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clang-p2996/libc/utils/gpu/server/rpc_server.cpp
Jinsong Ji e85a9f5540 libc: Prefix RPC Status code to avoid conflict in windows build (#119991) 
Somehow conflict with define in wingdi.h.

Fix build failures:

[ 52%] Building CXX object
projects/offload/plugins-nextgen/common/CMakeFiles/PluginCommon.dir/src/RPC.cpp.obj
In file included from
...llvm\offload\plugins-nextgen\common\src\RPC.cpp:16:
...\llvm\libc\shared\rpc.h(48,3): error: expected identifier
   48 |   ERROR = 0x1000,
      |   ^
c:\Program files (x86)\Windows
Kits\10\include\10.0.22000.0\um\wingdi.h(118,29): note: expanded from
macro 'ERROR'
  118 | #define ERROR               0
      |                             ^
...\llvm\offload\plugins-nextgen\common\src\RPC.cpp(75,17): error:
expected unqualified-id
   75 |     return rpc::ERROR;
      |                 ^
c:\Program files (x86)\Windows
Kits\10\include\10.0.22000.0\um\wingdi.h(118,29): note: expanded from
macro 'ERROR'
  118 | #define ERROR               0
      |                             ^
2 errors generated.
2024-12-15 09:35:44 -05:00

462 lines
15 KiB
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//===-- Shared memory RPC server instantiation ------------------*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
// Workaround for missing __has_builtin in < GCC 10.
#ifndef __has_builtin
#define __has_builtin(x) 0
#endif
// Make sure these are included first so they don't conflict with the system.
#include <limits.h>
#include "shared/rpc.h"
#include "shared/rpc_opcodes.h"
#include "src/__support/arg_list.h"
#include "src/stdio/printf_core/converter.h"
#include "src/stdio/printf_core/parser.h"
#include "src/stdio/printf_core/writer.h"
#include <algorithm>
#include <atomic>
#include <cstdio>
#include <cstring>
#include <memory>
#include <mutex>
#include <unordered_map>
#include <variant>
#include <vector>
using namespace LIBC_NAMESPACE;
using namespace LIBC_NAMESPACE::printf_core;
namespace {
struct TempStorage {
char *alloc(size_t size) {
storage.emplace_back(std::make_unique<char[]>(size));
return storage.back().get();
}
std::vector<std::unique_ptr<char[]>> storage;
};
} // namespace
enum Stream {
File = 0,
Stdin = 1,
Stdout = 2,
Stderr = 3,
};
// Get the associated stream out of an encoded number.
LIBC_INLINE ::FILE *to_stream(uintptr_t f) {
::FILE *stream = reinterpret_cast<FILE *>(f & ~0x3ull);
Stream type = static_cast<Stream>(f & 0x3ull);
if (type == Stdin)
return stdin;
if (type == Stdout)
return stdout;
if (type == Stderr)
return stderr;
return stream;
}
template <bool packed, uint32_t num_lanes>
static void handle_printf(rpc::Server::Port &port, TempStorage &temp_storage) {
FILE *files[num_lanes] = {nullptr};
// Get the appropriate output stream to use.
if (port.get_opcode() == LIBC_PRINTF_TO_STREAM ||
port.get_opcode() == LIBC_PRINTF_TO_STREAM_PACKED)
port.recv([&](rpc::Buffer *buffer, uint32_t id) {
files[id] = reinterpret_cast<FILE *>(buffer->data[0]);
});
else if (port.get_opcode() == LIBC_PRINTF_TO_STDOUT ||
port.get_opcode() == LIBC_PRINTF_TO_STDOUT_PACKED)
std::fill(files, files + num_lanes, stdout);
else
std::fill(files, files + num_lanes, stderr);
uint64_t format_sizes[num_lanes] = {0};
void *format[num_lanes] = {nullptr};
uint64_t args_sizes[num_lanes] = {0};
void *args[num_lanes] = {nullptr};
// Recieve the format string and arguments from the client.
port.recv_n(format, format_sizes,
[&](uint64_t size) { return temp_storage.alloc(size); });
// Parse the format string to get the expected size of the buffer.
for (uint32_t lane = 0; lane < num_lanes; ++lane) {
if (!format[lane])
continue;
WriteBuffer wb(nullptr, 0);
Writer writer(&wb);
internal::DummyArgList<packed> printf_args;
Parser<internal::DummyArgList<packed> &> parser(
reinterpret_cast<const char *>(format[lane]), printf_args);
for (FormatSection cur_section = parser.get_next_section();
!cur_section.raw_string.empty();
cur_section = parser.get_next_section())
;
args_sizes[lane] = printf_args.read_count();
}
port.send([&](rpc::Buffer *buffer, uint32_t id) {
buffer->data[0] = args_sizes[id];
});
port.recv_n(args, args_sizes,
[&](uint64_t size) { return temp_storage.alloc(size); });
// Identify any arguments that are actually pointers to strings on the client.
// Additionally we want to determine how much buffer space we need to print.
std::vector<void *> strs_to_copy[num_lanes];
int buffer_size[num_lanes] = {0};
for (uint32_t lane = 0; lane < num_lanes; ++lane) {
if (!format[lane])
continue;
WriteBuffer wb(nullptr, 0);
Writer writer(&wb);
internal::StructArgList<packed> printf_args(args[lane], args_sizes[lane]);
Parser<internal::StructArgList<packed>> parser(
reinterpret_cast<const char *>(format[lane]), printf_args);
for (FormatSection cur_section = parser.get_next_section();
!cur_section.raw_string.empty();
cur_section = parser.get_next_section()) {
if (cur_section.has_conv && cur_section.conv_name == 's' &&
cur_section.conv_val_ptr) {
strs_to_copy[lane].emplace_back(cur_section.conv_val_ptr);
// Get the minimum size of the string in the case of padding.
char c = '\0';
cur_section.conv_val_ptr = &c;
convert(&writer, cur_section);
} else if (cur_section.has_conv) {
// Ignore conversion errors for the first pass.
convert(&writer, cur_section);
} else {
writer.write(cur_section.raw_string);
}
}
buffer_size[lane] = writer.get_chars_written();
}
// Recieve any strings from the client and push them into a buffer.
std::vector<void *> copied_strs[num_lanes];
while (std::any_of(std::begin(strs_to_copy), std::end(strs_to_copy),
[](const auto &v) { return !v.empty() && v.back(); })) {
port.send([&](rpc::Buffer *buffer, uint32_t id) {
void *ptr = !strs_to_copy[id].empty() ? strs_to_copy[id].back() : nullptr;
buffer->data[1] = reinterpret_cast<uintptr_t>(ptr);
if (!strs_to_copy[id].empty())
strs_to_copy[id].pop_back();
});
uint64_t str_sizes[num_lanes] = {0};
void *strs[num_lanes] = {nullptr};
port.recv_n(strs, str_sizes,
[&](uint64_t size) { return temp_storage.alloc(size); });
for (uint32_t lane = 0; lane < num_lanes; ++lane) {
if (!strs[lane])
continue;
copied_strs[lane].emplace_back(strs[lane]);
buffer_size[lane] += str_sizes[lane];
}
}
// Perform the final formatting and printing using the LLVM C library printf.
int results[num_lanes] = {0};
for (uint32_t lane = 0; lane < num_lanes; ++lane) {
if (!format[lane])
continue;
char *buffer = temp_storage.alloc(buffer_size[lane]);
WriteBuffer wb(buffer, buffer_size[lane]);
Writer writer(&wb);
internal::StructArgList<packed> printf_args(args[lane], args_sizes[lane]);
Parser<internal::StructArgList<packed>> parser(
reinterpret_cast<const char *>(format[lane]), printf_args);
// Parse and print the format string using the arguments we copied from
// the client.
int ret = 0;
for (FormatSection cur_section = parser.get_next_section();
!cur_section.raw_string.empty();
cur_section = parser.get_next_section()) {
// If this argument was a string we use the memory buffer we copied from
// the client by replacing the raw pointer with the copied one.
if (cur_section.has_conv && cur_section.conv_name == 's') {
if (!copied_strs[lane].empty()) {
cur_section.conv_val_ptr = copied_strs[lane].back();
copied_strs[lane].pop_back();
} else {
cur_section.conv_val_ptr = nullptr;
}
}
if (cur_section.has_conv) {
ret = convert(&writer, cur_section);
if (ret == -1)
break;
} else {
writer.write(cur_section.raw_string);
}
}
results[lane] = fwrite(buffer, 1, writer.get_chars_written(), files[lane]);
if (results[lane] != writer.get_chars_written() || ret == -1)
results[lane] = -1;
}
// Send the final return value and signal completion by setting the string
// argument to null.
port.send([&](rpc::Buffer *buffer, uint32_t id) {
buffer->data[0] = static_cast<uint64_t>(results[id]);
buffer->data[1] = reinterpret_cast<uintptr_t>(nullptr);
});
}
template <uint32_t num_lanes>
rpc::Status handle_port_impl(rpc::Server::Port &port) {
TempStorage temp_storage;
switch (port.get_opcode()) {
case LIBC_WRITE_TO_STREAM:
case LIBC_WRITE_TO_STDERR:
case LIBC_WRITE_TO_STDOUT:
case LIBC_WRITE_TO_STDOUT_NEWLINE: {
uint64_t sizes[num_lanes] = {0};
void *strs[num_lanes] = {nullptr};
FILE *files[num_lanes] = {nullptr};
if (port.get_opcode() == LIBC_WRITE_TO_STREAM) {
port.recv([&](rpc::Buffer *buffer, uint32_t id) {
files[id] = reinterpret_cast<FILE *>(buffer->data[0]);
});
} else if (port.get_opcode() == LIBC_WRITE_TO_STDERR) {
std::fill(files, files + num_lanes, stderr);
} else {
std::fill(files, files + num_lanes, stdout);
}
port.recv_n(strs, sizes,
[&](uint64_t size) { return temp_storage.alloc(size); });
port.send([&](rpc::Buffer *buffer, uint32_t id) {
flockfile(files[id]);
buffer->data[0] = fwrite_unlocked(strs[id], 1, sizes[id], files[id]);
if (port.get_opcode() == LIBC_WRITE_TO_STDOUT_NEWLINE &&
buffer->data[0] == sizes[id])
buffer->data[0] += fwrite_unlocked("\n", 1, 1, files[id]);
funlockfile(files[id]);
});
break;
}
case LIBC_READ_FROM_STREAM: {
uint64_t sizes[num_lanes] = {0};
void *data[num_lanes] = {nullptr};
port.recv([&](rpc::Buffer *buffer, uint32_t id) {
data[id] = temp_storage.alloc(buffer->data[0]);
sizes[id] =
fread(data[id], 1, buffer->data[0], to_stream(buffer->data[1]));
});
port.send_n(data, sizes);
port.send([&](rpc::Buffer *buffer, uint32_t id) {
std::memcpy(buffer->data, &sizes[id], sizeof(uint64_t));
});
break;
}
case LIBC_READ_FGETS: {
uint64_t sizes[num_lanes] = {0};
void *data[num_lanes] = {nullptr};
port.recv([&](rpc::Buffer *buffer, uint32_t id) {
data[id] = temp_storage.alloc(buffer->data[0]);
const char *str = fgets(reinterpret_cast<char *>(data[id]),
buffer->data[0], to_stream(buffer->data[1]));
sizes[id] = !str ? 0 : std::strlen(str) + 1;
});
port.send_n(data, sizes);
break;
}
case LIBC_OPEN_FILE: {
uint64_t sizes[num_lanes] = {0};
void *paths[num_lanes] = {nullptr};
port.recv_n(paths, sizes,
[&](uint64_t size) { return temp_storage.alloc(size); });
port.recv_and_send([&](rpc::Buffer *buffer, uint32_t id) {
FILE *file = fopen(reinterpret_cast<char *>(paths[id]),
reinterpret_cast<char *>(buffer->data));
buffer->data[0] = reinterpret_cast<uintptr_t>(file);
});
break;
}
case LIBC_CLOSE_FILE: {
port.recv_and_send([&](rpc::Buffer *buffer, uint32_t id) {
FILE *file = reinterpret_cast<FILE *>(buffer->data[0]);
buffer->data[0] = fclose(file);
});
break;
}
case LIBC_EXIT: {
// Send a response to the client to signal that we are ready to exit.
port.recv_and_send([](rpc::Buffer *, uint32_t) {});
port.recv([](rpc::Buffer *buffer, uint32_t) {
int status = 0;
std::memcpy(&status, buffer->data, sizeof(int));
exit(status);
});
break;
}
case LIBC_ABORT: {
// Send a response to the client to signal that we are ready to abort.
port.recv_and_send([](rpc::Buffer *, uint32_t) {});
port.recv([](rpc::Buffer *, uint32_t) {});
abort();
break;
}
case LIBC_HOST_CALL: {
uint64_t sizes[num_lanes] = {0};
unsigned long long results[num_lanes] = {0};
void *args[num_lanes] = {nullptr};
port.recv_n(args, sizes,
[&](uint64_t size) { return temp_storage.alloc(size); });
port.recv([&](rpc::Buffer *buffer, uint32_t id) {
using func_ptr_t = unsigned long long (*)(void *);
auto func = reinterpret_cast<func_ptr_t>(buffer->data[0]);
results[id] = func(args[id]);
});
port.send([&](rpc::Buffer *buffer, uint32_t id) {
buffer->data[0] = static_cast<uint64_t>(results[id]);
});
break;
}
case LIBC_FEOF: {
port.recv_and_send([](rpc::Buffer *buffer, uint32_t) {
buffer->data[0] = feof(to_stream(buffer->data[0]));
});
break;
}
case LIBC_FERROR: {
port.recv_and_send([](rpc::Buffer *buffer, uint32_t) {
buffer->data[0] = ferror(to_stream(buffer->data[0]));
});
break;
}
case LIBC_CLEARERR: {
port.recv_and_send([](rpc::Buffer *buffer, uint32_t) {
clearerr(to_stream(buffer->data[0]));
});
break;
}
case LIBC_FSEEK: {
port.recv_and_send([](rpc::Buffer *buffer, uint32_t) {
buffer->data[0] =
fseek(to_stream(buffer->data[0]), static_cast<long>(buffer->data[1]),
static_cast<int>(buffer->data[2]));
});
break;
}
case LIBC_FTELL: {
port.recv_and_send([](rpc::Buffer *buffer, uint32_t) {
buffer->data[0] = ftell(to_stream(buffer->data[0]));
});
break;
}
case LIBC_FFLUSH: {
port.recv_and_send([](rpc::Buffer *buffer, uint32_t) {
buffer->data[0] = fflush(to_stream(buffer->data[0]));
});
break;
}
case LIBC_UNGETC: {
port.recv_and_send([](rpc::Buffer *buffer, uint32_t) {
buffer->data[0] =
ungetc(static_cast<int>(buffer->data[0]), to_stream(buffer->data[1]));
});
break;
}
case LIBC_PRINTF_TO_STREAM_PACKED:
case LIBC_PRINTF_TO_STDOUT_PACKED:
case LIBC_PRINTF_TO_STDERR_PACKED: {
handle_printf<true, num_lanes>(port, temp_storage);
break;
}
case LIBC_PRINTF_TO_STREAM:
case LIBC_PRINTF_TO_STDOUT:
case LIBC_PRINTF_TO_STDERR: {
handle_printf<false, num_lanes>(port, temp_storage);
break;
}
case LIBC_REMOVE: {
uint64_t sizes[num_lanes] = {0};
void *args[num_lanes] = {nullptr};
port.recv_n(args, sizes,
[&](uint64_t size) { return temp_storage.alloc(size); });
port.send([&](rpc::Buffer *buffer, uint32_t id) {
buffer->data[0] = static_cast<uint64_t>(
remove(reinterpret_cast<const char *>(args[id])));
});
break;
}
case LIBC_RENAME: {
uint64_t oldsizes[num_lanes] = {0};
uint64_t newsizes[num_lanes] = {0};
void *oldpath[num_lanes] = {nullptr};
void *newpath[num_lanes] = {nullptr};
port.recv_n(oldpath, oldsizes,
[&](uint64_t size) { return temp_storage.alloc(size); });
port.recv_n(newpath, newsizes,
[&](uint64_t size) { return temp_storage.alloc(size); });
port.send([&](rpc::Buffer *buffer, uint32_t id) {
buffer->data[0] = static_cast<uint64_t>(
rename(reinterpret_cast<const char *>(oldpath[id]),
reinterpret_cast<const char *>(newpath[id])));
});
break;
}
case LIBC_SYSTEM: {
uint64_t sizes[num_lanes] = {0};
void *args[num_lanes] = {nullptr};
port.recv_n(args, sizes,
[&](uint64_t size) { return temp_storage.alloc(size); });
port.send([&](rpc::Buffer *buffer, uint32_t id) {
buffer->data[0] = static_cast<uint64_t>(
system(reinterpret_cast<const char *>(args[id])));
});
break;
}
case LIBC_NOOP: {
port.recv([](rpc::Buffer *, uint32_t) {});
break;
}
default:
return rpc::RPC_UNHANDLED_OPCODE;
}
return rpc::RPC_SUCCESS;
}
namespace rpc {
// The implementation of this function currently lives in the utility directory
// at 'utils/gpu/server/rpc_server.cpp'.
rpc::Status handle_libc_opcodes(rpc::Server::Port &port, uint32_t num_lanes) {
switch (num_lanes) {
case 1:
return handle_port_impl<1>(port);
case 32:
return handle_port_impl<32>(port);
case 64:
return handle_port_impl<64>(port);
default:
return rpc::RPC_ERROR;
}
}
} // namespace rpc
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