_dw2(c,
- URB_WRITE_PRIM_END - URB_WRITE_PRIM_START);
- brw_ff_gs_emit_vue(c, c->reg.vertex[1], true);
- break;
- case 3:
- if (check_edge_flags) {
- /* Only emit vertices 0 and 1 if this is the first triangle of the
- * polygon. Otherwise they are redundant.
- */
- brw_AND(p, retype(brw_null_reg(), BRW_REGISTER_TYPE_UD),
- get_element_ud(c->reg.R0, 2),
- brw_imm_ud(BRW_GS_EDGE_INDICATOR_0));
- brw_inst_set_cond_modifier(p->devinfo, brw_last_inst, BRW_CONDITIONAL_NZ);
- brw_IF(p, BRW_EXECUTE_1);
- }
- brw_ff_gs_offset_header_dw2(c, URB_WRITE_PRIM_START);
- brw_ff_gs_emit_vue(c, c->reg.vertex[0], false);
- brw_ff_gs_offset_header_dw2(c, -URB_WRITE_PRIM_START);
- brw_ff_gs_emit_vue(c, c->reg.vertex[1], false);
- if (check_edge_flags) {
- brw_ENDIF(p);
- /* Only emit vertex 2 in PRIM_END mode if this is the last triangle
- * of the polygon. Otherwise leave the primitive incomplete because
- * there are more polygon vertices coming.
- */
- brw_AND(p, retype(brw_null_reg(), BRW_REGISTER_TYPE_UD),
- get_element_ud(c->reg.R0, 2),
- brw_imm_ud(BRW_GS_EDGE_INDICATOR_1));
- brw_inst_set_cond_modifier(p->devinfo, brw_last_inst, BRW_CONDITIONAL_NZ);
- brw_set_default_predicate_control(p, BRW_PREDICATE_NORMAL);
- }
- brw_ff_gs_offset_header_dw2(c, URB_WRITE_PRIM_END);
- brw_set_default_predicate_control(p, BRW_PREDICATE_NONE);
- brw_ff_gs_emit_vue(c, c->reg.vertex[2], true);
- break;
- }
-}
-
-const unsigned *
-brw_compile_ff_gs_prog(struct brw_compiler *compiler,
- void *mem_ctx,
- const struct brw_ff_gs_prog_key *key,
- struct brw_ff_gs_prog_data *prog_data,
- struct brw_vue_map *vue_map,
- unsigned *final_assembly_size)
-{
- struct brw_ff_gs_compile c;
- const GLuint *program;
-
- memset(&c, 0, sizeof(c));
-
- c.key = *key;
- c.vue_map = *vue_map;
- c.nr_regs = (c.vue_map.num_slots + 1)/2;
- c.prog_data = prog_data;
-
- mem_ctx = ralloc_context(NULL);
-
- /* Begin the compilation:
- */
- brw_init_codegen(compiler->devinfo, &c.func, mem_ctx);
-
- c.func.single_program_flow = 1;
-
- /* For some reason the thread is spawned with only 4 channels
- * unmasked.
- */
- brw_set_default_mask_control(&c.func, BRW_MASK_DISABLE);
-
- if (compiler->devinfo->ver >= 6) {
- unsigned num_verts;
- bool check_edge_flag;
- /* On Sandybridge, we use the GS for implementing transform feedback
- * (called "Stream Out" in the PRM).
- */
- switch (key->primitive) {
- case _3DPRIM_POINTLIST:
- num_verts = 1;
- check_edge_flag = false;
- break;
- case _3DPRIM_LINELIST:
- case _3DPRIM_LINESTRIP:
- case _3DPRIM_LINELOOP:
- num_verts = 2;
- check_edge_flag = false;
- break;
- case _3DPRIM_TRILIST:
- case _3DPRIM_TRIFAN:
- case _3DPRIM_TRISTRIP:
- case _3DPRIM_RECTLIST:
- num_verts = 3;
- check_edge_flag = false;
- break;
- case _3DPRIM_QUADLIST:
- case _3DPRIM_QUADSTRIP:
- case _3DPRIM_POLYGON:
- num_verts = 3;
- check_edge_flag = true;
- break;
- default:
- unreachable("Unexpected primitive type in Gen6 SOL program.");
- }
- gfx6_sol_program(&c, key, num_verts, check_edge_flag);
- } else {
- /* On Gen4-5, we use the GS to decompose certain types of primitives.
- * Note that primitives which don't require a GS program have already
- * been weeded out by now.
- */
- switch (key->primitive) {
- case _3DPRIM_QUADLIST:
- brw_ff_gs_quads( &c, key );
- break;
- case _3DPRIM_QUADSTRIP:
- brw_ff_gs_quad_strip( &c, key );
- break;
- case _3DPRIM_LINELOOP:
- brw_ff_gs_lines( &c );
- break;
- default:
- return NULL;
- }
- }
-
- brw_compact_instructions(&c.func, 0, NULL);
-
- /* get the program
- */
- program = brw_get_program(&c.func, final_assembly_size);
-
- if (INTEL_DEBUG & DEBUG_GS) {
- fprintf(stderr, "gs:\n");
- brw_disassemble_with_labels(compiler->devinfo, c.func.store,
- 0, *final_assembly_size, stderr);
- fprintf(stderr, "\n");
- }
-
- return program;
-}
-