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path: root/src/gallium/drivers/radeonsi/si_shader.c
blob: e54b9fb97ba4567c4ea2feab45a541cf8fe7695a (plain)
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/*
 * Copyright 2012 Advanced Micro Devices, Inc.
 * All Rights Reserved.
 *
 * 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
 * on the rights to use, copy, modify, merge, publish, distribute, sub
 * license, 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 NON-INFRINGEMENT. IN NO EVENT SHALL
 * THE AUTHOR(S) AND/OR THEIR 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.
 */

#include "util/u_memory.h"
#include "tgsi/tgsi_strings.h"
#include "tgsi/tgsi_from_mesa.h"

#include "ac_exp_param.h"
#include "ac_rtld.h"
#include "si_shader_internal.h"
#include "si_pipe.h"
#include "sid.h"

#include "compiler/nir/nir.h"
#include "compiler/nir/nir_serialize.h"

static const char scratch_rsrc_dword0_symbol[] =
	"SCRATCH_RSRC_DWORD0";

static const char scratch_rsrc_dword1_symbol[] =
	"SCRATCH_RSRC_DWORD1";

static void si_dump_shader_key(const struct si_shader *shader, FILE *f);

static void si_build_vs_prolog_function(struct si_shader_context *ctx,
					union si_shader_part_key *key);

/** Whether the shader runs as a combination of multiple API shaders */
static bool is_multi_part_shader(struct si_shader_context *ctx)
{
	if (ctx->screen->info.chip_class <= GFX8)
		return false;

	return ctx->shader->key.as_ls ||
	       ctx->shader->key.as_es ||
	       ctx->type == PIPE_SHADER_TESS_CTRL ||
	       ctx->type == PIPE_SHADER_GEOMETRY;
}

/** Whether the shader runs on a merged HW stage (LSHS or ESGS) */
bool si_is_merged_shader(struct si_shader_context *ctx)
{
	return ctx->shader->key.as_ngg || is_multi_part_shader(ctx);
}

/**
 * Returns a unique index for a per-patch semantic name and index. The index
 * must be less than 32, so that a 32-bit bitmask of used inputs or outputs
 * can be calculated.
 */
unsigned si_shader_io_get_unique_index_patch(unsigned semantic_name, unsigned index)
{
	switch (semantic_name) {
	case TGSI_SEMANTIC_TESSOUTER:
		return 0;
	case TGSI_SEMANTIC_TESSINNER:
		return 1;
	case TGSI_SEMANTIC_PATCH:
		assert(index < 30);
		return 2 + index;

	default:
		assert(!"invalid semantic name");
		return 0;
	}
}

/**
 * Returns a unique index for a semantic name and index. The index must be
 * less than 64, so that a 64-bit bitmask of used inputs or outputs can be
 * calculated.
 */
unsigned si_shader_io_get_unique_index(unsigned semantic_name, unsigned index,
				       unsigned is_varying)
{
	switch (semantic_name) {
	case TGSI_SEMANTIC_POSITION:
		return 0;
	case TGSI_SEMANTIC_GENERIC:
		/* Since some shader stages use the the highest used IO index
		 * to determine the size to allocate for inputs/outputs
		 * (in LDS, tess and GS rings). GENERIC should be placed right
		 * after POSITION to make that size as small as possible.
		 */
		if (index < SI_MAX_IO_GENERIC)
			return 1 + index;

		assert(!"invalid generic index");
		return 0;
	case TGSI_SEMANTIC_FOG:
		return SI_MAX_IO_GENERIC + 1;
	case TGSI_SEMANTIC_COLOR:
		assert(index < 2);
		return SI_MAX_IO_GENERIC + 2 + index;
	case TGSI_SEMANTIC_BCOLOR:
		assert(index < 2);
		/* If it's a varying, COLOR and BCOLOR alias. */
		if (is_varying)
			return SI_MAX_IO_GENERIC + 2 + index;
		else
			return SI_MAX_IO_GENERIC + 4 + index;
	case TGSI_SEMANTIC_TEXCOORD:
		assert(index < 8);
		return SI_MAX_IO_GENERIC + 6 + index;

	/* These are rarely used between LS and HS or ES and GS. */
	case TGSI_SEMANTIC_CLIPDIST:
		assert(index < 2);
		return SI_MAX_IO_GENERIC + 6 + 8 + index;
	case TGSI_SEMANTIC_CLIPVERTEX:
		return SI_MAX_IO_GENERIC + 6 + 8 + 2;
	case TGSI_SEMANTIC_PSIZE:
		return SI_MAX_IO_GENERIC + 6 + 8 + 3;

	/* These can't be written by LS, HS, and ES. */
	case TGSI_SEMANTIC_LAYER:
		return SI_MAX_IO_GENERIC + 6 + 8 + 4;
	case TGSI_SEMANTIC_VIEWPORT_INDEX:
		return SI_MAX_IO_GENERIC + 6 + 8 + 5;
	case TGSI_SEMANTIC_PRIMID:
		STATIC_ASSERT(SI_MAX_IO_GENERIC + 6 + 8 + 6 <= 63);
		return SI_MAX_IO_GENERIC + 6 + 8 + 6;
	default:
		fprintf(stderr, "invalid semantic name = %u\n", semantic_name);
		assert(!"invalid semantic name");
		return 0;
	}
}

/**
 * Get the value of a shader input parameter and extract a bitfield.
 */
static LLVMValueRef unpack_llvm_param(struct si_shader_context *ctx,
				      LLVMValueRef value, unsigned rshift,
				      unsigned bitwidth)
{
	if (LLVMGetTypeKind(LLVMTypeOf(value)) == LLVMFloatTypeKind)
		value = ac_to_integer(&ctx->ac, value);

	if (rshift)
		value = LLVMBuildLShr(ctx->ac.builder, value,
				      LLVMConstInt(ctx->i32, rshift, 0), "");

	if (rshift + bitwidth < 32) {
		unsigned mask = (1 << bitwidth) - 1;
		value = LLVMBuildAnd(ctx->ac.builder, value,
				     LLVMConstInt(ctx->i32, mask, 0), "");
	}

	return value;
}

LLVMValueRef si_unpack_param(struct si_shader_context *ctx,
			     struct ac_arg param, unsigned rshift,
			     unsigned bitwidth)
{
	LLVMValueRef value = ac_get_arg(&ctx->ac, param);

	return unpack_llvm_param(ctx, value, rshift, bitwidth);
}

static LLVMValueRef unpack_sint16(struct si_shader_context *ctx,
				 LLVMValueRef i32, unsigned index)
{
	assert(index <= 1);

	if (index == 1)
		return LLVMBuildAShr(ctx->ac.builder, i32,
				     LLVMConstInt(ctx->i32, 16, 0), "");

	return LLVMBuildSExt(ctx->ac.builder,
			     LLVMBuildTrunc(ctx->ac.builder, i32,
					    ctx->ac.i16, ""),
			     ctx->i32, "");
}

void si_llvm_load_input_vs(
	struct si_shader_context *ctx,
	unsigned input_index,
	LLVMValueRef out[4])
{
	const struct si_shader_info *info = &ctx->shader->selector->info;
	unsigned vs_blit_property = info->properties[TGSI_PROPERTY_VS_BLIT_SGPRS_AMD];

	if (vs_blit_property) {
		LLVMValueRef vertex_id = ctx->abi.vertex_id;
		LLVMValueRef sel_x1 = LLVMBuildICmp(ctx->ac.builder,
						    LLVMIntULE, vertex_id,
						    ctx->i32_1, "");
		/* Use LLVMIntNE, because we have 3 vertices and only
		 * the middle one should use y2.
		 */
		LLVMValueRef sel_y1 = LLVMBuildICmp(ctx->ac.builder,
						    LLVMIntNE, vertex_id,
						    ctx->i32_1, "");

		unsigned param_vs_blit_inputs = ctx->vs_blit_inputs.arg_index;
		if (input_index == 0) {
			/* Position: */
			LLVMValueRef x1y1 = LLVMGetParam(ctx->main_fn,
							 param_vs_blit_inputs);
			LLVMValueRef x2y2 = LLVMGetParam(ctx->main_fn,
							 param_vs_blit_inputs + 1);

			LLVMValueRef x1 = unpack_sint16(ctx, x1y1, 0);
			LLVMValueRef y1 = unpack_sint16(ctx, x1y1, 1);
			LLVMValueRef x2 = unpack_sint16(ctx, x2y2, 0);
			LLVMValueRef y2 = unpack_sint16(ctx, x2y2, 1);

			LLVMValueRef x = LLVMBuildSelect(ctx->ac.builder, sel_x1,
							 x1, x2, "");
			LLVMValueRef y = LLVMBuildSelect(ctx->ac.builder, sel_y1,
							 y1, y2, "");

			out[0] = LLVMBuildSIToFP(ctx->ac.builder, x, ctx->f32, "");
			out[1] = LLVMBuildSIToFP(ctx->ac.builder, y, ctx->f32, "");
			out[2] = LLVMGetParam(ctx->main_fn,
					      param_vs_blit_inputs + 2);
			out[3] = ctx->ac.f32_1;
			return;
		}

		/* Color or texture coordinates: */
		assert(input_index == 1);

		if (vs_blit_property == SI_VS_BLIT_SGPRS_POS_COLOR) {
			for (int i = 0; i < 4; i++) {
				out[i] = LLVMGetParam(ctx->main_fn,
						      param_vs_blit_inputs + 3 + i);
			}
		} else {
			assert(vs_blit_property == SI_VS_BLIT_SGPRS_POS_TEXCOORD);
			LLVMValueRef x1 = LLVMGetParam(ctx->main_fn,
						       param_vs_blit_inputs + 3);
			LLVMValueRef y1 = LLVMGetParam(ctx->main_fn,
						       param_vs_blit_inputs + 4);
			LLVMValueRef x2 = LLVMGetParam(ctx->main_fn,
						       param_vs_blit_inputs + 5);
			LLVMValueRef y2 = LLVMGetParam(ctx->main_fn,
						       param_vs_blit_inputs + 6);

			out[0] = LLVMBuildSelect(ctx->ac.builder, sel_x1,
						 x1, x2, "");
			out[1] = LLVMBuildSelect(ctx->ac.builder, sel_y1,
						 y1, y2, "");
			out[2] = LLVMGetParam(ctx->main_fn,
					      param_vs_blit_inputs + 7);
			out[3] = LLVMGetParam(ctx->main_fn,
					      param_vs_blit_inputs + 8);
		}
		return;
	}

	unsigned num_vbos_in_user_sgprs = ctx->shader->selector->num_vbos_in_user_sgprs;
	union si_vs_fix_fetch fix_fetch;
	LLVMValueRef vb_desc;
	LLVMValueRef vertex_index;
	LLVMValueRef tmp;

	if (input_index < num_vbos_in_user_sgprs) {
		vb_desc = ac_get_arg(&ctx->ac, ctx->vb_descriptors[input_index]);
	} else {
		unsigned index= input_index - num_vbos_in_user_sgprs;
		vb_desc = ac_build_load_to_sgpr(&ctx->ac,
						ac_get_arg(&ctx->ac, ctx->vertex_buffers),
						LLVMConstInt(ctx->i32, index, 0));
	}

	vertex_index = LLVMGetParam(ctx->main_fn,
				    ctx->vertex_index0.arg_index +
				    input_index);

	/* Use the open-coded implementation for all loads of doubles and
	 * of dword-sized data that needs fixups. We need to insert conversion
	 * code anyway, and the amd/common code does it for us.
	 *
	 * Note: On LLVM <= 8, we can only open-code formats with
	 * channel size >= 4 bytes.
	 */
	bool opencode = ctx->shader->key.mono.vs_fetch_opencode & (1 << input_index);
	fix_fetch.bits = ctx->shader->key.mono.vs_fix_fetch[input_index].bits;
	if (opencode ||
	    (fix_fetch.u.log_size == 3 && fix_fetch.u.format == AC_FETCH_FORMAT_FLOAT) ||
	    (fix_fetch.u.log_size == 2)) {
		tmp = ac_build_opencoded_load_format(
				&ctx->ac, fix_fetch.u.log_size, fix_fetch.u.num_channels_m1 + 1,
				fix_fetch.u.format, fix_fetch.u.reverse, !opencode,
				vb_desc, vertex_index, ctx->ac.i32_0, ctx->ac.i32_0, 0, true);
		for (unsigned i = 0; i < 4; ++i)
			out[i] = LLVMBuildExtractElement(ctx->ac.builder, tmp, LLVMConstInt(ctx->i32, i, false), "");
		return;
	}

	/* Do multiple loads for special formats. */
	unsigned required_channels = util_last_bit(info->input_usage_mask[input_index]);
	LLVMValueRef fetches[4];
	unsigned num_fetches;
	unsigned fetch_stride;
	unsigned channels_per_fetch;

	if (fix_fetch.u.log_size <= 1 && fix_fetch.u.num_channels_m1 == 2) {
		num_fetches = MIN2(required_channels, 3);
		fetch_stride = 1 << fix_fetch.u.log_size;
		channels_per_fetch = 1;
	} else {
		num_fetches = 1;
		fetch_stride = 0;
		channels_per_fetch = required_channels;
	}

	for (unsigned i = 0; i < num_fetches; ++i) {
		LLVMValueRef voffset = LLVMConstInt(ctx->i32, fetch_stride * i, 0);
		fetches[i] = ac_build_buffer_load_format(&ctx->ac, vb_desc, vertex_index, voffset,
							 channels_per_fetch, 0, true);
	}

	if (num_fetches == 1 && channels_per_fetch > 1) {
		LLVMValueRef fetch = fetches[0];
		for (unsigned i = 0; i < channels_per_fetch; ++i) {
			tmp = LLVMConstInt(ctx->i32, i, false);
			fetches[i] = LLVMBuildExtractElement(
				ctx->ac.builder, fetch, tmp, "");
		}
		num_fetches = channels_per_fetch;
		channels_per_fetch = 1;
	}

	for (unsigned i = num_fetches; i < 4; ++i)
		fetches[i] = LLVMGetUndef(ctx->f32);

	if (fix_fetch.u.log_size <= 1 && fix_fetch.u.num_channels_m1 == 2 &&
	    required_channels == 4) {
		if (fix_fetch.u.format == AC_FETCH_FORMAT_UINT || fix_fetch.u.format == AC_FETCH_FORMAT_SINT)
			fetches[3] = ctx->ac.i32_1;
		else
			fetches[3] = ctx->ac.f32_1;
	} else if (fix_fetch.u.log_size == 3 &&
		   (fix_fetch.u.format == AC_FETCH_FORMAT_SNORM ||
		    fix_fetch.u.format == AC_FETCH_FORMAT_SSCALED ||
		    fix_fetch.u.format == AC_FETCH_FORMAT_SINT) &&
		   required_channels == 4) {
		/* For 2_10_10_10, the hardware returns an unsigned value;
		 * convert it to a signed one.
		 */
		LLVMValueRef tmp = fetches[3];
		LLVMValueRef c30 = LLVMConstInt(ctx->i32, 30, 0);

		/* First, recover the sign-extended signed integer value. */
		if (fix_fetch.u.format == AC_FETCH_FORMAT_SSCALED)
			tmp = LLVMBuildFPToUI(ctx->ac.builder, tmp, ctx->i32, "");
		else
			tmp = ac_to_integer(&ctx->ac, tmp);

		/* For the integer-like cases, do a natural sign extension.
		 *
		 * For the SNORM case, the values are 0.0, 0.333, 0.666, 1.0
		 * and happen to contain 0, 1, 2, 3 as the two LSBs of the
		 * exponent.
		 */
		tmp = LLVMBuildShl(ctx->ac.builder, tmp,
				   fix_fetch.u.format == AC_FETCH_FORMAT_SNORM ?
				   LLVMConstInt(ctx->i32, 7, 0) : c30, "");
		tmp = LLVMBuildAShr(ctx->ac.builder, tmp, c30, "");

		/* Convert back to the right type. */
		if (fix_fetch.u.format == AC_FETCH_FORMAT_SNORM) {
			LLVMValueRef clamp;
			LLVMValueRef neg_one = LLVMConstReal(ctx->f32, -1.0);
			tmp = LLVMBuildSIToFP(ctx->ac.builder, tmp, ctx->f32, "");
			clamp = LLVMBuildFCmp(ctx->ac.builder, LLVMRealULT, tmp, neg_one, "");
			tmp = LLVMBuildSelect(ctx->ac.builder, clamp, neg_one, tmp, "");
		} else if (fix_fetch.u.format == AC_FETCH_FORMAT_SSCALED) {
			tmp = LLVMBuildSIToFP(ctx->ac.builder, tmp, ctx->f32, "");
		}

		fetches[3] = tmp;
	}

	for (unsigned i = 0; i < 4; ++i)
		out[i] = ac_to_float(&ctx->ac, fetches[i]);
}

LLVMValueRef si_get_primitive_id(struct si_shader_context *ctx,
				 unsigned swizzle)
{
	if (swizzle > 0)
		return ctx->i32_0;

	switch (ctx->type) {
	case PIPE_SHADER_VERTEX:
		return ac_get_arg(&ctx->ac, ctx->vs_prim_id);
	case PIPE_SHADER_TESS_CTRL:
		return ac_get_arg(&ctx->ac, ctx->args.tcs_patch_id);
	case PIPE_SHADER_TESS_EVAL:
		return ac_get_arg(&ctx->ac, ctx->args.tes_patch_id);
	case PIPE_SHADER_GEOMETRY:
		return ac_get_arg(&ctx->ac, ctx->args.gs_prim_id);
	default:
		assert(0);
		return ctx->i32_0;
	}
}

static LLVMValueRef get_base_vertex(struct ac_shader_abi *abi)
{
	struct si_shader_context *ctx = si_shader_context_from_abi(abi);

	/* For non-indexed draws, the base vertex set by the driver
	 * (for direct draws) or the CP (for indirect draws) is the
	 * first vertex ID, but GLSL expects 0 to be returned.
	 */
	LLVMValueRef vs_state = ac_get_arg(&ctx->ac,
					   ctx->vs_state_bits);
	LLVMValueRef indexed;

	indexed = LLVMBuildLShr(ctx->ac.builder, vs_state, ctx->i32_1, "");
	indexed = LLVMBuildTrunc(ctx->ac.builder, indexed, ctx->i1, "");

	return LLVMBuildSelect(ctx->ac.builder, indexed,
			       ac_get_arg(&ctx->ac, ctx->args.base_vertex),
			       ctx->i32_0, "");
}

static LLVMValueRef get_block_size(struct ac_shader_abi *abi)
{
	struct si_shader_context *ctx = si_shader_context_from_abi(abi);

	LLVMValueRef values[3];
	LLVMValueRef result;
	unsigned i;
	unsigned *properties = ctx->shader->selector->info.properties;

	if (properties[TGSI_PROPERTY_CS_FIXED_BLOCK_WIDTH] != 0) {
		unsigned sizes[3] = {
			properties[TGSI_PROPERTY_CS_FIXED_BLOCK_WIDTH],
			properties[TGSI_PROPERTY_CS_FIXED_BLOCK_HEIGHT],
			properties[TGSI_PROPERTY_CS_FIXED_BLOCK_DEPTH]
		};

		for (i = 0; i < 3; ++i)
			values[i] = LLVMConstInt(ctx->i32, sizes[i], 0);

		result = ac_build_gather_values(&ctx->ac, values, 3);
	} else {
		result = ac_get_arg(&ctx->ac, ctx->block_size);
	}

	return result;
}

void si_declare_compute_memory(struct si_shader_context *ctx)
{
	struct si_shader_selector *sel = ctx->shader->selector;
	unsigned lds_size = sel->info.properties[TGSI_PROPERTY_CS_LOCAL_SIZE];

	LLVMTypeRef i8p = LLVMPointerType(ctx->i8, AC_ADDR_SPACE_LDS);
	LLVMValueRef var;

	assert(!ctx->ac.lds);

	var = LLVMAddGlobalInAddressSpace(ctx->ac.module,
	                                  LLVMArrayType(ctx->i8, lds_size),
	                                  "compute_lds",
	                                  AC_ADDR_SPACE_LDS);
	LLVMSetAlignment(var, 64 * 1024);

	ctx->ac.lds = LLVMBuildBitCast(ctx->ac.builder, var, i8p, "");
}

/* Initialize arguments for the shader export intrinsic */
static void si_llvm_init_vs_export_args(struct si_shader_context *ctx,
					LLVMValueRef *values,
					unsigned target,
					struct ac_export_args *args)
{
	args->enabled_channels = 0xf; /* writemask - default is 0xf */
	args->valid_mask = 0; /* Specify whether the EXEC mask represents the valid mask */
	args->done = 0; /* Specify whether this is the last export */
	args->target = target; /* Specify the target we are exporting */
	args->compr = false;

	memcpy(&args->out[0], values, sizeof(values[0]) * 4);
}

static void si_llvm_emit_clipvertex(struct si_shader_context *ctx,
				    struct ac_export_args *pos, LLVMValueRef *out_elts)
{
	unsigned reg_index;
	unsigned chan;
	unsigned const_chan;
	LLVMValueRef base_elt;
	LLVMValueRef ptr = ac_get_arg(&ctx->ac, ctx->rw_buffers);
	LLVMValueRef constbuf_index = LLVMConstInt(ctx->i32,
						   SI_VS_CONST_CLIP_PLANES, 0);
	LLVMValueRef const_resource = ac_build_load_to_sgpr(&ctx->ac, ptr, constbuf_index);

	for (reg_index = 0; reg_index < 2; reg_index ++) {
		struct ac_export_args *args = &pos[2 + reg_index];

		args->out[0] =
		args->out[1] =
		args->out[2] =
		args->out[3] = LLVMConstReal(ctx->f32, 0.0f);

		/* Compute dot products of position and user clip plane vectors */
		for (chan = 0; chan < 4; chan++) {
			for (const_chan = 0; const_chan < 4; const_chan++) {
				LLVMValueRef addr =
					LLVMConstInt(ctx->i32, ((reg_index * 4 + chan) * 4 +
								const_chan) * 4, 0);
				base_elt = si_buffer_load_const(ctx, const_resource,
								addr);
				args->out[chan] = ac_build_fmad(&ctx->ac, base_elt,
								out_elts[const_chan], args->out[chan]);
			}
		}

		args->enabled_channels = 0xf;
		args->valid_mask = 0;
		args->done = 0;
		args->target = V_008DFC_SQ_EXP_POS + 2 + reg_index;
		args->compr = 0;
	}
}

static void si_dump_streamout(struct pipe_stream_output_info *so)
{
	unsigned i;

	if (so->num_outputs)
		fprintf(stderr, "STREAMOUT\n");

	for (i = 0; i < so->num_outputs; i++) {
		unsigned mask = ((1 << so->output[i].num_components) - 1) <<
				so->output[i].start_component;
		fprintf(stderr, "  %i: BUF%i[%i..%i] <- OUT[%i].%s%s%s%s\n",
			i, so->output[i].output_buffer,
			so->output[i].dst_offset, so->output[i].dst_offset + so->output[i].num_components - 1,
			so->output[i].register_index,
			mask & 1 ? "x" : "",
		        mask & 2 ? "y" : "",
		        mask & 4 ? "z" : "",
		        mask & 8 ? "w" : "");
	}
}

void si_emit_streamout_output(struct si_shader_context *ctx,
			      LLVMValueRef const *so_buffers,
			      LLVMValueRef const *so_write_offsets,
			      struct pipe_stream_output *stream_out,
			      struct si_shader_output_values *shader_out)
{
	unsigned buf_idx = stream_out->output_buffer;
	unsigned start = stream_out->start_component;
	unsigned num_comps = stream_out->num_components;
	LLVMValueRef out[4];

	assert(num_comps && num_comps <= 4);
	if (!num_comps || num_comps > 4)
		return;

	/* Load the output as int. */
	for (int j = 0; j < num_comps; j++) {
		assert(stream_out->stream == shader_out->vertex_stream[start + j]);

		out[j] = ac_to_integer(&ctx->ac, shader_out->values[start + j]);
	}

	/* Pack the output. */
	LLVMValueRef vdata = NULL;

	switch (num_comps) {
	case 1: /* as i32 */
		vdata = out[0];
		break;
	case 2: /* as v2i32 */
	case 3: /* as v3i32 */
		if (ac_has_vec3_support(ctx->screen->info.chip_class, false)) {
			vdata = ac_build_gather_values(&ctx->ac, out, num_comps);
			break;
		}
		/* as v4i32 (aligned to 4) */
		out[3] = LLVMGetUndef(ctx->i32);
		/* fall through */
	case 4: /* as v4i32 */
		vdata = ac_build_gather_values(&ctx->ac, out, util_next_power_of_two(num_comps));
		break;
	}

	ac_build_buffer_store_dword(&ctx->ac, so_buffers[buf_idx],
				    vdata, num_comps,
				    so_write_offsets[buf_idx],
				    ctx->i32_0,
				    stream_out->dst_offset * 4, ac_glc | ac_slc);
}

/**
 * Write streamout data to buffers for vertex stream @p stream (different
 * vertex streams can occur for GS copy shaders).
 */
void si_llvm_emit_streamout(struct si_shader_context *ctx,
			    struct si_shader_output_values *outputs,
			    unsigned noutput, unsigned stream)
{
	struct si_shader_selector *sel = ctx->shader->selector;
	struct pipe_stream_output_info *so = &sel->so;
	LLVMBuilderRef builder = ctx->ac.builder;
	int i;

	/* Get bits [22:16], i.e. (so_param >> 16) & 127; */
	LLVMValueRef so_vtx_count =
		si_unpack_param(ctx, ctx->streamout_config, 16, 7);

	LLVMValueRef tid = ac_get_thread_id(&ctx->ac);

	/* can_emit = tid < so_vtx_count; */
	LLVMValueRef can_emit =
		LLVMBuildICmp(builder, LLVMIntULT, tid, so_vtx_count, "");

	/* Emit the streamout code conditionally. This actually avoids
	 * out-of-bounds buffer access. The hw tells us via the SGPR
	 * (so_vtx_count) which threads are allowed to emit streamout data. */
	ac_build_ifcc(&ctx->ac, can_emit, 6501);
	{
		/* The buffer offset is computed as follows:
		 *   ByteOffset = streamout_offset[buffer_id]*4 +
		 *                (streamout_write_index + thread_id)*stride[buffer_id] +
		 *                attrib_offset
                 */

		LLVMValueRef so_write_index =
			ac_get_arg(&ctx->ac,
				   ctx->streamout_write_index);

		/* Compute (streamout_write_index + thread_id). */
		so_write_index = LLVMBuildAdd(builder, so_write_index, tid, "");

		/* Load the descriptor and compute the write offset for each
		 * enabled buffer. */
		LLVMValueRef so_write_offset[4] = {};
		LLVMValueRef so_buffers[4];
		LLVMValueRef buf_ptr = ac_get_arg(&ctx->ac,
						  ctx->rw_buffers);

		for (i = 0; i < 4; i++) {
			if (!so->stride[i])
				continue;

			LLVMValueRef offset = LLVMConstInt(ctx->i32,
							   SI_VS_STREAMOUT_BUF0 + i, 0);

			so_buffers[i] = ac_build_load_to_sgpr(&ctx->ac, buf_ptr, offset);

			LLVMValueRef so_offset = ac_get_arg(&ctx->ac,
							    ctx->streamout_offset[i]);
			so_offset = LLVMBuildMul(builder, so_offset, LLVMConstInt(ctx->i32, 4, 0), "");

			so_write_offset[i] = ac_build_imad(&ctx->ac, so_write_index,
							   LLVMConstInt(ctx->i32, so->stride[i]*4, 0),
							   so_offset);
		}

		/* Write streamout data. */
		for (i = 0; i < so->num_outputs; i++) {
			unsigned reg = so->output[i].register_index;

			if (reg >= noutput)
				continue;

			if (stream != so->output[i].stream)
				continue;

			si_emit_streamout_output(ctx, so_buffers, so_write_offset,
						 &so->output[i], &outputs[reg]);
		}
	}
	ac_build_endif(&ctx->ac, 6501);
}

static void si_export_param(struct si_shader_context *ctx, unsigned index,
			    LLVMValueRef *values)
{
	struct ac_export_args args;

	si_llvm_init_vs_export_args(ctx, values,
				    V_008DFC_SQ_EXP_PARAM + index, &args);
	ac_build_export(&ctx->ac, &args);
}

static void si_build_param_exports(struct si_shader_context *ctx,
				   struct si_shader_output_values *outputs,
			           unsigned noutput)
{
	struct si_shader *shader = ctx->shader;
	unsigned param_count = 0;

	for (unsigned i = 0; i < noutput; i++) {
		unsigned semantic_name = outputs[i].semantic_name;
		unsigned semantic_index = outputs[i].semantic_index;

		if (outputs[i].vertex_stream[0] != 0 &&
		    outputs[i].vertex_stream[1] != 0 &&
		    outputs[i].vertex_stream[2] != 0 &&
		    outputs[i].vertex_stream[3] != 0)
			continue;

		switch (semantic_name) {
		case TGSI_SEMANTIC_LAYER:
		case TGSI_SEMANTIC_VIEWPORT_INDEX:
		case TGSI_SEMANTIC_CLIPDIST:
		case TGSI_SEMANTIC_COLOR:
		case TGSI_SEMANTIC_BCOLOR:
		case TGSI_SEMANTIC_PRIMID:
		case TGSI_SEMANTIC_FOG:
		case TGSI_SEMANTIC_TEXCOORD:
		case TGSI_SEMANTIC_GENERIC:
			break;
		default:
			continue;
		}

		if ((semantic_name != TGSI_SEMANTIC_GENERIC ||
		     semantic_index < SI_MAX_IO_GENERIC) &&
		    shader->key.opt.kill_outputs &
		    (1ull << si_shader_io_get_unique_index(semantic_name,
							   semantic_index, true)))
			continue;

		si_export_param(ctx, param_count, outputs[i].values);

		assert(i < ARRAY_SIZE(shader->info.vs_output_param_offset));
		shader->info.vs_output_param_offset[i] = param_count++;
	}

	shader->info.nr_param_exports = param_count;
}

/**
 * Vertex color clamping.
 *
 * This uses a state constant loaded in a user data SGPR and
 * an IF statement is added that clamps all colors if the constant
 * is true.
 */
static void si_vertex_color_clamping(struct si_shader_context *ctx,
				     struct si_shader_output_values *outputs,
				     unsigned noutput)
{
	LLVMValueRef addr[SI_MAX_VS_OUTPUTS][4];
	bool has_colors = false;

	/* Store original colors to alloca variables. */
	for (unsigned i = 0; i < noutput; i++) {
		if (outputs[i].semantic_name != TGSI_SEMANTIC_COLOR &&
		    outputs[i].semantic_name != TGSI_SEMANTIC_BCOLOR)
			continue;

		for (unsigned j = 0; j < 4; j++) {
			addr[i][j] = ac_build_alloca_undef(&ctx->ac, ctx->f32, "");
			LLVMBuildStore(ctx->ac.builder, outputs[i].values[j], addr[i][j]);
		}
		has_colors = true;
	}

	if (!has_colors)
		return;

	/* The state is in the first bit of the user SGPR. */
	LLVMValueRef cond = ac_get_arg(&ctx->ac, ctx->vs_state_bits);
	cond = LLVMBuildTrunc(ctx->ac.builder, cond, ctx->i1, "");

	ac_build_ifcc(&ctx->ac, cond, 6502);

	/* Store clamped colors to alloca variables within the conditional block. */
	for (unsigned i = 0; i < noutput; i++) {
		if (outputs[i].semantic_name != TGSI_SEMANTIC_COLOR &&
		    outputs[i].semantic_name != TGSI_SEMANTIC_BCOLOR)
			continue;

		for (unsigned j = 0; j < 4; j++) {
			LLVMBuildStore(ctx->ac.builder,
				       ac_build_clamp(&ctx->ac, outputs[i].values[j]),
				       addr[i][j]);
		}
	}
	ac_build_endif(&ctx->ac, 6502);

	/* Load clamped colors */
	for (unsigned i = 0; i < noutput; i++) {
		if (outputs[i].semantic_name != TGSI_SEMANTIC_COLOR &&
		    outputs[i].semantic_name != TGSI_SEMANTIC_BCOLOR)
			continue;

		for (unsigned j = 0; j < 4; j++) {
			outputs[i].values[j] =
				LLVMBuildLoad(ctx->ac.builder, addr[i][j], "");
		}
	}
}

/* Generate export instructions for hardware VS shader stage or NGG GS stage
 * (position and parameter data only).
 */
void si_llvm_export_vs(struct si_shader_context *ctx,
		       struct si_shader_output_values *outputs,
		       unsigned noutput)
{
	struct si_shader *shader = ctx->shader;
	struct ac_export_args pos_args[4] = {};
	LLVMValueRef psize_value = NULL, edgeflag_value = NULL, layer_value = NULL, viewport_index_value = NULL;
	unsigned pos_idx;
	int i;

	si_vertex_color_clamping(ctx, outputs, noutput);

	/* Build position exports. */
	for (i = 0; i < noutput; i++) {
		switch (outputs[i].semantic_name) {
		case TGSI_SEMANTIC_POSITION:
			si_llvm_init_vs_export_args(ctx, outputs[i].values,
						    V_008DFC_SQ_EXP_POS, &pos_args[0]);
			break;
		case TGSI_SEMANTIC_PSIZE:
			psize_value = outputs[i].values[0];
			break;
		case TGSI_SEMANTIC_LAYER:
			layer_value = outputs[i].values[0];
			break;
		case TGSI_SEMANTIC_VIEWPORT_INDEX:
			viewport_index_value = outputs[i].values[0];
			break;
		case TGSI_SEMANTIC_EDGEFLAG:
			edgeflag_value = outputs[i].values[0];
			break;
		case TGSI_SEMANTIC_CLIPDIST:
			if (!shader->key.opt.clip_disable) {
				unsigned index = 2 + outputs[i].semantic_index;
				si_llvm_init_vs_export_args(ctx, outputs[i].values,
							    V_008DFC_SQ_EXP_POS + index,
							    &pos_args[index]);
			}
			break;
		case TGSI_SEMANTIC_CLIPVERTEX:
			if (!shader->key.opt.clip_disable) {
				si_llvm_emit_clipvertex(ctx, pos_args,
							outputs[i].values);
			}
			break;
		}
	}

	/* We need to add the position output manually if it's missing. */
	if (!pos_args[0].out[0]) {
		pos_args[0].enabled_channels = 0xf; /* writemask */
		pos_args[0].valid_mask = 0; /* EXEC mask */
		pos_args[0].done = 0; /* last export? */
		pos_args[0].target = V_008DFC_SQ_EXP_POS;
		pos_args[0].compr = 0; /* COMPR flag */
		pos_args[0].out[0] = ctx->ac.f32_0; /* X */
		pos_args[0].out[1] = ctx->ac.f32_0; /* Y */
		pos_args[0].out[2] = ctx->ac.f32_0; /* Z */
		pos_args[0].out[3] = ctx->ac.f32_1;  /* W */
	}

	bool pos_writes_edgeflag = shader->selector->info.writes_edgeflag &&
				   !shader->key.as_ngg;

	/* Write the misc vector (point size, edgeflag, layer, viewport). */
	if (shader->selector->info.writes_psize ||
	    pos_writes_edgeflag ||
	    shader->selector->info.writes_viewport_index ||
	    shader->selector->info.writes_layer) {
		pos_args[1].enabled_channels = shader->selector->info.writes_psize |
					       (pos_writes_edgeflag << 1) |
					       (shader->selector->info.writes_layer << 2);

		pos_args[1].valid_mask = 0; /* EXEC mask */
		pos_args[1].done = 0; /* last export? */
		pos_args[1].target = V_008DFC_SQ_EXP_POS + 1;
		pos_args[1].compr = 0; /* COMPR flag */
		pos_args[1].out[0] = ctx->ac.f32_0; /* X */
		pos_args[1].out[1] = ctx->ac.f32_0; /* Y */
		pos_args[1].out[2] = ctx->ac.f32_0; /* Z */
		pos_args[1].out[3] = ctx->ac.f32_0; /* W */

		if (shader->selector->info.writes_psize)
			pos_args[1].out[0] = psize_value;

		if (pos_writes_edgeflag) {
			/* The output is a float, but the hw expects an integer
			 * with the first bit containing the edge flag. */
			edgeflag_value = LLVMBuildFPToUI(ctx->ac.builder,
							 edgeflag_value,
							 ctx->i32, "");
			edgeflag_value = ac_build_umin(&ctx->ac,
						      edgeflag_value,
						      ctx->i32_1);

			/* The LLVM intrinsic expects a float. */
			pos_args[1].out[1] = ac_to_float(&ctx->ac, edgeflag_value);
		}

		if (ctx->screen->info.chip_class >= GFX9) {
			/* GFX9 has the layer in out.z[10:0] and the viewport
			 * index in out.z[19:16].
			 */
			if (shader->selector->info.writes_layer)
				pos_args[1].out[2] = layer_value;

			if (shader->selector->info.writes_viewport_index) {
				LLVMValueRef v = viewport_index_value;

				v = ac_to_integer(&ctx->ac, v);
				v = LLVMBuildShl(ctx->ac.builder, v,
						 LLVMConstInt(ctx->i32, 16, 0), "");
				v = LLVMBuildOr(ctx->ac.builder, v,
						ac_to_integer(&ctx->ac,  pos_args[1].out[2]), "");
				pos_args[1].out[2] = ac_to_float(&ctx->ac, v);
				pos_args[1].enabled_channels |= 1 << 2;
			}
		} else {
			if (shader->selector->info.writes_layer)
				pos_args[1].out[2] = layer_value;

			if (shader->selector->info.writes_viewport_index) {
				pos_args[1].out[3] = viewport_index_value;
				pos_args[1].enabled_channels |= 1 << 3;
			}
		}
	}

	for (i = 0; i < 4; i++)
		if (pos_args[i].out[0])
			shader->info.nr_pos_exports++;

	/* Navi10-14 skip POS0 exports if EXEC=0 and DONE=0, causing a hang.
	 * Setting valid_mask=1 prevents it and has no other effect.
	 */
	if (ctx->screen->info.family == CHIP_NAVI10 ||
	    ctx->screen->info.family == CHIP_NAVI12 ||
	    ctx->screen->info.family == CHIP_NAVI14)
		pos_args[0].valid_mask = 1;

	pos_idx = 0;
	for (i = 0; i < 4; i++) {
		if (!pos_args[i].out[0])
			continue;

		/* Specify the target we are exporting */
		pos_args[i].target = V_008DFC_SQ_EXP_POS + pos_idx++;

		if (pos_idx == shader->info.nr_pos_exports)
			/* Specify that this is the last export */
			pos_args[i].done = 1;

		ac_build_export(&ctx->ac, &pos_args[i]);
	}

	/* Build parameter exports. */
	si_build_param_exports(ctx, outputs, noutput);
}

static void si_llvm_emit_vs_epilogue(struct ac_shader_abi *abi,
				     unsigned max_outputs,
				     LLVMValueRef *addrs)
{
	struct si_shader_context *ctx = si_shader_context_from_abi(abi);
	struct si_shader_info *info = &ctx->shader->selector->info;
	struct si_shader_output_values *outputs = NULL;
	int i,j;

	assert(!ctx->shader->is_gs_copy_shader);
	assert(info->num_outputs <= max_outputs);

	outputs = MALLOC((info->num_outputs + 1) * sizeof(outputs[0]));

	for (i = 0; i < info->num_outputs; i++) {
		outputs[i].semantic_name = info->output_semantic_name[i];
		outputs[i].semantic_index = info->output_semantic_index[i];

		for (j = 0; j < 4; j++) {
			outputs[i].values[j] =
				LLVMBuildLoad(ctx->ac.builder,
					      addrs[4 * i + j],
					      "");
			outputs[i].vertex_stream[j] =
				(info->output_streams[i] >> (2 * j)) & 3;
		}
	}

	if (!ctx->screen->use_ngg_streamout &&
	    ctx->shader->selector->so.num_outputs)
		si_llvm_emit_streamout(ctx, outputs, i, 0);

	/* Export PrimitiveID. */
	if (ctx->shader->key.mono.u.vs_export_prim_id) {
		outputs[i].semantic_name = TGSI_SEMANTIC_PRIMID;
		outputs[i].semantic_index = 0;
		outputs[i].values[0] = ac_to_float(&ctx->ac, si_get_primitive_id(ctx, 0));
		for (j = 1; j < 4; j++)
			outputs[i].values[j] = LLVMConstReal(ctx->f32, 0);

		memset(outputs[i].vertex_stream, 0,
		       sizeof(outputs[i].vertex_stream));
		i++;
	}

	si_llvm_export_vs(ctx, outputs, i);
	FREE(outputs);
}

static void si_llvm_emit_prim_discard_cs_epilogue(struct ac_shader_abi *abi,
						  unsigned max_outputs,
						  LLVMValueRef *addrs)
{
	struct si_shader_context *ctx = si_shader_context_from_abi(abi);
	struct si_shader_info *info = &ctx->shader->selector->info;
	LLVMValueRef pos[4] = {};

	assert(info->num_outputs <= max_outputs);

	for (unsigned i = 0; i < info->num_outputs; i++) {
		if (info->output_semantic_name[i] != TGSI_SEMANTIC_POSITION)
			continue;

		for (unsigned chan = 0; chan < 4; chan++)
			pos[chan] = LLVMBuildLoad(ctx->ac.builder, addrs[4 * i + chan], "");
		break;
	}
	assert(pos[0] != NULL);

	/* Return the position output. */
	LLVMValueRef ret = ctx->return_value;
	for (unsigned chan = 0; chan < 4; chan++)
		ret = LLVMBuildInsertValue(ctx->ac.builder, ret, pos[chan], chan, "");
	ctx->return_value = ret;
}

static void declare_streamout_params(struct si_shader_context *ctx,
				     struct pipe_stream_output_info *so)
{
	if (ctx->screen->use_ngg_streamout) {
		if (ctx->type == PIPE_SHADER_TESS_EVAL)
			ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, NULL);
		return;
	}

	/* Streamout SGPRs. */
	if (so->num_outputs) {
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->streamout_config);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->streamout_write_index);
	} else if (ctx->type == PIPE_SHADER_TESS_EVAL) {
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, NULL);
	}

	/* A streamout buffer offset is loaded if the stride is non-zero. */
	for (int i = 0; i < 4; i++) {
		if (!so->stride[i])
			continue;

		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->streamout_offset[i]);
	}
}

static unsigned si_get_max_workgroup_size(const struct si_shader *shader)
{
	switch (shader->selector->type) {
	case PIPE_SHADER_VERTEX:
	case PIPE_SHADER_TESS_EVAL:
		return shader->key.as_ngg ? 128 : 0;

	case PIPE_SHADER_TESS_CTRL:
		/* Return this so that LLVM doesn't remove s_barrier
		 * instructions on chips where we use s_barrier. */
		return shader->selector->screen->info.chip_class >= GFX7 ? 128 : 0;

	case PIPE_SHADER_GEOMETRY:
		return shader->selector->screen->info.chip_class >= GFX9 ? 128 : 0;

	case PIPE_SHADER_COMPUTE:
		break; /* see below */

	default:
		return 0;
	}

	const unsigned *properties = shader->selector->info.properties;
	unsigned max_work_group_size =
	               properties[TGSI_PROPERTY_CS_FIXED_BLOCK_WIDTH] *
	               properties[TGSI_PROPERTY_CS_FIXED_BLOCK_HEIGHT] *
	               properties[TGSI_PROPERTY_CS_FIXED_BLOCK_DEPTH];

	if (!max_work_group_size) {
		/* This is a variable group size compute shader,
		 * compile it for the maximum possible group size.
		 */
		max_work_group_size = SI_MAX_VARIABLE_THREADS_PER_BLOCK;
	}
	return max_work_group_size;
}

static void declare_const_and_shader_buffers(struct si_shader_context *ctx,
					     bool assign_params)
{
	enum ac_arg_type const_shader_buf_type;

	if (ctx->shader->selector->info.const_buffers_declared == 1 &&
	    ctx->shader->selector->info.shader_buffers_declared == 0)
		const_shader_buf_type = AC_ARG_CONST_FLOAT_PTR;
	else
		const_shader_buf_type = AC_ARG_CONST_DESC_PTR;

	ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, const_shader_buf_type,
		   assign_params ? &ctx->const_and_shader_buffers :
		   &ctx->other_const_and_shader_buffers);
}

static void declare_samplers_and_images(struct si_shader_context *ctx,
					bool assign_params)
{
	ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_CONST_IMAGE_PTR,
		   assign_params ? &ctx->samplers_and_images :
		   &ctx->other_samplers_and_images);
}

static void declare_per_stage_desc_pointers(struct si_shader_context *ctx,
					    bool assign_params)
{
	declare_const_and_shader_buffers(ctx, assign_params);
	declare_samplers_and_images(ctx, assign_params);
}

static void declare_global_desc_pointers(struct si_shader_context *ctx)
{
	ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_CONST_DESC_PTR,
		   &ctx->rw_buffers);
	ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_CONST_IMAGE_PTR,
		   &ctx->bindless_samplers_and_images);
}

static void declare_vs_specific_input_sgprs(struct si_shader_context *ctx)
{
	ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->vs_state_bits);
	if (!ctx->shader->is_gs_copy_shader) {
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->args.base_vertex);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->args.start_instance);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->args.draw_id);
	}
}

static void declare_vb_descriptor_input_sgprs(struct si_shader_context *ctx)
{
	ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_CONST_DESC_PTR, &ctx->vertex_buffers);

	unsigned num_vbos_in_user_sgprs = ctx->shader->selector->num_vbos_in_user_sgprs;
	if (num_vbos_in_user_sgprs) {
		unsigned user_sgprs = ctx->args.num_sgprs_used;

		if (si_is_merged_shader(ctx))
			user_sgprs -= 8;
		assert(user_sgprs <= SI_SGPR_VS_VB_DESCRIPTOR_FIRST);

		/* Declare unused SGPRs to align VB descriptors to 4 SGPRs (hw requirement). */
		for (unsigned i = user_sgprs; i < SI_SGPR_VS_VB_DESCRIPTOR_FIRST; i++)
			ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, NULL); /* unused */

		assert(num_vbos_in_user_sgprs <= ARRAY_SIZE(ctx->vb_descriptors));
		for (unsigned i = 0; i < num_vbos_in_user_sgprs; i++)
			ac_add_arg(&ctx->args, AC_ARG_SGPR, 4, AC_ARG_INT, &ctx->vb_descriptors[i]);
	}
}

static void declare_vs_input_vgprs(struct si_shader_context *ctx,
				   unsigned *num_prolog_vgprs,
				   bool ngg_cull_shader)
{
	struct si_shader *shader = ctx->shader;

	ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->args.vertex_id);
	if (shader->key.as_ls) {
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->rel_auto_id);
		if (ctx->screen->info.chip_class >= GFX10) {
			ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, NULL); /* user VGPR */
			ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->args.instance_id);
		} else {
			ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->args.instance_id);
			ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, NULL); /* unused */
		}
	} else if (ctx->screen->info.chip_class >= GFX10) {
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, NULL); /* user VGPR */
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT,
			   &ctx->vs_prim_id); /* user vgpr or PrimID (legacy) */
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->args.instance_id);
	} else {
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->args.instance_id);
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->vs_prim_id);
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, NULL); /* unused */
	}

	if (!shader->is_gs_copy_shader) {
		if (shader->key.opt.ngg_culling && !ngg_cull_shader) {
			ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT,
				   &ctx->ngg_old_thread_id);
		}

		/* Vertex load indices. */
		if (shader->selector->info.num_inputs) {
			ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT,
				   &ctx->vertex_index0);
			for (unsigned i = 1; i < shader->selector->info.num_inputs; i++)
				ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, NULL);
		}
		*num_prolog_vgprs += shader->selector->info.num_inputs;
	}
}

static void declare_vs_blit_inputs(struct si_shader_context *ctx,
				   unsigned vs_blit_property)
{
	ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT,
		   &ctx->vs_blit_inputs); /* i16 x1, y1 */
	ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, NULL); /* i16 x1, y1 */
	ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_FLOAT, NULL); /* depth */

	if (vs_blit_property == SI_VS_BLIT_SGPRS_POS_COLOR) {
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_FLOAT, NULL); /* color0 */
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_FLOAT, NULL); /* color1 */
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_FLOAT, NULL); /* color2 */
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_FLOAT, NULL); /* color3 */
	} else if (vs_blit_property == SI_VS_BLIT_SGPRS_POS_TEXCOORD) {
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_FLOAT, NULL); /* texcoord.x1 */
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_FLOAT, NULL); /* texcoord.y1 */
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_FLOAT, NULL); /* texcoord.x2 */
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_FLOAT, NULL); /* texcoord.y2 */
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_FLOAT, NULL); /* texcoord.z */
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_FLOAT, NULL); /* texcoord.w */
	}
}

static void declare_tes_input_vgprs(struct si_shader_context *ctx, bool ngg_cull_shader)
{
	ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_FLOAT, &ctx->tes_u);
	ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_FLOAT, &ctx->tes_v);
	ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->tes_rel_patch_id);
	ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->args.tes_patch_id);

	if (ctx->shader->key.opt.ngg_culling && !ngg_cull_shader) {
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT,
			   &ctx->ngg_old_thread_id);
	}
}

enum {
	/* Convenient merged shader definitions. */
	SI_SHADER_MERGED_VERTEX_TESSCTRL = PIPE_SHADER_TYPES,
	SI_SHADER_MERGED_VERTEX_OR_TESSEVAL_GEOMETRY,
};

void si_add_arg_checked(struct ac_shader_args *args,
			enum ac_arg_regfile file,
			unsigned registers, enum ac_arg_type type,
			struct ac_arg *arg,
			unsigned idx)
{
	assert(args->arg_count == idx);
	ac_add_arg(args, file, registers, type, arg);
}

void si_create_function(struct si_shader_context *ctx, bool ngg_cull_shader)
{
	struct si_shader *shader = ctx->shader;
	LLVMTypeRef returns[AC_MAX_ARGS];
	unsigned i, num_return_sgprs;
	unsigned num_returns = 0;
	unsigned num_prolog_vgprs = 0;
	unsigned type = ctx->type;
	unsigned vs_blit_property =
		shader->selector->info.properties[TGSI_PROPERTY_VS_BLIT_SGPRS_AMD];

	memset(&ctx->args, 0, sizeof(ctx->args));

	/* Set MERGED shaders. */
	if (ctx->screen->info.chip_class >= GFX9) {
		if (shader->key.as_ls || type == PIPE_SHADER_TESS_CTRL)
			type = SI_SHADER_MERGED_VERTEX_TESSCTRL; /* LS or HS */
		else if (shader->key.as_es || shader->key.as_ngg || type == PIPE_SHADER_GEOMETRY)
			type = SI_SHADER_MERGED_VERTEX_OR_TESSEVAL_GEOMETRY;
	}

	switch (type) {
	case PIPE_SHADER_VERTEX:
		declare_global_desc_pointers(ctx);

		if (vs_blit_property) {
			declare_vs_blit_inputs(ctx, vs_blit_property);

			/* VGPRs */
			declare_vs_input_vgprs(ctx, &num_prolog_vgprs, ngg_cull_shader);
			break;
		}

		declare_per_stage_desc_pointers(ctx, true);
		declare_vs_specific_input_sgprs(ctx); 
		if (!shader->is_gs_copy_shader)
			declare_vb_descriptor_input_sgprs(ctx);

		if (shader->key.as_es) {
			ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT,
				   &ctx->es2gs_offset);
		} else if (shader->key.as_ls) {
			/* no extra parameters */
		} else {
			/* The locations of the other parameters are assigned dynamically. */
			declare_streamout_params(ctx, &shader->selector->so);
		}

		/* VGPRs */
		declare_vs_input_vgprs(ctx, &num_prolog_vgprs, ngg_cull_shader);

		/* Return values */
		if (shader->key.opt.vs_as_prim_discard_cs) {
			for (i = 0; i < 4; i++)
				returns[num_returns++] = ctx->f32; /* VGPRs */
		}
		break;

	case PIPE_SHADER_TESS_CTRL: /* GFX6-GFX8 */
		declare_global_desc_pointers(ctx);
		declare_per_stage_desc_pointers(ctx, true);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tcs_offchip_layout);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tcs_out_lds_offsets);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tcs_out_lds_layout);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->vs_state_bits);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tcs_offchip_offset);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tcs_factor_offset);

		/* VGPRs */
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->args.tcs_patch_id);
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->args.tcs_rel_ids);

		/* param_tcs_offchip_offset and param_tcs_factor_offset are
		 * placed after the user SGPRs.
		 */
		for (i = 0; i < GFX6_TCS_NUM_USER_SGPR + 2; i++)
			returns[num_returns++] = ctx->i32; /* SGPRs */
		for (i = 0; i < 11; i++)
			returns[num_returns++] = ctx->f32; /* VGPRs */
		break;

	case SI_SHADER_MERGED_VERTEX_TESSCTRL:
		/* Merged stages have 8 system SGPRs at the beginning. */
		/* SPI_SHADER_USER_DATA_ADDR_LO/HI_HS */
		declare_per_stage_desc_pointers(ctx,
						ctx->type == PIPE_SHADER_TESS_CTRL);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tcs_offchip_offset);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->merged_wave_info);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tcs_factor_offset);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->merged_scratch_offset);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, NULL); /* unused */
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, NULL); /* unused */

		declare_global_desc_pointers(ctx);
		declare_per_stage_desc_pointers(ctx,
						ctx->type == PIPE_SHADER_VERTEX);
		declare_vs_specific_input_sgprs(ctx);

		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tcs_offchip_layout);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tcs_out_lds_offsets);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tcs_out_lds_layout);
		declare_vb_descriptor_input_sgprs(ctx);

		/* VGPRs (first TCS, then VS) */
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->args.tcs_patch_id);
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->args.tcs_rel_ids);

		if (ctx->type == PIPE_SHADER_VERTEX) {
			declare_vs_input_vgprs(ctx, &num_prolog_vgprs, ngg_cull_shader);

			/* LS return values are inputs to the TCS main shader part. */
			for (i = 0; i < 8 + GFX9_TCS_NUM_USER_SGPR; i++)
				returns[num_returns++] = ctx->i32; /* SGPRs */
			for (i = 0; i < 2; i++)
				returns[num_returns++] = ctx->f32; /* VGPRs */
		} else {
			/* TCS return values are inputs to the TCS epilog.
			 *
			 * param_tcs_offchip_offset, param_tcs_factor_offset,
			 * param_tcs_offchip_layout, and param_rw_buffers
			 * should be passed to the epilog.
			 */
			for (i = 0; i <= 8 + GFX9_SGPR_TCS_OUT_LAYOUT; i++)
				returns[num_returns++] = ctx->i32; /* SGPRs */
			for (i = 0; i < 11; i++)
				returns[num_returns++] = ctx->f32; /* VGPRs */
		}
		break;

	case SI_SHADER_MERGED_VERTEX_OR_TESSEVAL_GEOMETRY:
		/* Merged stages have 8 system SGPRs at the beginning. */
		/* SPI_SHADER_USER_DATA_ADDR_LO/HI_GS */
		declare_per_stage_desc_pointers(ctx,
						ctx->type == PIPE_SHADER_GEOMETRY);

		if (ctx->shader->key.as_ngg)
			ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->gs_tg_info);
		else
			ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->gs2vs_offset);

		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->merged_wave_info);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tcs_offchip_offset);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->merged_scratch_offset);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_CONST_DESC_PTR,
			   &ctx->small_prim_cull_info); /* SPI_SHADER_PGM_LO_GS << 8 */
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, NULL); /* unused (SPI_SHADER_PGM_LO/HI_GS >> 24) */

		declare_global_desc_pointers(ctx);
		if (ctx->type != PIPE_SHADER_VERTEX || !vs_blit_property) {
			declare_per_stage_desc_pointers(ctx,
							(ctx->type == PIPE_SHADER_VERTEX ||
							 ctx->type == PIPE_SHADER_TESS_EVAL));
		}

		if (ctx->type == PIPE_SHADER_VERTEX) {
			if (vs_blit_property)
				declare_vs_blit_inputs(ctx, vs_blit_property);
			else
				declare_vs_specific_input_sgprs(ctx);
		} else {
			ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->vs_state_bits);
			ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tcs_offchip_layout);
			ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tes_offchip_addr);
			/* Declare as many input SGPRs as the VS has. */
		}

		if (ctx->type == PIPE_SHADER_VERTEX)
			declare_vb_descriptor_input_sgprs(ctx);

		/* VGPRs (first GS, then VS/TES) */
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->gs_vtx01_offset);
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->gs_vtx23_offset);
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->args.gs_prim_id);
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->args.gs_invocation_id);
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->gs_vtx45_offset);

		if (ctx->type == PIPE_SHADER_VERTEX) {
			declare_vs_input_vgprs(ctx, &num_prolog_vgprs, ngg_cull_shader);
		} else if (ctx->type == PIPE_SHADER_TESS_EVAL) {
			declare_tes_input_vgprs(ctx, ngg_cull_shader);
		}

		if ((ctx->shader->key.as_es || ngg_cull_shader) &&
		    (ctx->type == PIPE_SHADER_VERTEX ||
		     ctx->type == PIPE_SHADER_TESS_EVAL)) {
			unsigned num_user_sgprs, num_vgprs;

			/* For the NGG cull shader, add 1 SGPR to hold the vertex buffer pointer. */
			if (ctx->type == PIPE_SHADER_VERTEX)
				num_user_sgprs = GFX9_VSGS_NUM_USER_SGPR + ngg_cull_shader;
			else
				num_user_sgprs = GFX9_TESGS_NUM_USER_SGPR;

			/* The NGG cull shader has to return all 9 VGPRs + the old thread ID.
			 *
			 * The normal merged ESGS shader only has to return the 5 VGPRs
			 * for the GS stage.
			 */
			num_vgprs = ngg_cull_shader ? 10 : 5;

			/* ES return values are inputs to GS. */
			for (i = 0; i < 8 + num_user_sgprs; i++)
				returns[num_returns++] = ctx->i32; /* SGPRs */
			for (i = 0; i < num_vgprs; i++)
				returns[num_returns++] = ctx->f32; /* VGPRs */
		}
		break;

	case PIPE_SHADER_TESS_EVAL:
		declare_global_desc_pointers(ctx);
		declare_per_stage_desc_pointers(ctx, true);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->vs_state_bits);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tcs_offchip_layout);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tes_offchip_addr);

		if (shader->key.as_es) {
			ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tcs_offchip_offset);
			ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, NULL);
			ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->es2gs_offset);
		} else {
			declare_streamout_params(ctx, &shader->selector->so);
			ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->tcs_offchip_offset);
		}

		/* VGPRs */
		declare_tes_input_vgprs(ctx, ngg_cull_shader);
		break;

	case PIPE_SHADER_GEOMETRY:
		declare_global_desc_pointers(ctx);
		declare_per_stage_desc_pointers(ctx, true);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->gs2vs_offset);
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->gs_wave_id);

		/* VGPRs */
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->gs_vtx_offset[0]);
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->gs_vtx_offset[1]);
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->args.gs_prim_id);
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->gs_vtx_offset[2]);
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->gs_vtx_offset[3]);
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->gs_vtx_offset[4]);
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->gs_vtx_offset[5]);
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &ctx->args.gs_invocation_id);
		break;

	case PIPE_SHADER_FRAGMENT:
		declare_global_desc_pointers(ctx);
		declare_per_stage_desc_pointers(ctx, true);
		si_add_arg_checked(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, NULL,
				SI_PARAM_ALPHA_REF);
		si_add_arg_checked(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT,
				&ctx->args.prim_mask, SI_PARAM_PRIM_MASK);

		si_add_arg_checked(&ctx->args, AC_ARG_VGPR, 2, AC_ARG_INT, &ctx->args.persp_sample,
				SI_PARAM_PERSP_SAMPLE);
		si_add_arg_checked(&ctx->args, AC_ARG_VGPR, 2, AC_ARG_INT,
				&ctx->args.persp_center, SI_PARAM_PERSP_CENTER);
		si_add_arg_checked(&ctx->args, AC_ARG_VGPR, 2, AC_ARG_INT,
				&ctx->args.persp_centroid, SI_PARAM_PERSP_CENTROID);
		si_add_arg_checked(&ctx->args, AC_ARG_VGPR, 3, AC_ARG_INT,
				NULL, SI_PARAM_PERSP_PULL_MODEL);
		si_add_arg_checked(&ctx->args, AC_ARG_VGPR, 2, AC_ARG_INT,
				&ctx->args.linear_sample, SI_PARAM_LINEAR_SAMPLE);
		si_add_arg_checked(&ctx->args, AC_ARG_VGPR, 2, AC_ARG_INT,
				&ctx->args.linear_center, SI_PARAM_LINEAR_CENTER);
		si_add_arg_checked(&ctx->args, AC_ARG_VGPR, 2, AC_ARG_INT,
				&ctx->args.linear_centroid, SI_PARAM_LINEAR_CENTROID);
		si_add_arg_checked(&ctx->args, AC_ARG_VGPR, 3, AC_ARG_FLOAT,
				NULL, SI_PARAM_LINE_STIPPLE_TEX);
		si_add_arg_checked(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_FLOAT,
				&ctx->args.frag_pos[0], SI_PARAM_POS_X_FLOAT);
		si_add_arg_checked(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_FLOAT,
				&ctx->args.frag_pos[1], SI_PARAM_POS_Y_FLOAT);
		si_add_arg_checked(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_FLOAT,
				&ctx->args.frag_pos[2], SI_PARAM_POS_Z_FLOAT);
		si_add_arg_checked(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_FLOAT,
				&ctx->args.frag_pos[3], SI_PARAM_POS_W_FLOAT);
		shader->info.face_vgpr_index = ctx->args.num_vgprs_used;
		si_add_arg_checked(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT,
				&ctx->args.front_face, SI_PARAM_FRONT_FACE);
		shader->info.ancillary_vgpr_index = ctx->args.num_vgprs_used;
		si_add_arg_checked(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT,
				&ctx->args.ancillary, SI_PARAM_ANCILLARY);
		si_add_arg_checked(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_FLOAT,
				&ctx->args.sample_coverage, SI_PARAM_SAMPLE_COVERAGE);
		si_add_arg_checked(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT,
				&ctx->pos_fixed_pt, SI_PARAM_POS_FIXED_PT);

		/* Color inputs from the prolog. */
		if (shader->selector->info.colors_read) {
			unsigned num_color_elements =
				util_bitcount(shader->selector->info.colors_read);

			for (i = 0; i < num_color_elements; i++)
				ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_FLOAT, NULL);

			num_prolog_vgprs += num_color_elements;
		}

		/* Outputs for the epilog. */
		num_return_sgprs = SI_SGPR_ALPHA_REF + 1;
		num_returns =
			num_return_sgprs +
			util_bitcount(shader->selector->info.colors_written) * 4 +
			shader->selector->info.writes_z +
			shader->selector->info.writes_stencil +
			shader->selector->info.writes_samplemask +
			1 /* SampleMaskIn */;

		num_returns = MAX2(num_returns,
				   num_return_sgprs +
				   PS_EPILOG_SAMPLEMASK_MIN_LOC + 1);

		for (i = 0; i < num_return_sgprs; i++)
			returns[i] = ctx->i32;
		for (; i < num_returns; i++)
			returns[i] = ctx->f32;
		break;

	case PIPE_SHADER_COMPUTE:
		declare_global_desc_pointers(ctx);
		declare_per_stage_desc_pointers(ctx, true);
		if (shader->selector->info.uses_grid_size)
			ac_add_arg(&ctx->args, AC_ARG_SGPR, 3, AC_ARG_INT,
				   &ctx->args.num_work_groups);
		if (shader->selector->info.uses_block_size &&
		    shader->selector->info.properties[TGSI_PROPERTY_CS_FIXED_BLOCK_WIDTH] == 0)
			ac_add_arg(&ctx->args, AC_ARG_SGPR, 3, AC_ARG_INT, &ctx->block_size);

		unsigned cs_user_data_dwords =
			shader->selector->info.properties[TGSI_PROPERTY_CS_USER_DATA_COMPONENTS_AMD];
		if (cs_user_data_dwords) {
			ac_add_arg(&ctx->args, AC_ARG_SGPR, cs_user_data_dwords, AC_ARG_INT,
				   &ctx->cs_user_data);
		}

		/* Hardware SGPRs. */
		for (i = 0; i < 3; i++) {
			if (shader->selector->info.uses_block_id[i]) {
				ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT,
					   &ctx->args.workgroup_ids[i]);
			}
		}
		if (shader->selector->info.uses_subgroup_info)
			ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT, &ctx->args.tg_size);

		/* Hardware VGPRs. */
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 3, AC_ARG_INT,
			   &ctx->args.local_invocation_ids);
		break;
	default:
		assert(0 && "unimplemented shader");
		return;
	}

	si_llvm_create_func(ctx, ngg_cull_shader ? "ngg_cull_main" : "main",
			    returns, num_returns, si_get_max_workgroup_size(shader));

	/* Reserve register locations for VGPR inputs the PS prolog may need. */
	if (ctx->type == PIPE_SHADER_FRAGMENT && !ctx->shader->is_monolithic) {
		ac_llvm_add_target_dep_function_attr(ctx->main_fn,
						     "InitialPSInputAddr",
						     S_0286D0_PERSP_SAMPLE_ENA(1) |
						     S_0286D0_PERSP_CENTER_ENA(1) |
						     S_0286D0_PERSP_CENTROID_ENA(1) |
						     S_0286D0_LINEAR_SAMPLE_ENA(1) |
						     S_0286D0_LINEAR_CENTER_ENA(1) |
						     S_0286D0_LINEAR_CENTROID_ENA(1) |
						     S_0286D0_FRONT_FACE_ENA(1) |
						     S_0286D0_ANCILLARY_ENA(1) |
						     S_0286D0_POS_FIXED_PT_ENA(1));
	}

	shader->info.num_input_sgprs = ctx->args.num_sgprs_used;
	shader->info.num_input_vgprs = ctx->args.num_vgprs_used;

	assert(shader->info.num_input_vgprs >= num_prolog_vgprs);
	shader->info.num_input_vgprs -= num_prolog_vgprs;

	if (shader->key.as_ls || ctx->type == PIPE_SHADER_TESS_CTRL) {
		if (USE_LDS_SYMBOLS && LLVM_VERSION_MAJOR >= 9) {
			/* The LSHS size is not known until draw time, so we append it
			 * at the end of whatever LDS use there may be in the rest of
			 * the shader (currently none, unless LLVM decides to do its
			 * own LDS-based lowering).
			 */
			ctx->ac.lds = LLVMAddGlobalInAddressSpace(
				ctx->ac.module, LLVMArrayType(ctx->i32, 0),
				"__lds_end", AC_ADDR_SPACE_LDS);
			LLVMSetAlignment(ctx->ac.lds, 256);
		} else {
			ac_declare_lds_as_pointer(&ctx->ac);
		}
	}

	/* Unlike radv, we override these arguments in the prolog, so to the
	 * API shader they appear as normal arguments.
	 */
	if (ctx->type == PIPE_SHADER_VERTEX) {
		ctx->abi.vertex_id = ac_get_arg(&ctx->ac, ctx->args.vertex_id);
		ctx->abi.instance_id = ac_get_arg(&ctx->ac, ctx->args.instance_id);
	} else if (ctx->type == PIPE_SHADER_FRAGMENT) {
		ctx->abi.persp_centroid = ac_get_arg(&ctx->ac, ctx->args.persp_centroid);
		ctx->abi.linear_centroid = ac_get_arg(&ctx->ac, ctx->args.linear_centroid);
	}
}

/* For the UMR disassembler. */
#define DEBUGGER_END_OF_CODE_MARKER	0xbf9f0000 /* invalid instruction */
#define DEBUGGER_NUM_MARKERS		5

static bool si_shader_binary_open(struct si_screen *screen,
				  struct si_shader *shader,
				  struct ac_rtld_binary *rtld)
{
	const struct si_shader_selector *sel = shader->selector;
	const char *part_elfs[5];
	size_t part_sizes[5];
	unsigned num_parts = 0;

#define add_part(shader_or_part) \
	if (shader_or_part) { \
		part_elfs[num_parts] = (shader_or_part)->binary.elf_buffer; \
		part_sizes[num_parts] = (shader_or_part)->binary.elf_size; \
		num_parts++; \
	}

	add_part(shader->prolog);
	add_part(shader->previous_stage);
	add_part(shader->prolog2);
	add_part(shader);
	add_part(shader->epilog);

#undef add_part

	struct ac_rtld_symbol lds_symbols[2];
	unsigned num_lds_symbols = 0;

	if (sel && screen->info.chip_class >= GFX9 && !shader->is_gs_copy_shader &&
	    (sel->type == PIPE_SHADER_GEOMETRY || shader->key.as_ngg)) {
		/* We add this symbol even on LLVM <= 8 to ensure that
		 * shader->config.lds_size is set correctly below.
		 */
		struct ac_rtld_symbol *sym = &lds_symbols[num_lds_symbols++];
		sym->name = "esgs_ring";
		sym->size = shader->gs_info.esgs_ring_size;
		sym->align = 64 * 1024;
	}

	if (shader->key.as_ngg && sel->type == PIPE_SHADER_GEOMETRY) {
		struct ac_rtld_symbol *sym = &lds_symbols[num_lds_symbols++];
		sym->name = "ngg_emit";
		sym->size = shader->ngg.ngg_emit_size * 4;
		sym->align = 4;
	}

	bool ok = ac_rtld_open(rtld, (struct ac_rtld_open_info){
			.info = &screen->info,
			.options = {
				.halt_at_entry = screen->options.halt_shaders,
			},
			.shader_type = tgsi_processor_to_shader_stage(sel->type),
			.wave_size = si_get_shader_wave_size(shader),
			.num_parts = num_parts,
			.elf_ptrs = part_elfs,
			.elf_sizes = part_sizes,
			.num_shared_lds_symbols = num_lds_symbols,
			.shared_lds_symbols = lds_symbols });

	if (rtld->lds_size > 0) {
		unsigned alloc_granularity = screen->info.chip_class >= GFX7 ? 512 : 256;
		shader->config.lds_size =
			align(rtld->lds_size, alloc_granularity) / alloc_granularity;
	}

	return ok;
}

static unsigned si_get_shader_binary_size(struct si_screen *screen, struct si_shader *shader)
{
	struct ac_rtld_binary rtld;
	si_shader_binary_open(screen, shader, &rtld);
	return rtld.exec_size;
}

static bool si_get_external_symbol(void *data, const char *name, uint64_t *value)
{
	uint64_t *scratch_va = data;

	if (!strcmp(scratch_rsrc_dword0_symbol, name)) {
		*value = (uint32_t)*scratch_va;
		return true;
	}
	if (!strcmp(scratch_rsrc_dword1_symbol, name)) {
		/* Enable scratch coalescing. */
		*value = S_008F04_BASE_ADDRESS_HI(*scratch_va >> 32) |
			 S_008F04_SWIZZLE_ENABLE(1);
		return true;
	}

	return false;
}

bool si_shader_binary_upload(struct si_screen *sscreen, struct si_shader *shader,
			     uint64_t scratch_va)
{
	struct ac_rtld_binary binary;
	if (!si_shader_binary_open(sscreen, shader, &binary))
		return false;

	si_resource_reference(&shader->bo, NULL);
	shader->bo = si_aligned_buffer_create(&sscreen->b,
					      sscreen->info.cpdma_prefetch_writes_memory ?
						0 : SI_RESOURCE_FLAG_READ_ONLY,
                                              PIPE_USAGE_IMMUTABLE,
                                              align(binary.rx_size, SI_CPDMA_ALIGNMENT),
                                              256);
	if (!shader->bo)
		return false;

	/* Upload. */
	struct ac_rtld_upload_info u = {};
	u.binary = &binary;
	u.get_external_symbol = si_get_external_symbol;
	u.cb_data = &scratch_va;
	u.rx_va = shader->bo->gpu_address;
	u.rx_ptr = sscreen->ws->buffer_map(shader->bo->buf, NULL,
					PIPE_TRANSFER_READ_WRITE |
					PIPE_TRANSFER_UNSYNCHRONIZED |
					RADEON_TRANSFER_TEMPORARY);
	if (!u.rx_ptr)
		return false;

	bool ok = ac_rtld_upload(&u);

	sscreen->ws->buffer_unmap(shader->bo->buf);
	ac_rtld_close(&binary);

	return ok;
}

static void si_shader_dump_disassembly(struct si_screen *screen,
				       const struct si_shader_binary *binary,
				       enum pipe_shader_type shader_type,
				       unsigned wave_size,
				       struct pipe_debug_callback *debug,
				       const char *name, FILE *file)
{
	struct ac_rtld_binary rtld_binary;

	if (!ac_rtld_open(&rtld_binary, (struct ac_rtld_open_info){
			.info = &screen->info,
			.shader_type = tgsi_processor_to_shader_stage(shader_type),
			.wave_size = wave_size,
			.num_parts = 1,
			.elf_ptrs = &binary->elf_buffer,
			.elf_sizes = &binary->elf_size }))
		return;

	const char *disasm;
	size_t nbytes;

	if (!ac_rtld_get_section_by_name(&rtld_binary, ".AMDGPU.disasm", &disasm, &nbytes))
		goto out;

	if (nbytes > INT_MAX)
		goto out;

	if (debug && debug->debug_message) {
		/* Very long debug messages are cut off, so send the
		 * disassembly one line at a time. This causes more
		 * overhead, but on the plus side it simplifies
		 * parsing of resulting logs.
		 */
		pipe_debug_message(debug, SHADER_INFO,
				   "Shader Disassembly Begin");

		uint64_t line = 0;
		while (line < nbytes) {
			int count = nbytes - line;
			const char *nl = memchr(disasm + line, '\n', nbytes - line);
			if (nl)
				count = nl - (disasm + line);

			if (count) {
				pipe_debug_message(debug, SHADER_INFO,
						   "%.*s", count, disasm + line);
			}

			line += count + 1;
		}

		pipe_debug_message(debug, SHADER_INFO,
				   "Shader Disassembly End");
	}

	if (file) {
		fprintf(file, "Shader %s disassembly:\n", name);
		fprintf(file, "%*s", (int)nbytes, disasm);
	}

out:
	ac_rtld_close(&rtld_binary);
}

static void si_calculate_max_simd_waves(struct si_shader *shader)
{
	struct si_screen *sscreen = shader->selector->screen;
	struct ac_shader_config *conf = &shader->config;
	unsigned num_inputs = shader->selector->info.num_inputs;
	unsigned lds_increment = sscreen->info.chip_class >= GFX7 ? 512 : 256;
	unsigned lds_per_wave = 0;
	unsigned max_simd_waves;

	max_simd_waves = sscreen->info.max_wave64_per_simd;

	/* Compute LDS usage for PS. */
	switch (shader->selector->type) {
	case PIPE_SHADER_FRAGMENT:
		/* The minimum usage per wave is (num_inputs * 48). The maximum
		 * usage is (num_inputs * 48 * 16).
		 * We can get anything in between and it varies between waves.
		 *
		 * The 48 bytes per input for a single primitive is equal to
		 * 4 bytes/component * 4 components/input * 3 points.
		 *
		 * Other stages don't know the size at compile time or don't
		 * allocate LDS per wave, but instead they do it per thread group.
		 */
		lds_per_wave = conf->lds_size * lds_increment +
			       align(num_inputs * 48, lds_increment);
		break;
	case PIPE_SHADER_COMPUTE:
		if (shader->selector) {
			unsigned max_workgroup_size =
				si_get_max_workgroup_size(shader);
			lds_per_wave = (conf->lds_size * lds_increment) /
				       DIV_ROUND_UP(max_workgroup_size,
						    sscreen->compute_wave_size);
		}
		break;
	default:;
	}

	/* Compute the per-SIMD wave counts. */
	if (conf->num_sgprs) {
		max_simd_waves =
			MIN2(max_simd_waves,
			     sscreen->info.num_physical_sgprs_per_simd / conf->num_sgprs);
	}

	if (conf->num_vgprs) {
		/* Always print wave limits as Wave64, so that we can compare
		 * Wave32 and Wave64 with shader-db fairly. */
		unsigned max_vgprs = sscreen->info.num_physical_wave64_vgprs_per_simd;
		max_simd_waves = MIN2(max_simd_waves, max_vgprs / conf->num_vgprs);
	}

	/* LDS is 64KB per CU (4 SIMDs) on GFX6-9, which is 16KB per SIMD (usage above
	 * 16KB makes some SIMDs unoccupied).
	 *
	 * LDS is 128KB in WGP mode and 64KB in CU mode. Assume the WGP mode is used.
	 */
	unsigned max_lds_size = sscreen->info.chip_class >= GFX10 ? 128*1024 : 64*1024;
	unsigned max_lds_per_simd = max_lds_size / 4;
	if (lds_per_wave)
		max_simd_waves = MIN2(max_simd_waves, max_lds_per_simd / lds_per_wave);

	shader->info.max_simd_waves = max_simd_waves;
}

void si_shader_dump_stats_for_shader_db(struct si_screen *screen,
					struct si_shader *shader,
					struct pipe_debug_callback *debug)
{
	const struct ac_shader_config *conf = &shader->config;

	if (screen->options.debug_disassembly)
		si_shader_dump_disassembly(screen, &shader->binary,
					   shader->selector->type,
					   si_get_shader_wave_size(shader),
					   debug, "main", NULL);

	pipe_debug_message(debug, SHADER_INFO,
			   "Shader Stats: SGPRS: %d VGPRS: %d Code Size: %d "
			   "LDS: %d Scratch: %d Max Waves: %d Spilled SGPRs: %d "
			   "Spilled VGPRs: %d PrivMem VGPRs: %d",
			   conf->num_sgprs, conf->num_vgprs,
			   si_get_shader_binary_size(screen, shader),
			   conf->lds_size, conf->scratch_bytes_per_wave,
			   shader->info.max_simd_waves, conf->spilled_sgprs,
			   conf->spilled_vgprs, shader->info.private_mem_vgprs);
}

static void si_shader_dump_stats(struct si_screen *sscreen,
				 struct si_shader *shader,
				 FILE *file,
				 bool check_debug_option)
{
	const struct ac_shader_config *conf = &shader->config;

	if (!check_debug_option ||
	    si_can_dump_shader(sscreen, shader->selector->type)) {
		if (shader->selector->type == PIPE_SHADER_FRAGMENT) {
			fprintf(file, "*** SHADER CONFIG ***\n"
				"SPI_PS_INPUT_ADDR = 0x%04x\n"
				"SPI_PS_INPUT_ENA  = 0x%04x\n",
				conf->spi_ps_input_addr, conf->spi_ps_input_ena);
		}

		fprintf(file, "*** SHADER STATS ***\n"
			"SGPRS: %d\n"
			"VGPRS: %d\n"
		        "Spilled SGPRs: %d\n"
			"Spilled VGPRs: %d\n"
			"Private memory VGPRs: %d\n"
			"Code Size: %d bytes\n"
			"LDS: %d blocks\n"
			"Scratch: %d bytes per wave\n"
			"Max Waves: %d\n"
			"********************\n\n\n",
			conf->num_sgprs, conf->num_vgprs,
			conf->spilled_sgprs, conf->spilled_vgprs,
			shader->info.private_mem_vgprs,
			si_get_shader_binary_size(sscreen, shader),
			conf->lds_size, conf->scratch_bytes_per_wave,
			shader->info.max_simd_waves);
	}
}

const char *si_get_shader_name(const struct si_shader *shader)
{
	switch (shader->selector->type) {
	case PIPE_SHADER_VERTEX:
		if (shader->key.as_es)
			return "Vertex Shader as ES";
		else if (shader->key.as_ls)
			return "Vertex Shader as LS";
		else if (shader->key.opt.vs_as_prim_discard_cs)
			return "Vertex Shader as Primitive Discard CS";
		else if (shader->key.as_ngg)
			return "Vertex Shader as ESGS";
		else
			return "Vertex Shader as VS";
	case PIPE_SHADER_TESS_CTRL:
		return "Tessellation Control Shader";
	case PIPE_SHADER_TESS_EVAL:
		if (shader->key.as_es)
			return "Tessellation Evaluation Shader as ES";
		else if (shader->key.as_ngg)
			return "Tessellation Evaluation Shader as ESGS";
		else
			return "Tessellation Evaluation Shader as VS";
	case PIPE_SHADER_GEOMETRY:
		if (shader->is_gs_copy_shader)
			return "GS Copy Shader as VS";
		else
			return "Geometry Shader";
	case PIPE_SHADER_FRAGMENT:
		return "Pixel Shader";
	case PIPE_SHADER_COMPUTE:
		return "Compute Shader";
	default:
		return "Unknown Shader";
	}
}

void si_shader_dump(struct si_screen *sscreen, struct si_shader *shader,
		    struct pipe_debug_callback *debug,
		    FILE *file, bool check_debug_option)
{
	enum pipe_shader_type shader_type = shader->selector->type;

	if (!check_debug_option ||
	    si_can_dump_shader(sscreen, shader_type))
		si_dump_shader_key(shader, file);

	if (!check_debug_option && shader->binary.llvm_ir_string) {
		if (shader->previous_stage &&
		    shader->previous_stage->binary.llvm_ir_string) {
			fprintf(file, "\n%s - previous stage - LLVM IR:\n\n",
				si_get_shader_name(shader));
			fprintf(file, "%s\n", shader->previous_stage->binary.llvm_ir_string);
		}

		fprintf(file, "\n%s - main shader part - LLVM IR:\n\n",
			si_get_shader_name(shader));
		fprintf(file, "%s\n", shader->binary.llvm_ir_string);
	}

	if (!check_debug_option ||
	    (si_can_dump_shader(sscreen, shader_type) &&
	     !(sscreen->debug_flags & DBG(NO_ASM)))) {
		unsigned wave_size = si_get_shader_wave_size(shader);

		fprintf(file, "\n%s:\n", si_get_shader_name(shader));

		if (shader->prolog)
			si_shader_dump_disassembly(sscreen, &shader->prolog->binary,
						   shader_type, wave_size, debug, "prolog", file);
		if (shader->previous_stage)
			si_shader_dump_disassembly(sscreen, &shader->previous_stage->binary,
						   shader_type, wave_size, debug, "previous stage", file);
		if (shader->prolog2)
			si_shader_dump_disassembly(sscreen, &shader->prolog2->binary,
						   shader_type, wave_size, debug, "prolog2", file);

		si_shader_dump_disassembly(sscreen, &shader->binary, shader_type,
					   wave_size, debug, "main", file);

		if (shader->epilog)
			si_shader_dump_disassembly(sscreen, &shader->epilog->binary,
						   shader_type, wave_size, debug, "epilog", file);
		fprintf(file, "\n");
	}

	si_shader_dump_stats(sscreen, shader, file, check_debug_option);
}

static void si_dump_shader_key_vs(const struct si_shader_key *key,
				  const struct si_vs_prolog_bits *prolog,
				  const char *prefix, FILE *f)
{
	fprintf(f, "  %s.instance_divisor_is_one = %u\n",
		prefix, prolog->instance_divisor_is_one);
	fprintf(f, "  %s.instance_divisor_is_fetched = %u\n",
		prefix, prolog->instance_divisor_is_fetched);
	fprintf(f, "  %s.unpack_instance_id_from_vertex_id = %u\n",
		prefix, prolog->unpack_instance_id_from_vertex_id);
	fprintf(f, "  %s.ls_vgpr_fix = %u\n",
		prefix, prolog->ls_vgpr_fix);

	fprintf(f, "  mono.vs.fetch_opencode = %x\n", key->mono.vs_fetch_opencode);
	fprintf(f, "  mono.vs.fix_fetch = {");
	for (int i = 0; i < SI_MAX_ATTRIBS; i++) {
		union si_vs_fix_fetch fix = key->mono.vs_fix_fetch[i];
		if (i)
			fprintf(f, ", ");
		if (!fix.bits)
			fprintf(f, "0");
		else
			fprintf(f, "%u.%u.%u.%u", fix.u.reverse, fix.u.log_size,
				fix.u.num_channels_m1, fix.u.format);
	}
	fprintf(f, "}\n");
}

static void si_dump_shader_key(const struct si_shader *shader, FILE *f)
{
	const struct si_shader_key *key = &shader->key;
	enum pipe_shader_type shader_type = shader->selector->type;

	fprintf(f, "SHADER KEY\n");

	switch (shader_type) {
	case PIPE_SHADER_VERTEX:
		si_dump_shader_key_vs(key, &key->part.vs.prolog,
				      "part.vs.prolog", f);
		fprintf(f, "  as_es = %u\n", key->as_es);
		fprintf(f, "  as_ls = %u\n", key->as_ls);
		fprintf(f, "  as_ngg = %u\n", key->as_ngg);
		fprintf(f, "  mono.u.vs_export_prim_id = %u\n",
			key->mono.u.vs_export_prim_id);
		fprintf(f, "  opt.vs_as_prim_discard_cs = %u\n",
			key->opt.vs_as_prim_discard_cs);
		fprintf(f, "  opt.cs_prim_type = %s\n",
			tgsi_primitive_names[key->opt.cs_prim_type]);
		fprintf(f, "  opt.cs_indexed = %u\n",
			key->opt.cs_indexed);
		fprintf(f, "  opt.cs_instancing = %u\n",
			key->opt.cs_instancing);
		fprintf(f, "  opt.cs_primitive_restart = %u\n",
			key->opt.cs_primitive_restart);
		fprintf(f, "  opt.cs_provoking_vertex_first = %u\n",
			key->opt.cs_provoking_vertex_first);
		fprintf(f, "  opt.cs_need_correct_orientation = %u\n",
			key->opt.cs_need_correct_orientation);
		fprintf(f, "  opt.cs_cull_front = %u\n",
			key->opt.cs_cull_front);
		fprintf(f, "  opt.cs_cull_back = %u\n",
			key->opt.cs_cull_back);
		fprintf(f, "  opt.cs_cull_z = %u\n",
			key->opt.cs_cull_z);
		fprintf(f, "  opt.cs_halfz_clip_space = %u\n",
			key->opt.cs_halfz_clip_space);
		break;

	case PIPE_SHADER_TESS_CTRL:
		if (shader->selector->screen->info.chip_class >= GFX9) {
			si_dump_shader_key_vs(key, &key->part.tcs.ls_prolog,
					      "part.tcs.ls_prolog", f);
		}
		fprintf(f, "  part.tcs.epilog.prim_mode = %u\n", key->part.tcs.epilog.prim_mode);
		fprintf(f, "  mono.u.ff_tcs_inputs_to_copy = 0x%"PRIx64"\n", key->mono.u.ff_tcs_inputs_to_copy);
		break;

	case PIPE_SHADER_TESS_EVAL:
		fprintf(f, "  as_es = %u\n", key->as_es);
		fprintf(f, "  as_ngg = %u\n", key->as_ngg);
		fprintf(f, "  mono.u.vs_export_prim_id = %u\n",
			key->mono.u.vs_export_prim_id);
		break;

	case PIPE_SHADER_GEOMETRY:
		if (shader->is_gs_copy_shader)
			break;

		if (shader->selector->screen->info.chip_class >= GFX9 &&
		    key->part.gs.es->type == PIPE_SHADER_VERTEX) {
			si_dump_shader_key_vs(key, &key->part.gs.vs_prolog,
					      "part.gs.vs_prolog", f);
		}
		fprintf(f, "  part.gs.prolog.tri_strip_adj_fix = %u\n", key->part.gs.prolog.tri_strip_adj_fix);
		fprintf(f, "  part.gs.prolog.gfx9_prev_is_vs = %u\n", key->part.gs.prolog.gfx9_prev_is_vs);
		fprintf(f, "  as_ngg = %u\n", key->as_ngg);
		break;

	case PIPE_SHADER_COMPUTE:
		break;

	case PIPE_SHADER_FRAGMENT:
		fprintf(f, "  part.ps.prolog.color_two_side = %u\n", key->part.ps.prolog.color_two_side);
		fprintf(f, "  part.ps.prolog.flatshade_colors = %u\n", key->part.ps.prolog.flatshade_colors);
		fprintf(f, "  part.ps.prolog.poly_stipple = %u\n", key->part.ps.prolog.poly_stipple);
		fprintf(f, "  part.ps.prolog.force_persp_sample_interp = %u\n", key->part.ps.prolog.force_persp_sample_interp);
		fprintf(f, "  part.ps.prolog.force_linear_sample_interp = %u\n", key->part.ps.prolog.force_linear_sample_interp);
		fprintf(f, "  part.ps.prolog.force_persp_center_interp = %u\n", key->part.ps.prolog.force_persp_center_interp);
		fprintf(f, "  part.ps.prolog.force_linear_center_interp = %u\n", key->part.ps.prolog.force_linear_center_interp);
		fprintf(f, "  part.ps.prolog.bc_optimize_for_persp = %u\n", key->part.ps.prolog.bc_optimize_for_persp);
		fprintf(f, "  part.ps.prolog.bc_optimize_for_linear = %u\n", key->part.ps.prolog.bc_optimize_for_linear);
		fprintf(f, "  part.ps.prolog.samplemask_log_ps_iter = %u\n", key->part.ps.prolog.samplemask_log_ps_iter);
		fprintf(f, "  part.ps.epilog.spi_shader_col_format = 0x%x\n", key->part.ps.epilog.spi_shader_col_format);
		fprintf(f, "  part.ps.epilog.color_is_int8 = 0x%X\n", key->part.ps.epilog.color_is_int8);
		fprintf(f, "  part.ps.epilog.color_is_int10 = 0x%X\n", key->part.ps.epilog.color_is_int10);
		fprintf(f, "  part.ps.epilog.last_cbuf = %u\n", key->part.ps.epilog.last_cbuf);
		fprintf(f, "  part.ps.epilog.alpha_func = %u\n", key->part.ps.epilog.alpha_func);
		fprintf(f, "  part.ps.epilog.alpha_to_one = %u\n", key->part.ps.epilog.alpha_to_one);
		fprintf(f, "  part.ps.epilog.poly_line_smoothing = %u\n", key->part.ps.epilog.poly_line_smoothing);
		fprintf(f, "  part.ps.epilog.clamp_color = %u\n", key->part.ps.epilog.clamp_color);
		fprintf(f, "  mono.u.ps.interpolate_at_sample_force_center = %u\n", key->mono.u.ps.interpolate_at_sample_force_center);
		fprintf(f, "  mono.u.ps.fbfetch_msaa = %u\n", key->mono.u.ps.fbfetch_msaa);
		fprintf(f, "  mono.u.ps.fbfetch_is_1D = %u\n", key->mono.u.ps.fbfetch_is_1D);
		fprintf(f, "  mono.u.ps.fbfetch_layered = %u\n", key->mono.u.ps.fbfetch_layered);
		break;

	default:
		assert(0);
	}

	if ((shader_type == PIPE_SHADER_GEOMETRY ||
	     shader_type == PIPE_SHADER_TESS_EVAL ||
	     shader_type == PIPE_SHADER_VERTEX) &&
	    !key->as_es && !key->as_ls) {
		fprintf(f, "  opt.kill_outputs = 0x%"PRIx64"\n", key->opt.kill_outputs);
		fprintf(f, "  opt.clip_disable = %u\n", key->opt.clip_disable);
		if (shader_type != PIPE_SHADER_GEOMETRY)
			fprintf(f, "  opt.ngg_culling = 0x%x\n", key->opt.ngg_culling);
	}
}

static void si_optimize_vs_outputs(struct si_shader_context *ctx)
{
	struct si_shader *shader = ctx->shader;
	struct si_shader_info *info = &shader->selector->info;

	if ((ctx->type != PIPE_SHADER_VERTEX &&
	     ctx->type != PIPE_SHADER_TESS_EVAL) ||
	    shader->key.as_ls ||
	    shader->key.as_es)
		return;

	ac_optimize_vs_outputs(&ctx->ac,
			       ctx->main_fn,
			       shader->info.vs_output_param_offset,
			       info->num_outputs,
			       &shader->info.nr_param_exports);
}

static void si_init_exec_from_input(struct si_shader_context *ctx,
				    struct ac_arg param, unsigned bitoffset)
{
	LLVMValueRef args[] = {
		ac_get_arg(&ctx->ac, param),
		LLVMConstInt(ctx->i32, bitoffset, 0),
	};
	ac_build_intrinsic(&ctx->ac,
			   "llvm.amdgcn.init.exec.from.input",
			   ctx->voidt, args, 2, AC_FUNC_ATTR_CONVERGENT);
}

static bool si_vs_needs_prolog(const struct si_shader_selector *sel,
			       const struct si_vs_prolog_bits *key)
{
	/* VGPR initialization fixup for Vega10 and Raven is always done in the
	 * VS prolog. */
	return sel->vs_needs_prolog ||
	       key->ls_vgpr_fix ||
	       key->unpack_instance_id_from_vertex_id;
}

static bool si_build_main_function(struct si_shader_context *ctx,
				   struct nir_shader *nir, bool free_nir,
				   bool ngg_cull_shader)
{
	struct si_shader *shader = ctx->shader;
	struct si_shader_selector *sel = shader->selector;

	si_llvm_init_resource_callbacks(ctx);

	switch (ctx->type) {
	case PIPE_SHADER_VERTEX:
		if (shader->key.as_ls)
			ctx->abi.emit_outputs = si_llvm_emit_ls_epilogue;
		else if (shader->key.as_es)
			ctx->abi.emit_outputs = si_llvm_emit_es_epilogue;
		else if (shader->key.opt.vs_as_prim_discard_cs)
			ctx->abi.emit_outputs = si_llvm_emit_prim_discard_cs_epilogue;
		else if (ngg_cull_shader)
			ctx->abi.emit_outputs = gfx10_emit_ngg_culling_epilogue_4x_wave32;
		else if (shader->key.as_ngg)
			ctx->abi.emit_outputs = gfx10_emit_ngg_epilogue;
		else
			ctx->abi.emit_outputs = si_llvm_emit_vs_epilogue;
		ctx->abi.load_base_vertex = get_base_vertex;
		break;
	case PIPE_SHADER_TESS_CTRL:
		si_llvm_init_tcs_callbacks(ctx);
		break;
	case PIPE_SHADER_TESS_EVAL:
		si_llvm_init_tes_callbacks(ctx);

		if (shader->key.as_es)
			ctx->abi.emit_outputs = si_llvm_emit_es_epilogue;
		else if (ngg_cull_shader)
			ctx->abi.emit_outputs = gfx10_emit_ngg_culling_epilogue_4x_wave32;
		else if (shader->key.as_ngg)
			ctx->abi.emit_outputs = gfx10_emit_ngg_epilogue;
		else
			ctx->abi.emit_outputs = si_llvm_emit_vs_epilogue;
		break;
	case PIPE_SHADER_GEOMETRY:
		si_llvm_init_gs_callbacks(ctx);
		break;
	case PIPE_SHADER_FRAGMENT:
		si_llvm_init_ps_callbacks(ctx);
		break;
	case PIPE_SHADER_COMPUTE:
		ctx->abi.load_local_group_size = get_block_size;
		break;
	default:
		assert(!"Unsupported shader type");
		return false;
	}

	si_create_function(ctx, ngg_cull_shader);

	if (ctx->shader->key.as_es || ctx->type == PIPE_SHADER_GEOMETRY)
		si_preload_esgs_ring(ctx);

	if (ctx->type == PIPE_SHADER_GEOMETRY)
		si_preload_gs_rings(ctx);
	else if (ctx->type == PIPE_SHADER_TESS_EVAL)
		si_llvm_preload_tes_rings(ctx);

	if (ctx->type == PIPE_SHADER_TESS_CTRL &&
	    sel->info.tessfactors_are_def_in_all_invocs) {
		for (unsigned i = 0; i < 6; i++) {
			ctx->invoc0_tess_factors[i] =
				ac_build_alloca_undef(&ctx->ac, ctx->i32, "");
		}
	}

	if (ctx->type == PIPE_SHADER_GEOMETRY) {
		for (unsigned i = 0; i < 4; i++) {
			ctx->gs_next_vertex[i] =
				ac_build_alloca(&ctx->ac, ctx->i32, "");
		}
		if (shader->key.as_ngg) {
			for (unsigned i = 0; i < 4; ++i) {
				ctx->gs_curprim_verts[i] =
					ac_build_alloca(&ctx->ac, ctx->ac.i32, "");
				ctx->gs_generated_prims[i] =
					ac_build_alloca(&ctx->ac, ctx->ac.i32, "");
			}

			unsigned scratch_size = 8;
			if (sel->so.num_outputs)
				scratch_size = 44;

			assert(!ctx->gs_ngg_scratch);
			LLVMTypeRef ai32 = LLVMArrayType(ctx->i32, scratch_size);
			ctx->gs_ngg_scratch = LLVMAddGlobalInAddressSpace(ctx->ac.module,
				ai32, "ngg_scratch", AC_ADDR_SPACE_LDS);
			LLVMSetInitializer(ctx->gs_ngg_scratch, LLVMGetUndef(ai32));
			LLVMSetAlignment(ctx->gs_ngg_scratch, 4);

			ctx->gs_ngg_emit = LLVMAddGlobalInAddressSpace(ctx->ac.module,
				LLVMArrayType(ctx->i32, 0), "ngg_emit", AC_ADDR_SPACE_LDS);
			LLVMSetLinkage(ctx->gs_ngg_emit, LLVMExternalLinkage);
			LLVMSetAlignment(ctx->gs_ngg_emit, 4);
		}
	}

	if (ctx->type != PIPE_SHADER_GEOMETRY &&
	    (shader->key.as_ngg && !shader->key.as_es)) {
		/* Unconditionally declare scratch space base for streamout and
		 * vertex compaction. Whether space is actually allocated is
		 * determined during linking / PM4 creation.
		 *
		 * Add an extra dword per vertex to ensure an odd stride, which
		 * avoids bank conflicts for SoA accesses.
		 */
		if (!gfx10_is_ngg_passthrough(shader))
			si_llvm_declare_esgs_ring(ctx);

		/* This is really only needed when streamout and / or vertex
		 * compaction is enabled.
		 */
		if (!ctx->gs_ngg_scratch &&
		    (sel->so.num_outputs || shader->key.opt.ngg_culling)) {
			LLVMTypeRef asi32 = LLVMArrayType(ctx->i32, 8);
			ctx->gs_ngg_scratch = LLVMAddGlobalInAddressSpace(ctx->ac.module,
				asi32, "ngg_scratch", AC_ADDR_SPACE_LDS);
			LLVMSetInitializer(ctx->gs_ngg_scratch, LLVMGetUndef(asi32));
			LLVMSetAlignment(ctx->gs_ngg_scratch, 4);
		}
	}

	/* For GFX9 merged shaders:
	 * - Set EXEC for the first shader. If the prolog is present, set
	 *   EXEC there instead.
	 * - Add a barrier before the second shader.
	 * - In the second shader, reset EXEC to ~0 and wrap the main part in
	 *   an if-statement. This is required for correctness in geometry
	 *   shaders, to ensure that empty GS waves do not send GS_EMIT and
	 *   GS_CUT messages.
	 *
	 * For monolithic merged shaders, the first shader is wrapped in an
	 * if-block together with its prolog in si_build_wrapper_function.
	 *
	 * NGG vertex and tess eval shaders running as the last
	 * vertex/geometry stage handle execution explicitly using
	 * if-statements.
	 */
	if (ctx->screen->info.chip_class >= GFX9) {
		if (!shader->is_monolithic &&
		    (shader->key.as_es || shader->key.as_ls) &&
		    (ctx->type == PIPE_SHADER_TESS_EVAL ||
		     (ctx->type == PIPE_SHADER_VERTEX &&
		      !si_vs_needs_prolog(sel, &shader->key.part.vs.prolog)))) {
			si_init_exec_from_input(ctx,
						ctx->merged_wave_info, 0);
		} else if (ctx->type == PIPE_SHADER_TESS_CTRL ||
			   ctx->type == PIPE_SHADER_GEOMETRY ||
			   (shader->key.as_ngg && !shader->key.as_es)) {
			LLVMValueRef thread_enabled;
			bool nested_barrier;

			if (!shader->is_monolithic ||
			    (ctx->type == PIPE_SHADER_TESS_EVAL &&
			     shader->key.as_ngg && !shader->key.as_es &&
			     !shader->key.opt.ngg_culling))
				ac_init_exec_full_mask(&ctx->ac);

			if ((ctx->type == PIPE_SHADER_VERTEX ||
			     ctx->type == PIPE_SHADER_TESS_EVAL) &&
			    shader->key.as_ngg && !shader->key.as_es &&
			    !shader->key.opt.ngg_culling) {
				gfx10_ngg_build_sendmsg_gs_alloc_req(ctx);

				/* Build the primitive export at the beginning
				 * of the shader if possible.
				 */
				if (gfx10_ngg_export_prim_early(shader))
					gfx10_ngg_build_export_prim(ctx, NULL, NULL);
			}

			if (ctx->type == PIPE_SHADER_TESS_CTRL ||
			    ctx->type == PIPE_SHADER_GEOMETRY) {
				if (ctx->type == PIPE_SHADER_GEOMETRY && shader->key.as_ngg) {
					gfx10_ngg_gs_emit_prologue(ctx);
					nested_barrier = false;
				} else {
					nested_barrier = true;
				}

				thread_enabled = si_is_gs_thread(ctx);
			} else {
				thread_enabled = si_is_es_thread(ctx);
				nested_barrier = false;
			}

			ctx->merged_wrap_if_entry_block = LLVMGetInsertBlock(ctx->ac.builder);
			ctx->merged_wrap_if_label = 11500;
			ac_build_ifcc(&ctx->ac, thread_enabled, ctx->merged_wrap_if_label);

			if (nested_barrier) {
				/* Execute a barrier before the second shader in
				 * a merged shader.
				 *
				 * Execute the barrier inside the conditional block,
				 * so that empty waves can jump directly to s_endpgm,
				 * which will also signal the barrier.
				 *
				 * This is possible in gfx9, because an empty wave
				 * for the second shader does not participate in
				 * the epilogue. With NGG, empty waves may still
				 * be required to export data (e.g. GS output vertices),
				 * so we cannot let them exit early.
				 *
				 * If the shader is TCS and the TCS epilog is present
				 * and contains a barrier, it will wait there and then
				 * reach s_endpgm.
				 */
				si_llvm_emit_barrier(ctx);
			}
		}
	}

	if (sel->force_correct_derivs_after_kill) {
		ctx->postponed_kill = ac_build_alloca_undef(&ctx->ac, ctx->i1, "");
		/* true = don't kill. */
		LLVMBuildStore(ctx->ac.builder, ctx->i1true,
			       ctx->postponed_kill);
	}

	bool success = si_nir_build_llvm(ctx, nir);
	if (free_nir)
		ralloc_free(nir);
	if (!success) {
		fprintf(stderr, "Failed to translate shader from NIR to LLVM\n");
		return false;
	}

	si_llvm_build_ret(ctx, ctx->return_value);
	return true;
}

/**
 * Compute the VS prolog key, which contains all the information needed to
 * build the VS prolog function, and set shader->info bits where needed.
 *
 * \param info             Shader info of the vertex shader.
 * \param num_input_sgprs  Number of input SGPRs for the vertex shader.
 * \param has_old_  Whether the preceding shader part is the NGG cull shader.
 * \param prolog_key       Key of the VS prolog
 * \param shader_out       The vertex shader, or the next shader if merging LS+HS or ES+GS.
 * \param key              Output shader part key.
 */
static void si_get_vs_prolog_key(const struct si_shader_info *info,
				 unsigned num_input_sgprs,
				 bool ngg_cull_shader,
				 const struct si_vs_prolog_bits *prolog_key,
				 struct si_shader *shader_out,
				 union si_shader_part_key *key)
{
	memset(key, 0, sizeof(*key));
	key->vs_prolog.states = *prolog_key;
	key->vs_prolog.num_input_sgprs = num_input_sgprs;
	key->vs_prolog.num_inputs = info->num_inputs;
	key->vs_prolog.as_ls = shader_out->key.as_ls;
	key->vs_prolog.as_es = shader_out->key.as_es;
	key->vs_prolog.as_ngg = shader_out->key.as_ngg;

	if (!ngg_cull_shader)
		key->vs_prolog.has_ngg_cull_inputs = !!shader_out->key.opt.ngg_culling;

	if (shader_out->selector->type == PIPE_SHADER_TESS_CTRL) {
		key->vs_prolog.as_ls = 1;
		key->vs_prolog.num_merged_next_stage_vgprs = 2;
	} else if (shader_out->selector->type == PIPE_SHADER_GEOMETRY) {
		key->vs_prolog.as_es = 1;
		key->vs_prolog.num_merged_next_stage_vgprs = 5;
	} else if (shader_out->key.as_ngg) {
		key->vs_prolog.num_merged_next_stage_vgprs = 5;
	}

	/* Enable loading the InstanceID VGPR. */
	uint16_t input_mask = u_bit_consecutive(0, info->num_inputs);

	if ((key->vs_prolog.states.instance_divisor_is_one |
	     key->vs_prolog.states.instance_divisor_is_fetched) & input_mask)
		shader_out->info.uses_instanceid = true;
}

/**
 * Given a list of shader part functions, build a wrapper function that
 * runs them in sequence to form a monolithic shader.
 */
void si_build_wrapper_function(struct si_shader_context *ctx, LLVMValueRef *parts,
			       unsigned num_parts, unsigned main_part,
			       unsigned next_shader_first_part)
{
	LLVMBuilderRef builder = ctx->ac.builder;
	/* PS epilog has one arg per color component; gfx9 merged shader
	 * prologs need to forward 40 SGPRs.
	 */
	LLVMValueRef initial[AC_MAX_ARGS], out[AC_MAX_ARGS];
	LLVMTypeRef function_type;
	unsigned num_first_params;
	unsigned num_out, initial_num_out;
	ASSERTED unsigned num_out_sgpr; /* used in debug checks */
	ASSERTED unsigned initial_num_out_sgpr; /* used in debug checks */
	unsigned num_sgprs, num_vgprs;
	unsigned gprs;

	memset(&ctx->args, 0, sizeof(ctx->args));

	for (unsigned i = 0; i < num_parts; ++i) {
		ac_add_function_attr(ctx->ac.context, parts[i], -1,
				     AC_FUNC_ATTR_ALWAYSINLINE);
		LLVMSetLinkage(parts[i], LLVMPrivateLinkage);
	}

	/* The parameters of the wrapper function correspond to those of the
	 * first part in terms of SGPRs and VGPRs, but we use the types of the
	 * main part to get the right types. This is relevant for the
	 * dereferenceable attribute on descriptor table pointers.
	 */
	num_sgprs = 0;
	num_vgprs = 0;

	function_type = LLVMGetElementType(LLVMTypeOf(parts[0]));
	num_first_params = LLVMCountParamTypes(function_type);

	for (unsigned i = 0; i < num_first_params; ++i) {
		LLVMValueRef param = LLVMGetParam(parts[0], i);

		if (ac_is_sgpr_param(param)) {
			assert(num_vgprs == 0);
			num_sgprs += ac_get_type_size(LLVMTypeOf(param)) / 4;
		} else {
			num_vgprs += ac_get_type_size(LLVMTypeOf(param)) / 4;
		}
	}

	gprs = 0;
	while (gprs < num_sgprs + num_vgprs) {
		LLVMValueRef param = LLVMGetParam(parts[main_part], ctx->args.arg_count);
		LLVMTypeRef type = LLVMTypeOf(param);
		unsigned size = ac_get_type_size(type) / 4;

		/* This is going to get casted anyways, so we don't have to
		 * have the exact same type. But we do have to preserve the
		 * pointer-ness so that LLVM knows about it.
		 */
		enum ac_arg_type arg_type = AC_ARG_INT;
		if (LLVMGetTypeKind(type) == LLVMPointerTypeKind) {
			type = LLVMGetElementType(type);

			if (LLVMGetTypeKind(type) == LLVMVectorTypeKind) {
				if (LLVMGetVectorSize(type) == 4)
					arg_type = AC_ARG_CONST_DESC_PTR;
				else if (LLVMGetVectorSize(type) == 8)
					arg_type = AC_ARG_CONST_IMAGE_PTR;
				else
					assert(0);
			} else if (type == ctx->f32) {
				arg_type = AC_ARG_CONST_FLOAT_PTR;
			} else {
				assert(0);
			}
		}

		ac_add_arg(&ctx->args, gprs < num_sgprs ? AC_ARG_SGPR : AC_ARG_VGPR,
			   size, arg_type, NULL);

		assert(ac_is_sgpr_param(param) == (gprs < num_sgprs));
		assert(gprs + size <= num_sgprs + num_vgprs &&
		       (gprs >= num_sgprs || gprs + size <= num_sgprs));

		gprs += size;
	}

	/* Prepare the return type. */
	unsigned num_returns = 0;
	LLVMTypeRef returns[AC_MAX_ARGS], last_func_type, return_type;

	last_func_type = LLVMGetElementType(LLVMTypeOf(parts[num_parts - 1]));
	return_type = LLVMGetReturnType(last_func_type);

	switch (LLVMGetTypeKind(return_type)) {
	case LLVMStructTypeKind:
		num_returns = LLVMCountStructElementTypes(return_type);
		assert(num_returns <= ARRAY_SIZE(returns));
		LLVMGetStructElementTypes(return_type, returns);
		break;
	case LLVMVoidTypeKind:
		break;
	default:
		unreachable("unexpected type");
	}

	si_llvm_create_func(ctx, "wrapper", returns, num_returns,
			    si_get_max_workgroup_size(ctx->shader));

	if (si_is_merged_shader(ctx))
		ac_init_exec_full_mask(&ctx->ac);

	/* Record the arguments of the function as if they were an output of
	 * a previous part.
	 */
	num_out = 0;
	num_out_sgpr = 0;

	for (unsigned i = 0; i < ctx->args.arg_count; ++i) {
		LLVMValueRef param = LLVMGetParam(ctx->main_fn, i);
		LLVMTypeRef param_type = LLVMTypeOf(param);
		LLVMTypeRef out_type = ctx->args.args[i].file == AC_ARG_SGPR ? ctx->i32 : ctx->f32;
		unsigned size = ac_get_type_size(param_type) / 4;

		if (size == 1) {
			if (LLVMGetTypeKind(param_type) == LLVMPointerTypeKind) {
				param = LLVMBuildPtrToInt(builder, param, ctx->i32, "");
				param_type = ctx->i32;
			}

			if (param_type != out_type)
				param = LLVMBuildBitCast(builder, param, out_type, "");
			out[num_out++] = param;
		} else {
			LLVMTypeRef vector_type = LLVMVectorType(out_type, size);

			if (LLVMGetTypeKind(param_type) == LLVMPointerTypeKind) {
				param = LLVMBuildPtrToInt(builder, param, ctx->i64, "");
				param_type = ctx->i64;
			}

			if (param_type != vector_type)
				param = LLVMBuildBitCast(builder, param, vector_type, "");

			for (unsigned j = 0; j < size; ++j)
				out[num_out++] = LLVMBuildExtractElement(
					builder, param, LLVMConstInt(ctx->i32, j, 0), "");
		}

		if (ctx->args.args[i].file == AC_ARG_SGPR)
			num_out_sgpr = num_out;
	}

	memcpy(initial, out, sizeof(out));
	initial_num_out = num_out;
	initial_num_out_sgpr = num_out_sgpr;

	/* Now chain the parts. */
	LLVMValueRef ret = NULL;
	for (unsigned part = 0; part < num_parts; ++part) {
		LLVMValueRef in[AC_MAX_ARGS];
		LLVMTypeRef ret_type;
		unsigned out_idx = 0;
		unsigned num_params = LLVMCountParams(parts[part]);

		/* Merged shaders are executed conditionally depending
		 * on the number of enabled threads passed in the input SGPRs. */
		if (is_multi_part_shader(ctx) && part == 0) {
			LLVMValueRef ena, count = initial[3];

			count = LLVMBuildAnd(builder, count,
					     LLVMConstInt(ctx->i32, 0x7f, 0), "");
			ena = LLVMBuildICmp(builder, LLVMIntULT,
					    ac_get_thread_id(&ctx->ac), count, "");
			ac_build_ifcc(&ctx->ac, ena, 6506);
		}

		/* Derive arguments for the next part from outputs of the
		 * previous one.
		 */
		for (unsigned param_idx = 0; param_idx < num_params; ++param_idx) {
			LLVMValueRef param;
			LLVMTypeRef param_type;
			bool is_sgpr;
			unsigned param_size;
			LLVMValueRef arg = NULL;

			param = LLVMGetParam(parts[part], param_idx);
			param_type = LLVMTypeOf(param);
			param_size = ac_get_type_size(param_type) / 4;
			is_sgpr = ac_is_sgpr_param(param);

			if (is_sgpr) {
				ac_add_function_attr(ctx->ac.context, parts[part],
						     param_idx + 1, AC_FUNC_ATTR_INREG);
			} else if (out_idx < num_out_sgpr) {
				/* Skip returned SGPRs the current part doesn't
				 * declare on the input. */
				out_idx = num_out_sgpr;
			}

			assert(out_idx + param_size <= (is_sgpr ? num_out_sgpr : num_out));

			if (param_size == 1)
				arg = out[out_idx];
			else
				arg = ac_build_gather_values(&ctx->ac, &out[out_idx], param_size);

			if (LLVMTypeOf(arg) != param_type) {
				if (LLVMGetTypeKind(param_type) == LLVMPointerTypeKind) {
					if (LLVMGetPointerAddressSpace(param_type) ==
					    AC_ADDR_SPACE_CONST_32BIT) {
						arg = LLVMBuildBitCast(builder, arg, ctx->i32, "");
						arg = LLVMBuildIntToPtr(builder, arg, param_type, "");
					} else {
						arg = LLVMBuildBitCast(builder, arg, ctx->i64, "");
						arg = LLVMBuildIntToPtr(builder, arg, param_type, "");
					}
				} else {
					arg = LLVMBuildBitCast(builder, arg, param_type, "");
				}
			}

			in[param_idx] = arg;
			out_idx += param_size;
		}

		ret = ac_build_call(&ctx->ac, parts[part], in, num_params);

		if (is_multi_part_shader(ctx) &&
		    part + 1 == next_shader_first_part) {
			ac_build_endif(&ctx->ac, 6506);

			/* The second half of the merged shader should use
			 * the inputs from the toplevel (wrapper) function,
			 * not the return value from the last call.
			 *
			 * That's because the last call was executed condi-
			 * tionally, so we can't consume it in the main
			 * block.
			 */
			memcpy(out, initial, sizeof(initial));
			num_out = initial_num_out;
			num_out_sgpr = initial_num_out_sgpr;
			continue;
		}

		/* Extract the returned GPRs. */
		ret_type = LLVMTypeOf(ret);
		num_out = 0;
		num_out_sgpr = 0;

		if (LLVMGetTypeKind(ret_type) != LLVMVoidTypeKind) {
			assert(LLVMGetTypeKind(ret_type) == LLVMStructTypeKind);

			unsigned ret_size = LLVMCountStructElementTypes(ret_type);

			for (unsigned i = 0; i < ret_size; ++i) {
				LLVMValueRef val =
					LLVMBuildExtractValue(builder, ret, i, "");

				assert(num_out < ARRAY_SIZE(out));
				out[num_out++] = val;

				if (LLVMTypeOf(val) == ctx->i32) {
					assert(num_out_sgpr + 1 == num_out);
					num_out_sgpr = num_out;
				}
			}
		}
	}

	/* Return the value from the last part. */
	if (LLVMGetTypeKind(LLVMTypeOf(ret)) == LLVMVoidTypeKind)
		LLVMBuildRetVoid(builder);
	else
		LLVMBuildRet(builder, ret);
}

static bool si_should_optimize_less(struct ac_llvm_compiler *compiler,
				    struct si_shader_selector *sel)
{
	if (!compiler->low_opt_passes)
		return false;

	/* Assume a slow CPU. */
	assert(!sel->screen->info.has_dedicated_vram &&
	       sel->screen->info.chip_class <= GFX8);

	/* For a crazy dEQP test containing 2597 memory opcodes, mostly
	 * buffer stores. */
	return sel->type == PIPE_SHADER_COMPUTE &&
	       sel->info.num_memory_instructions > 1000;
}

static struct nir_shader *get_nir_shader(struct si_shader_selector *sel,
					 bool *free_nir)
{
	*free_nir = false;

	if (sel->nir) {
		return sel->nir;
	} else if (sel->nir_binary) {
		struct pipe_screen *screen = &sel->screen->b;
		const void *options =
			screen->get_compiler_options(screen, PIPE_SHADER_IR_NIR,
						     sel->type);

		struct blob_reader blob_reader;
		blob_reader_init(&blob_reader, sel->nir_binary, sel->nir_size);
		*free_nir = true;
		return nir_deserialize(NULL, options, &blob_reader);
	}
	return NULL;
}

int si_compile_shader(struct si_screen *sscreen,
		      struct ac_llvm_compiler *compiler,
		      struct si_shader *shader,
		      struct pipe_debug_callback *debug)
{
	struct si_shader_selector *sel = shader->selector;
	struct si_shader_context ctx;
	bool free_nir;
	struct nir_shader *nir = get_nir_shader(sel, &free_nir);
	int r = -1;

	/* Dump NIR before doing NIR->LLVM conversion in case the
	 * conversion fails. */
	if (si_can_dump_shader(sscreen, sel->type) &&
	    !(sscreen->debug_flags & DBG(NO_NIR))) {
		nir_print_shader(nir, stderr);
		si_dump_streamout(&sel->so);
	}

	si_llvm_context_init(&ctx, sscreen, compiler, si_get_shader_wave_size(shader));
	si_llvm_context_set_ir(&ctx, shader);

	memset(shader->info.vs_output_param_offset, AC_EXP_PARAM_UNDEFINED,
	       sizeof(shader->info.vs_output_param_offset));

	shader->info.uses_instanceid = sel->info.uses_instanceid;

	LLVMValueRef ngg_cull_main_fn = NULL;
	if (ctx.shader->key.opt.ngg_culling) {
		if (!si_build_main_function(&ctx, nir, false, true)) {
			si_llvm_dispose(&ctx);
			return -1;
		}
		ngg_cull_main_fn = ctx.main_fn;
		ctx.main_fn = NULL;
		/* Re-set the IR. */
		si_llvm_context_set_ir(&ctx, shader);
	}

	if (!si_build_main_function(&ctx, nir, free_nir, false)) {
		si_llvm_dispose(&ctx);
		return -1;
	}

	if (shader->is_monolithic && ctx.type == PIPE_SHADER_VERTEX) {
		LLVMValueRef parts[4];
		unsigned num_parts = 0;
		bool need_prolog = si_vs_needs_prolog(sel, &shader->key.part.vs.prolog);
		LLVMValueRef main_fn = ctx.main_fn;

		if (ngg_cull_main_fn) {
			if (need_prolog) {
				union si_shader_part_key prolog_key;
				si_get_vs_prolog_key(&sel->info,
						     shader->info.num_input_sgprs,
						     true,
						     &shader->key.part.vs.prolog,
						     shader, &prolog_key);
				prolog_key.vs_prolog.is_monolithic = true;
				si_build_vs_prolog_function(&ctx, &prolog_key);
				parts[num_parts++] = ctx.main_fn;
			}
			parts[num_parts++] = ngg_cull_main_fn;
		}

		if (need_prolog) {
			union si_shader_part_key prolog_key;
			si_get_vs_prolog_key(&sel->info,
					     shader->info.num_input_sgprs,
					     false,
					     &shader->key.part.vs.prolog,
					     shader, &prolog_key);
			prolog_key.vs_prolog.is_monolithic = true;
			si_build_vs_prolog_function(&ctx, &prolog_key);
			parts[num_parts++] = ctx.main_fn;
		}
		parts[num_parts++] = main_fn;

		si_build_wrapper_function(&ctx, parts, num_parts,
					  need_prolog ? 1 : 0, 0);

		if (ctx.shader->key.opt.vs_as_prim_discard_cs)
			si_build_prim_discard_compute_shader(&ctx);
	} else if (shader->is_monolithic && ctx.type == PIPE_SHADER_TESS_EVAL &&
		   ngg_cull_main_fn) {
		LLVMValueRef parts[2];

		parts[0] = ngg_cull_main_fn;
		parts[1] = ctx.main_fn;

		si_build_wrapper_function(&ctx, parts, 2, 0, 0);
	} else if (shader->is_monolithic && ctx.type == PIPE_SHADER_TESS_CTRL) {
		if (sscreen->info.chip_class >= GFX9) {
			struct si_shader_selector *ls = shader->key.part.tcs.ls;
			LLVMValueRef parts[4];
			bool vs_needs_prolog =
				si_vs_needs_prolog(ls, &shader->key.part.tcs.ls_prolog);

			/* TCS main part */
			parts[2] = ctx.main_fn;

			/* TCS epilog */
			union si_shader_part_key tcs_epilog_key;
			memset(&tcs_epilog_key, 0, sizeof(tcs_epilog_key));
			tcs_epilog_key.tcs_epilog.states = shader->key.part.tcs.epilog;
			si_llvm_build_tcs_epilog(&ctx, &tcs_epilog_key);
			parts[3] = ctx.main_fn;

			/* VS as LS main part */
			nir = get_nir_shader(ls, &free_nir);
			struct si_shader shader_ls = {};
			shader_ls.selector = ls;
			shader_ls.key.as_ls = 1;
			shader_ls.key.mono = shader->key.mono;
			shader_ls.key.opt = shader->key.opt;
			shader_ls.is_monolithic = true;
			si_llvm_context_set_ir(&ctx, &shader_ls);

			if (!si_build_main_function(&ctx, nir, free_nir, false)) {
				si_llvm_dispose(&ctx);
				return -1;
			}
			shader->info.uses_instanceid |= ls->info.uses_instanceid;
			parts[1] = ctx.main_fn;

			/* LS prolog */
			if (vs_needs_prolog) {
				union si_shader_part_key vs_prolog_key;
				si_get_vs_prolog_key(&ls->info,
						     shader_ls.info.num_input_sgprs,
						     false,
						     &shader->key.part.tcs.ls_prolog,
						     shader, &vs_prolog_key);
				vs_prolog_key.vs_prolog.is_monolithic = true;
				si_build_vs_prolog_function(&ctx, &vs_prolog_key);
				parts[0] = ctx.main_fn;
			}

			/* Reset the shader context. */
			ctx.shader = shader;
			ctx.type = PIPE_SHADER_TESS_CTRL;

			si_build_wrapper_function(&ctx,
						  parts + !vs_needs_prolog,
						  4 - !vs_needs_prolog, vs_needs_prolog,
						  vs_needs_prolog ? 2 : 1);
		} else {
			LLVMValueRef parts[2];
			union si_shader_part_key epilog_key;

			parts[0] = ctx.main_fn;

			memset(&epilog_key, 0, sizeof(epilog_key));
			epilog_key.tcs_epilog.states = shader->key.part.tcs.epilog;
			si_llvm_build_tcs_epilog(&ctx, &epilog_key);
			parts[1] = ctx.main_fn;

			si_build_wrapper_function(&ctx, parts, 2, 0, 0);
		}
	} else if (shader->is_monolithic && ctx.type == PIPE_SHADER_GEOMETRY) {
		if (ctx.screen->info.chip_class >= GFX9) {
			struct si_shader_selector *es = shader->key.part.gs.es;
			LLVMValueRef es_prolog = NULL;
			LLVMValueRef es_main = NULL;
			LLVMValueRef gs_prolog = NULL;
			LLVMValueRef gs_main = ctx.main_fn;

			/* GS prolog */
			union si_shader_part_key gs_prolog_key;
			memset(&gs_prolog_key, 0, sizeof(gs_prolog_key));
			gs_prolog_key.gs_prolog.states = shader->key.part.gs.prolog;
			gs_prolog_key.gs_prolog.is_monolithic = true;
			gs_prolog_key.gs_prolog.as_ngg = shader->key.as_ngg;
			si_llvm_build_gs_prolog(&ctx, &gs_prolog_key);
			gs_prolog = ctx.main_fn;

			/* ES main part */
			nir = get_nir_shader(es, &free_nir);
			struct si_shader shader_es = {};
			shader_es.selector = es;
			shader_es.key.as_es = 1;
			shader_es.key.as_ngg = shader->key.as_ngg;
			shader_es.key.mono = shader->key.mono;
			shader_es.key.opt = shader->key.opt;
			shader_es.is_monolithic = true;
			si_llvm_context_set_ir(&ctx, &shader_es);

			if (!si_build_main_function(&ctx, nir, free_nir, false)) {
				si_llvm_dispose(&ctx);
				return -1;
			}
			shader->info.uses_instanceid |= es->info.uses_instanceid;
			es_main = ctx.main_fn;

			/* ES prolog */
			if (es->type == PIPE_SHADER_VERTEX &&
			    si_vs_needs_prolog(es, &shader->key.part.gs.vs_prolog)) {
				union si_shader_part_key vs_prolog_key;
				si_get_vs_prolog_key(&es->info,
						     shader_es.info.num_input_sgprs,
						     false,
						     &shader->key.part.gs.vs_prolog,
						     shader, &vs_prolog_key);
				vs_prolog_key.vs_prolog.is_monolithic = true;
				si_build_vs_prolog_function(&ctx, &vs_prolog_key);
				es_prolog = ctx.main_fn;
			}

			/* Reset the shader context. */
			ctx.shader = shader;
			ctx.type = PIPE_SHADER_GEOMETRY;

			/* Prepare the array of shader parts. */
			LLVMValueRef parts[4];
			unsigned num_parts = 0, main_part, next_first_part;

			if (es_prolog)
				parts[num_parts++] = es_prolog;

			parts[main_part = num_parts++] = es_main;
			parts[next_first_part = num_parts++] = gs_prolog;
			parts[num_parts++] = gs_main;

			si_build_wrapper_function(&ctx, parts, num_parts,
						  main_part, next_first_part);
		} else {
			LLVMValueRef parts[2];
			union si_shader_part_key prolog_key;

			parts[1] = ctx.main_fn;

			memset(&prolog_key, 0, sizeof(prolog_key));
			prolog_key.gs_prolog.states = shader->key.part.gs.prolog;
			si_llvm_build_gs_prolog(&ctx, &prolog_key);
			parts[0] = ctx.main_fn;

			si_build_wrapper_function(&ctx, parts, 2, 1, 0);
		}
	} else if (shader->is_monolithic && ctx.type == PIPE_SHADER_FRAGMENT) {
		si_llvm_build_monolithic_ps(&ctx, shader);
	}

	si_llvm_optimize_module(&ctx);

	/* Post-optimization transformations and analysis. */
	si_optimize_vs_outputs(&ctx);

	if ((debug && debug->debug_message) ||
	    si_can_dump_shader(sscreen, ctx.type)) {
		ctx.shader->info.private_mem_vgprs =
			ac_count_scratch_private_memory(ctx.main_fn);
	}

	/* Make sure the input is a pointer and not integer followed by inttoptr. */
	assert(LLVMGetTypeKind(LLVMTypeOf(LLVMGetParam(ctx.main_fn, 0))) ==
	       LLVMPointerTypeKind);

	/* Compile to bytecode. */
	r = si_compile_llvm(sscreen, &shader->binary, &shader->config, compiler,
			    &ctx.ac, debug, ctx.type, si_get_shader_name(shader),
			    si_should_optimize_less(compiler, shader->selector));
	si_llvm_dispose(&ctx);
	if (r) {
		fprintf(stderr, "LLVM failed to compile shader\n");
		return r;
	}

	/* Validate SGPR and VGPR usage for compute to detect compiler bugs.
	 * LLVM 3.9svn has this bug.
	 */
	if (sel->type == PIPE_SHADER_COMPUTE) {
		unsigned wave_size = sscreen->compute_wave_size;
		unsigned max_vgprs = sscreen->info.num_physical_wave64_vgprs_per_simd *
				     (wave_size == 32 ? 2 : 1);
		unsigned max_sgprs = sscreen->info.num_physical_sgprs_per_simd;
		unsigned max_sgprs_per_wave = 128;
		unsigned simds_per_tg = 4; /* assuming WGP mode on gfx10 */
		unsigned threads_per_tg = si_get_max_workgroup_size(shader);
		unsigned waves_per_tg = DIV_ROUND_UP(threads_per_tg, wave_size);
		unsigned waves_per_simd = DIV_ROUND_UP(waves_per_tg, simds_per_tg);

		max_vgprs = max_vgprs / waves_per_simd;
		max_sgprs = MIN2(max_sgprs / waves_per_simd, max_sgprs_per_wave);

		if (shader->config.num_sgprs > max_sgprs ||
		    shader->config.num_vgprs > max_vgprs) {
			fprintf(stderr, "LLVM failed to compile a shader correctly: "
				"SGPR:VGPR usage is %u:%u, but the hw limit is %u:%u\n",
				shader->config.num_sgprs, shader->config.num_vgprs,
				max_sgprs, max_vgprs);

			/* Just terminate the process, because dependent
			 * shaders can hang due to bad input data, but use
			 * the env var to allow shader-db to work.
			 */
			if (!debug_get_bool_option("SI_PASS_BAD_SHADERS", false))
				abort();
		}
	}

	/* Add the scratch offset to input SGPRs. */
	if (shader->config.scratch_bytes_per_wave && !si_is_merged_shader(&ctx))
		shader->info.num_input_sgprs += 1; /* scratch byte offset */

	/* Calculate the number of fragment input VGPRs. */
	if (ctx.type == PIPE_SHADER_FRAGMENT) {
		shader->info.num_input_vgprs = ac_get_fs_input_vgpr_cnt(&shader->config,
						&shader->info.face_vgpr_index,
						&shader->info.ancillary_vgpr_index);
	}

	si_calculate_max_simd_waves(shader);
	si_shader_dump_stats_for_shader_db(sscreen, shader, debug);
	return 0;
}

/**
 * Create, compile and return a shader part (prolog or epilog).
 *
 * \param sscreen	screen
 * \param list		list of shader parts of the same category
 * \param type		shader type
 * \param key		shader part key
 * \param prolog	whether the part being requested is a prolog
 * \param tm		LLVM target machine
 * \param debug		debug callback
 * \param build		the callback responsible for building the main function
 * \return		non-NULL on success
 */
static struct si_shader_part *
si_get_shader_part(struct si_screen *sscreen,
		   struct si_shader_part **list,
		   enum pipe_shader_type type,
		   bool prolog,
		   union si_shader_part_key *key,
		   struct ac_llvm_compiler *compiler,
		   struct pipe_debug_callback *debug,
		   void (*build)(struct si_shader_context *,
				 union si_shader_part_key *),
		   const char *name)
{
	struct si_shader_part *result;

	simple_mtx_lock(&sscreen->shader_parts_mutex);

	/* Find existing. */
	for (result = *list; result; result = result->next) {
		if (memcmp(&result->key, key, sizeof(*key)) == 0) {
			simple_mtx_unlock(&sscreen->shader_parts_mutex);
			return result;
		}
	}

	/* Compile a new one. */
	result = CALLOC_STRUCT(si_shader_part);
	result->key = *key;

	struct si_shader shader = {};

	switch (type) {
	case PIPE_SHADER_VERTEX:
		shader.key.as_ls = key->vs_prolog.as_ls;
		shader.key.as_es = key->vs_prolog.as_es;
		shader.key.as_ngg = key->vs_prolog.as_ngg;
		break;
	case PIPE_SHADER_TESS_CTRL:
		assert(!prolog);
		shader.key.part.tcs.epilog = key->tcs_epilog.states;
		break;
	case PIPE_SHADER_GEOMETRY:
		assert(prolog);
		shader.key.as_ngg = key->gs_prolog.as_ngg;
		break;
	case PIPE_SHADER_FRAGMENT:
		if (prolog)
			shader.key.part.ps.prolog = key->ps_prolog.states;
		else
			shader.key.part.ps.epilog = key->ps_epilog.states;
		break;
	default:
		unreachable("bad shader part");
	}

	struct si_shader_context ctx;
	si_llvm_context_init(&ctx, sscreen, compiler,
			     si_get_wave_size(sscreen, type, shader.key.as_ngg,
					      shader.key.as_es));
	ctx.shader = &shader;
	ctx.type = type;

	build(&ctx, key);

	/* Compile. */
	si_llvm_optimize_module(&ctx);

	if (si_compile_llvm(sscreen, &result->binary, &result->config, compiler,
			    &ctx.ac, debug, ctx.type, name, false)) {
		FREE(result);
		result = NULL;
		goto out;
	}

	result->next = *list;
	*list = result;

out:
	si_llvm_dispose(&ctx);
	simple_mtx_unlock(&sscreen->shader_parts_mutex);
	return result;
}

/**
 * Build the vertex shader prolog function.
 *
 * The inputs are the same as VS (a lot of SGPRs and 4 VGPR system values).
 * All inputs are returned unmodified. The vertex load indices are
 * stored after them, which will be used by the API VS for fetching inputs.
 *
 * For example, the expected outputs for instance_divisors[] = {0, 1, 2} are:
 *   input_v0,
 *   input_v1,
 *   input_v2,
 *   input_v3,
 *   (VertexID + BaseVertex),
 *   (InstanceID + StartInstance),
 *   (InstanceID / 2 + StartInstance)
 */
static void si_build_vs_prolog_function(struct si_shader_context *ctx,
					union si_shader_part_key *key)
{
	LLVMTypeRef *returns;
	LLVMValueRef ret, func;
	int num_returns, i;
	unsigned first_vs_vgpr = key->vs_prolog.num_merged_next_stage_vgprs;
	unsigned num_input_vgprs = key->vs_prolog.num_merged_next_stage_vgprs + 4 +
				   (key->vs_prolog.has_ngg_cull_inputs ? 1 : 0);
	struct ac_arg input_sgpr_param[key->vs_prolog.num_input_sgprs];
	struct ac_arg input_vgpr_param[13];
	LLVMValueRef input_vgprs[13];
	unsigned num_all_input_regs = key->vs_prolog.num_input_sgprs +
				      num_input_vgprs;
	unsigned user_sgpr_base = key->vs_prolog.num_merged_next_stage_vgprs ? 8 : 0;

	memset(&ctx->args, 0, sizeof(ctx->args));

	/* 4 preloaded VGPRs + vertex load indices as prolog outputs */
	returns = alloca((num_all_input_regs + key->vs_prolog.num_inputs) *
			 sizeof(LLVMTypeRef));
	num_returns = 0;

	/* Declare input and output SGPRs. */
	for (i = 0; i < key->vs_prolog.num_input_sgprs; i++) {
		ac_add_arg(&ctx->args, AC_ARG_SGPR, 1, AC_ARG_INT,
			   &input_sgpr_param[i]);
		returns[num_returns++] = ctx->i32;
	}

	struct ac_arg merged_wave_info = input_sgpr_param[3];

	/* Preloaded VGPRs (outputs must be floats) */
	for (i = 0; i < num_input_vgprs; i++) {
		ac_add_arg(&ctx->args, AC_ARG_VGPR, 1, AC_ARG_INT, &input_vgpr_param[i]);
		returns[num_returns++] = ctx->f32;
	}

	/* Vertex load indices. */
	for (i = 0; i < key->vs_prolog.num_inputs; i++)
		returns[num_returns++] = ctx->f32;

	/* Create the function. */
	si_llvm_create_func(ctx, "vs_prolog", returns, num_returns, 0);
	func = ctx->main_fn;

	for (i = 0; i < num_input_vgprs; i++) {
		input_vgprs[i] = ac_get_arg(&ctx->ac, input_vgpr_param[i]);
	}

	if (key->vs_prolog.num_merged_next_stage_vgprs) {
		if (!key->vs_prolog.is_monolithic)
			si_init_exec_from_input(ctx, merged_wave_info, 0);

		if (key->vs_prolog.as_ls &&
		    ctx->screen->info.has_ls_vgpr_init_bug) {
			/* If there are no HS threads, SPI loads the LS VGPRs
			 * starting at VGPR 0. Shift them back to where they
			 * belong.
			 */
			LLVMValueRef has_hs_threads =
				LLVMBuildICmp(ctx->ac.builder, LLVMIntNE,
				    si_unpack_param(ctx, input_sgpr_param[3], 8, 8),
				    ctx->i32_0, "");

			for (i = 4; i > 0; --i) {
				input_vgprs[i + 1] =
					LLVMBuildSelect(ctx->ac.builder, has_hs_threads,
						        input_vgprs[i + 1],
						        input_vgprs[i - 1], "");
			}
		}
	}

	unsigned vertex_id_vgpr = first_vs_vgpr;
	unsigned instance_id_vgpr =
		ctx->screen->info.chip_class >= GFX10 ?
			first_vs_vgpr + 3 :
			first_vs_vgpr + (key->vs_prolog.as_ls ? 2 : 1);

	ctx->abi.vertex_id = input_vgprs[vertex_id_vgpr];
	ctx->abi.instance_id = input_vgprs[instance_id_vgpr];

	/* InstanceID = VertexID >> 16;
	 * VertexID   = VertexID & 0xffff;
	 */
	if (key->vs_prolog.states.unpack_instance_id_from_vertex_id) {
		ctx->abi.instance_id = LLVMBuildLShr(ctx->ac.builder, ctx->abi.vertex_id,
						     LLVMConstInt(ctx->i32, 16, 0), "");
		ctx->abi.vertex_id = LLVMBuildAnd(ctx->ac.builder, ctx->abi.vertex_id,
						  LLVMConstInt(ctx->i32, 0xffff, 0), "");
	}

	/* Copy inputs to outputs. This should be no-op, as the registers match,
	 * but it will prevent the compiler from overwriting them unintentionally.
	 */
	ret = ctx->return_value;
	for (i = 0; i < key->vs_prolog.num_input_sgprs; i++) {
		LLVMValueRef p = LLVMGetParam(func, i);
		ret = LLVMBuildInsertValue(ctx->ac.builder, ret, p, i, "");
	}
	for (i = 0; i < num_input_vgprs; i++) {
		LLVMValueRef p = input_vgprs[i];

		if (i == vertex_id_vgpr)
			p = ctx->abi.vertex_id;
		else if (i == instance_id_vgpr)
			p = ctx->abi.instance_id;

		p = ac_to_float(&ctx->ac, p);
		ret = LLVMBuildInsertValue(ctx->ac.builder, ret, p,
					   key->vs_prolog.num_input_sgprs + i, "");
	}

	/* Compute vertex load indices from instance divisors. */
	LLVMValueRef instance_divisor_constbuf = NULL;

	if (key->vs_prolog.states.instance_divisor_is_fetched) {
		LLVMValueRef list = si_prolog_get_rw_buffers(ctx);
		LLVMValueRef buf_index =
			LLVMConstInt(ctx->i32, SI_VS_CONST_INSTANCE_DIVISORS, 0);
		instance_divisor_constbuf =
			ac_build_load_to_sgpr(&ctx->ac, list, buf_index);
	}

	for (i = 0; i < key->vs_prolog.num_inputs; i++) {
		bool divisor_is_one =
			key->vs_prolog.states.instance_divisor_is_one & (1u << i);
		bool divisor_is_fetched =
			key->vs_prolog.states.instance_divisor_is_fetched & (1u << i);
		LLVMValueRef index = NULL;

		if (divisor_is_one) {
			index = ctx->abi.instance_id;
		} else if (divisor_is_fetched) {
			LLVMValueRef udiv_factors[4];

			for (unsigned j = 0; j < 4; j++) {
				udiv_factors[j] =
					si_buffer_load_const(ctx, instance_divisor_constbuf,
							     LLVMConstInt(ctx->i32, i*16 + j*4, 0));
				udiv_factors[j] = ac_to_integer(&ctx->ac, udiv_factors[j]);
			}
			/* The faster NUW version doesn't work when InstanceID == UINT_MAX.
			 * Such InstanceID might not be achievable in a reasonable time though.
			 */
			index = ac_build_fast_udiv_nuw(&ctx->ac, ctx->abi.instance_id,
						       udiv_factors[0], udiv_factors[1],
						       udiv_factors[2], udiv_factors[3]);
		}

		if (divisor_is_one || divisor_is_fetched) {
			/* Add StartInstance. */
			index = LLVMBuildAdd(ctx->ac.builder, index,
					     LLVMGetParam(ctx->main_fn, user_sgpr_base +
							  SI_SGPR_START_INSTANCE), "");
		} else {
			/* VertexID + BaseVertex */
			index = LLVMBuildAdd(ctx->ac.builder,
					     ctx->abi.vertex_id,
					     LLVMGetParam(func, user_sgpr_base +
								SI_SGPR_BASE_VERTEX), "");
		}

		index = ac_to_float(&ctx->ac, index);
		ret = LLVMBuildInsertValue(ctx->ac.builder, ret, index,
					   ctx->args.arg_count + i, "");
	}

	si_llvm_build_ret(ctx, ret);
}

static bool si_get_vs_prolog(struct si_screen *sscreen,
			     struct ac_llvm_compiler *compiler,
			     struct si_shader *shader,
			     struct pipe_debug_callback *debug,
			     struct si_shader *main_part,
			     const struct si_vs_prolog_bits *key)
{
	struct si_shader_selector *vs = main_part->selector;

	if (!si_vs_needs_prolog(vs, key))
		return true;

	/* Get the prolog. */
	union si_shader_part_key prolog_key;
	si_get_vs_prolog_key(&vs->info, main_part->info.num_input_sgprs, false,
			     key, shader, &prolog_key);

	shader->prolog =
		si_get_shader_part(sscreen, &sscreen->vs_prologs,
				   PIPE_SHADER_VERTEX, true, &prolog_key, compiler,
				   debug, si_build_vs_prolog_function,
				   "Vertex Shader Prolog");
	return shader->prolog != NULL;
}

/**
 * Select and compile (or reuse) vertex shader parts (prolog & epilog).
 */
static bool si_shader_select_vs_parts(struct si_screen *sscreen,
				      struct ac_llvm_compiler *compiler,
				      struct si_shader *shader,
				      struct pipe_debug_callback *debug)
{
	return si_get_vs_prolog(sscreen, compiler, shader, debug, shader,
				&shader->key.part.vs.prolog);
}

/**
 * Select and compile (or reuse) TCS parts (epilog).
 */
static bool si_shader_select_tcs_parts(struct si_screen *sscreen,
				       struct ac_llvm_compiler *compiler,
				       struct si_shader *shader,
				       struct pipe_debug_callback *debug)
{
	if (sscreen->info.chip_class >= GFX9) {
		struct si_shader *ls_main_part =
			shader->key.part.tcs.ls->main_shader_part_ls;

		if (!si_get_vs_prolog(sscreen, compiler, shader, debug, ls_main_part,
				      &shader->key.part.tcs.ls_prolog))
			return false;

		shader->previous_stage = ls_main_part;
	}

	/* Get the epilog. */
	union si_shader_part_key epilog_key;
	memset(&epilog_key, 0, sizeof(epilog_key));
	epilog_key.tcs_epilog.states = shader->key.part.tcs.epilog;

	shader->epilog = si_get_shader_part(sscreen, &sscreen->tcs_epilogs,
					    PIPE_SHADER_TESS_CTRL, false,
					    &epilog_key, compiler, debug,
					    si_llvm_build_tcs_epilog,
					    "Tessellation Control Shader Epilog");
	return shader->epilog != NULL;
}

/**
 * Select and compile (or reuse) GS parts (prolog).
 */
static bool si_shader_select_gs_parts(struct si_screen *sscreen,
				      struct ac_llvm_compiler *compiler,
				      struct si_shader *shader,
				      struct pipe_debug_callback *debug)
{
	if (sscreen->info.chip_class >= GFX9) {
		struct si_shader *es_main_part;
		enum pipe_shader_type es_type = shader->key.part.gs.es->type;

		if (shader->key.as_ngg)
			es_main_part = shader->key.part.gs.es->main_shader_part_ngg_es;
		else
			es_main_part = shader->key.part.gs.es->main_shader_part_es;

		if (es_type == PIPE_SHADER_VERTEX &&
		    !si_get_vs_prolog(sscreen, compiler, shader, debug, es_main_part,
				      &shader->key.part.gs.vs_prolog))
			return false;

		shader->previous_stage = es_main_part;
	}

	if (!shader->key.part.gs.prolog.tri_strip_adj_fix)
		return true;

	union si_shader_part_key prolog_key;
	memset(&prolog_key, 0, sizeof(prolog_key));
	prolog_key.gs_prolog.states = shader->key.part.gs.prolog;
	prolog_key.gs_prolog.as_ngg = shader->key.as_ngg;

	shader->prolog2 = si_get_shader_part(sscreen, &sscreen->gs_prologs,
					    PIPE_SHADER_GEOMETRY, true,
					    &prolog_key, compiler, debug,
					    si_llvm_build_gs_prolog,
					    "Geometry Shader Prolog");
	return shader->prolog2 != NULL;
}

/**
 * Compute the PS prolog key, which contains all the information needed to
 * build the PS prolog function, and set related bits in shader->config.
 */
void si_get_ps_prolog_key(struct si_shader *shader,
			  union si_shader_part_key *key,
			  bool separate_prolog)
{
	struct si_shader_info *info = &shader->selector->info;

	memset(key, 0, sizeof(*key));
	key->ps_prolog.states = shader->key.part.ps.prolog;
	key->ps_prolog.colors_read = info->colors_read;
	key->ps_prolog.num_input_sgprs = shader->info.num_input_sgprs;
	key->ps_prolog.num_input_vgprs = shader->info.num_input_vgprs;
	key->ps_prolog.wqm = info->uses_derivatives &&
		(key->ps_prolog.colors_read ||
		 key->ps_prolog.states.force_persp_sample_interp ||
		 key->ps_prolog.states.force_linear_sample_interp ||
		 key->ps_prolog.states.force_persp_center_interp ||
		 key->ps_prolog.states.force_linear_center_interp ||
		 key->ps_prolog.states.bc_optimize_for_persp ||
		 key->ps_prolog.states.bc_optimize_for_linear);
	key->ps_prolog.ancillary_vgpr_index = shader->info.ancillary_vgpr_index;

	if (info->colors_read) {
		unsigned *color = shader->selector->color_attr_index;

		if (shader->key.part.ps.prolog.color_two_side) {
			/* BCOLORs are stored after the last input. */
			key->ps_prolog.num_interp_inputs = info->num_inputs;
			key->ps_prolog.face_vgpr_index = shader->info.face_vgpr_index;
			if (separate_prolog)
				shader->config.spi_ps_input_ena |= S_0286CC_FRONT_FACE_ENA(1);
		}

		for (unsigned i = 0; i < 2; i++) {
			unsigned interp = info->input_interpolate[color[i]];
			unsigned location = info->input_interpolate_loc[color[i]];

			if (!(info->colors_read & (0xf << i*4)))
				continue;

			key->ps_prolog.color_attr_index[i] = color[i];

			if (shader->key.part.ps.prolog.flatshade_colors &&
			    interp == TGSI_INTERPOLATE_COLOR)
				interp = TGSI_INTERPOLATE_CONSTANT;

			switch (interp) {
			case TGSI_INTERPOLATE_CONSTANT:
				key->ps_prolog.color_interp_vgpr_index[i] = -1;
				break;
			case TGSI_INTERPOLATE_PERSPECTIVE:
			case TGSI_INTERPOLATE_COLOR:
				/* Force the interpolation location for colors here. */
				if (shader->key.part.ps.prolog.force_persp_sample_interp)
					location = TGSI_INTERPOLATE_LOC_SAMPLE;
				if (shader->key.part.ps.prolog.force_persp_center_interp)
					location = TGSI_INTERPOLATE_LOC_CENTER;

				switch (location) {
				case TGSI_INTERPOLATE_LOC_SAMPLE:
					key->ps_prolog.color_interp_vgpr_index[i] = 0;
					if (separate_prolog) {
						shader->config.spi_ps_input_ena |=
							S_0286CC_PERSP_SAMPLE_ENA(1);
					}
					break;
				case TGSI_INTERPOLATE_LOC_CENTER:
					key->ps_prolog.color_interp_vgpr_index[i] = 2;
					if (separate_prolog) {
						shader->config.spi_ps_input_ena |=
							S_0286CC_PERSP_CENTER_ENA(1);
					}
					break;
				case TGSI_INTERPOLATE_LOC_CENTROID:
					key->ps_prolog.color_interp_vgpr_index[i] = 4;
					if (separate_prolog) {
						shader->config.spi_ps_input_ena |=
							S_0286CC_PERSP_CENTROID_ENA(1);
					}
					break;
				default:
					assert(0);
				}
				break;
			case TGSI_INTERPOLATE_LINEAR:
				/* Force the interpolation location for colors here. */
				if (shader->key.part.ps.prolog.force_linear_sample_interp)
					location = TGSI_INTERPOLATE_LOC_SAMPLE;
				if (shader->key.part.ps.prolog.force_linear_center_interp)
					location = TGSI_INTERPOLATE_LOC_CENTER;

				/* The VGPR assignment for non-monolithic shaders
				 * works because InitialPSInputAddr is set on the
				 * main shader and PERSP_PULL_MODEL is never used.
				 */
				switch (location) {
				case TGSI_INTERPOLATE_LOC_SAMPLE:
					key->ps_prolog.color_interp_vgpr_index[i] =
						separate_prolog ? 6 : 9;
					if (separate_prolog) {
						shader->config.spi_ps_input_ena |=
							S_0286CC_LINEAR_SAMPLE_ENA(1);
					}
					break;
				case TGSI_INTERPOLATE_LOC_CENTER:
					key->ps_prolog.color_interp_vgpr_index[i] =
						separate_prolog ? 8 : 11;
					if (separate_prolog) {
						shader->config.spi_ps_input_ena |=
							S_0286CC_LINEAR_CENTER_ENA(1);
					}
					break;
				case TGSI_INTERPOLATE_LOC_CENTROID:
					key->ps_prolog.color_interp_vgpr_index[i] =
						separate_prolog ? 10 : 13;
					if (separate_prolog) {
						shader->config.spi_ps_input_ena |=
							S_0286CC_LINEAR_CENTROID_ENA(1);
					}
					break;
				default:
					assert(0);
				}
				break;
			default:
				assert(0);
			}
		}
	}
}

/**
 * Check whether a PS prolog is required based on the key.
 */
bool si_need_ps_prolog(const union si_shader_part_key *key)
{
	return key->ps_prolog.colors_read ||
	       key->ps_prolog.states.force_persp_sample_interp ||
	       key->ps_prolog.states.force_linear_sample_interp ||
	       key->ps_prolog.states.force_persp_center_interp ||
	       key->ps_prolog.states.force_linear_center_interp ||
	       key->ps_prolog.states.bc_optimize_for_persp ||
	       key->ps_prolog.states.bc_optimize_for_linear ||
	       key->ps_prolog.states.poly_stipple ||
	       key->ps_prolog.states.samplemask_log_ps_iter;
}

/**
 * Compute the PS epilog key, which contains all the information needed to
 * build the PS epilog function.
 */
void si_get_ps_epilog_key(struct si_shader *shader,
			  union si_shader_part_key *key)
{
	struct si_shader_info *info = &shader->selector->info;
	memset(key, 0, sizeof(*key));
	key->ps_epilog.colors_written = info->colors_written;
	key->ps_epilog.writes_z = info->writes_z;
	key->ps_epilog.writes_stencil = info->writes_stencil;
	key->ps_epilog.writes_samplemask = info->writes_samplemask;
	key->ps_epilog.states = shader->key.part.ps.epilog;
}

/**
 * Select and compile (or reuse) pixel shader parts (prolog & epilog).
 */
static bool si_shader_select_ps_parts(struct si_screen *sscreen,
				      struct ac_llvm_compiler *compiler,
				      struct si_shader *shader,
				      struct pipe_debug_callback *debug)
{
	union si_shader_part_key prolog_key;
	union si_shader_part_key epilog_key;

	/* Get the prolog. */
	si_get_ps_prolog_key(shader, &prolog_key, true);

	/* The prolog is a no-op if these aren't set. */
	if (si_need_ps_prolog(&prolog_key)) {
		shader->prolog =
			si_get_shader_part(sscreen, &sscreen->ps_prologs,
					   PIPE_SHADER_FRAGMENT, true,
					   &prolog_key, compiler, debug,
					   si_llvm_build_ps_prolog,
					   "Fragment Shader Prolog");
		if (!shader->prolog)
			return false;
	}

	/* Get the epilog. */
	si_get_ps_epilog_key(shader, &epilog_key);

	shader->epilog =
		si_get_shader_part(sscreen, &sscreen->ps_epilogs,
				   PIPE_SHADER_FRAGMENT, false,
				   &epilog_key, compiler, debug,
				   si_llvm_build_ps_epilog,
				   "Fragment Shader Epilog");
	if (!shader->epilog)
		return false;

	/* Enable POS_FIXED_PT if polygon stippling is enabled. */
	if (shader->key.part.ps.prolog.poly_stipple) {
		shader->config.spi_ps_input_ena |= S_0286CC_POS_FIXED_PT_ENA(1);
		assert(G_0286CC_POS_FIXED_PT_ENA(shader->config.spi_ps_input_addr));
	}

	/* Set up the enable bits for per-sample shading if needed. */
	if (shader->key.part.ps.prolog.force_persp_sample_interp &&
	    (G_0286CC_PERSP_CENTER_ENA(shader->config.spi_ps_input_ena) ||
	     G_0286CC_PERSP_CENTROID_ENA(shader->config.spi_ps_input_ena))) {
		shader->config.spi_ps_input_ena &= C_0286CC_PERSP_CENTER_ENA;
		shader->config.spi_ps_input_ena &= C_0286CC_PERSP_CENTROID_ENA;
		shader->config.spi_ps_input_ena |= S_0286CC_PERSP_SAMPLE_ENA(1);
	}
	if (shader->key.part.ps.prolog.force_linear_sample_interp &&
	    (G_0286CC_LINEAR_CENTER_ENA(shader->config.spi_ps_input_ena) ||
	     G_0286CC_LINEAR_CENTROID_ENA(shader->config.spi_ps_input_ena))) {
		shader->config.spi_ps_input_ena &= C_0286CC_LINEAR_CENTER_ENA;
		shader->config.spi_ps_input_ena &= C_0286CC_LINEAR_CENTROID_ENA;
		shader->config.spi_ps_input_ena |= S_0286CC_LINEAR_SAMPLE_ENA(1);
	}
	if (shader->key.part.ps.prolog.force_persp_center_interp &&
	    (G_0286CC_PERSP_SAMPLE_ENA(shader->config.spi_ps_input_ena) ||
	     G_0286CC_PERSP_CENTROID_ENA(shader->config.spi_ps_input_ena))) {
		shader->config.spi_ps_input_ena &= C_0286CC_PERSP_SAMPLE_ENA;
		shader->config.spi_ps_input_ena &= C_0286CC_PERSP_CENTROID_ENA;
		shader->config.spi_ps_input_ena |= S_0286CC_PERSP_CENTER_ENA(1);
	}
	if (shader->key.part.ps.prolog.force_linear_center_interp &&
	    (G_0286CC_LINEAR_SAMPLE_ENA(shader->config.spi_ps_input_ena) ||
	     G_0286CC_LINEAR_CENTROID_ENA(shader->config.spi_ps_input_ena))) {
		shader->config.spi_ps_input_ena &= C_0286CC_LINEAR_SAMPLE_ENA;
		shader->config.spi_ps_input_ena &= C_0286CC_LINEAR_CENTROID_ENA;
		shader->config.spi_ps_input_ena |= S_0286CC_LINEAR_CENTER_ENA(1);
	}

	/* POW_W_FLOAT requires that one of the perspective weights is enabled. */
	if (G_0286CC_POS_W_FLOAT_ENA(shader->config.spi_ps_input_ena) &&
	    !(shader->config.spi_ps_input_ena & 0xf)) {
		shader->config.spi_ps_input_ena |= S_0286CC_PERSP_CENTER_ENA(1);
		assert(G_0286CC_PERSP_CENTER_ENA(shader->config.spi_ps_input_addr));
	}

	/* At least one pair of interpolation weights must be enabled. */
	if (!(shader->config.spi_ps_input_ena & 0x7f)) {
		shader->config.spi_ps_input_ena |= S_0286CC_LINEAR_CENTER_ENA(1);
		assert(G_0286CC_LINEAR_CENTER_ENA(shader->config.spi_ps_input_addr));
	}

	/* Samplemask fixup requires the sample ID. */
	if (shader->key.part.ps.prolog.samplemask_log_ps_iter) {
		shader->config.spi_ps_input_ena |= S_0286CC_ANCILLARY_ENA(1);
		assert(G_0286CC_ANCILLARY_ENA(shader->config.spi_ps_input_addr));
	}

	/* The sample mask input is always enabled, because the API shader always
	 * passes it through to the epilog. Disable it here if it's unused.
	 */
	if (!shader->key.part.ps.epilog.poly_line_smoothing &&
	    !shader->selector->info.reads_samplemask)
		shader->config.spi_ps_input_ena &= C_0286CC_SAMPLE_COVERAGE_ENA;

	return true;
}

void si_multiwave_lds_size_workaround(struct si_screen *sscreen,
				      unsigned *lds_size)
{
	/* If tessellation is all offchip and on-chip GS isn't used, this
	 * workaround is not needed.
	 */
	return;

	/* SPI barrier management bug:
	 *   Make sure we have at least 4k of LDS in use to avoid the bug.
	 *   It applies to workgroup sizes of more than one wavefront.
	 */
	if (sscreen->info.family == CHIP_BONAIRE ||
	    sscreen->info.family == CHIP_KABINI)
		*lds_size = MAX2(*lds_size, 8);
}

void si_fix_resource_usage(struct si_screen *sscreen, struct si_shader *shader)
{
	unsigned min_sgprs = shader->info.num_input_sgprs + 2; /* VCC */

	shader->config.num_sgprs = MAX2(shader->config.num_sgprs, min_sgprs);

	if (shader->selector->type == PIPE_SHADER_COMPUTE &&
	    si_get_max_workgroup_size(shader) > sscreen->compute_wave_size) {
		si_multiwave_lds_size_workaround(sscreen,
						 &shader->config.lds_size);
	}
}

bool si_create_shader_variant(struct si_screen *sscreen,
			      struct ac_llvm_compiler *compiler,
			      struct si_shader *shader,
			      struct pipe_debug_callback *debug)
{
	struct si_shader_selector *sel = shader->selector;
	struct si_shader *mainp = *si_get_main_shader_part(sel, &shader->key);
	int r;

	/* LS, ES, VS are compiled on demand if the main part hasn't been
	 * compiled for that stage.
	 *
	 * GS are compiled on demand if the main part hasn't been compiled
	 * for the chosen NGG-ness.
	 *
	 * Vertex shaders are compiled on demand when a vertex fetch
	 * workaround must be applied.
	 */
	if (shader->is_monolithic) {
		/* Monolithic shader (compiled as a whole, has many variants,
		 * may take a long time to compile).
		 */
		r = si_compile_shader(sscreen, compiler, shader, debug);
		if (r)
			return false;
	} else {
		/* The shader consists of several parts:
		 *
		 * - the middle part is the user shader, it has 1 variant only
		 *   and it was compiled during the creation of the shader
		 *   selector
		 * - the prolog part is inserted at the beginning
		 * - the epilog part is inserted at the end
		 *
		 * The prolog and epilog have many (but simple) variants.
		 *
		 * Starting with gfx9, geometry and tessellation control
		 * shaders also contain the prolog and user shader parts of
		 * the previous shader stage.
		 */

		if (!mainp)
			return false;

		/* Copy the compiled shader data over. */
		shader->is_binary_shared = true;
		shader->binary = mainp->binary;
		shader->config = mainp->config;
		shader->info.num_input_sgprs = mainp->info.num_input_sgprs;
		shader->info.num_input_vgprs = mainp->info.num_input_vgprs;
		shader->info.face_vgpr_index = mainp->info.face_vgpr_index;
		shader->info.ancillary_vgpr_index = mainp->info.ancillary_vgpr_index;
		memcpy(shader->info.vs_output_param_offset,
		       mainp->info.vs_output_param_offset,
		       sizeof(mainp->info.vs_output_param_offset));
		shader->info.uses_instanceid = mainp->info.uses_instanceid;
		shader->info.nr_pos_exports = mainp->info.nr_pos_exports;
		shader->info.nr_param_exports = mainp->info.nr_param_exports;

		/* Select prologs and/or epilogs. */
		switch (sel->type) {
		case PIPE_SHADER_VERTEX:
			if (!si_shader_select_vs_parts(sscreen, compiler, shader, debug))
				return false;
			break;
		case PIPE_SHADER_TESS_CTRL:
			if (!si_shader_select_tcs_parts(sscreen, compiler, shader, debug))
				return false;
			break;
		case PIPE_SHADER_TESS_EVAL:
			break;
		case PIPE_SHADER_GEOMETRY:
			if (!si_shader_select_gs_parts(sscreen, compiler, shader, debug))
				return false;
			break;
		case PIPE_SHADER_FRAGMENT:
			if (!si_shader_select_ps_parts(sscreen, compiler, shader, debug))
				return false;

			/* Make sure we have at least as many VGPRs as there
			 * are allocated inputs.
			 */
			shader->config.num_vgprs = MAX2(shader->config.num_vgprs,
							shader->info.num_input_vgprs);
			break;
		default:;
		}

		/* Update SGPR and VGPR counts. */
		if (shader->prolog) {
			shader->config.num_sgprs = MAX2(shader->config.num_sgprs,
							shader->prolog->config.num_sgprs);
			shader->config.num_vgprs = MAX2(shader->config.num_vgprs,
							shader->prolog->config.num_vgprs);
		}
		if (shader->previous_stage) {
			shader->config.num_sgprs = MAX2(shader->config.num_sgprs,
							shader->previous_stage->config.num_sgprs);
			shader->config.num_vgprs = MAX2(shader->config.num_vgprs,
							shader->previous_stage->config.num_vgprs);
			shader->config.spilled_sgprs =
				MAX2(shader->config.spilled_sgprs,
				     shader->previous_stage->config.spilled_sgprs);
			shader->config.spilled_vgprs =
				MAX2(shader->config.spilled_vgprs,
				     shader->previous_stage->config.spilled_vgprs);
			shader->info.private_mem_vgprs =
				MAX2(shader->info.private_mem_vgprs,
				     shader->previous_stage->info.private_mem_vgprs);
			shader->config.scratch_bytes_per_wave =
				MAX2(shader->config.scratch_bytes_per_wave,
				     shader->previous_stage->config.scratch_bytes_per_wave);
			shader->info.uses_instanceid |=
				shader->previous_stage->info.uses_instanceid;
		}
		if (shader->prolog2) {
			shader->config.num_sgprs = MAX2(shader->config.num_sgprs,
							shader->prolog2->config.num_sgprs);
			shader->config.num_vgprs = MAX2(shader->config.num_vgprs,
							shader->prolog2->config.num_vgprs);
		}
		if (shader->epilog) {
			shader->config.num_sgprs = MAX2(shader->config.num_sgprs,
							shader->epilog->config.num_sgprs);
			shader->config.num_vgprs = MAX2(shader->config.num_vgprs,
							shader->epilog->config.num_vgprs);
		}
		si_calculate_max_simd_waves(shader);
	}

	if (shader->key.as_ngg) {
		assert(!shader->key.as_es && !shader->key.as_ls);
		gfx10_ngg_calculate_subgroup_info(shader);
	} else if (sscreen->info.chip_class >= GFX9 && sel->type == PIPE_SHADER_GEOMETRY) {
		gfx9_get_gs_info(shader->previous_stage_sel, sel, &shader->gs_info);
	}

	si_fix_resource_usage(sscreen, shader);
	si_shader_dump(sscreen, shader, debug, stderr, true);

	/* Upload. */
	if (!si_shader_binary_upload(sscreen, shader, 0)) {
		fprintf(stderr, "LLVM failed to upload shader\n");
		return false;
	}

	return true;
}

void si_shader_destroy(struct si_shader *shader)
{
	if (shader->scratch_bo)
		si_resource_reference(&shader->scratch_bo, NULL);

	si_resource_reference(&shader->bo, NULL);

	if (!shader->is_binary_shared)
		si_shader_binary_clean(&shader->binary);

	free(shader->shader_log);
}