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proxy_mutator.c
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proxy_mutator.c
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/* -*- Mode: C; tab-width: 4; c-basic-offset: 4; indent-tabs-mode: nil -*- */
#include "proxy.h"
/*
* !!!WARNING!!!
* This is an experimental interface and is not to be used in production until
* after this warning has been removed.
* The req/res mutator system is currently an experimental draft, merged to
* allow code experiments and further information gathering before completing
* the interface.
*
* it currently has bugs, unfinished features, and will not immediately
* release request or result buffers after a request completes.
*/
// space or \r\n
#define MIN_BUF_SPACE 2
enum mcp_mut_type {
MUT_REQ = 1,
MUT_RES,
};
enum mcp_mut_steptype {
mcp_mut_step_none = 0,
mcp_mut_step_cmdset,
mcp_mut_step_cmdcopy,
mcp_mut_step_keycopy,
mcp_mut_step_keyset,
mcp_mut_step_rescodeset,
mcp_mut_step_rescodecopy,
mcp_mut_step_reserr,
mcp_mut_step_flagset,
mcp_mut_step_flagcopy,
mcp_mut_step_valcopy,
mcp_mut_step_final, // not used.
};
enum mcp_mut_step_arg {
mcp_mut_step_arg_none = 0,
mcp_mut_step_arg_request,
mcp_mut_step_arg_response,
mcp_mut_step_arg_string,
mcp_mut_step_arg_int,
};
// START STEP STRUCTS
// struct forward declarations for entry/step function pointers
struct mcp_mut_step;
struct mcp_mutator;
struct mcp_mut_run;
struct mcp_mut_part;
typedef int (*mcp_mut_c)(lua_State *L, int tidx);
typedef int (*mcp_mut_i)(lua_State *L, int tidx, int sc, struct mcp_mutator *mut);
typedef int (*mcp_mut_r)(struct mcp_mut_run *run, struct mcp_mut_step *s, struct mcp_mut_part *p);
struct mcp_mut_entry {
const char *s; // string name
mcp_mut_c c; // argument checker
mcp_mut_i i; // argument initializer
mcp_mut_r n; // runtime length totaller
mcp_mut_r r; // runtime assembly
unsigned int t; // allowed object types
int rc; // number of results to expect
};
struct mcp_mut_string {
unsigned int str; // arena offset for match string.
unsigned int len;
};
struct mcp_mut_flag {
uint64_t bit; // flag converted for bitmask test
char f;
};
#define RESERR_ERROR 1
#define RESERR_ERROR_STR "ERROR"
#define RESERR_CLIENT 2
#define RESERR_CLIENT_STR "CLIENT_ERROR"
#define RESERR_SERVER 3
#define RESERR_SERVER_STR "SERVER_ERROR"
struct mcp_mut_flagval {
struct mcp_mut_flag flag;
struct mcp_mut_string str;
};
struct mcp_mut_step {
enum mcp_mut_steptype type;
unsigned int idx; // common: input argument position
enum mcp_mut_step_arg arg; // common: type of input argument
mcp_mut_r n; // totaller function
mcp_mut_r r; // data copy function
union {
struct mcp_mut_string string;
struct mcp_mut_flag flag;
struct mcp_mut_flagval flagval;
} c;
};
// END STEP STRUCTS
struct mcp_mutator {
enum mcp_mut_type type;
int scount;
unsigned int aused; // arena memory used
unsigned int rcount; // number of results to expect
char *arena; // string/data storage for steps
struct mcp_mut_step steps[];
};
// scratch space for steps between total and execution stages.
struct mcp_mut_part {
const char *src;
size_t slen;
};
// stack scratch variables for mutation execution
struct mcp_mut_run {
lua_State *L;
struct mcp_mutator *mut;
void *arg;
char *numbuf; // stack space for rendering numerics
char *d_pos; // current offset to the write string.
const char *vbuf; // buffer or ptr if a value is being attached
size_t vlen; // length of the actual value buffer.
};
#define mut_step_c(n) static int mcp_mutator_##n##_c(lua_State *L, int tidx)
#define mut_step_i(n) static int mcp_mutator_##n##_i(lua_State *L, int tidx, int sc, struct mcp_mutator *mut)
#define mut_step_r(n) static int mcp_mutator_##n##_r(struct mcp_mut_run *run, struct mcp_mut_step *s, struct mcp_mut_part *p)
#define mut_step_n(n) static int mcp_mutator_##n##_n(struct mcp_mut_run *run, struct mcp_mut_step *s, struct mcp_mut_part *p)
// PRIVATE INTERFACE
// COMMON ARG HANDLERS
static void _mut_check_idx(lua_State *L, int tidx) {
if (lua_getfield(L, tidx, "idx") != LUA_TNIL) {
luaL_checktype(L, -1, LUA_TNUMBER);
int isnum = 0;
lua_Integer i = lua_tointegerx(L, -1, &isnum);
if (!isnum) {
proxy_lua_ferror(L, "mutator step %d: must provide 'idx' argument as an integer", tidx);
}
if (i < 2) {
proxy_lua_ferror(L, "mutator step %d: 'idx' argument must be greater than 1", tidx);
}
} else {
proxy_lua_ferror(L, "mutator step %d: must provide 'idx' argument", tidx);
}
lua_pop(L, 1);
}
static size_t _mut_check_strlen(lua_State *L, int tidx, const char *n) {
size_t len = 0;
if (lua_getfield(L, tidx, n) != LUA_TNIL) {
lua_tolstring(L, -1, &len);
} else {
proxy_lua_ferror(L, "mutator step %d: must provide '%s' argument", tidx, n);
}
lua_pop(L, 1);
return len;
}
static void _mut_check_flag(lua_State *L, int tidx) {
if (lua_getfield(L, tidx, "flag") != LUA_TNIL) {
size_t len = 0;
const char *flag = lua_tolstring(L, -1, &len);
if (len != 1) {
proxy_lua_ferror(L, "mutator step %d: 'flag' must be a single character", tidx);
}
if (mcp_is_flag_invalid(flag[0])) {
proxy_lua_ferror(L, "mutator step %d: 'flag' must be alphanumeric", tidx);
}
} else {
proxy_lua_ferror(L, "mutator step %d: must provide 'flag' argument", tidx);
}
lua_pop(L, 1); // val or nil
}
static void _mut_init_flag(lua_State *L, int tidx, struct mcp_mut_flag *c) {
if (lua_getfield(L, tidx, "flag") != LUA_TNIL) {
const char *flag = lua_tostring(L, -1);
c->f = flag[0];
c->bit = (uint64_t)1 << (c->f - 65);
}
lua_pop(L, 1); // val or nil
}
// END COMMMON ARG HANDLERS
// START STEPS
// FIXME: decide on if this should take an mcp.CMD_etc instead, or at least
// optionally.
// we could also parse this into the int to avoid copying a string here.
// FIXME: track step progress and validate we're the first one.
mut_step_c(cmdset) {
size_t len = 0;
if (lua_getfield(L, tidx, "cmd") != LUA_TNIL) {
lua_tolstring(L, -1, &len);
// TODO: know either exact max length or parse for valid commands
// this small sanity check should help against user error for now.
if (len > 20) {
proxy_lua_ferror(L, "mutator step %d: 'cmd' too long", tidx);
}
} else {
proxy_lua_ferror(L, "mutator step %d: must provide 'cmd' argument", tidx);
}
lua_pop(L, 1);
return len;
}
mut_step_i(cmdset) {
struct mcp_mut_step *s = &mut->steps[sc];
struct mcp_mut_string *c = &s->c.string;
size_t len = 0;
if (lua_getfield(L, tidx, "cmd") != LUA_TNIL) {
const char *cmd = lua_tolstring(L, -1, &len);
c->str = mut->aused;
c->len = len;
char *a = mut->arena + mut->aused;
memcpy(a, cmd, len);
mut->aused += len;
}
lua_pop(L, 1);
return 0;
}
mut_step_n(cmdset) {
struct mcp_mut_string *c = &s->c.string;
return c->len;
}
mut_step_r(cmdset) {
struct mcp_mutator *mut = run->mut;
struct mcp_mut_string *c = &s->c.string;
const char *str = mut->arena + c->str;
memcpy(run->d_pos, str, c->len);
run->d_pos += c->len;
return 0;
}
// TODO: validate we're at the right stage to copy a command (no command set)
mut_step_c(cmdcopy) {
_mut_check_idx(L, tidx);
return 0;
}
mut_step_i(cmdcopy) {
struct mcp_mut_step *s = &mut->steps[sc];
if (lua_getfield(L, tidx, "idx") != LUA_TNIL) {
s->idx = lua_tointeger(L, -1);
}
lua_pop(L, 1);
return 0;
}
mut_step_n(cmdcopy) {
unsigned idx = s->idx;
// TODO: validate metatable matches or pull from cached entry
mcp_request_t *srq = lua_touserdata(run->L, idx);
// command must be at the start
const char *cmd = srq->pr.request;
// command ends at the first token
int clen = srq->pr.tokens[1];
if (cmd[clen] == ' ') {
clen--;
}
p->src = cmd;
p->slen = clen;
return clen;
}
mut_step_r(cmdcopy) {
memcpy(run->d_pos, p->src, p->slen);
run->d_pos += p->slen;
return 0;
}
// TODO: validate a cmd is already slated to be set
// NOTE: we might need to know the integer CMD because key position can move
// with the stupid GAT command.
mut_step_c(keycopy) {
_mut_check_idx(L, tidx);
return 0;
}
// FIXME: idx_i_g?
mut_step_i(keycopy) {
struct mcp_mut_step *s = &mut->steps[sc];
if (lua_getfield(L, tidx, "idx") != LUA_TNIL) {
s->idx = lua_tointeger(L, -1);
}
lua_pop(L, 1);
return 0;
}
mut_step_n(keycopy) {
unsigned idx = s->idx;
// TODO: validate metatable table matches or pull from cached entry
mcp_request_t *srq = lua_touserdata(run->L, idx);
p->src = MCP_PARSER_KEY(srq->pr);
p->slen = srq->pr.klen;
return p->slen;
}
mut_step_r(keycopy) {
memcpy(run->d_pos, p->src, p->slen);
run->d_pos += p->slen;
return 0;
}
// TODO: check we're okay to set a key
mut_step_c(keyset) {
size_t len = 0;
if (lua_getfield(L, tidx, "str") != LUA_TNIL) {
lua_tolstring(L, -1, &len);
if (len < 1) {
proxy_lua_ferror(L, "mutator step %d: 'str' must have nonzero length", tidx);
}
} else {
proxy_lua_ferror(L, "mutator step %d: must provide 'str' argument", tidx);
}
lua_pop(L, 1); // val or nil
return len;
}
mut_step_i(keyset) {
struct mcp_mut_step *s = &mut->steps[sc];
struct mcp_mut_string *c = &s->c.string;
size_t len = 0;
// store our match string in the arena space that we reserved before.
if (lua_getfield(L, tidx, "str") != LUA_TNIL) {
const char *str = lua_tolstring(L, -1, &len);
c->str = mut->aused;
c->len = len;
char *a = mut->arena + mut->aused;
memcpy(a, str, len);
mut->aused += len;
}
lua_pop(L, 1); // val or nil
return len;
}
mut_step_n(keyset) {
struct mcp_mut_string *c = &s->c.string;
return c->len;
}
mut_step_r(keyset) {
struct mcp_mutator *mut = run->mut;
struct mcp_mut_string *c = &s->c.string;
const char *str = mut->arena + c->str;
memcpy(run->d_pos, str, c->len);
run->d_pos += c->len;
return 0;
}
// TODO: ensure step is first
// TODO: pre-validate that it's an accepted code?
mut_step_c(rescodeset) {
return _mut_check_strlen(L, tidx, "str");
}
mut_step_i(rescodeset) {
struct mcp_mut_step *s = &mut->steps[sc];
struct mcp_mut_string *c = &s->c.string;
size_t len = 0;
if (lua_getfield(L, tidx, "str") != LUA_TNIL) {
const char *str = lua_tolstring(L, -1, &len);
c->str = mut->aused;
c->len = len;
char *a = mut->arena + mut->aused;
memcpy(a, str, len);
mut->aused += len;
}
lua_pop(L, 1);
return 0;
}
mut_step_n(rescodeset) {
struct mcp_mut_string *c = &s->c.string;
return c->len;
}
mut_step_r(rescodeset) {
struct mcp_mutator *mut = run->mut;
struct mcp_mut_string *c = &s->c.string;
const char *str = mut->arena + c->str;
memcpy(run->d_pos, str, c->len);
run->d_pos += c->len;
return 0;
}
// TODO: check we're the first step
mut_step_c(rescodecopy) {
_mut_check_idx(L, tidx);
return 0;
}
mut_step_i(rescodecopy) {
struct mcp_mut_step *s = &mut->steps[sc];
if (lua_getfield(L, tidx, "idx") != LUA_TNIL) {
s->idx = lua_tointeger(L, -1);
}
lua_pop(L, 1);
return 0;
}
mut_step_n(rescodecopy) {
unsigned idx = s->idx;
// TODO: validate metatable matches or pull from cached entry
mcp_resp_t *srs = lua_touserdata(run->L, idx);
// TODO: can't recover the exact from the mcmc resp object, so lets make
// sure it's tokenized and copy the first token.
if (srs->resp.type == MCMC_RESP_META) {
mcmc_tokenize_res(srs->buf, srs->resp.reslen, &srs->tok);
} else {
// FIXME: above only does meta responses
assert(1 == 0);
}
int len = 0;
p->src = mcmc_token_get(srs->buf, &srs->tok, 0, &len);
p->slen = len;
return len;
}
// TODO: take a string or number from that position.
mut_step_r(rescodecopy) {
// FIXME: error propagation
// FIXME: can we do all the error handling in the totalling phase?
if (p->slen < 2) {
return -1;
}
memcpy(run->d_pos, p->src, p->slen);
run->d_pos += p->slen;
return 0;
}
// TODO: can be no other steps after an error is set.
mut_step_c(reserr) {
size_t total = 0;
char *code = NULL;
// FIXME: add code length to len
if (lua_getfield(L, tidx, "code") != LUA_TNIL) {
const char *val = lua_tostring(L, -1);
if (strcmp(val, "error") == 0) {
code = RESERR_ERROR_STR;
} else if (strcmp(val, "server") == 0) {
code = RESERR_SERVER_STR;
} else if (strcmp(val, "client") == 0) {
code = RESERR_CLIENT_STR;
} else {
proxy_lua_ferror(L, "mutator step %d: mode must be 'error', server', or 'client'", tidx);
}
total += strlen(code);
} else {
proxy_lua_ferror(L, "mutator step %d: must provide 'mode' argument", tidx);
}
lua_pop(L, 1);
if (lua_getfield(L, tidx, "msg") != LUA_TNIL) {
size_t len = 0;
lua_tolstring(L, -1, &len);
if (len < 1) {
proxy_lua_ferror(L, "mutator step %d: 'msg' must be a nonzero length string", tidx);
}
total += len + 1; // room for space between code and msg
}
lua_pop(L, 1);
return total;
}
mut_step_i(reserr) {
struct mcp_mut_step *s = &mut->steps[sc];
struct mcp_mut_string *c = &s->c.string;
size_t len = 0;
const char *code = NULL;
char *a = mut->arena + mut->aused;
if (lua_getfield(L, tidx, "code") != LUA_TNIL) {
const char *val = lua_tostring(L, -1);
if (strcmp(val, "error") == 0) {
code = RESERR_ERROR_STR;
} else if (strcmp(val, "server") == 0) {
code = RESERR_SERVER_STR;
} else if (strcmp(val, "client") == 0) {
code = RESERR_CLIENT_STR;
} else {
// shouldn't be possible
proxy_lua_ferror(L, "mutator step %d: code must be 'error', server', or 'client'", tidx);
}
size_t clen = strlen(code);
memcpy(a, code, clen);
a += clen;
*a = ' ';
a++;
mut->aused += clen + 1;
} else {
proxy_lua_ferror(L, "mutator step %d: must provide 'code' argument", tidx);
}
lua_pop(L, 1);
if (lua_getfield(L, tidx, "msg") != LUA_TNIL) {
const char *str = lua_tolstring(L, -1, &len);
c->str = mut->aused;
c->len = len;
memcpy(a, str, len);
mut->aused += len;
} else {
// TODO: note no error msg
}
lua_pop(L, 1);
return len;
}
mut_step_n(reserr) {
struct mcp_mut_string *c = &s->c.string;
return c->len;
}
mut_step_r(reserr) {
struct mcp_mutator *mut = run->mut;
struct mcp_mut_string *c = &s->c.string;
const char *str = mut->arena + c->str;
int len = c->len;
// set error code first
memcpy(run->d_pos, str, len);
run->d_pos += len;
return 0;
}
// TODO: track which flags we've already set and error on dupes
mut_step_c(flagset) {
_mut_check_flag(L, tidx);
size_t len = 0;
int vtype = lua_getfield(L, tidx, "val");
if (vtype == LUA_TNUMBER || vtype == LUA_TSTRING) {
// this converts the arg into a string for us.
lua_tolstring(L, -1, &len);
} else if (vtype != LUA_TNIL) {
proxy_lua_ferror(L, "mutator step %d: unsupported type for 'val'", tidx);
}
lua_pop(L, 1);
return len;
}
mut_step_i(flagset) {
struct mcp_mut_step *s = &mut->steps[sc];
struct mcp_mut_flagval *c = &s->c.flagval;
size_t len = 0;
_mut_init_flag(L, tidx, &c->flag);
if (lua_getfield(L, tidx, "val") != LUA_TNIL) {
const char *str = lua_tolstring(L, -1, &len);
c->str.str = mut->aused;
c->str.len = len;
char *a = mut->arena + mut->aused;
memcpy(a, str, len);
mut->aused += len;
}
lua_pop(L, 1);
return len;
}
mut_step_n(flagset) {
struct mcp_mut_flagval *c = &s->c.flagval;
return c->str.len + 1; // room for flag
}
// TODO: validate we're okay to set flags.
// FIXME: triple check that this is actually the same code for req vs res?
// seems like it is.
mut_step_r(flagset) {
struct mcp_mutator *mut = run->mut;
struct mcp_mut_flagval *c = &s->c.flagval;
const char *str = mut->arena + c->str.str;
int len = c->str.len;
*(run->d_pos) = c->flag.f;
run->d_pos++;
if (len > 0) {
memcpy(run->d_pos, str, len);
run->d_pos += len;
}
return 0;
}
mut_step_c(flagcopy) {
_mut_check_flag(L, tidx);
_mut_check_idx(L, tidx);
return 0;
}
// TODO: maybe: optional default val if copy source missing
mut_step_i(flagcopy) {
struct mcp_mut_step *s = &mut->steps[sc];
struct mcp_mut_flag *c = &s->c.flag;
_mut_init_flag(L, tidx, c);
if (lua_getfield(L, tidx, "idx") != LUA_TNIL) {
s->idx = lua_tointeger(L, -1);
}
lua_pop(L, 1);
return 0;
}
// TODO: any reason for a req to pull from a res or vice versa?
// FIXME: handling when source flag doesn't exist might need a special case.
mut_step_n(flagcopy) {
struct mcp_mutator *mut = run->mut;
struct mcp_mut_flag *c = &s->c.flag;
unsigned idx = s->idx;
// TODO: validate idx or use cached entry.
if (mut->type == MUT_REQ) {
mcp_request_t *srq = lua_touserdata(run->L, idx);
if (srq->pr.cmd_type != CMD_TYPE_META) {
return -1;
}
if (srq->pr.t.meta.flags & c->bit) {
const char *tok = NULL;
size_t tlen = 0;
mcp_request_find_flag_token(srq, c->f, &tok, &tlen);
if (tlen > 0) {
p->src = tok;
p->slen = tlen;
} else {
p->slen = 0;
}
}
} else {
mcp_resp_t *srs = lua_touserdata(run->L, idx);
if (srs->resp.type != MCMC_RESP_META) {
// FIXME: error, can't copy flag from non-meta res
return -1;
}
mcmc_tokenize_res(srs->buf, srs->resp.reslen, &srs->tok);
if (mcmc_token_has_flag_bit(&srs->tok, c->bit) == MCMC_OK) {
// flag exists, so copy that in.
// realistically this func is only used if we're also copying a
// token, so we look for that too.
// could add an option to avoid checking for a token?
int len = 0;
const char *tok = mcmc_token_get_flag(srs->buf, &srs->tok, c->f, &len);
if (len > 0) {
p->src = tok;
p->slen = len;
} else {
p->slen = 0;
}
}
}
return 0;
}
mut_step_r(flagcopy) {
struct mcp_mut_flag *c = &s->c.flag;
*(run->d_pos) = c->f;
run->d_pos++;
if (p->slen) {
memcpy(run->d_pos, p->src, p->slen);
run->d_pos += p->slen;
}
return 0;
}
// TODO: check that the value hasn't been set yet.
mut_step_c(valcopy) {
_mut_check_idx(L, tidx);
// TODO: lift to common func
if (lua_getfield(L, tidx, "arg") == LUA_TSTRING) {
const char *a = lua_tostring(L, -1);
if (strcmp(a, "request") != 0 &&
strcmp(a, "response") != 0 &&
strcmp(a, "string") != 0 &&
strcmp(a, "int") != 0) {
proxy_lua_ferror(L, "mutator step %d: 'arg' must be request, response, string or int", tidx);
}
} else {
proxy_lua_ferror(L, "mutator step %d: missing 'arg' for input type", tidx);
}
lua_pop(L, 1);
return 0;
}
mut_step_i(valcopy) {
struct mcp_mut_step *s = &mut->steps[sc];
if (lua_getfield(L, tidx, "idx") != LUA_TNIL) {
s->idx = lua_tointeger(L, -1);
}
lua_pop(L, 1);
// TODO: lift to common func
if (lua_getfield(L, tidx, "arg") == LUA_TSTRING) {
const char *a = lua_tostring(L, -1);
if (strcmp(a, "request") == 0) {
s->arg = mcp_mut_step_arg_request;
} else if (strcmp(a, "response") == 0) {
s->arg = mcp_mut_step_arg_response;
} else if (strcmp(a, "string") == 0) {
s->arg = mcp_mut_step_arg_string;
} else if (strcmp(a, "int") == 0) {
s->arg = mcp_mut_step_arg_int;
} else {
proxy_lua_ferror(L, "mutator step %d: 'arg' must be request, response, string or int", tidx);
}
}
lua_pop(L, 1);
return 0;
}
mut_step_n(valcopy) {
lua_State *L = run->L;
unsigned idx = s->idx;
// extract the string + length we need to copy
mcp_request_t *srq;
//mcp_resp_t *srs;
// TODO: lift to common func?
// parts of it? with callback?
switch (s->arg) {
case mcp_mut_step_arg_none:
// can't get here.
break;
case mcp_mut_step_arg_request:
lua_getmetatable(L, idx);
lua_getiuservalue(L, 1, MUT_REQ);
if (lua_rawequal(L, -1, -2) == 0) {
// FIXME: error propagation
return -1;
}
lua_pop(L, 2);
srq = lua_touserdata(L, idx);
if (srq->pr.vbuf) {
run->vbuf = srq->pr.vbuf;
run->vlen = srq->pr.vlen;
}
break;
case mcp_mut_step_arg_response:
lua_getmetatable(L, idx);
lua_getiuservalue(L, 1, MUT_RES);
if (lua_rawequal(L, -1, -2) == 0) {
// FIXME: error propagation
return -1;
}
lua_pop(L, 2);
assert(1 == 0);
//srs = lua_touserdata(L, idx);
// TODO: need to locally parse the result to get the actual val
// offsets until later refactoring takes place.
break;
case mcp_mut_step_arg_string:
if (lua_isstring(L, idx)) {
// TODO: do we require the user supplies "\r\n"?
// detect it here and add a flag or adjust or etc?
run->vbuf = lua_tolstring(L, idx, &run->vlen);
}
break;
case mcp_mut_step_arg_int:
// TODO: just do number instead of int? meh.
// we want to not auto-convert this to a string.
lua_isnumber(L, idx);
assert(1 == 0); // TODO: unimplemented.
break;
}
// count the number of digits in vlen to reserve space.
//
// oddly algorithms to count digits and write digits are similar (outside
// of hyper optimization via bit math), so just reuse the same code here.
// if I can ever get arena allocations to work and remove the pre-calc
// steps this is moot anyway.
char temp[22];
const char *e = itoa_u64(run->vlen, temp);
return e - temp;
}
// print the vlen into the buffer
// we remove the \r\n from the protocol length
mut_step_r(valcopy) {
run->d_pos = itoa_u64(run->vlen-2, run->d_pos);
return 0;
}
// END STEPS
static const struct mcp_mut_entry mcp_mut_entries[] = {
[mcp_mut_step_none] = {NULL, NULL, NULL, NULL, NULL, 0, 0},
[mcp_mut_step_cmdset] = {"cmdset", mcp_mutator_cmdset_c, mcp_mutator_cmdset_i, mcp_mutator_cmdset_n, mcp_mutator_cmdset_r, MUT_REQ, 0},
[mcp_mut_step_cmdcopy] = {"cmdcopy", mcp_mutator_cmdcopy_c, mcp_mutator_cmdcopy_i, mcp_mutator_cmdcopy_n, mcp_mutator_cmdcopy_r, MUT_REQ, 0},
[mcp_mut_step_keycopy] = {"keycopy", mcp_mutator_keycopy_c, mcp_mutator_keycopy_i, mcp_mutator_keycopy_n, mcp_mutator_keycopy_r, MUT_REQ, 0},
[mcp_mut_step_keyset] = {"keyset", mcp_mutator_keyset_c, mcp_mutator_keyset_i, mcp_mutator_keyset_n, mcp_mutator_keyset_r, MUT_REQ, 0},
[mcp_mut_step_rescodeset] = {"rescodeset", mcp_mutator_rescodeset_c, mcp_mutator_rescodeset_i, mcp_mutator_rescodeset_n, mcp_mutator_rescodeset_r, MUT_RES, 0},
[mcp_mut_step_rescodecopy] = {"rescodecopy", mcp_mutator_rescodecopy_c, mcp_mutator_rescodecopy_i, mcp_mutator_rescodecopy_n, mcp_mutator_rescodecopy_r, MUT_RES, 0},
[mcp_mut_step_reserr] = {"reserr", mcp_mutator_reserr_c, mcp_mutator_reserr_i, mcp_mutator_reserr_n, mcp_mutator_reserr_r, MUT_RES, 0},
[mcp_mut_step_flagset] = {"flagset", mcp_mutator_flagset_c, mcp_mutator_flagset_i, mcp_mutator_flagset_n, mcp_mutator_flagset_r, MUT_REQ|MUT_RES, 0},
[mcp_mut_step_flagcopy] = {"flagcopy", mcp_mutator_flagcopy_c, mcp_mutator_flagcopy_i, mcp_mutator_flagcopy_n, mcp_mutator_flagcopy_r, MUT_REQ|MUT_RES, 0},
[mcp_mut_step_valcopy] = {"valcopy", mcp_mutator_valcopy_c, mcp_mutator_valcopy_i, mcp_mutator_valcopy_n, mcp_mutator_valcopy_r, MUT_REQ|MUT_RES, 0},
[mcp_mut_step_final] = {NULL, NULL, NULL, NULL, NULL, 0, 0},
};
// call with type string on top
static enum mcp_mut_steptype mcp_mutator_steptype(lua_State *L) {
const char *type = luaL_checkstring(L, -1);
for (int x = 0; x < mcp_mut_step_final; x++) {
const struct mcp_mut_entry *e = &mcp_mut_entries[x];
if (e->s && strcmp(type, e->s) == 0) {
return x;
}
}
return mcp_mut_step_none;
}
static int mcp_mutator_new(lua_State *L, enum mcp_mut_type type) {
int argc = lua_gettop(L);
size_t size = 0;
int scount = 0;
// loop argument tables once for validation and pre-calculations.
for (int x = 1; x <= argc; x++) {
luaL_checktype(L, x, LUA_TTABLE);
if (lua_getfield(L, x, "t") != LUA_TNIL) {
enum mcp_mut_steptype st = mcp_mutator_steptype(L);
const struct mcp_mut_entry *e = &mcp_mut_entries[st];
if (!(e->t & type)) {
proxy_lua_ferror(L, "mutator step %d: step incompatible with mutator type", x);
}
if ((st == mcp_mut_step_none) || e->c == NULL) {
proxy_lua_ferror(L, "mutator step %d: unknown step type", x);
}
size += e->c(L, x);
}
lua_pop(L, 1); // drop 't' or nil
scount++;
}
// we now know the size and number of steps. allocate some flat memory.
size_t extsize = sizeof(struct mcp_mut_step) * scount;
struct mcp_mutator *mut = lua_newuserdatauv(L, sizeof(*mut) + extsize, 2);
memset(mut, 0, sizeof(*mut));
mut->arena = malloc(size);
if (mut->arena == NULL) {
proxy_lua_error(L, "mutator_new: failed to allocate memory");
}
luaL_setmetatable(L, "mcp.mutator");
mut->type = type;
// Cache both request and result metatables for arg validation.
// Since a req mutator can take a res argument and vice versa
luaL_getmetatable(L, "mcp.request");
lua_setiuservalue(L, -2, MUT_REQ);
luaL_getmetatable(L, "mcp.response");
lua_setiuservalue(L, -2, MUT_RES);
// loop the arg tables again to fill in the steps
// skip checks since we did that during the first loop.
scount = 0;
for (int x = 1; x <= argc; x++) {
if (lua_getfield(L, x, "t") != LUA_TNIL) {
enum mcp_mut_steptype st = mcp_mutator_steptype(L);
mut->steps[scount].type = st;
mcp_mut_entries[st].i(L, x, scount, mut);
mut->rcount += mcp_mut_entries[st].rc;
// copy function pointers into the step so we don't have to skip
// around the much larger mcp_mut_entries at runtime.
mut->steps[scount].n = mcp_mut_entries[st].n;
mut->steps[scount].r = mcp_mut_entries[st].r;
mut->steps[scount].idx++; // actual args are "self, etc, etc"
}
lua_pop(L, 1); // drop t or nil
scount++;
}
if (size != mut->aused) {
proxy_lua_error(L, "mutator failed to properly initialize, memory not filled correctly");
}
mut->scount = scount;
return 1;
}
static inline int _mcp_mut_run_total(struct mcp_mut_run *run, struct mcp_mut_part *parts) {
int total = 0;
struct mcp_mutator *mut = run->mut;
for (int x = 0; x < mut->scount; x++) {
struct mcp_mut_step *s = &mut->steps[x];
assert(s->type != mcp_mut_step_none);
int len = s->n(run, s, &parts[x]);
if (len < 0) {
assert(1 == 0);
break;
} else {
total += len;
}
}
// account for spaces between "steps" and \r\n
// note that steps that themselves can make multiple tokens _must_ account
// for this on their own.
total += mut->scount + MIN_BUF_SPACE;
return total;
}
static inline int _mcp_mut_run_assemble(struct mcp_mut_run *run, struct mcp_mut_part *parts) {
struct mcp_mutator *mut = run->mut;
// assemble final req/res
for (int x = 0; x < mut->scount; x++) {
struct mcp_mut_step *s = &mut->steps[x];
assert(s->type != mcp_mut_step_none);
// TODO: handle -1 errors, halt.
// TODO: can we structure this so we don't have to check for errors at
// this stage, only the first one? would be nice to cut the branch out
if (s->r(run, s, &parts[x]) < 0) {
assert(1 == 0);
}
*(run->d_pos) = ' ';
run->d_pos++;
}
// TODO: any cases where we need to check if the final char is a space or
// not?
// add the \r\n after all steps
*(run->d_pos-1) = '\r';
*(run->d_pos) = '\n';
run->d_pos++;
return 0;
}
static int mcp_mut_run(struct mcp_mut_run *run) {
struct mcp_mutator *mut = run->mut;
LIBEVENT_THREAD *t = PROXY_GET_THR(run->L);
int ret = 0;
struct mcp_mut_part parts[mut->scount];
// first accumulate the length tally
int total = _mcp_mut_run_total(run, parts);
// FIXME: error handling from total call
// ensure space and/or allocate memory then seed our destination pointer.