GX backend updates

This commit is contained in:
Jack Andersen 2015-10-16 16:06:27 -10:00
parent f2c77a62fc
commit 5b88fa6af4
6 changed files with 232 additions and 74 deletions

View File

@ -591,6 +591,20 @@ BlenderConnection::DataStream::Mesh::Material::Material
conn.m_loadedBlend.getProject().getProjectRootPath().getProjectRelativeFromAbsolute(absolute);
texs.emplace_back(conn.m_loadedBlend.getProject().getProjectWorkingPath(), relative);
}
uint32_t iPropCount;
conn._readBuf(&iPropCount, 4);
iprops.reserve(iPropCount);
for (uint32_t i=0 ; i<iPropCount ; ++i)
{
conn._readBuf(&bufSz, 4);
std::string readStr(bufSz, ' ');
conn._readBuf(&readStr[0], bufSz);
int32_t val;
conn._readBuf(&val, 4);
iprops[readStr] = val;
}
}
BlenderConnection::DataStream::Mesh::Surface::Surface

View File

@ -18,6 +18,7 @@
#include <string>
#include <functional>
#include <iostream>
#include <unordered_map>
#include "HECL/HECL.hpp"
#include <Athena/Types.hpp>
@ -311,6 +312,7 @@ public:
std::string name;
std::string source;
std::vector<ProjectPath> texs;
std::unordered_map<std::string, int32_t> iprops;
Material(BlenderConnection& conn);
};

View File

@ -141,7 +141,7 @@ def recursive_color_trace(mat_obj, mesh_obj, tex_list, node, socket=None):
if socket.name == 'Value':
if matrix_str:
uvsource_str = matrix_str % uvsource_str
return 'Texture(%d, %s).a' % (get_texmap_idx(tex_list, node.texture.name), uvsource_str)
return 'Texture(%d, %s).aaa' % (get_texmap_idx(tex_list, node.texture.name), uvsource_str)
if socket.name == 'Color':
if matrix_str:
uvsource_str = matrix_str % uvsource_str
@ -297,7 +297,7 @@ def recursive_alpha_trace(mat_obj, mesh_obj, tex_list, node, socket=None):
if socket.name == 'Value':
if matrix_str:
uvsource_str = matrix_str % uvsource_str
return 'Texture(%d, %s).a' % (get_texmap_idx(tex_list, node.texture.name), uvsource_str)
return 'Texture(%d, %s).aaa' % (get_texmap_idx(tex_list, node.texture.name), uvsource_str)
else:
raise RuntimeError("Only the 'Value' output sockets may be used from Texture nodes")
@ -321,7 +321,7 @@ def recursive_alpha_trace(mat_obj, mesh_obj, tex_list, node, socket=None):
if node.label.startswith('DYNAMIC_'):
dynamic_index = int(node.label[8:])
return 'ColorReg(%d).a' % dynamic_index
return 'ColorReg(%d).aaa' % dynamic_index
return '%g' % node.outputs['Value'].default_value

View File

@ -65,6 +65,28 @@ def generate_skeleton_info(armature, endian_char='<'):
return info_bytes
def write_out_material(writebuf, mat, mesh_obj):
hecl_str, texs = HMDLShader.shader(mat, mesh_obj)
writebuf(struct.pack('I', len(mat.name)))
writebuf(mat.name.encode())
writebuf(struct.pack('I', len(hecl_str)))
writebuf(hecl_str.encode())
writebuf(struct.pack('I', len(texs)))
for tex in texs:
writebuf(struct.pack('I', len(tex)))
writebuf(tex.encode())
prop_count = 0
for prop in mat.items():
if isinstance(prop[1], int):
prop_count += 1
writebuf(struct.pack('I', prop_count))
prop_count = 0
for prop in mat.items():
if isinstance(prop[1], int):
writebuf(struct.pack('I', len(prop[0])))
writebuf(prop[0].encode())
writebuf(struct.pack('i', prop[1]))
# Takes a Blender 'Mesh' object (not the datablock)
# and performs a one-shot conversion process to HMDL; packaging
@ -126,15 +148,7 @@ def cook(writebuf, mesh_obj, max_skin_banks, max_octant_length=None):
found = False
for mat in bpy.data.materials:
if mat.name.endswith('_%u_%u' % (grp_idx, mat_idx)):
hecl_str, texs = HMDLShader.shader(mat, mesh_obj)
writebuf(struct.pack('I', len(mat.name)))
writebuf(mat.name.encode())
writebuf(struct.pack('I', len(hecl_str)))
writebuf(hecl_str.encode())
writebuf(struct.pack('I', len(texs)))
for tex in texs:
writebuf(struct.pack('I', len(tex)))
writebuf(tex.encode())
write_out_material(writebuf, mat, mesh_obj)
found = True
break
if not found:
@ -143,15 +157,7 @@ def cook(writebuf, mesh_obj, max_skin_banks, max_octant_length=None):
writebuf(struct.pack('II', 1, len(sorted_material_idxs)))
for mat_idx in sorted_material_idxs:
mat = mesh_obj.data.materials[mat_idx]
hecl_str, texs = HMDLShader.shader(mat, mesh_obj)
writebuf(struct.pack('I', len(mat.name)))
writebuf(mat.name.encode())
writebuf(struct.pack('I', len(hecl_str)))
writebuf(hecl_str.encode())
writebuf(struct.pack('I', len(texs)))
for tex in texs:
writebuf(struct.pack('I', len(tex)))
writebuf(tex.encode())
write_out_material(writebuf, mat, mesh_obj)
# Output vert pool
vert_pool.write_out(writebuf, mesh_obj.vertex_groups)

View File

@ -2,7 +2,7 @@
#define HECLBACKEND_GX_HPP
#include "Backend.hpp"
#include <Athena/Types.hpp>
#include <Athena/DNA.hpp>
#include <stdint.h>
#include <stdlib.h>
#include <algorithm>
@ -14,6 +14,14 @@ namespace Backend
struct GX : IBackend
{
enum AttrType
{
NONE,
DIRECT,
INDEX8,
INDEX16
};
enum TevOp
{
TEV_ADD = 0,
@ -30,6 +38,36 @@ struct GX : IBackend
TEV_COMP_A8_EQ = TEV_COMP_RGB8_EQ // for alpha channel
};
enum TevBias
{
TB_ZERO = 0,
TB_ADDHALF = 1,
TB_SUBHALF = 2,
};
enum TevScale
{
CS_SCALE_1 = 0,
CS_SCALE_2 = 1,
CS_SCALE_4 = 2,
CS_DIVIDE_2 = 3
};
enum TexGenType
{
TG_MTX3x4 = 0,
TG_MTX2x4,
TG_BUMP0,
TG_BUMP1,
TG_BUMP2,
TG_BUMP3,
TG_BUMP4,
TG_BUMP5,
TG_BUMP6,
TG_BUMP7,
TG_SRTG
};
enum TevRegID
{
TEVPREV = 0,
@ -189,6 +227,56 @@ struct GX : IBackend
IDENTITY = 60
};
enum PTTexMtx
{
PTTEXMTX0 = 64,
PTTEXMTX1 = 67,
PTTEXMTX2 = 70,
PTTEXMTX3 = 73,
PTTEXMTX4 = 76,
PTTEXMTX5 = 79,
PTTEXMTX6 = 82,
PTTEXMTX7 = 85,
PTTEXMTX8 = 88,
PTTEXMTX9 = 91,
PTTEXMTX10 = 94,
PTTEXMTX11 = 97,
PTTEXMTX12 = 100,
PTTEXMTX13 = 103,
PTTEXMTX14 = 106,
PTTEXMTX15 = 109,
PTTEXMTX16 = 112,
PTTEXMTX17 = 115,
PTTEXMTX18 = 118,
PTTEXMTX19 = 121,
PTIDENTITY = 125
};
enum DiffuseFn
{
DF_NONE = 0,
DF_SIGN,
DF_CLAMP
};
enum AttnFn
{
AF_SPEC = 0,
AF_SPOT = 1,
AF_NONE
};
enum Primitive
{
POINTS = 0xb8,
LINES = 0xa8,
LINESTRIP = 0xb0,
TRIANGLES = 0x90,
TRIANGLESTRIP = 0x98,
TRIANGLEFAN = 0xa0,
QUADS = 0x80
};
struct TexCoordGen
{
TexGenSrc m_src = TG_TEX0;
@ -207,15 +295,18 @@ struct GX : IBackend
struct TEVStage
{
TevOp m_op = TEV_ADD;
TevOp m_cop = TEV_ADD;
TevOp m_aop = TEV_ADD;
TevColorArg m_color[4] = {CC_ZERO, CC_ZERO, CC_ZERO, CC_ZERO};
TevAlphaArg m_alpha[4] = {CA_ZERO, CA_ZERO, CA_ZERO, CA_ZERO};
TevKColorSel m_kColor = TEV_KCSEL_1;
TevKAlphaSel m_kAlpha = TEV_KASEL_1;
TevRegID m_regOut = TEVPREV;
TevRegID m_cRegOut = TEVPREV;
TevRegID m_aRegOut = TEVPREV;
int m_lazyCInIdx = -1;
int m_lazyAInIdx = -1;
int m_lazyOutIdx = -1;
int m_lazyCOutIdx = -1;
int m_lazyAOutIdx = -1;
int m_texMapIdx = -1;
int m_texGenIdx = -1;
@ -240,6 +331,9 @@ struct GX : IBackend
int m_cRegMask = 0;
int m_cRegLazy = 0;
int m_aRegMask = 0;
int m_aRegLazy = 0;
int pickCLazy(Diagnostics& diag, const SourceLocation& loc, int stageIdx) const
{
int regMask = m_cRegMask;
@ -248,17 +342,11 @@ struct GX : IBackend
const TEVStage& stage = m_tevs[i];
for (int c=0 ; c<4 ; ++c)
{
if (stage.m_color[c] == CC_C0 ||
stage.m_color[c] == CC_A0 ||
stage.m_alpha[c] == CA_A0)
if (stage.m_color[c] == CC_C0)
regMask |= 1;
if (stage.m_color[c] == CC_C1 ||
stage.m_color[c] == CC_A1 ||
stage.m_alpha[c] == CA_A1)
if (stage.m_color[c] == CC_C1)
regMask |= 2;
if (stage.m_color[c] == CC_C2 ||
stage.m_color[c] == CC_A2 ||
stage.m_alpha[c] == CA_A2)
if (stage.m_color[c] == CC_C2)
regMask |= 4;
}
}
@ -271,6 +359,34 @@ struct GX : IBackend
return -1;
}
int pickALazy(Diagnostics& diag, const SourceLocation& loc, int stageIdx) const
{
int regMask = m_aRegMask;
for (int i=stageIdx+1 ; i<int(m_tevCount) ; ++i)
{
const TEVStage& stage = m_tevs[i];
for (int c=0 ; c<4 ; ++c)
{
if (stage.m_color[c] == CC_A0 ||
stage.m_alpha[c] == CA_A0)
regMask |= 1;
if (stage.m_color[c] == CC_A1 ||
stage.m_alpha[c] == CA_A1)
regMask |= 2;
if (stage.m_color[c] == CC_A2 ||
stage.m_alpha[c] == CA_A2)
regMask |= 4;
}
}
for (int i=0 ; i<3 ; ++i)
if (!(regMask & (1 << i)))
return i;
diag.reportBackendErr(loc, "TEV A Register overflow");
return -1;
}
enum BlendFactor
{
BL_ZERO,
@ -285,7 +401,7 @@ struct GX : IBackend
BlendFactor m_blendSrc;
BlendFactor m_blendDst;
struct Color
struct Color : Athena::io::DNA<Athena::BigEndian>
{
union
{
@ -315,6 +431,11 @@ struct GX : IBackend
bool operator!=(const Color& other) const {return num != other.num;}
uint8_t operator[](size_t idx) const {return color[idx];}
uint8_t& operator[](size_t idx) {return color[idx];}
void read(Athena::io::IStreamReader& reader)
{reader.readUBytesToBuf(&num, 4);}
void write(Athena::io::IStreamWriter& writer) const
{writer.writeUBytes(reinterpret_cast<const atUint8*>(&num), 4);}
};
unsigned m_kcolorCount = 0;
Color m_kcolors[4];

View File

@ -132,7 +132,10 @@ GX::TraceResult GX::RecursiveTraceColor(const IR& ir, Diagnostics& diag, const I
{
const IR::Instruction& idxInst = inst.getChildInst(ir, 0);
unsigned idx = unsigned(idxInst.getImmVec().vec[0]);
m_cRegMask |= 1 << idx;
if (swizzleAlpha)
m_aRegMask |= 1 << idx;
else
m_cRegMask |= 1 << idx;
return TraceResult(TevColorArg((swizzleAlpha ? CC_A0 : CC_C0) + idx * 2));
}
else if (!name.compare("Lighting"))
@ -207,10 +210,10 @@ GX::TraceResult GX::RecursiveTraceColor(const IR& ir, Diagnostics& diag, const I
TEVStage* b = bTrace.tevStage;
if (b->m_prev != a)
{
a->m_regOut = TEVLAZY;
a->m_cRegOut = TEVLAZY;
b->m_color[3] = CC_LAZY;
b->m_lazyCInIdx = m_cRegLazy;
a->m_lazyOutIdx = m_cRegLazy++;
a->m_lazyCOutIdx = m_cRegLazy++;
}
else if (b == &m_tevs[m_tevCount-1] &&
a->m_texMapIdx == b->m_texMapIdx && a->m_texGenIdx == b->m_texGenIdx &&
@ -255,14 +258,14 @@ GX::TraceResult GX::RecursiveTraceColor(const IR& ir, Diagnostics& diag, const I
TEVStage* b = bTrace.tevStage;
if (b->m_prev != a)
{
a->m_regOut = TEVLAZY;
a->m_cRegOut = TEVLAZY;
b->m_color[3] = CC_LAZY;
b->m_lazyCInIdx = m_cRegLazy;
a->m_lazyOutIdx = m_cRegLazy++;
a->m_lazyCOutIdx = m_cRegLazy++;
}
else
b->m_color[3] = CC_CPREV;
b->m_op = TEV_SUB;
b->m_cop = TEV_SUB;
return TraceResult(b);
}
else if (aTrace.type == TraceResult::TraceTEVStage &&
@ -273,7 +276,7 @@ GX::TraceResult GX::RecursiveTraceColor(const IR& ir, Diagnostics& diag, const I
diag.reportBackendErr(inst.m_loc, "unable to modify TEV stage for subtract combine");
a->m_color[3] = bTrace.tevColorArg;
a->m_kColor = newKColor;
a->m_op = TEV_SUB;
a->m_cop = TEV_SUB;
return TraceResult(a);
}
break;
@ -289,10 +292,10 @@ GX::TraceResult GX::RecursiveTraceColor(const IR& ir, Diagnostics& diag, const I
diag.reportBackendErr(inst.m_loc, "unable to modify TEV stage for multiply combine");
if (b->m_prev != a)
{
a->m_regOut = TEVLAZY;
a->m_cRegOut = TEVLAZY;
b->m_color[2] = CC_LAZY;
b->m_lazyCInIdx = m_cRegLazy;
a->m_lazyOutIdx = m_cRegLazy++;
a->m_lazyCOutIdx = m_cRegLazy++;
}
else
b->m_color[2] = CC_CPREV;
@ -316,7 +319,7 @@ GX::TraceResult GX::RecursiveTraceColor(const IR& ir, Diagnostics& diag, const I
TEVStage* a = aTrace.tevStage;
if (a->m_color[1] != CC_ZERO)
{
if (a->m_regOut != TEVPREV)
if (a->m_cRegOut != TEVPREV)
diag.reportBackendErr(inst.m_loc, "unable to modify TEV stage for multiply combine");
TEVStage& stage = addTEVStage(diag, inst.m_loc);
stage.m_color[1] = CC_CPREV;
@ -336,7 +339,7 @@ GX::TraceResult GX::RecursiveTraceColor(const IR& ir, Diagnostics& diag, const I
TEVStage* b = bTrace.tevStage;
if (b->m_color[1] != CC_ZERO)
{
if (b->m_regOut != TEVPREV)
if (b->m_cRegOut != TEVPREV)
diag.reportBackendErr(inst.m_loc, "unable to modify TEV stage for multiply combine");
TEVStage& stage = addTEVStage(diag, inst.m_loc);
stage.m_color[1] = aTrace.tevColorArg;
@ -360,8 +363,8 @@ GX::TraceResult GX::RecursiveTraceColor(const IR& ir, Diagnostics& diag, const I
}
case IR::OpSwizzle:
{
if (inst.m_swizzle.m_idxs[0] == 3 && inst.m_swizzle.m_idxs[1] == -1 &&
inst.m_swizzle.m_idxs[2] == -1 && inst.m_swizzle.m_idxs[3] == -1)
if (inst.m_swizzle.m_idxs[0] == 3 && inst.m_swizzle.m_idxs[1] == 3 &&
inst.m_swizzle.m_idxs[2] == 3 && inst.m_swizzle.m_idxs[3] == -1)
{
const IR::Instruction& cInst = inst.getChildInst(ir, 0);
if (cInst.m_op != IR::OpCall)
@ -428,7 +431,7 @@ GX::TraceResult GX::RecursiveTraceAlpha(const IR& ir, Diagnostics& diag, const I
{
const IR::Instruction& idxInst = inst.getChildInst(ir, 0);
unsigned idx = unsigned(idxInst.getImmVec().vec[0]);
m_cRegMask |= 1 << idx;
m_aRegMask |= 1 << idx;
return TraceResult(TevAlphaArg(CA_A0 + idx));
}
else if (!name.compare("Lighting"))
@ -493,14 +496,14 @@ GX::TraceResult GX::RecursiveTraceAlpha(const IR& ir, Diagnostics& diag, const I
TEVStage* b = bTrace.tevStage;
if (b->m_prev != a)
{
a->m_regOut = TEVLAZY;
a->m_aRegOut = TEVLAZY;
b->m_alpha[3] = CA_LAZY;
if (a->m_lazyOutIdx != -1)
b->m_lazyAInIdx = a->m_lazyOutIdx;
if (a->m_lazyAOutIdx != -1)
b->m_lazyAInIdx = a->m_lazyAOutIdx;
else
{
b->m_lazyAInIdx = m_cRegLazy;
a->m_lazyOutIdx = m_cRegLazy++;
b->m_lazyAInIdx = m_aRegLazy;
a->m_lazyAOutIdx = m_aRegLazy++;
}
}
else
@ -536,18 +539,18 @@ GX::TraceResult GX::RecursiveTraceAlpha(const IR& ir, Diagnostics& diag, const I
{
TEVStage* a = aTrace.tevStage;
TEVStage* b = bTrace.tevStage;
if (b->m_op != TEV_SUB)
if (b->m_aop != TEV_SUB)
diag.reportBackendErr(inst.m_loc, "unable to integrate alpha subtraction into stage chain");
if (b->m_prev != a)
{
a->m_regOut = TEVLAZY;
a->m_aRegOut = TEVLAZY;
b->m_alpha[3] = CA_LAZY;
if (a->m_lazyOutIdx != -1)
b->m_lazyAInIdx = a->m_lazyOutIdx;
if (a->m_lazyAOutIdx != -1)
b->m_lazyAInIdx = a->m_lazyAOutIdx;
else
{
b->m_lazyAInIdx = m_cRegLazy;
a->m_lazyOutIdx = m_cRegLazy++;
b->m_lazyAInIdx = m_aRegLazy;
a->m_lazyAOutIdx = m_aRegLazy++;
}
}
else
@ -558,7 +561,7 @@ GX::TraceResult GX::RecursiveTraceAlpha(const IR& ir, Diagnostics& diag, const I
bTrace.type == TraceResult::TraceTEVAlphaArg)
{
TEVStage* a = aTrace.tevStage;
if (a->m_op != TEV_SUB)
if (a->m_aop != TEV_SUB)
diag.reportBackendErr(inst.m_loc, "unable to integrate alpha subtraction into stage chain");
if (a->m_alpha[3] != CA_ZERO)
diag.reportBackendErr(inst.m_loc, "unable to modify TEV stage for add combine");
@ -579,10 +582,10 @@ GX::TraceResult GX::RecursiveTraceAlpha(const IR& ir, Diagnostics& diag, const I
diag.reportBackendErr(inst.m_loc, "unable to modify TEV stage for multiply combine");
if (b->m_prev != a)
{
a->m_regOut = TEVLAZY;
a->m_aRegOut = TEVLAZY;
b->m_alpha[2] = CA_LAZY;
b->m_lazyAInIdx = m_cRegLazy;
a->m_lazyOutIdx = m_cRegLazy++;
b->m_lazyAInIdx = m_aRegLazy;
a->m_lazyAOutIdx = m_aRegLazy++;
}
else
b->m_alpha[2] = CA_APREV;
@ -607,7 +610,7 @@ GX::TraceResult GX::RecursiveTraceAlpha(const IR& ir, Diagnostics& diag, const I
TEVStage* a = aTrace.tevStage;
if (a->m_alpha[1] != CA_ZERO)
{
if (a->m_regOut != TEVPREV)
if (a->m_aRegOut != TEVPREV)
diag.reportBackendErr(inst.m_loc, "unable to modify TEV stage for multiply combine");
TEVStage& stage = addTEVStage(diag, inst.m_loc);
stage.m_alpha[1] = CA_APREV;
@ -627,7 +630,7 @@ GX::TraceResult GX::RecursiveTraceAlpha(const IR& ir, Diagnostics& diag, const I
TEVStage* b = bTrace.tevStage;
if (b->m_alpha[1] != CA_ZERO)
{
if (b->m_regOut != TEVPREV)
if (b->m_aRegOut != TEVPREV)
diag.reportBackendErr(inst.m_loc, "unable to modify TEV stage for multiply combine");
TEVStage& stage = addTEVStage(diag, inst.m_loc);
stage.m_alpha[1] = aTrace.tevAlphaArg;
@ -651,8 +654,8 @@ GX::TraceResult GX::RecursiveTraceAlpha(const IR& ir, Diagnostics& diag, const I
}
case IR::OpSwizzle:
{
if (inst.m_swizzle.m_idxs[0] == 3 && inst.m_swizzle.m_idxs[1] == -1 &&
inst.m_swizzle.m_idxs[2] == -1 && inst.m_swizzle.m_idxs[3] == -1)
if (inst.m_swizzle.m_idxs[0] == 3 && inst.m_swizzle.m_idxs[1] == 3 &&
inst.m_swizzle.m_idxs[2] == 3 && inst.m_swizzle.m_idxs[3] == -1)
{
const IR::Instruction& cInst = inst.getChildInst(ir, 0);
if (cInst.m_op != IR::OpCall)
@ -671,12 +674,16 @@ GX::TraceResult GX::RecursiveTraceAlpha(const IR& ir, Diagnostics& diag, const I
void GX::reset(const IR& ir, Diagnostics& diag)
{
diag.setBackend("GX");
m_tevCount = 0;
m_tcgCount = 0;
m_texMtxCount = 0;
m_kcolorCount = 0;
m_cRegMask = 0;
m_cRegLazy = 0;
m_aRegMask = 0;
m_aRegLazy = 0;
m_alphaTraceStage = -1;
/* Final instruction is the root call by hecl convention */
@ -730,18 +737,28 @@ void GX::reset(const IR& ir, Diagnostics& diag)
for (int i=0 ; i<int(m_tevCount) ; ++i)
{
TEVStage& stage = m_tevs[i];
if (stage.m_regOut == TEVLAZY)
if (stage.m_cRegOut == TEVLAZY)
{
int picked = pickCLazy(diag, stage.m_loc, i);
stage.m_regOut = TevRegID(TEVREG0 + picked);
stage.m_cRegOut = TevRegID(TEVREG0 + picked);
for (int j=i+1 ; j<int(m_tevCount) ; ++j)
{
TEVStage& nstage = m_tevs[j];
if (nstage.m_lazyCInIdx == stage.m_lazyOutIdx)
if (nstage.m_lazyCInIdx == stage.m_lazyCOutIdx)
for (int c=0 ; c<4 ; ++c)
if (nstage.m_color[c] == CC_LAZY)
nstage.m_color[c] = TevColorArg(CC_C0 + picked * 2);
if (nstage.m_lazyAInIdx == stage.m_lazyOutIdx)
}
}
if (stage.m_aRegOut == TEVLAZY)
{
int picked = pickALazy(diag, stage.m_loc, i);
stage.m_aRegOut = TevRegID(TEVREG0 + picked);
for (int j=i+1 ; j<int(m_tevCount) ; ++j)
{
TEVStage& nstage = m_tevs[j];
if (nstage.m_lazyAInIdx == stage.m_lazyAOutIdx)
for (int c=0 ; c<4 ; ++c)
if (nstage.m_alpha[c] == CA_LAZY)
nstage.m_alpha[c] = TevAlphaArg(CA_A0 + picked);
@ -749,8 +766,6 @@ void GX::reset(const IR& ir, Diagnostics& diag)
}
}
}
printf("");
}
}