/* * Copyright © 2009 Intel Corporation * * 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. * * Authors: * Eric Anholt * */ #include "brw_context.h" #include "brw_state.h" #include "brw_defines.h" #include "brw_util.h" #include "main/macros.h" #include "main/fbobject.h" #include "main/framebuffer.h" #include "intel_batchbuffer.h" /** * Determine the appropriate attribute override value to store into the * 3DSTATE_SF structure for a given fragment shader attribute. The attribute * override value contains two pieces of information: the location of the * attribute in the VUE (relative to urb_entry_read_offset, see below), and a * flag indicating whether to "swizzle" the attribute based on the direction * the triangle is facing. * * If an attribute is "swizzled", then the given VUE location is used for * front-facing triangles, and the VUE location that immediately follows is * used for back-facing triangles. We use this to implement the mapping from * gl_FrontColor/gl_BackColor to gl_Color. * * urb_entry_read_offset is the offset into the VUE at which the SF unit is * being instructed to begin reading attribute data. It can be set to a * nonzero value to prevent the SF unit from wasting time reading elements of * the VUE that are not needed by the fragment shader. It is measured in * 256-bit increments. */ static uint32_t get_attr_override(const struct brw_vue_map *vue_map, int urb_entry_read_offset, int fs_attr, bool two_side_color, uint32_t *max_source_attr) { /* Find the VUE slot for this attribute. */ int slot = vue_map->varying_to_slot[fs_attr]; /* Viewport and Layer are stored in the VUE header. We need to override * them to zero if earlier stages didn't write them, as GL requires that * they read back as zero when not explicitly set. */ if (fs_attr == VARYING_SLOT_VIEWPORT || fs_attr == VARYING_SLOT_LAYER) { unsigned override = ATTRIBUTE_0_OVERRIDE_X | ATTRIBUTE_0_OVERRIDE_W | ATTRIBUTE_CONST_0000 << ATTRIBUTE_0_CONST_SOURCE_SHIFT; if (!(vue_map->slots_valid & VARYING_BIT_LAYER)) override |= ATTRIBUTE_0_OVERRIDE_Y; if (!(vue_map->slots_valid & VARYING_BIT_VIEWPORT)) override |= ATTRIBUTE_0_OVERRIDE_Z; return override; } /* If there was only a back color written but not front, use back * as the color instead of undefined */ if (slot == -1 && fs_attr == VARYING_SLOT_COL0) slot = vue_map->varying_to_slot[VARYING_SLOT_BFC0]; if (slot == -1 && fs_attr == VARYING_SLOT_COL1) slot = vue_map->varying_to_slot[VARYING_SLOT_BFC1]; if (slot == -1) { /* This attribute does not exist in the VUE--that means that the vertex * shader did not write to it. This means that either: * * (a) This attribute is a texture coordinate, and it is going to be * replaced with point coordinates (as a consequence of a call to * glTexEnvi(GL_POINT_SPRITE, GL_COORD_REPLACE, GL_TRUE)), so the * hardware will ignore whatever attribute override we supply. * * (b) This attribute is read by the fragment shader but not written by * the vertex shader, so its value is undefined. Therefore the * attribute override we supply doesn't matter. * * (c) This attribute is gl_PrimitiveID, and it wasn't written by the * previous shader stage. * * Note that we don't have to worry about the cases where the attribute * is gl_PointCoord or is undergoing point sprite coordinate * replacement, because in those cases, this function isn't called. * * In case (c), we need to program the attribute overrides so that the * primitive ID will be stored in this slot. In every other case, the * attribute override we supply doesn't matter. So just go ahead and * program primitive ID in every case. */ return (ATTRIBUTE_0_OVERRIDE_W | ATTRIBUTE_0_OVERRIDE_Z | ATTRIBUTE_0_OVERRIDE_Y | ATTRIBUTE_0_OVERRIDE_X | (ATTRIBUTE_CONST_PRIM_ID << ATTRIBUTE_0_CONST_SOURCE_SHIFT)); } /* Compute the location of the attribute relative to urb_entry_read_offset. * Each increment of urb_entry_read_offset represents a 256-bit value, so * it counts for two 128-bit VUE slots. */ int source_attr = slot - 2 * urb_entry_read_offset; assert(source_attr >= 0 && source_attr < 32); /* If we are doing two-sided color, and the VUE slot following this one * represents a back-facing color, then we need to instruct the SF unit to * do back-facing swizzling. */ bool swizzling = two_side_color && ((vue_map->slot_to_varying[slot] == VARYING_SLOT_COL0 && vue_map->slot_to_varying[slot+1] == VARYING_SLOT_BFC0) || (vue_map->slot_to_varying[slot] == VARYING_SLOT_COL1 && vue_map->slot_to_varying[slot+1] == VARYING_SLOT_BFC1)); /* Update max_source_attr. If swizzling, the SF will read this slot + 1. */ if (*max_source_attr < source_attr + swizzling) *max_source_attr = source_attr + swizzling; if (swizzling) { return source_attr | (ATTRIBUTE_SWIZZLE_INPUTATTR_FACING << ATTRIBUTE_SWIZZLE_SHIFT); } return source_attr; } /** * Create the mapping from the FS inputs we produce to the previous pipeline * stage (GS or VS) outputs they source from. */ void calculate_attr_overrides(const struct brw_context *brw, uint16_t *attr_overrides, uint32_t *point_sprite_enables, uint32_t *urb_entry_read_length, uint32_t *urb_entry_read_offset) { uint32_t max_source_attr = 0; *point_sprite_enables = 0; *urb_entry_read_offset = BRW_SF_URB_ENTRY_READ_OFFSET; /* BRW_NEW_FRAGMENT_PROGRAM * * If the fragment shader reads VARYING_SLOT_LAYER, then we need to pass in * the full vertex header. Otherwise, we can program the SF to start * reading at an offset of 1 (2 varying slots) to skip unnecessary data: * - VARYING_SLOT_PSIZ and BRW_VARYING_SLOT_NDC on gen4-5 * - VARYING_SLOT_{PSIZ,LAYER} and VARYING_SLOT_POS on gen6+ */ bool fs_needs_vue_header = brw->fragment_program->Base.InputsRead & (VARYING_BIT_LAYER | VARYING_BIT_VIEWPORT); *urb_entry_read_offset = fs_needs_vue_header ? 0 : 1; /* From the Ivybridge PRM, Vol 2 Part 1, 3DSTATE_SBE, * description of dw10 Point Sprite Texture Coordinate Enable: * * "This field must be programmed to zero when non-point primitives * are rendered." * * The SandyBridge PRM doesn't explicitly say that point sprite enables * must be programmed to zero when rendering non-point primitives, but * the IvyBridge PRM does, and if we don't, we get garbage. * * This is not required on Haswell, as the hardware ignores this state * when drawing non-points -- although we do still need to be careful to * correctly set the attr overrides. * * _NEW_POLYGON * BRW_NEW_PRIMITIVE | BRW_NEW_GEOMETRY_PROGRAM | BRW_NEW_TES_PROG_DATA */ bool drawing_points = is_drawing_points(brw); /* Initialize all the attr_overrides to 0. In the loop below we'll modify * just the ones that correspond to inputs used by the fs. */ memset(attr_overrides, 0, 16*sizeof(*attr_overrides)); for (int attr = 0; attr < VARYING_SLOT_MAX; attr++) { /* BRW_NEW_FS_PROG_DATA */ int input_index = brw->wm.prog_data->urb_setup[attr]; if (input_index < 0) continue; /* _NEW_POINT */ bool point_sprite = false; if (drawing_points) { if (brw->ctx.Point.PointSprite && (attr >= VARYING_SLOT_TEX0 && attr <= VARYING_SLOT_TEX7) && brw->ctx.Point.CoordReplace[attr - VARYING_SLOT_TEX0]) { point_sprite = true; } if (attr == VARYING_SLOT_PNTC) point_sprite = true; if (point_sprite) *point_sprite_enables |= (1 << input_index); } /* BRW_NEW_VUE_MAP_GEOM_OUT | _NEW_LIGHT | _NEW_PROGRAM */ uint16_t attr_override = point_sprite ? 0 : get_attr_override(&brw->vue_map_geom_out, *urb_entry_read_offset, attr, brw->ctx.VertexProgram._TwoSideEnabled, &max_source_attr); /* The hardware can only do the overrides on 16 overrides at a * time, and the other up to 16 have to be lined up so that the * input index = the output index. We'll need to do some * tweaking to make sure that's the case. */ if (input_index < 16) attr_overrides[input_index] = attr_override; else assert(attr_override == input_index); } /* From the Sandy Bridge PRM, Volume 2, Part 1, documentation for * 3DSTATE_SF DWord 1 bits 15:11, "Vertex URB Entry Read Length": * * "This field should be set to the minimum length required to read the * maximum source attribute. The maximum source attribute is indicated * by the maximum value of the enabled Attribute # Source Attribute if * Attribute Swizzle Enable is set, Number of Output Attributes-1 if * enable is not set. * read_length = ceiling((max_source_attr + 1) / 2) * * [errata] Corruption/Hang possible if length programmed larger than * recommended" * * Similar text exists for Ivy Bridge. */ *urb_entry_read_length = ALIGN(max_source_attr + 1, 2) / 2; } static void upload_sf_state(struct brw_context *brw) { struct gl_context *ctx = &brw->ctx; /* BRW_NEW_FS_PROG_DATA */ uint32_t num_outputs = brw->wm.prog_data->num_varying_inputs; uint32_t dw1, dw2, dw3, dw4; uint32_t point_sprite_enables; int i; /* _NEW_BUFFER */ bool render_to_fbo = _mesa_is_user_fbo(ctx->DrawBuffer); const bool multisampled_fbo = _mesa_geometric_samples(ctx->DrawBuffer) > 1; float point_size; uint16_t attr_overrides[16]; uint32_t point_sprite_origin; dw1 = GEN6_SF_SWIZZLE_ENABLE | num_outputs << GEN6_SF_NUM_OUTPUTS_SHIFT; dw2 = GEN6_SF_STATISTICS_ENABLE; if (brw->sf.viewport_transform_enable) dw2 |= GEN6_SF_VIEWPORT_TRANSFORM_ENABLE; dw3 = 0; dw4 = 0; /* _NEW_POLYGON */ if (ctx->Polygon._FrontBit == render_to_fbo) dw2 |= GEN6_SF_WINDING_CCW; if (ctx->Polygon.OffsetFill) dw2 |= GEN6_SF_GLOBAL_DEPTH_OFFSET_SOLID; if (ctx->Polygon.OffsetLine) dw2 |= GEN6_SF_GLOBAL_DEPTH_OFFSET_WIREFRAME; if (ctx->Polygon.OffsetPoint) dw2 |= GEN6_SF_GLOBAL_DEPTH_OFFSET_POINT; switch (ctx->Polygon.FrontMode) { case GL_FILL: dw2 |= GEN6_SF_FRONT_SOLID; break; case GL_LINE: dw2 |= GEN6_SF_FRONT_WIREFRAME; break; case GL_POINT: dw2 |= GEN6_SF_FRONT_POINT; break; default: unreachable("not reached"); } switch (ctx->Polygon.BackMode) { case GL_FILL: dw2 |= GEN6_SF_BACK_SOLID; break; case GL_LINE: dw2 |= GEN6_SF_BACK_WIREFRAME; break; case GL_POINT: dw2 |= GEN6_SF_BACK_POINT; break; default: unreachable("not reached"); } /* _NEW_SCISSOR _NEW_POLYGON BRW_NEW_GEOMETRY_PROGRAM BRW_NEW_PRIMITIVE */ if (ctx->Scissor.EnableFlags || is_drawing_points(brw) || is_drawing_lines(brw)) dw3 |= GEN6_SF_SCISSOR_ENABLE; /* _NEW_POLYGON */ if (ctx->Polygon.CullFlag) { switch (ctx->Polygon.CullFaceMode) { case GL_FRONT: dw3 |= GEN6_SF_CULL_FRONT; break; case GL_BACK: dw3 |= GEN6_SF_CULL_BACK; break; case GL_FRONT_AND_BACK: dw3 |= GEN6_SF_CULL_BOTH; break; default: unreachable("not reached"); } } else { dw3 |= GEN6_SF_CULL_NONE; } /* _NEW_LINE */ { uint32_t line_width_u3_7 = brw_get_line_width(brw); dw3 |= line_width_u3_7 << GEN6_SF_LINE_WIDTH_SHIFT; } if (ctx->Line.SmoothFlag) { dw3 |= GEN6_SF_LINE_AA_ENABLE; dw3 |= GEN6_SF_LINE_AA_MODE_TRUE; dw3 |= GEN6_SF_LINE_END_CAP_WIDTH_1_0; } /* _NEW_MULTISAMPLE */ if (multisampled_fbo && ctx->Multisample.Enabled) dw3 |= GEN6_SF_MSRAST_ON_PATTERN; /* _NEW_PROGRAM | _NEW_POINT */ if (!(ctx->VertexProgram.PointSizeEnabled || ctx->Point._Attenuated)) dw4 |= GEN6_SF_USE_STATE_POINT_WIDTH; /* Clamp to ARB_point_parameters user limits */ point_size = CLAMP(ctx->Point.Size, ctx->Point.MinSize, ctx->Point.MaxSize); /* Clamp to the hardware limits and convert to fixed point */ dw4 |= U_FIXED(CLAMP(point_size, 0.125f, 255.875f), 3); /* * Window coordinates in an FBO are inverted, which means point * sprite origin must be inverted, too. */ if ((ctx->Point.SpriteOrigin == GL_LOWER_LEFT) != render_to_fbo) { point_sprite_origin = GEN6_SF_POINT_SPRITE_LOWERLEFT; } else { point_sprite_origin = GEN6_SF_POINT_SPRITE_UPPERLEFT; } dw1 |= point_sprite_origin; /* _NEW_LIGHT */ if (ctx->Light.ProvokingVertex != GL_FIRST_VERTEX_CONVENTION) { dw4 |= (2 << GEN6_SF_TRI_PROVOKE_SHIFT) | (2 << GEN6_SF_TRIFAN_PROVOKE_SHIFT) | (1 << GEN6_SF_LINE_PROVOKE_SHIFT); } else { dw4 |= (1 << GEN6_SF_TRIFAN_PROVOKE_SHIFT); } /* BRW_NEW_VUE_MAP_GEOM_OUT | BRW_NEW_FRAGMENT_PROGRAM | * _NEW_POINT | _NEW_LIGHT | _NEW_PROGRAM | BRW_NEW_FS_PROG_DATA */ uint32_t urb_entry_read_length; uint32_t urb_entry_read_offset; calculate_attr_overrides(brw, attr_overrides, &point_sprite_enables, &urb_entry_read_length, &urb_entry_read_offset); dw1 |= (urb_entry_read_length << GEN6_SF_URB_ENTRY_READ_LENGTH_SHIFT | urb_entry_read_offset << GEN6_SF_URB_ENTRY_READ_OFFSET_SHIFT); BEGIN_BATCH(20); OUT_BATCH(_3DSTATE_SF << 16 | (20 - 2)); OUT_BATCH(dw1); OUT_BATCH(dw2); OUT_BATCH(dw3); OUT_BATCH(dw4); OUT_BATCH_F(ctx->Polygon.OffsetUnits * 2); /* constant. copied from gen4 */ OUT_BATCH_F(ctx->Polygon.OffsetFactor); /* scale */ OUT_BATCH_F(ctx->Polygon.OffsetClamp); /* global depth offset clamp */ for (i = 0; i < 8; i++) { OUT_BATCH(attr_overrides[i * 2] | attr_overrides[i * 2 + 1] << 16); } OUT_BATCH(point_sprite_enables); /* dw16 */ OUT_BATCH(brw->wm.prog_data->flat_inputs); OUT_BATCH(0); /* wrapshortest enables 0-7 */ OUT_BATCH(0); /* wrapshortest enables 8-15 */ ADVANCE_BATCH(); } const struct brw_tracked_state gen6_sf_state = { .dirty = { .mesa = _NEW_BUFFERS | _NEW_LIGHT | _NEW_LINE | _NEW_MULTISAMPLE | _NEW_POINT | _NEW_POLYGON | _NEW_PROGRAM | _NEW_SCISSOR, .brw = BRW_NEW_CONTEXT | BRW_NEW_FRAGMENT_PROGRAM | BRW_NEW_FS_PROG_DATA | BRW_NEW_GEOMETRY_PROGRAM | BRW_NEW_PRIMITIVE | BRW_NEW_TES_PROG_DATA | BRW_NEW_VUE_MAP_GEOM_OUT, }, .emit = upload_sf_state, };